APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 (FOUO i9J79) iS JUNE 1979 VESTNIK AKAOEMII NAUK SSSR N0. 30i979 i OF 3 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2047102/09: CIA-RDP82-00850R000100060026-6 FOR OFFICIAL USE ONLY JnRS L/8515 - 15 June 1979 TRANSLATIONS ON USSR SCIENCE AND TECHNOLOGY BIOMEDICAL AND BEHAVIORAL SCIENCES (FOUO 19/79) VESTNIK AKADEMII NAUK SSSR No, 3, 1979 U. S. JOINT pUBLICATIONS RESEARCH SERVICE - FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 NOTE JI'Et5 publications conCttin information primarily from foreign - ttewspapers, periodicnls and books, buC also from news agency traZn � o (h ) II (CH,0)2PSCHC00C2H3 3,4 - CIaCeH;,NHC IOCH3 NHC(S)NHQOOCZ* S CH2COOC2Hs CHt ( i )H�P604*C j Y12Byp�H NHC(S)vHG00CHs 0 ( k )Toncns-M _ (C2II60)2PSCH2K.._ / (CHa)eC- rI\N\Hz 0 CIis . 11 s ~ N~ _ I 0 0 Cl , N SCH' C (1 0oaaaua . (mpeaxop . . C(O)NHCJ16 . . . ( n )Hap6o1tceg ' . p (HOhry CHaNHCFizC00H ~ I CI2C=CH CQCHa- 0 CE' 0\ : (p )Pnn~OCar ~ ~Ta~urupes ~o He 7\ Cg' OCSH6 C1CH2CH'N(CHi) ,CL' ~Iep~aerpsa ( r Xnop=onsisanopaA 0 11 j~Hs a-CioIi~ CNHCH, ~p~~CIi (S ) Kap6apan ( t ) Key on following page. 35 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR nFFICIAL U5E ONLY Kpyi (a) UD'C (k) '1'npg{n-M (b) MODE[tN PE5'CICInE3 (1) Phnza1 on (c) InseCticideg (m) Zpncor (d) Nerbicideg and plunt Crowth (n) Carbnxyn Etcgulatorg (o) Permetrin (r) F'ungtcideg (p) Glyphogat (C) Mptephoe (q) Tgchtgarrn (g) D (r) ChlernChnlinrhloridh (h) zinpb (s) Carbaryi (i) Carbophas (t) Estrel (J) Linuron In 1977, che U53It Arndemy of Scienees in cnllabnration wich the U55[t Minigtry of Agriculture, the U5SEt Miniatry of Chemical Industry , and�:other dppartmentg, drew up und submitted proposgis on improving the development of sCientific researclt in the �ield of ptant protection, but up to now no decigiong hgve been made with regard to this vitnl prnbtem of ugricuttural production. It is esgential to help the acientific institutions to strengthen their bases, because they are dealing witlt a big and complex problem. Without the participation of key institutes of the Aeademy of 5ctences, this problem connot be salved, because it is esaentiel to develop effective methods of synthesizing pesticides, to study the mechanisms of thcir physiological effect, and to devetop methods of breaking t}iem down in order to prevent environmental pollution. Recently a number of in- stitutes of the Academy of Sciences and the acedemies of bCietlCeS o[ the union republics--the Academy of Sciences Institute of Urgenic Chemistry, the USSR Academy of Sciences Institute of Organoelemental Compounds, the USSR Academy of Sciences Institute of Bioorg..nic Chemistry, and the Latvian SSR Academy of Sciences Institute of Organic Synthesis--have proposed for practical use a large number of pesticides (alvison, EOS-117, phenazon, dextramin, oxyamin, toluin, and others) that will undergo scate testtng. A number of academic ins[itutes are working out highl/-sensit!:I. methods of determining residuat quantities of pesticides. So far, howcver the path from the scientific development of e pesticide to its adoption in agricultural practice has been thorny. The herbicide alvison, Ior exaMple, developed by the USSR Academy of Sciences Institute of Organic Ctiemiscry in 1965, has not yet managed to go [hrough state testa because of depart- mental conflicts. It must be pointed out that most pesticides are developed as a resulc of empirical investigation. But this method is costly, because ic requires masg syrthesis and rnass testing, and according to world statistics an average of only 1 out of every 10,000 compounds finds practical use. it is necessary to develop the scientific principles of the deliberate synthesis of pesticides having specified biological properties. This kind of work is beinp, carried out sur.cessfully by the U5SR Academy of Sciences Institute of Organoelementel Compounds in collaboration with 36 FOR OFFICIAL U5E ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOlt dFFICtAL U5E ONLY Chp U55it Argdemy of 5c:ienceg Inatttute binchhmigtry frneni I. M. 5echendv, the and the Uxbek 55Ct Academy of 5cienceg of Evolueinnary phyginlogy gnd Ingtitute of Uidorganic Chpmtgery, Ingtieute of Zddldgy and raragitology. Cndd prospeetg fdr agriculture are td bc fdund in the une of phygtdtogicatiy active gubgtanreg encauneered in naturh whirh regulgtp the grnWtki and bp- hgvcnr of animalg. 'Chege might be termed third-genpration ehemiral pest!- cideg. Fdr example, very ldw Cnncentratidng of pheromones (sex attraceantg of high gperlfirity) nrp rnpable dE attracting ingeetg nver grent digtanGes. The relativp gimpltcity of their Chpmical makeup makeg it pagy td syntheaize thpm and use them piehee wieh or aithout contdCt tngpGticides by ecting on inspet pnpulationg (digorienting them). At pregent, pheromanes and eheir analogueg are being gUcC(?HsCULLy used in other cnuntrieg. (a) I08EHZ4JIbHLIE LI AHTNtOBEHHJIbNbIE POpMOHbI CHi CHs CNI 0 R CNi CHi CNo 0 CHi / Ni CH~ OB' (b) 10eerttnbueci ropuoa uecexowtt: A-N, H1480-C,Ht: R+�OCHI, R'��Cj+ ~ C~ Ciinretaaocxno ~BanorN aeeguatiaoro rop~tou Amepmu u Ap. (1972 r.) OCH, CHIO Q0 CHe I ~ CHo cH,o o cH, c~o cH, A22"msagnAbaue ropwooti ( d ) (opwcoqeau) Key: (a) JUVENILE ANb ANTIJUVENILE HOEtMONE5 (b) Juvenite insect llormone (c) 5ynth,,tic Analogues of Juvenile Normone (Jerassy et et., 1972) (d) Antijuvenite 1{ormones (Precocens) Also of great interest are analogues of the juvenile hormonep which breaks up the normal course of development of insects and sterilizes ma[ure specimens; at present n number of countries have started the production of certain analogues of juvenile hormones. Both in the case of pheromones and juvenile hormones, the research being done in the US5R is lagging far behind research In foreign countries. In particutar, research is going too sloaly into the chemical nature of pheromones, and field tests of promising hormone compounds are delayed because of the lack of semi-Industrial production of them. And although 37 FOR OFFICIAL U5E ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOtt flFFIGIAL USH ONLX 80t11@ ACBdEmiC aitd gpcEdC iriatiCUCEs haV@ recently gteppEd UN regearch pfEortg along chpse lineg (the US5R Academy dE 3eihncen ingtitute of Evolutionary Animal Morphology and Ecology imeni A. N. Sevrrtgdv, the USSR Academy of Seipncee Siberian Depertment Ndvosibirgk institutp of t3rganiC Chemiatry, end others), the weak matertel base of these eEEorts make8 it lmpoggibtp to aetain the npspagary 1evp1. It is alsn very important tn aork out a bioldgical meehnd nE controlling Eerm plant pe$es. 'Che U3SR Acedemy of 5cience$ and and aeademies of gCi@t1CEg of the unien cepublicg mugc examfne pnssibilitips Cor expanding thp Erant of scientiEic resegrch in this problem. It haa been stated that a vital rondition Eor regolvtng the problem of peatieides and other regulatore of groNeh and developmpnt in plantg and Animalg is the Eormulatidn end implementation of a prepared warka prdgram. Naturally, this progrgm catts fdr shgrply stepping up EffbCts along thesp - linea in our arademy, thc intensification of research in pxisting ingti- tutea and labnratoripe, gnd thp rreation of new scientifiC colleettveg. in particular, recenely thp new U3Sk Academy of Scienceg Institute of Physiologically Active 5ubstancea was set up near Moscow= one of itg main research thrusts is the synthesis and study aE new p@sticides and pheromonea. Plang ralled Eor setting up a nCw ecademic inatitute of chemical-biologicai profile in Saratov, which will deal With the tasks of farm produceion on the basis of fundamental theoretical research. However intensively and successfutly it develops, however, scicnce by itselE cannot resolve the pescicidp problpm. For this reason, a Eew aords should be said about sn-called " smali-scale chemistry." This field, Eor which a suitable designation has not yet been found, ia supposed to be engaged in the production of reletively complex and very vital substances--low-tonnage and costly produccion which Erequencty changes assortment--that which is called in English "fine chemical industry." In our country thia field is lagging badly; it has riot worked aut its own ideology, has not found its own paths and solutions. Yct this industry--"small-scale chemistry"--must deal with the produccion at pesticides. We are aiso not producing enough medicines (cheir assortmerit is about five times less than ahat is needed), and we are not prcdl, ii�� enough new semisynthetic antibiotics and synthetic hormonal subst:incc , including those necessary for agriculture; we do not have enough reaqrnts for color and self-developing photography, various stabilizers, anci- knock compounds, inhibitors, and so on. The situation ts very bad With regard to the production of chemical reagents and biochemical c:)mpounds for scientific research. And in all cases, one of the chieE reasons is the Weakness of "small-scale chemistry," which we might just as aell calt "small" in the literal sense of the word. It seems to us that this pro- blem deserves prompt discussion on the highest levels; it requires thc creacion of a new sector built on the basis of relatively small, mobilc enterprises with modern equipment that are similar in nature to exprrt- mentel plants. Such enterprises could be set up within che syscem of " special main administrations in the USSR Ministry of Chemical Industry 38 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FdR OFFtGtAL U5E ONLY and ehp Mgin Adminigtratidn nt hlicrdbinlagica1 Induatry dr in ehe frame= aork of gseparate dppgrtment. In rnhnectinn atth thig, it ig degirable td atrengthpn and modernizp thp pxpeetmental base of the corregpdnding aeademfe institutes, bringing it up eo the levpl dE ehe bese seieneifir enllpceives ouch an the Ldtvian 5SR Arademy of Sei@ne@s institute of Orgdflic Synehesis in Riga, the Armenian SSR Acgdpmy of 3eienrp# InatiCUte of Organie Chemigtry in Yerevan, or ehe Ukrainian 99tt Acedemy OE SCi@flC@6 Physieal-Ci!P!nieal Ingtitute ifl Odl9gd� Thp prdblem of "M11-gCa1e ehpm- isery" in our country reust bp resolved promptly and thdroughly. The FplClg Bage, `Cn imprave the lpvel and quality of lfvegtork nuteition it i8 essential eo resnlvo problems rel8eing tn ehp addption of fu11-vatup diets whieh arp balanred in termg of eheir amino acid, vitamin, and mineral com- position, includtng gyflthetie mineral and orgnnic BUbgtatlCeB� Ac pf@gpflt, the 9tatU6 of the feed# base is unsatigfaetory Qither in terms of quantity dr quality. Egpeciglly urgent is the problem aE feed protein, which can bp largety rpsnived tn the Euturp by ghgrply innreasing the productian of cnrn and grain legump$, expanding feed grags ptantings, and improving methadg of proeuring hAy, haylape, and gilagp. In this case, hoWpvQr# the ghortage must be made up throijgh thp indu$trial productinn of feede in the Eorm of minprgl feed additivps and feed yeasts. 'Chanks to the efEorts of ehpmises, btologigtg, and tivegtock experts in rpCene yeara the USSR has creatpd a nea chemieal industry--the Eeed phos- phate industry. Ae present the research institueeg are Working out pro- cessea for producing rompiex faed componpnts containing several plpmenta of animal nutrition, Eor example phoephates and polyphoaphates of car- bamide, sodium, and magna.sium, with trace eiements and physiologically activp gubstances. At pregenc, houevpr, tivestdck farming demandg for Eeed phosphates are not being fully met. In addition to mineral feed additives, the lacking protein cen be supplied to agriculture in the form of feed ypasts and other products of micro- biologicgl synthesis. The task of the microbiology institutions is to provide the theoretical principles of the technology of producing in- expensive Eeed protein. The scientiEic and technical conditiong for pro- ducing microbial protein on hydrdearbons have bpen explainpd. A major contribution to this problem Was made by the U55R Academy of Sciences Ititscitute of 9iochemistry and Physiology of Microorganisms in Pushchino. Production is already underway in the USSR. HoWever, U5SEt Academy of Sciences institutes will have to coltabarate with industry in setting up eEEorts to create eEfective technotogtes for synthesizing microbial pro- tein on hydrogen, organic: acidsl and alcohols. It is also essential to step up research and technological expertmencation in the firld of pro- ducing and using various kinds of vitamins. Problems of plant physiology and photosynthesis. largely depends on the plant's ability to use the Cenerally, however, less than one percent of the 39 FUR OFFICIAL U5E ONLY The aize of crops sun's radiation. physiologicelly active APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR OFFtCIAL USE dNLY radiaeian in utilized; plgnt phntdsynthegig produceivity cnuld be gharply increased by gelpr,cint Edrmo having the mose active chloroplaytg, xnd ulgo by modifying ehe geneeic apparatug whieh eantrolg phocogynthesig. it t$ alaa very impaYeant tn dett-rmine ehe magt Egvorable photogynthesig cnndi- tidng Eor paeh crop, to hvalunee agrotechnical factorg prdperly, td de- termine optimat cnncentrations of carbonic acid, ard su on. in addition eo thdraugh theoreticQl work in ehe study of ehe physiaal and Chpmical principlea of photosynthesis, ehis resparch mugt play a vital role In re- solving the problem of improving plane cultivgtion praductivlty. It ia esgpntial, moreover, thgt thp apprdpriate ingtitueeg of r.hp U5SEt ACgdemy of Scieneps nnd the republiC academiea dpal with thear probtems more effectivply. The ahalp romplex of plant physiology regegrch, including problema of plant rddt nutrieidn, trgngport of gubgtances in ehem, and problpms of regpirgeion and resiseance eo diseages, ere of viegi importence in in- fluencing plants and rontrolling their development; they are of crucial importanep in correctly forecasting Crop yields. Mention must aigo bp mgde of the importance of work being done to find the optimat conditinns of raising plants in hothouses, because excellpnt resultg can be achieved in this way. By way of example, let me cice wdrk being done in raising tomatoea in the USStt Academy of Sciences Institute of plant Physiology imeni K. A. Timiryazev. In plant physiology research, increasing impor- tance attaches to modern methods, including the use of cell and tissue cutturea, and this approach is being taken auccesaEully in the U5SR Academy of Sciences Institute of plant Physiotogy, the US5R Academy of Scienees Siberian Departmpnt Siberian Institute of Plnnt physiology and Biochemistry, the Ukratnian S5it Academy of Sciencea Institute of Botany, th.^. Tadzhik SSR Acgdemy of Sciences Institute of Plant Physi- ology and Biophysics, the Georgian SSR Academy of Sciences Institute of Plant Biochemiatry, and other centers. These efforts deserve Eull support. Problems of genetics and selection. The adoption of new varieties nnd breeds of higher producrivity and better quality constitutes the main course of intensification of farm production. Our science deser~_,s a lot of credit, and in connection aich this mention musc be made of thc outstanding Work being done by academicians P. P. Luk'yanenko, Pustovoyt, V. N. Remeslo, N. V. Tsitsin, M. I. KhodZhinov, and many others. But continued efforts must be made. In the future, farm pro- duction must be based chiefly on continuous replacement of varieties-- every fivc to seven years. First of all, this will make it possible to rapidly and fully realize the latest advances in the science of selection and genetics; secondly, diseases and pests Will not have time to regroup and form populations adapted to the new varieties. Of great importance Eor agricuiture are methods of modern genetic selection worked out by scientists of the US5R Academy of Sciences in collaboration with scien- tists of VASKhNIL, among which special attention should be paid to experimental and natural mutagenesis,polyploidy, genetically regulaced heterosis, and remote hybridizatiqn. 40 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FdIt dFFICIAL U5E dNLY 'Che uge of thege methudg hns made it pogsible to introduce n numbpr of varietipg intn produceinns Grhkum-114, a wheat-qUgCICgYllgg spring wheae hybrid, Start wt.nter rye, nnd dernHtayuehchgyg-38, a whent grain feed, all develnped in thp Mgin gotanicnl Gerdpn of rlie U55tt Acndemy nC Sc:lencewi Novasibirskayn-67 spring wheat, drvelaped by thp USSR Academy of Sciences Siberian Department Ingtieute ot Cyeology nnd GenetiGS; the Vegna vgriery of early potatn developed in ehp tlSSR Acgdemy of 5CietlCeg Ingtf.tuCe of Cenpral Genetics; end varieCieg of wilt-resistant 'Caghkent cotton dpveloped in the U2bplt SSEZ ACAdEl11y OE SCiEt1CC9 Institute of Experimental Bidingy. Also undprway is the producCion prdpggaCion aE n muCgnt varipty dE highly produeeive semi-dwarf winter wheat, Kiyankn, developed by the Ukrainian SSR Academy of $ciences InsCiCute of Mnlecular Bioingy and Genetics. New, highly-productive varieties of wheat, bnrley, and tobaccn have been develppd in thp USSEt Academy of SCiencpg Institute of Chemical Physics by the method of chemiCal mueggenegis; they are now undergoing sCaCe vnrieties CegCing. It is also necesgary to emphasize the impnrtance of work in remote plant hybridizaCion. Interspecies hybridizetion makes it possible to create new forms not found in the plene wnrld. Such, for example, is the new crop Triticale, developed by crnssing whege with rye. Triticnle succegsfully combines wheat's high protein COflt@ht nnd rye's high lysine content; Che crop yteld runs as high as 100 to 120 quintals per hectare. It is adapt- able to severe conditions such ag cold, sandy end acid soils, and rust. In 52 countries, Triticalp occupies land totgling about 400,000 hectares; the main centera of cultivation are Mexico, Canada, the United States, and Ethiopia. In the US5R, rye-wheat hybrids were Eirst developed by N. V. Tsitsin in the 1940's. Dut varie`ies of Triticale have been subjected to extensive state testing only recently, thanks chieEly to efforts of the Ukrainian Institute of Plant Nusbandry, Cenetics, and Selection. It would be desirable to intensify these efforts in the institutes of the USSR Academy of Sciences, in order to develop forms of Triticale that are not only highly-productive but also meet agrotechnical standards. No less important is selective breeding and genetic work in livestock farming. Thus, the interspecies crossing of small, low-milk zebu with milk and meat br�ieds of cattle has made it possible to develop hybrids of up to 450 kg live weight which are resistant to various kinds of diseases and are distinguished by high productivity. Such work is underway in the Main Botanical Garden of the USSR Academy of Sciences, the Azerbaydzhan SSR Academy of Sciencas Institute of Genetics and Selection, and the �Georgian SSR Academy of Sciences Instituce of Zoology. The work of the USSR Academy of Sciences Siberian bepartment Institute of Cy[ology and Cenetics on hybridizing domestic swine with wild boars has made it possible to substantially improve the meat qualities and vigor of the hybrids. Unfortunately, we cannot yet say that this work has been widely adopted in praccice. Mention should also be made of mutagenesis. This is a very powerEul method which yields excellent results. Radiation mutagenesis has played a vital role in developing new varieties of wheat during the "green 41 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOit OFFICIAL USE dNLY revolution." -Chemicgl mueageneaig hgs glso become effecCive. Mention should glso be made of work being done in this field in the USSEt Academy oE Sciences InsCitute of ChemiceL Phygicg and the UkrAinien 531t ACademy oE SGiencea InsCiwCe of Mdlecular Btntogy nnd Cencttcs. 'Chr wlde pruc- r.icnl. adoption of the Elndinga of thesc lnsefturus wltl uiidnubrrdly ylt-lci subgtantial economic efEeCe, and the nc:ademies oE setencps must collabnrnte with the appropriate departmentg to speed up rhe proepss. New Varieties of wheat developed by means of modern methods of genetic selection (on the left, Novosibirskaya-67, on the right, Mutant-404). Triticale--a new farm crop developed by crossing wheat with rye. In connection with the tasks of agriculture, we will focus on new dtrections in biology. New discoveries and advances in biotogy and the appearance oE powerful methods of enalysfs are capable of revolutionizing agricultural science. In cases where such approaches and methods are adopted rapidly, results are not slow in coming. In this regard, the academic scientific institutions are making a large contribution to the intensification of agri- culture, and this contribution will continue to grow. 42 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 rdit nFFICIAL USL' dNLX Speaking in Alma-Atn in 1974, CC c:p5U Cenergl 5erreCary.and.U55lt 5uNrame Snvier Presidium Chgirman Comrade L. I. Orpzhnev said; "AgriculCUre needg new ideag capable of revolueidnizing agricultural production, it needg thp congCanC inElux of fundamentgl kndwLedge prnvidnd by binchemigtry, genetice, and molpculnr biology cdncprning the nature of planes and animals." Abdve a11 it is necessury en wnrk out npw technnlugies of 5p1ECCivE brepding in the shortegt pogsible time, based on the broad use, et gll BCAgE'.9 of selection, of madprn edvgnces in biochemistry gnd mdlecular genptics, alao mathematical analysis. Up td now, for example, selection has not made ade- quate use of polymorphous proepins as merkers of gcnes or blockg of genes controlling the variabiliCy of economicatly vnluable traits. E;xperiments carried out in VASKhNIL's All-Union Institute of 5plpceive 8repding and Cenetics have shown that e number of wheae and barley chromosomes mgnifest the phennmenon of multiple allelism of blocks of componentg of prolamines. It has been found that combinations of ehese blocks correlate eo the qual- ity of the grnint resistance Co frast, resistance to diseeses, and other propereies. This makes it possible nn the basis of the genetic formules of the proeein-prolamines, formulas based on recomputation of variants of blocks of components of proCein of the line or vuriety under atudy, to judge their genotypically determined properties. Of great practical importance now is molecular-cytogenetic research into the linenr differentiation of chromosome structure. 5uch reseArch was uncil recently dismi.ssed as merely "academic." Thanks to microscopic determination of structural heterochromatin it has become possible to identify the chromosomes of the most important farm crops. It has been found that each variety of Triticale, wheat, and barley posseas a specific karyotype, its own unique combination of morphological traits of the chromosome set. This opens up completely new possibilities for accelerating work in genetics and selective breeding based on the use of Gheoretically long-Eamiliar methods of chromosome engineering--that is, the ciliberate designing of karyotypes having an optimal, preselected erray ot chromosomea. In conneccion with this, great interest attaches to the Morfokvant instru- menc, developed by the USSR Academy of 5ciences of Biological Physics in collaboration with the GDR's Karl Zeiss Jena VEB. This instrument makes it possible in 20 minutes to plot the karyotype (classiEication chart of the set of chromosomes) of plants, animals or humans. It is, however, necessary to develop simpler and cheaper instruments for chromosame analysis. Recent years have seen the intensive adoption of several fundamental and technical advances in embryology and developmental genetics in live- sCock practice. Specialists have worked out new methods of animal re- production based on the manipulation of egg cells and embryos. In principle these methods make it possible in a short time to increase 43 FOR OFFICIAL USE OYLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt OFFICIAL U5E tlNLY herds of valuable breedg dE farm animals. 'I'he nature dE the eech- nology nonsistg of the fact ChgC by means of hormonal tregtmentx tt Is possiblp to ebtain up to 60 embryos per year inseead of juse one nr two Erom a gingip pedigree female. They can ehen bp implaneed i.n non- pedigrep females, rhus obtaining 20 to 30 calves per sCasdn frnm a gingle cow. Techniques have been developed for freezing embryoe Eor gtorage and transport. All of this taken eogpther hag Created the base Enr sharply increaging the pEfeCeiveness and the pere nE ppdigrec work on the one hand, and for further, more delicate manipulations with farm gnimal embryos and their genetic apparatus, on the nther. Although today's achievements in this regard are just the beginning, and atthough wp are still dealing with relatively simple manipulations, researcli ls proceeding very rapidly, and its adoption in practice promiges to yield enormnus economic effpcts in livestock raising. There are firms edopting CheB@ techniques in livestock farming in the United States, Canada, Great Britatn, France, Australig, gnd New Zealand. A num- ber oE speciglized scientific centers gre engaged in further research to create the prerequisites for morp refined manipulations with egg cells, embryos, and their nuclear apparetus. The adoption of the latest advances of cell biology and molecutar genetics now underway in this field opens up broad prospects for resolving such pro- blems as sex cloning, genetic manipulation, and so on. A program oE [unda- mental work in this area is in preparation now by the USSR Academy oE Sciences in collaboration with VASKhNIL and other departments. Of great interest to animal husbandry are the proscaglandins, thanks to their high and variegated physiological activity. ProscAglandins are a group of related lipids that are widely dispersed in animal tissues, where they evidently serve as mediators of hormonal action. There arc three basic ways to use prostaglandins: enhencemcnt of the efEectiveness of artificial insemination of farm animals, synchronization of t}ieir sex cycle, and artificial ab ortion, which is essential in certain par.tio- logical situations or, for example, in obtnining karakul. In the near future we can expect the massive usE of natural prostaglandins and syn- thetic analogues of them in livestock farming; this should yield sub- sCantial economic effect. In our country, work on producing prostaglandtns and using them in livestock farming began only recently and is proreeding very slowly, although in other countries, in particular the United States, prostaglandins are produced by industry and are beginning to be used in agricultural practice. The mass use of prostaglandins in livestock Earming requires methods of full chemical synthesis characterized by technological and patent purity. Successful work is being done in the Latvian SSR Academy of Sciences Institute of Organic Synthesis and the USSR Academy of Medicat Sciences Institute of Endocrinology and Hormone Chemistry. 44 FOR OFFICIAL USE ONLY  APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 , ~ , t pH , 1 . COOH DH (b) nr F,, (e) CMHna npocrRnIHAHnoe no KopN (flf F,r)  Key: , . ( g~ ~ 8 MANA FdR dFFICIAL USE dNLY _ " . npocTA rnA NAH14 w : COOH / HO CHs ( c )11�.e3ox~oK ~~e~T nr e, 0 ( E) 8 ctIANA HO CN2OCH2C&N& (a) pROSTAGLANDINS (b) PG E2cc (c) il- desoxy-l5-methyl-PG E1 (doxaprost) OH , ..~r 001 OH OH CI ( d ) 9xctpywAt � OH coo OH OH (d) Extrumat (e) Synthesis of prostaglandins after Cory (PG F2 d) (E) 8 stages The Interdepartmental Scientific-Technical Council for Problems of Molecular $iolopy and Molecular Genetics under the State Committee Eor Science and 'Cectinology and US.hR Academy of Sciences Presidium has set up a Prostaglandin Program participated in by nine institutes in various departments. It is essential to expand the Eront oE research in thts vital agricultural problem. Large prospects in plant husbandry and possibly livestock farming are to be seen in methods of tissue culture, somatic hybridi2ation, and genetic engineering. In partfcular, the U5SK Academy of Sciences is broadly de- veloping research in subject matter relating to genetic engineering. Altering the fine struc[ure of nucleic acids and replacing some genes with others in a broad systematic range can revolutionize selective breeding, lead to the creation of completely new forms, and open up possibilities of programming Che form-physiological characteristics of organisms. Also in the oEEing are such experiments as restructuring the genetic apparatus by "shifting" genes from one organism to another; this is already being 45 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOit nFFICIAL USE dNLY done with microorggnisms. Such wnrk ig being narried out in a number of institutea of the US512 Academy of Scienceg, and iC must be intensiE'ied. Etesparch in molecular biology and molecular genetics constiCuees nne nf Che cornerseones in Coday's biology, and consequenely it is an egsential basis for gcientific agricultural oppraeion. Bue such research requtres that the institutes be prnvided with modern scientific equipment and re- agents. Our indusCry, howpver, is not yet providing enough inserumenrs or reagenCS. A CC CPSU and USSR Council of Ministers decree on moleculnr biology and molecular geneticg in 1974 called for measures to develop SovieC scienCific instrument making. Scientific and design organizations of the USSR Academy of Sciences and certain other departments have de- veloped a number of instruments meeeing today's high stgndards, but the organization of series production of new equipmenC has run up against un- surmountable difficulties. The Ministry of Instrument Making and a number of other departments which were supposed to instieute the production of such equipment do not have available prodtiction capacities; meanwhile, consCrucCion has not begun on a single instrument making plant as stipu- lated in the decree. As a result, the USSR Academy of Sciences has been obliged to begin the construction of its own plants in order to resolve the problem at least partially. It seems to me that the problem of carrying out the CC CPSU and the USSR Council of Ministers decree 1Measures to bevelop Scientific Research in Molecular Biology and Molecular Genetics and usei-their Advances in, the National Economy" requires special discussion. This decree has brought enormous benefiCS to our biology and our science in general; it has made it possible to take the lead in several directions of biology and pro- gress in many areas of agricultural and medical practice. The storage and processing of agricultural products. The problem of reducing losses of farm products during transporting, storage, and pro- cessing was urgently raised at the November 1978 CC CPSU Plenum; it was the object of special attention in the speech at the plenum by Comrade L. I. Brezhnev. With regard to the development oE new technologies for storing graiii w,d other products, one promising direction is the use of special acceleracors capable of detoxifying grain products rapidlyr chieEly by rapidly breaking down pesticide residues. The first models of such accelerators are already in operation, and further research needs to be done. It is also necessary to perfect drying processes so as to determine in each specific case, on the basis of detailed study, optimal, sufficiently mild and at the same time effective operating conditions which will not harm the germination of the seed, the quality of the protein components, and so on. Mention musc be made here of the work of the USSR Academy of Sciences Institute of Bio-- chemistry imeni A N. Bakh; this institute has developed methods of activr ventilation for the storage of potatoes and vegetables. The USSR Academy of Sciences lnstitute of Petrochemical Synthesis has proposed semipermeable polymer film which is very effective in controlling the gas mixture in FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 Fox orrYCinL usE ONLY sCnragp feClliCieg. A number dt instiCUeeg of the Ukruinian SSR Academy of Scienceg in collgboraCintt wieh the ScienCiEtC-RegearCfi Ingtitute of the Sugar Indugtry of the Minigery of Fond industry tieve workcd our a new meehod of storing sugar beees. MenGion should also be made of the necessity of developing high-speed autn- matic mprhods of evaluaCing and mnnitoring the finishpd prnduct: the tevel of protein, toxiciCy, weed infestaeion, and sn on. Many of Chpse operati,ong are now carried out by hand, although it would be best to use new methods involving compueers. MeehanizaCion end automgCinn. In terma of ehe production of tractora and Earm machinery, our country holds first placp in the world. Neverthelegs) the fleet gnd nompnclature of trectors and �arm mgChinery ia sti11 inade- quate Co provide integrated mechanization of all agricultural processes. For this regson, it is essential to furCher boosC the productive potential of the machine building industry and ta substantially improve Che quality of the equipment being produced. These are especially urgent prnblems be- cause of our agricultureals unfavorable labor sieuatinn. There are many problems which have not yet been resolved by rhe agricultural machinery industry: increasing the durability and wear-resistance, using tlle latest methods of disgnostics, using rew materials and caatingqq using more effective sysrems and components, manipulators and robots, reducing the consumption of fuel and lubricants, and so on. The amount of inetal used in making our farm machinery, as a rule, is subsCantially greater then in foreign models. Some kinds of farm equipment, in particular many Cypes of combines, are too complicated and are not equipped with standard, easily interchangeable components; as a result, repair costs exceed per- missable normatives. In terms of convenience, controls, and comfort our tractor cabs lag behind similar models of foreign make. It is essential to Eind solutions to problems of inechanization and auto- mation of processes of transporting, storage, and processing of farm pra- ducts. This involves the development of automated plants to process grain and produce combination feeds, improvement of systems of in-plant transport, and, finally, the development of more effective technologies in the mil.ling of flour and the manufacture of combinaCion feeds. Many problems that have not been resolved within the agricultural machinery industry frequently turn out to have been solved in other machine building sectors, and this experience ought to be utilized. However, the extensive dissemination of this experience and the application of the latest advences of science and technology, it seems to us, are hampered by the lack of a base institute within the USSR Academy of Sciences to deal with problems of machine building, a base capable of coordinating these efforts and directing them, in particular, into widespread use in agriculture. Very likely such an institute ought to be organized in the near future within the USSR Academy of Sciences. 47 FOR OFFICIAL USE ONLY l' ` APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR oFFicIat, usE OrrLY Agricultural economicg. 'Che denree of the July 1978 CC CP5U rLenum nneey the necessity of Eocuging aCCenCion on problems oE agricultural economicy, of improving the efEectiveneas of prnduction and reducing product prime cogt, on perfecCing eednnmic rplaCions amnng aectora o[ the agroindustrial cnmplex. Ae present, the process of forming this Complnx is proceeding wiChout adequaCe gcipntific gubgtanCigtion; for this rpaqon, there is a clegr 1aclc oE balance in its development. In particular, most of the workers employed by the agroindustrial complex are involved directly in agriculture. They amount rn 61 percent of the toral, while only 7 percent are engaged in the produceion oE industrial means of production, and 32 percpnt are engaged in Cransport, storage, processing, and the sale of finished goods. This distribution cxnnot be considered optimal. InstituCions of the USSR Academy of 5ciences are collaborgCing with insti- tutes in oCher departments on importanC reseaxch in the field oE the eco- nomics of agricultural production and, in particular, they are eaking part in formulating problems of the future ngroitidustrial complex as stipu- lated in the integrated program of scientific-technical progress. But it is worthwhile Co examine the question of strengthening the corresponding subunits in the key economic institutes, including in the union republics and the scientific cenCers of the Urals, Siberia, and the Far East, so that the contribution of the USSR Academy of Sciences can be substantial. Very large problems will have to be resolved. In particular, the problem of labor supply is extremely important to the development of the agricul- ture in many areas of the country. I should also like to emphasize the necessiCy of fundamentally improving forms of organization of laboc nnd wages for workers fn agriculture and related sectors, also resolving a large number of tasks of a social nature. One serious problem is price formation on farm equipment and spare parts. We can state definitely that the rasolution of these problems will largely determine the effec- tiveness of farm production in our country. It is hardly possible to cover all problems relating to scientific- technical progress in agriculture and the application of fundamental scientific advances in this area. But we may already conclude that the problem we are discussing today is unusually complex and is of priority importance to our state. For this reason, the USSIt Academy oE Sciences must step up its efforts along these lines; it must above all strengttien its own ranks, refine and coordinate the thematics of its work, lay down the exact time tables for carrying the work out, and strengthen thetr base in the corresponding institutes of the USSR Academy of 5ciences and the academies of sciences of the union republics. In order that the dis- cussion at this session may lead to specific results, we propose that the works program of the USSR Academy of Sciences "Scientific Principles of Agriculture" for 1975-1985 be approved and that the work being done in the program be given priority importance. In the long run this document must reflect the development of the basic directions in science for the sake oE agriculture, with the participation of institutes of the USSR Academy oE 48 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR OFFICIAL USE ONLY Sciencas, the USSR Minisery of Agriculture, VASKhNIL, the Minisrry of Chemical Indusrry, the Main Administration oE Microbinlogy IndusCry, and other deparCments. A preliminar,y variant of this program hes been worked ouC with the parCicipation of departments of the USSR Acndemy of Sciences and is kept in the USSR Academy of Sciences Presidium. BuC the acrual problems and tasks must be made more specific. The program should not incorporaCe all possible problems but only the mose import.r.nt economic problems in which the contribution of the academic institttions can be decisive. It is also advisable to provide f or a special system to co- ordinare and control the research incorporated in the program. In addiCion, it is advisable to specially earmark appropriations for the agricultural works program and provide for priority financing of the most important projecCs and problems. As a result of implementing such a pro- gram, undoubtedLy, the USSR Academy of Sciences will make a subst+antial contribution toward boosting agriculCure in our country. Both in spirit and in coneent, such a program will be consistent with the decisions of the November 1978 CC CPSU Plenum, at which Comrade L. I. Brezhnev said: "Fundamentally new scientific ideas and technical solutions, the concentra- tion of efforts on key problems of the development of the national economy-- these must be the focus of the efforts of our scientists, the USSR Academy of Sciences, and the State Committee for Science and Technology." Members of the USSR Academy of Sciences assuxe the CC CPSU, the Soviet government, and CC CPSU General Secretary and USSR Supreme Soviet Presidium Chairman Comrade L. I. Brezhnev that our country's scientists will exert all their creative strength and knowledge to resolve the big tasks facing our agriculture; they will accomplish new goals in developing fundamental science and using its advances in practice; they will gratify their great Homeland with new discoveries and accomplishments for the good of our people, for the sake of peace, progress, and happiness on earth. 6854 CSO: 1870 49 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR aFuzciai, usE oxLY UDL 630=1 TASK5 0F AGI2ICUL'CURAL SCIENCE IN LICHT 0F TNE UECISIONS 0F TNE JULY 1978 CC CPSU PLENUM Moscow VESTNIK AKAbEMII NAUK SSSR in Russian No 3, 1979 pp 43-53 [Eteport by VASKhNIL President Academician P. p. Vavilov] [Text] Our party is focusing consCant eCtention on the country's agriculture end scientifir regearch in this sector end manifesting constant concern for its development. New prooE of this is seen in the report by CC CPSU Cencral Secretary and USSR Supreme Soviet Preaidium Chairman Comrade L. 2. 8rezhnev at the July 1978 CC CPSU plenum and the decisions adopted there. Pormulat:on of the multiple problems of accelerating scientific-technical progress in agriculture has become so urgent that it has become necessary to focus the efforts of scientists in a variety of scientific disciplines in this direction. We face the task of subatantially boosting che effectiveness of scientific reseqrch thet will assure progress in agri- cuttural development. The resolution of this task in the near future will be the focua of research work of both agrarian scientists and scien- tists in many other specialties. I will dwell on several problems of agricultural science in light of the decisions of the July 1978 CC CPSU Plenum. As is well known, the development of new varieties and hybrids is a power- Eul means oE upgrading the effectiveness of farm production. In recenc years, academicians P. P. Luk'yanenko and V. N. Remesto, VASKhNIL Aca�f"- mician D. A. Dolgushia, VASKhNIL corresponding members 1. Ya. Kalinenko and Yu. V. Puchkov, and others have developed and adopted in agricultural practice such high-yield varieties of winter wheat as Mironovskaya Yubiley- naya, Odasskaya-51, Oneprovskaya-775, Krasnodarskaya-39, Severodonskaya, I11'ichevka, and many others which under high ctopping techniques yield 60 to 70 quintals of grain pcr her:tare (more than 80 quintals under irriaation). In 1979, win[er wheaC varieties with shortened stglk will go into production; these are known as semidwarf, are not subject to lodging, and have a poten- tial yield of up to 100 quintals per hectare (Polukarlikovaya-49, Odesskaya 50 FOR OFFICIAL USE ONLY (A _ APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR tlFFICIAi, USE ONLY pnlukarlikaveya, ddeaskayu-75, and Mironnvgkayd Nixkoroalaya). VASKhNIL Academicinn p. P. Carknvyy ig Cnmpleting wnrk nn the devetnpment nf new, lndging-rhgigtane varieties nf 3pring barley, inrluding gix-row varieties wiCh yipldg of 60 Co 70 quintnlg per hectare. For exnmpte, thp gix-row bnrley varieCy pallidum-90 nn thp Dondixhnn SCdCe VarieCiee Testing plot in Moldgvia chig year yielded 82.8 quinCalg nE grgin ppr hecture, eur- pessing the zone adapted varieties by 17.4 quineals. On the bggiS of ehe mutant YeM-i, ehe Bdghkir Scienrifin RpgBflrC}1 IM- gCituee nf Crain Farming fnr the Eirse time prnduced the ghore-sCalk winter rye variety Chulpgn, and the All-Union ItlgtitUtE of Plant Nugbandry produchd the Mglysh-72; the gtelk in Chege varieties in twice ag ,hore as in the older varieties--thcy nre practicallv invulnernble tn lodging and have potential yieids of 50 to 60 quintals per hectarp. Selective breeding of spring wheat has become considerably gCtivated. Ite- cent years hnve seen the zone-adgptation of highly-productive varieties of rhis crop such as Saratovskaya-46, Sarntnvgkaya-52, Tselinnaya-20, 5ibiryachka-4, 0 mskaya-9, and others. L Breeders have developed millet varieties cheracterized by high panicle grain content and resistance to diseases producing yiclds of 80 to 90 quintals per hectare. In recent years they have developed ricp varieties with yields as high es 100 quintals or more per hectare. Thus, the new variety 5palchik on the Krasnoperokopsk Varieties Testing Plot in Krym- skaya Oblast in 1977 yielded 109.9 quinCals per hectare, while the Solnechnyy variety on the Kharabati Varieties Testing Plot in Astrakhan- sknya Oblast yielded 95.5 quintals. Advances have been made in the selection of corn, sunflowers, sugar beets, cotton, vegetables, and other crops. We can state with conEidence that in the selection of a number oE crops our country holds a leading place in the world. But the present level is by no means up to current production requirements. It is sufEicient to note that thrce varieties of winter wheae--Mironovskaya-808, Bezostaya-1, and Odesskaya-51--occupy about 70 percent of all areas planted in this crop in the US5K. These are unquestionably good varieties, but even ~ their extensive adaptive capabilities are not able to assure maximum crop yields given the considerable variation in soil and climatic con- ditions in zones where they are cultivated. Practically all varieties of winter and spring wheat are susceptible to such diseases as stem and brown rust, root rot, powdery mildew, and others. The situation is especially bad with respect to heterotic selection. We da not yet have in production sunflower hybr.ids and sugar beet hybrids based on cytoplasmic male sterili[y; we have a limited array of highly-productive early-ripening, medium-ripening, and late-ripening corn hybrids. We are not making adequate use of the heterosis effect in the selection of grain and especially feed crops. We are not finding adequate solutions to the 51 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 Fox oFFicini. vsE orrLY prdblem of develnping varietieg of Eicld eropy having cnmplhx immunity and tnlprnnCe td the mosc aggrpggive dlg@HgCg gfld p@9t5� Scleceive breed- ing to improve crop quality ig noe prnceeding Eagt enough. It hns now beCOme neeessary to subgtantially intensiEy the selertinn proceag, ed develnp varieeieg and hybridg through ehe ugp of modern advances in geneticg, molecular bidlogy, molecular gpnetics, binchemigtry, physiology, and other gCieflCE!g. It ig eggptitial ed subgtantially shnrten the time it takeg to develop new varietieg and in thp next Eew years reach a levpl of planned deeign of gEnotypes in eccdrdancp with g preset progrgm. 'Chig entaila gubseantially serpngthpning ehporptieal rpsearch carripd aut in acipntific inaCitutiong of the USSR Ac:adpmy of Sciencpa and VASKhNIL de- signpd to resolve applied tA8It8 of gelectivp breeding. The most vnluable practical regults can be expected glong thp following tines. Above all we must develop more cEfeetive methodg of trensferring genetic information frnm one plent genotype to anothpr on the intrespeetpx and ineerspecieg levels--ehat is, it is necessary to devplop Chromnsnme engineering. The long-tcrm nature of such wnrk is indicated by the re- search oi Academician N. V. Tsitsin, whn has developed e serieg of wheat- quackgrasa, WhEgC-rye, and wheat-wildrye hybrids combining useful properties of different specieg in a singte genotype. We must step up eEforts to develop the directed transEer of chramnsumes from one variety to another by means of aneuploid serics. The Krnsnodar ScientiEic Research Institute of Agriculture has already produced linc�s of Bezostaya-11 in which individual chromosomes have been replaced by chromosomes of the highly frost-resistant variety A1'bidum-114. Simtinr work is underway with other vurieties ln the All-Union Selection-Cenetic Institute and the Siberian Scientific-Research Institute of Agriculture. The All-Union Institute of Plant Nusbandry has developed 42-chromosome allohexaploids of wheat (by crossing 28-chromosome species with einkorn), which are distinguished by high resistance to fungous diseases. Polypoidy is a very promising line of research. In this field we have already achieved some success for a number of crops. Another promising technique is that of transferring the nuclear apparatus of one species into ttie cytoplasm of another. It has been demonstrated, Eor example, that the cytoplasm of soft wheat has a marked effect on certain crait:, of alloplasmic rye. Broad possibilities are opening up [o chromosome engineering in connection with the development of inethods of embryoculture and the produccion of protoplasts and suspension cell culture. Breeders have developed wheat- barley and rye-barley hybrids. They are resolving many problems of com- bining in a single genotype genetic material from various species. Obviously, it is now time to combine the eEforts of the scientists of the USSR Academy of Sciences and VASK,hNIL in order to speed up the development of inethods of chromosome engineering that are vital in resolving problems of practical selective breeding. 52 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR dFFIciN, usE oNt.Y In order td dtvclnp heteratic oplectidn, it i.g pxtremety tmpnrtnnt to have eEfective meEhodg of fnrecastfng hhterdgig in plantg. Scicneigta have nirendy ddne a grpat deal in thig CEgdCd. Up tn nnw, hdwcver, gll heterotic gelertinn hag been bagpd dn cnnducting n largp number of tegt crogs breedings to determine genaeypes having high rombinatorial capabiliey. Thig severply compiicates ptfnreg to develdp valuablp 1ih@s and highly- heterotia hybrida. Subgtantiel etEdrtg are required of rpgearchers in ordpr en wark oue thp theoreeical principles of selecting plantg to aptimalize the gpleetion prdcesg, iteluding nn the basis of aeeive utiiization of artificial ctimate. llere a major EgCtdr ig wnrk in thp field nE evolution and populaeidn genptics. tn connection wieh thts, I will Edcus briefly an poagibilitiQS of $ubstantially pxpanding pEEortg in biaChemical genetics. As ig wpll known, ehe primary product dE the activity nf geneg nr btocks of genes aftpr trangrription and translation is ehr pnlypeptideg. Mpthads of separgeing and identifying proteim molerules have been thoroughly warked aut, npening up broad praspects Eor the extensive ugp of proCeins as markers or gignalg (td use A. S. 5erebrovski's terminology) of genpa nr blockg of genes canditioning the vgriability of economirnily useEui trgits and propertips. 'Cheoreticatl.y important and practically valugble results in thia regard have been achieved in the All-Union Selertion Cenetics Institute. Because of our severe climate which is unstable over lnrge areag, speciat importancp attaches to selective breeding to increase frost-resiscance, winter-hardiness, drought-rpsistanre, and so on in farm crops. We must confess, unfortunately, that for many crops almost all new varieties of intensive type are less resistant to stress factors than the old aboriginal varieties. This involves the influence of a number of Eactors, in par- cicular a cer[ain negative correlation which is physiologically-genetically condi[ioned. $ut research in recent years has shown that in principle it is possible to combine high yields, Erost-resistance, and drought-reststance in a single genotype. But realizing these possibilities will require special, integrated research. In connection with the implementation of ineasures mapped out by the party to substantially boost deliveries of mineral Eertilizer, a new probtem has appeared on the agenda; directed development of varieties distinguished by the ability to make more efEective use of mineral nutrients to build up an economically valuable crop. In resolving this problem, a key role is played by mineral plant nutrition genetics. This is a new line in biologicat science, and we intend to develop it in every aay. Among the most important long-range problems, mention must be made of the use of suspension cell culture in selection work. In essence, bio- logical and selective breeding science stand on the threshhold of 53 FOR OFFICIAL IJSE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR oFFIcinL usE orrLY selerting valuable mutaEidng and r@combing�es nn the lpvel nE individual ce11g Ear gubspquent rp$pnergCion and ehe produceion of Cruir bearing planeg. Work along thesp tines is gtready underway in this cnuntry, bur 1t 19 not dpvelaping fase enough. it is nnw necpssary cd cnmbinr the pEEorts of gcfentlgeg in working dut meehdds of suspension cell selectton E`or ouch cropo as wheot, cnrn, barley, eoy, pnratops, and feed cropg. 'Che prospeCtg of using these mpthods in selective breeding, especiglly fnr resistance eo certain paehogenes, pesticides, salt buildup, and Ernst, arp exeremely high. 'Chp regnlution of this tgak requires eadreg, equip- mpnt, and reagents. Unfnrtunately, hopes for qualitative edvances in plane aelection on the bAgiB of using methoda of generic enginepring on ehe tevel of manipu!ating Eragments of DNA molecules are not being realized Easr enough. 8ut we are cnnvinced that this problem will be galved SUCC09gEUlly through the joint efforts of the gcientists of our acadpmies. In the Eield of selective breeding for immunity, apecial importance attaches tn studying thc narure of non-speciEic resiseance to pathogenes. PracticAt work has shown thaC the development of varieties having only what is known as vertical or race-specific resistance give rise to rapid adaptation and then increased virulence of the pathogene to genotypes having this type of resistance. A clear example is seen in the history of the Pvrora and Kav- kax varieties. We need varieties possessing stable resistance to the most aggressive dispases. Very likely a big step Eorward in resolving this problem can be made by speeding up the Eormulation of the hypothesis eoncerning the link between plant resiatance and the formation of phyto- alexins. in any case, theoretical solutions in the field of studying the genetic nature of plant resistance to pathagenes and tolerance co pests are coming to be of increasing importance in selective breeding. Let me inform you that our country has organized 44 selecCive breeding centers dealing with grain, legume, and feed crops. They are setting up (with difficulty, to be sure) the necessary conditions for seleccive breeding at the presen[ level. In the project planning of the complicated facilities for selective breeding centers, VASKhNtL is getting considerable aid from the US5R Academy of Sciences CIPRONII [All-Union State Project-Planning and Scientific-Research Institute for the Project-Planning of 5cientific- Research Institutes, Laboratories, and Scientific Centers of the US5It Academy of Sciences and the Unicrt Republic Academies of Sciences] for which we are sincerely grateful. Nothouses, phytotrons and facilities for processing selection material are being built; com- plicated scientiEic equipment has been installed and is in operation. All of this is making it possible to raise the question of developing essentially new technology for the selection process based on the active use of artificial climate conditions, and especially the use of 54 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FdR dFFICIAL U3E dNLY modern advances tn the natural gcienceg. 1.n partlcular, the All-Uninn GcneCicg Inseieute in ndeggg has Complctc�d the conseructlun nE thc wnrtd'g 1nrqeHt phyentrnn. Wr hnph thnt Kclr.ntlxtg o[ thr U55I2 Ar.ndrmy oC 5elrncrN wlll Cnko netive parl ln fiftcliKlCying Suvtnt Helucl.1011 wnrlt. We ar4 nuw building up real pogaibilitieg Cor qualirgtive changes in Buch work. 'I'he presidium of VASKhNIL ig ascribing special importance to this regeArch and will take the necesgary measureg to implemcnt it. Pareicular conditiona arQ necespary eo realize the poeentials of rhe new varietieg. 'Chey are being crpated on ehp bagi8 of the usp of modern technoingies aE crop cultivation. Thp convergion of pldnt husbendry to an indugtrial bagig eneailg Che necesaiey of develnping technologies which will make it possible Co produce high, stable yields per unit of land nrea at mitiiimal coat. In developing 5UCI1 eechnologies, the scientists are encountering considerable difficuleies. The fact is that modern tech- nology combines in itself achipvemenCs in many sciences and Cechnical pro- gress. Complex problems arige at the interfgCe of biology and the technical scienCeg, problems of prdtecting the envirdnment, gnd so nn. For exarople,in- Creased doses of fertilizer sCrengthen the development of weed vegetarion. Agrotechnical means of controlling weeds are by no means nlways effective. We need a broad spectrum of herbicides which suppresa the weeds without having a negative impact on the crops and the environment. This has al- ready bpen discussed by Agriculture Minister V. K. Mesyats and Academician Yu. A. Ovchinnikov. This problem is at the interEace of biology and chem- istry. Increasing the vigor of soil cultivaCion gives rise to rapid de- velopment of aerobic processes, which result in reduced potential soil fertility and the loss' of nutrients. For this reason, it is very im- portant tn take an integrated approach to the development of new tech- nologies of cultivacing crop plants. It is very important not to allow the development of bottlenecks in the sequence of techniques designed to produce high, stable crop yields. We hope that in the future the agrarian scientists will collaborate more actively with scientists working in various fields to resolve problems of plant husbandry. A rational system of land cultivation serves as the long-term basis of plant husbandry development. Our scientists have made substantial successes in working out land cultivation systems. In the field of land cultivation and its chemicalization, the efforts of scientists must be focused on the theoretical study of t1ie physical, chemical, physiochemical, and biological processes taking place in the soil, on studying the soil's organic matter, development of the physiochemical mechanics of earth and soil systems (with the end goal of developing soil classification and methods of improving fertility), on the study of the moisture cycle and the water balance in the main farming zones of the country, on forecasting the level of soil fertility, and on working out ways to make rational use of land resources. 55 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt OFFICIAL USE ONLY It is egsenCial Cd gcienCifically subseaneiate and work oue the opCimel vgrtant of agriculturel zoning oE the Soviet Union's tErriedry. 'Che bnetC dirrctlon nE scipntific-technicsl progrcgs ln iand eulefvntfon and turther lneengiCtcatlon nf thig gector uE agrirulture wlll bn thr adoption of speCialized r.rop rotatlon cyclea, the improvement of sdil fertility through the brogd use of mineral and organic fertilizera, the liming of gcid soils and gypsuming of alkaline soils, also the adopeion nE advanced cropping techniques in the culeivation of farm crops. In connectinn with this, gpeeigl impdrtance aCtaches to more rhorough formulation of the theory of mineral plant nutrition (retations between the root system and the soil solution, the mechaniam by which mineral nutricnts enter the plants and are converted there) and the study of nutrient metabolism in land culCivation. Specialization and concentration of farm producCion obligea us to take a new approach to the structure of crop rotation cyCles. The scientific instituCions especially, must study problems of sgturaCing specialized crop rotation cycles with key crops in each zone, subzone, nnd oblast and make appropriaCe recummendations. 'Chis will make it possible to obtain the maximum yield of high-quality output with minimal outlays oE labor and funds and ensure expanded reproduction of soil fertility. In arid regions of the country, the most eEfective means of ensuring high and stable grain crop yields is to include bare faltow in the rotation cycles. According to scientific data, the production of grain in areas of insufficient and unstable moisture is possible only under conditions of correct proportions between grain crop plantings and the bare fallow. Unjustified reduction of the bare fallow area brings about disruption of the grain fallow crop rotation cycle and leads to a slowing of the rate of growth of gross grain harvests in a number of farming areas of the country and to increased losses of grain crops. In the Euture we must spread the use of intensive crop rotation cycles which make it possible to harvest 1.5 crops per year in the southern parts of the European USSR and 2 or 3 crops on irrigated lands through the adoption of secondary sowing. In zones of sufficient moisture and on irrigated and drained lands, areas under perennial leguminous grasses in crop ratation cycles must be maintained at 20 to 25 percent. In connection with intensification of agriculture, great importance attaches to strengthened theoretical and applied researcti into problems of inechanical soil cultivation. In the forefront of efforts in recent years is the search for ways to minimfze soil cultivation without re- ducing crop yields. It is essential to continue research in the follow- ing basic lines of this problem: reduction in the number and depth oE cultivation; combination of technological operations in a single process; reductinn in the number oE operations by developing unft equipment and combine machinery; reduction of the negative effect of the machinery's running gear on the soil and crops; reduction of the surface of the , cultivated fields. 56 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 xox oFFicIni, usc oNLY In areas af Ndreh Kazakahgtan and 5iberin, more than 31 nitlidn hectdreg are under a gdil proCeceion sygepm develuped by ehe All-Union Scientific- Ite$earCh IngtiCUCp of Grain rarming under rhe gupervisidn of VASKhNiL Academician A. I. 'Barayev. 'Chis has made ie pngsible td hn1C wind grosidn in many aregs, Create cnndiCions for moisture accumulatinn ih thc soil, boost the yields dE varioug grain crops, and rhus ensurp an additional harveat of 5 eo 6 million edng of grein every yegr in ehar areg. Undpr intensified farm productton, waeer erosion hag risen gubgtantially; on erndpd goils, erdp yields, as is well knnwn, deG1ine by Sd and mometime 80 percent. About 38 million tons of nutrients are washed gway every yegr. The gnnugl loss due to snil prnsion in the counery exceeds ten billion rubles. Wp have a great deal of work Co do in this reggrd. Almogt 80 per- cenC of our country'g farm lands arf to some extent sub,ject tn eroaion. The problem of soil protection is gn urgent one. Ie is essentiel eo focug scientistg' efforCS on finning intpgrated solutions. Of great importance to booseing the productivity of land cultivation in the southeastern zone dE ehe country is the reclemACion of elkeline lands, which add up to more than 100 million hectares. VASKhNIL research has shown that about 18 to 20 million hectares of such land could be re- habilitated gnd used to raise chiefly feed crops. Thta will require integrated research into chemical processes taking p1aCe under mechanical reclamation of alkaline soils; it will be necessary to study the effects of gypsum in alkaline soils of various typps, the nature of hydrological cycle processes and so on. This complex, integrated task will require the ,joinC eEforts of scientists in various spec3alties. The sails have begun to build up an excess quantity of nitrates introduced along with mineral fertilizers, also nitri.fication of the ammonia of iive- stock farm runoff. Nitrates are easily leached out and contaminate the environment. For this reason, it is of great practical importance to work on the problem of inhibiting microbial nitrification. Also of great importance is research into the role played by micro-organisms in what happens tn mineral fertilizer in the soil. It is also necessary to study micro-organisms capable of mobilizing the phosphorus of mineral and organic compounds that are not easily accessible. The microbiologists face a serious task--that of determining the ways of microbial degradation of organic matter discharged along with industrial and household wastes, also thos2 that enter the soil when plants are treated with pesticides. As V. K. Mesyats has stated, in the next few years the microbiologists wil have to make a substantial contribution toward resolving the problem of feed pro[ein through intensification of biological ni[rogen-fixation. A basic goal of xesearch designed to boost Eeed production must be Euture maximum intensification of field feed production on the basis of increased yields of feed crops, improvements of the structure of crop planting, and 57 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt OFFICIAI, USE ONLY mdst productive pnssible uge of plnwed land ehrough thp use oE intrrmhdiate crops making it paggible, in grecag dC suEEiciene mdigeure nr under irrige- tion, to produce scveral crops per year on Clte snmp tgnd, AC present, rpgolution of the feed problem depends more on organizaeional-eCOnomic measurea than on acientific research. Under cdnditians of concpnCraeion and specialization of farm producCion, when high-yield cropg are bping culCivaCed dn largp areas, a scientifically- substantiaCed gystem of plant prnCenCion plays an increasing rdle. In recenC ypgrs, despite Che incrpasing usp of pestieideg, grain shortfalls have been increasing bpcause of root rot, powdery mildew, rust, and enzyme-mycotic depletion of the plants. It is of great importance in the system of plant protection, therefore, not juse to deatroy harmEul types of organigms but eo suppress and inhibit their populaeion thrnugh the inte.. grared use of chpmical, biotogfcal, and agrotechnical methuds. In thig re- gard, wp are not doing sufEicient research. The development of integrated control systems combining bll methnds and taking gccount of the econnmic threshholds of disease and pest harmfulnesa is one of the main problems far.ing science in p1anC proCection. And, as follows from rhe decisions of the July 1978 CC CpSU Plenum, we must not slacken efforts to improve the chemicgl method of controlling hazmful organisms and to find highly-effective and safe pesticides. Research being conducted along these lines by institutes of the chemicgl industry is not adequate. For example, the All-Union Scientific Research Institute of Chemical Means of plant Protection has recommended hardly a singte compound for practical use in recent years. The development of herbicides is lagging especially badly. Our situation witli regard to herbicides and deEoliants is especially bad. Institutes of the US5R Academy of Sciences and the USSR Ministry of Chemical Industry must take more active part in developing new compounds. It is essential to expand efforts to develop new, perfected forms of pesticides and advahced methods of applying them. Special attention must be foCUSed on the developmcnt and adoption of biological methods of controlling harmful organisms in agriculture. As Academician Yu. A. Ovchinnikov mentioned in his report, good prospects are to be found in new lines of research based on the use of biotogically active snbstances such as hormones, pheromones, and others whicli control the growth, development and behavior of insects. Research has shown that substantial success has already been achieved in this regard, but the lack of modern equipment and instruments has been hampering research. Mean- while, the use of pheromon,s yields substantial economic effect (re- ducing the number of chemicr.l treatments by two or three times). An inportant reserve for riaducing crop losses is the organization of virus-free seed breeding fo: nt~ratoes and vegetables and the creation of heatthy conditions for fruits and berries that are frequently subject to virus infection. SS FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR dFFICIAL USE ONI,Y Ie ig esaential ed fdCUS mdre gCtentton on the development dE ngroeechnicgt meehodg df protecting p1anCg egainst pegCs, digeaseg, and weedg. tiligh- quelity land cultivation and edvanced tcchnoingies in Crap cultivaeion con_ grieure the bgsig of en tntegratpd sygrpm oE plant prneeceion. IC is important to wdrk out mnre eEfecCive sysrems of plane prneeceion on the bgsis of znnal gystema of land culeivaeion and the lntegt gCientifiC and practiCal advances with regnrd to the chnracCerisCics of developmene oE furm produceion under cdnditions of Conneneraeinn gnd speciAlization. In the field df land reclamation, science faces the tgskg nC seeking out ways tn bnost the productivity oE reclaimed land and developing meChods of reducing wgeer logses in irrigatinn ttnd meesures Co protece the environment when building land reclnmaLion proJecta. BuG the main direction in regearch on prdblems of irriga:ion and land drainngp, in our opinion, must include the development oE meehods of con- Crolling the growth and development of farm crops in all sCages of life. This will help Cn maximally optimalize the VABiC factors of the plant's life and mgke the Eullest possiblp determination and utilizaCion of the plane's biological potential. The initigl StdgE should be to work on programming farm crop yields under condiCions in which the two basic fnctors of plant life are regulated: water and nutrition. This kind of effort, carried out by the US5R Academy of Sciences and VASKhNIL deserves encouragement. Modern inCegrated land reclamation measures are characterized by conversion to steady contrnl of the growCh and developmenr of plants by regutating not only the water and nuerient conditions of the soil and the phytoclimate but also the soil's heat and gas conditions, also the plant's physiological processes. This problem is a vast one, and its solution will involve the efforts of specialists in various scientific fields. Crucial tasks involved with improving the productivity of the forests and improving their qualitatfve composition face scientisrs in forestry. From the agricultural standpoint, grear importAnce attaches to research into the environ,nen[al-protection and environmentttl-formation role played by natural and man-made forests within the complex of ineasures designed to boost the efEectiveness of agricultural production, also research deal- ing with determining the social role played by protective forest plantings and their signifiCance in efforts to combat drought, dry winds, and wind and water erosion of the soil. In this regard, the scientific institutions of the USSR Academy of Sciences can provide invaluable aid both to agri- cultural sc"Lence and farm productton. Implementation of the party's master plan to further enhance the people's wellbeing largely depends on the development of livestock farming. The July 1978 CC CPSU Plenum noted that the present level of livestock development is not keeping pace with the rapidly rising needs oE the peop le. 59 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR OF'FZCIAL USC ONLY Thp overalL direceinn of devetopment in this sector is the Cnnverstnn to indugtrial technnlogies of ehe production of meat, milk, eggs, and so dn. In connection with thig, ehe livestock breedprs face ehp task of quickLy developing breeds and serains of farm animals ChaC are ndaprablp eo such , teChnologiea. It is also necessary to work out improved merhnds of acceleraring Che development of new breeds, serains, types, nnd hybrids of ri farm animgls, methods of egrly prognosis of unimal productivity and recommendaeions on ehe use of thesC methods in selecCive breeding aiid hybrid- ization on the basis of modern aCiVal1C89 in population genetics, the analysis of geneeic inEormation by means of compuCers, and more precise meChods of eveluating e genotype by means of modern selection eechnology. Life it- self demands expanded research in problems of livegtock selection designed tn develop genetic immunity to a number of widespread diseeses (leucosis, mastitis, And others) and to enhance the reproductive cnpabilities of animgls and improve the quality of livestock products. Still not cnm- pletely resolved are problems of selecting livestock for fast maturaCion and increased productivity. . Special importance attaches to the cycle of research and spplications in the theory and methods of breeding livestock specialized for meat produc- tion, the development of new high-yield breeds of ineat livestock adapted to specific natural and climatic conditions. It is essenCial to srep up scientific effort in the theory of heterosis and the system of cross breeding making more extensive use of world genetic resources (in par- ticular, Holstein Frisian cattle) in order to improve breeds of farm arlimals that are most widespread in this country. Very promising at present is exploratory research on developing methods of cloning, genetic copying of farm animals by means of modern cyto- genetic and transplantation methods. In the field of feeding farm animals, more efforts must be made in re- search designed to improve the animals' assimilation of nutrients, especially protein, to raise the coefficient of feed nutrient trans- formation into high-quality livestock products. It is worthwhile to expand research into the microbiology of rumen digestion among ruminants in order to improve the effectiveness of the animals' assimilation of nutrients from coarse feeds, including straw, which in terms of the volume of annual production of organic matter constitutes an enormous and still inadequately utilized reserve for the production of livestock products. � It is very important to seek out new, nontraditional sources of feeds based on products of chemical and microbiological synthesis. It is necessary to complete work on determining optimal dimensions of live- stock complexes of various types in all zones of the country and to make specific scientific recommendations on problems of organfzing technological processes and the recovery and proper use of livestock complex wastes. 60 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR OFFICIAL USC ONLY Ie shduld be stated that in ehe yearg nE Soviet rule our vcterinary BCiet1C@, egpeCinlly in Y@Cet1t deCade5, hAq mnde cnngidprable 5UCC0gg, fOC whiCh our gcienCigts in ehis field desErve muCh thanks. Nevertheleag, thp nnnveegion u't tivpstork farming eo an industriel basig bringe up many big npw easka. Speclnl aCLenClon mugC be Eocuged nn dpvploping 3ygtetllg en prevent animal diseases under cdndtCions of large livestock Earms. Labor prnduceiviey in agriculture will in the futurp be lgrgely determinpd - by its level of mechxnizaeion and auComation. kegegrCh by VASKhNIL scien- tists in the field of inechanization, plectrificatinn, nnd gutometion of agriculture in the next few ypars must be focused nn developing and creating new technologies end technical means necessary to convert all farm sectors to an indugCrinl bagig. It is necessary to develnp new-generation machinery that ia 2 to 2.5 Cimes more producrive than present designs. It is essential eo design models of machinery cnmplexes for ehe productinn and processing of liveseock products. In the electromechanization of live- stock farming, basic research should look for optimal meehods of automating the operation of technological procegses noC only in industrial livesCock complexes but in large kolkhoz and sovkhoz farm units. Research by scientists of VASKhNIL end other deparrments muet also promote accelerated development of new equipment for agriculture through the formu- lation of integrated, goal-direcCed economic programs. The tasks of agroeconomic science in the lOth Five Year Plan and the longer- term future are mapped out in the decisions of the 25th CPSU Congress, CC - CPSU plenums, and the CC CPSU and USSF2 Council of Ministers decree "Mea- sures to Further Improve the Effectiveness of Agricultural Science and Strengthen Its Ties With Production" dated 26 August 1976. I should like here to emphasize that agrarian economists must focus atten- tion on more thorough formulation of problems of specialization and co�- - centration of farm production on the basis of interfarm cooperation and agroindustrial integration, on theoretical and practical substantiation of optimal levels of concentration of specialized production, on formulation of the basic directions of systematic and proportional development of agriculture in conjunction with other sectors of the agroindustrial com- plex. Extremely great importance attaches to research designed to improve economic incentives to develop farm production, to equalize economic con- ditions of management, and also to improve price formation and cost- accounting relations on kolkhozes and sovkhozes and in interfarm and agroindustrial associations. It is essential to study the social aspects of agricultural development and certain other problems. ~ It must be acknowledged that in these respects, unfortunately, we do not yet have sufficiently precise, clear, and thorough theoretical solutions. Agrarian economists have published many aooks, pamphlets, and articles summarizing what has been done in practice, but what-is really required of the scientists is illumination of ways to further develop these processes. 61 FOR OFFICIAL USE 0NL,Y APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOit nFFICIAL USC ONLY We believe that these problems must be ehe fucus of xeeention the ngra- _ rian gCOnomists, VA5KhNIL's Presidium, and sector and regionnl dpparemeneg of VA5KhNIL, beC8U9e they are of. Eundamental importnnCe eo agriCUltural development and Snviet; gociety as a whole. The difEiculey and complexicy of these problems lies in the face ehat there is a lgck not only of well- I trodden roads but even footpathg. There is prnCeically no one we can turn to [or help in Chis regard; we have to work out these problems Erom scratch, and in a vigorous manner. For this reason, the resolution nE a1L agrarinn- economic problems must involve the gcCive participatinn of scientists not only in VASKhNIL bur nlso in Che insCitutes of economics of the USSR Academy of Sciences and rhe aCademies of sciences of the union republics and the institutes of the agricultureal ministries. Not having the possibiliey of dwelling in detai-l on all the problems Eacing the acienCisCs of VA5KhNIL and Che US5It Ministry of Agriculrure in light of Che decisions of the July 1978 CC CPSU Plenum, I have named jusr the basic ones as well as those which should be worked out in creative cnllaboration with scientises of VASKhNIL and the USSR Academy of Sciences. It should be noted Chat collaboration between the USSIt Acudemy of Sciences and VASKhNIL has been expanded in recent times. I am convinced that by ' joining our e�fforts we can resolve the rasks the party has assigned to ~ science in the field of agriculture. We must also step up research efforts in problems of the Nonchernozem Zone. This applies to scientista and scientific institutions regardless of aEfilia- tion. No one can remain uninvolved. Each of us must obey the call of our heart and mind in finding our place in efforts to help the agriculture of this important region. In the name of the scientists of VASKhNIL, allow me to assure all those attending this meeting that we will exert all our effort and skill to promote the resolution of the tasks facing our country in accordance with the decisions of the July 1978 CC CPSU Plenum and the speech given there by CC CPSU General SecreCary and USSR Supreme Soviet Presidium Chairman Comrade L. I. Brezhnev. 6854 CSO: 1870 62 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 rotz orFzcznt, usE orrt,Y UDC 630:001 EARTH SCIENCE FOR AGRICULTURE Moscow VESTNIK AKADEMII NAUK SSSR in Russian No 3, 1979 pp 54-59 [Report by Academician A. V. Sidorenko] [Text] The session of the General Meeting of the USSR Academy of Sciences heard coreports by USSR Academy of Sciences Vice President Academician A. V. Sidorenko, academicians Ye. N. Mishustin and S. I. Vol'fkovich, USSR Academy of Sciences Presidium Chief Academic Secretary USSR Academy of Sciences Corresponding Mem- ber G. K. Skryabin, USSR Academy of Sciences Vice Presi- dent Academician P. N. Fedoseyev, and USSR Academy of Sciences Corresponding Member K. V. Frolov. Boosting the USSR's agricultural development is the cause of the whole party, the whole Soviet people. Guided by this directive of CC CPSU General Secre- tary and USSR Supreme Soviet Presidium Chairman Comrade L. I. Brezhnev, the scientists--geologists, hydrogeologists, geographers, hydrologists, clima- tologist:, and specialists in the study of earth from space--consider it their duey to take active part in resolving this most vital problem of our time. Of the great variety of problems relating to agriculture being dealt wiCh by institu*_ions of the Section on Earth Sciences of the USSR Academy of Sciences Presidium, we will dwell on the three most important ones. The country's land holdings. The land is the main means of production in agriculture, the spatial basis for the location of industry, transport, the place where human beings live. We are accustomed to speaking of the limitless expanses of our Homeland, saying that the Soviet Union occupies one-sixth of the earth's surface, but we do not always keep in mind that � our land resources are not unlimited, and land areas suitable for agri- culture are limited. The effectiveness of utilization of land resources-- boosting their productivity, protecting the land against destruction-- constitutes a vital national economy task which requires all-out scientific effort. The land, the soil, the vegetation, the water--these are the main components of the biosphere. - 63 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 Fnlt tlFFICIAL USE dNLY In considcration of nll this, KEp5 [Cnmmigston for the 5tudy dE rroduetlvc FbCC@8 Elt1d NBCUCFIl KC'9nUCCl'g] of thc USSEt ticademy 0f SCIEt1CE5 in cnllnborn- tion with the US5R Minigtry of Agriculture, VA5KhNIL [AII-Unton Acndemy of Agricultural Scienceg], State Cnmmittpe Eor Forestry, the U55R Mtnistry of Water Management, and other organizatidng recently held u scientiflc-tpchni- cal cnnfprence nn thp cduntry'g land resourees. Materials of Che conErrence remind us oncp again thgt our ugricultural lands must be used rgtionnlly. Hglf nE the c.ountry'n territory is fnrest land. Narm innds take up 607 million hectares or 27.2 percent of the cnuntry's territory, with plowed land constituting onLy 224 million heetnres or less than 0.9 hectares of plowed land per inhebitnnt. It must also be kept in mind that dtmogt three-quartprs of our land ig locgted in conditions that nre extremcly unEavornble Eor agriculture--in cold, erid, degert, nnd mountain regions. OE the arable land, onty nbout 60 percent ts locnted in favorgbip sotl and climatic condi.tiong. bespite the development of huge areas of virgin lands, the area of plowell land per capits is continuing tn shrink because substan- tial areas are be!.ng set aside tor nonagriculturel use (industry, transporC, cities, and so on)� Calculations show that by the ycar 2000 the locating of new industrial enterprises, roads, and population centers will require about 35 million hectares of farm land and forest land. Land reserves suitable for ngri- culture are limited--about 38 million hectares. From L. I. Brezhnev's work "Tselina" [Virgin Lands] we know about the enormous outlays of man- power, energy, and Einancial and material resources it rook to develop tlie vtrgin lands in past years. And the development of new areas in thr, Norch (six mtllion hectares), in the deserts and semi-deserts (about six milltori hectares), and in the Nonchernozem Zone of the European part and in the East (21 million hectares) will require more substantial outlays. For this reason, rational utilization of our land, even considering our vast expanses, is a most vi[al economic task. A serious cause of concern is the destruction of the lan!. More than 150 million hectares of plowed land and about half of the nntural pasture land are afEected by deflation and erosion which impair soil fertility. The Master plan of Utilization of Resources of the USSR, now being wortced out, places grPat responsibility on the institutes of geography, water pro- blems, agrochemistry, and soils science, on the scientiEic institutions o( the Siberian Department, the Far Eas[ern Scientific Center, brancties oE tlie USSR Academy of Sciences, the republic academies, and the scientific institu- tions of VASKhNIL Eor the scientific substantiation oi the development of new lands and the rationat utilization of lands put into farm productiov. Our Soviet science has always been famous for its high level of soit anJ geographic research. The Dokuchayev School of Soils Science is known throughout the world. Now, soil-geographic research must be raised to a new level. Classic soil geography must be supplemented by spacc mettiods of investigating land resources and closely coordinated wirh physical and 64 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 rnk oFrr.cinl, usE ncr1.Y chemicat methnds oF studytng naCurnl renources. Only nn the basis of inte- grdting the ngCUrnl nnd exncC ec:tenceg cnn we gCt n modern idea about the country'g lgnd pnteneial gnd lay e gcicnCiliC foundntidn Cnr expanding the Country'g farm lande. At the present stage it is possible eo increQge the nurput of Earm products _ nnly by Eurther intengiEying the productivity of the lnnd. providing the nntional pcnnomy with explored reserves oE raw material for the production of minernl ferCilizers. SCienCistg nE the US5R Acbdemy oE 5ciences iave made a substsntial contributinn eoward developing a reliable rnw materials base Eot, the production oE fertilizers. Our country holds Eirst place in the wnrld with respecC to the producrion of mineral ferti- lizers. At the preaent gtage, fertilizer production is not held back by explored reserves. The main thing which hampers the production of potassium and phnsphorus fertilizers is the sCatus of industrial capactties and tech- nologies for processing the rnw material. This is especially true of Belo- russia, which has a powerful poeassium industry that produces halt of all of the country's potassium fertiliaers. The urgent problem Chere is the recovery oE wastes Erom the mining of salt polluting the environment. Sslt mining technology needs to be streamlined in the Solikamsk Basin thts side oE the Urals. But the geologists of the USSR Academy of Sciences and the USSR Ministry oE Geology also face major theoretical and practical tasks in boosting reserves of mineral raw materials and improving the:r geograph- ical deployment. 5pecial attention ought to be paid to the problem of prospecting for potassium salts in Siberta, a region where such salts have not yet been found--all reserves of the raw material for producing potassium fertilizers are located west of the Urals and in Central Asia. Scientists of the Siberian Department of the USSR Academy oE Sciences have scientifically sub- stantiated, and geologists of the Eastern Siberian Geology Administration of the RSFSR Ministry of Geology as a rpsult of many years of work, have proved the possibility of discovering industrial potassium deposits in the Eastern Siberian salt basin. We need more intensive geological-exploration work in Irkutskaya Oblast. It is difficult to exaggerate the importance of pros- pecting for depostts of potassium salt to the development of the agriculture of Siberia and the }'ar East. Organizing the production of potassium ferti- lizers in Siberia will reduce long-distance hauling and yield substantial economic effect. The main supplier of phosphates (up to three-quarters of all phosphate con- centrate production) is the Khibiny apatite basin. Thorough scientific substantiation of prospectirig for new ore in Khibiny begun by Academician A. Ye. Fersman and continued by scientists of the USSR Academy of Scfences Kola Branch imeni S. M. Kirov, has shown that new major phosphate deposits may be discovered in Khibiny. At present, ore reserves there will provide for reliable development of the mining industry for many years. Even the level of ore production estimated for the year 2000 will provide for at leaeC fifty years. 65 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR nFFtcinr, UsC nxLY Neverthelegs, Che geogrgphy of phoaphaCe producCion nlgn needs tn bc geriously improved. We havf large regerveg of phoaphoriees In Aktyubin- akaya Oblagt in Knzakhaten. But they nre not being dpveloped East pnough. Development ig algo going roo slowly in Kazgkhatan's huge Karatau phospbate bagin. These ores are diEficult to procegs. It is necessnry eo geurch more vigorously for new methoda of proceasing the tough phosphorua ores of this area. This is g task which must be rpgnlvpd by ehe chemiats of the USSR Academy of Sciences and the technology specialista of rhe U5Stt Ministry of Chemical Industry. Until recenC years, Siberta did not heve its own major phosphate deposits. Small deposits have been explored there, but iC is not economicalty profit- able to work them. In recent years on the USSit-Mongolian border eEforts by the USSR Miniatry of Geology and the Joint Soviet-Mongolian InCegrated Ceo- logical ExpediCion of the US3R Academy of Sciences and Chp Mongolian Aca- demy of Sciences have resulted in the discovery of a major new phosphate basin (the Khubsugul depnait in Mongolia and the Ukhagol in Buryatia). DevelopmenC of this basin will radically change the possibilities of supplying phosphates to Siberia and the Far East as well as fraternal Mongolia. Preliminary estimates and exploration of these deposits have shown that the basin is comparable to the Karatau in terms of size. The ore is of high quality and is accessible to open-pit mining. Oevelopment is being delayed by a number of organizational-technical factors, chiefly the inadequate attention paid to this region by the USSR Ministry of Chem- ical Industry. We believe that in the framework of Soviet-Mongolian eco- nomic cooperation it is essential Co step up the development of mining- concentration enterprises and chemical plants there to produce superphospliate and other kinds of fertilizers. This will provide the eastern areas of the country with scarce phosphorus fertilizers. Calculations of the Sibe:ian Department of the USSR Academy of Sciences have shown that supplying Siberia and the Far East with adequate amounts of fertilizer will make it possible to boost grairi production there to 30 million tons. The resolution of this task will be a specific ~answer Co the directives of Comrade L. I. Brezhnev during his trip to Siberia and the Far East. It is necessary to continue prospecting for phosphate ores. In recent years we have found major deposits of phosphorites in Khabarov- skiy Kray, apatites in Yakutia, and apatite-bearing alkaline intrusions in northern Krasnoyarskiy Kray. In order to assess the importance of these deposits for the future, the exploration and technological and eco- nomic evaluation work must proceed systematically, purposefully, without sensationalism and haste. We are deeply convinced that major new deposits of phosphorus materia2 will be discovered in Siberia, especially in its ancient precambrian and lower paleozoic geological complexes. In order to resolve the national task of boosting the agriculture of the Nonchernozem Zone, developing new lands there, and increasing the fertility of acid soils, it is necessary to have greater quantities of local fertilzers 66 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FdIt Ob'FYCIN, USL hNi,Y to 1ime the gnil, dlso peat and gapropelites to use an orgatiiC additiveg. At onc; time, the All-Unidn Gcoldgy Invpntory of thE U55K Mitiigcry nf Gen- logy drew up detniled CQtltlgtpYg of depogitg o[ that raw matErial Eor eacli nblagt. tiut the ngricultural drgang of tkie Nonrhernaxem zone are not using tltrbe mnterigls. Thr USS[2 Ministry of Agriculture must EOCUS atten- tiun dn t11e u$e of lncal fertilizerg to improvp ehc aotl feretlity in the - NnnchErnozem znne. Thus, our Cnuntry's agriculture and Chemical industry have tt reliablc raw materialg base fdr developing the mincrnl fertilizer Industry in the coming Eive-year plnns. There ig no regsnn tn Eear that potasgium and phnsphorus resources will be depleted even gECer 1990. But if we set nurselves the task of applying the sgme emount of phosphdrus per hpctare uE ptnwed land and hay lands ns ehey do in Burope and geCting the same crdp yields as they do there, the need for phosphorus will rise shgrply. E'nr this reason, it is essential to step up the senrch fnr new depdsits. The USSR ACgdemy of 5ciences must cnllabdrate wich Che USSIt Ministry of Geology in drawing up _ a special integrated progrem to prepare the raw materiats base fnr the phnspharus industry nvcr the long rerm, and KEPS of the USSl2 Academy of 5ciencps must collaborgte with VASKhNIL to draw up a scientific prognosis of the long-term minernl fertilizer needs. Considering that the mineral fertilizer needs will rise rapidly, the USSEt Academy of Sciences nnd the republic academies must collabornte with the chemical-technology organizations of the various ministries in working on the search for radically new types of minerals Eor the national economy, including agricul[ure. In siberia, in the BAM [Baykal-Amur Railroad] area, we have found leucitic syenites containing up to 18 percent potassium gnd 28 percent aluminum. They can serve as complex raw macerial for the pro- duction of potassium fertilizers end an unlimited source for nonEerrous metallurgy. Everyone knows of the high effectiveness of using bentonite clays as additives in combination feeds, zeolites to improve soil structure, and so on. Obviously, the initiator of rhis work in the interests of de- veloping the economy should be the USSR Academy of Sciences. Water resources. Large areas in the USSLt comprise either arid or excessively moist land. In =onnection with this, the problem of rational utilization, regulation, and redistribution of water resources is an urgent one. The largest consumer of fresh water is agriculture. It accounts for about halE of the total water consumption--150 to 180 cubic kilometers. By the end of the century, because of stronger development of artificial irrigation, these indicators will at least double. Considering industry's water needs, supplying fresh water Eot fArm produc- tion and supplying pure water for the population centers have become vital problems. Calculations show that in the next Eew years this problem will become just as crucial as that of supplytng people with food, fuel and energy resources, and minerals. It is necessary to get rid of the idea that zhe country has a surplus of fresh wacer. Already a number of regions, even those outside the arid zone, are encountering serious difficulties in supptying water for industry and the population. Even in areas of Siberia 67 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt bFFICIAL USS nNLY and ehp norehprn Eurdpcan partg nE the count.ry ehtre nrh diEEiCUltirs in gupplying wgCer eo thp populaeinn, eBpcc:iqlly in the citips. Yroblems of redigtributing gurfarp waeer bptween variaug areas of ehe country nnd ehe erpatlon of a uniEied sygtpm of managing waCer resources, about which so much has been gaid, require profound yeientiEic nnalygis to predict the ecologieat cansequencpg of such mpagureg. Man's global interferenCp in redistributing wgter regources hns in a num- ber of eases led to serious nhanges in the environment that nre difficult to correct. We are nor ggninat Che redisCribution of waCer between znnes of excesa and deEicient moisture, but we do advocgte ehat this be not only technically and economically but algo ecologically sound. It is already beyond questinn, however, that we need more rational means of utilizing water fnr irrigation (Che efficiency of many irriggCion systems does not exceed 0.5--thnt ig, irrigation consumes twice as much water as is necessnry fnr plant growth), also fuller utilization of ground water and tempnrary surfaCe runoff. By directive of the USSit Academy of Sciences Presidium, a special commission has been set up under the supervision of Academician L. M. Brekhovskikh, academic serretary of the Department of Oceanology, Atmospheric Physics, and Geography; the commission is to collaboraCe with the organizations con- cerned in drawing up a program and the acientific principles governing the transfer of the rivers of Siberia into Central Asia, also procedures for forecasting the effect this transfer will have on the environment. It must be stated that the work front on water problems has been slacken- ing in the US5R Academy of Sciences. At one point, the academic scientiEic organizations involved with problems of hydrogeology, hydrology, limnology, and meliorative hydrogeology were transferred entirely over to the depart- ment. The Institute of Water Problems that was created within the Academy of Sciences several years ago, also other small scientific collectives, are still in the organizational stage, they do not have the materials base for scientific research and cannot deal with all the variety of scientific pro- blems involved with supplying fresh water for agriculture, industry, and the population. It is urgently necessary to strengthen the institutes of water problems and limnology. It is also necessary to do everything possible to promote more effective cooperation in scientific research dealing with water problems on a national scale. Although a composite program of integrated research into the problem "Scientific Substantiation of the Feasibility, Scale, and Sequence of Projects for the Territorial Distribution of Water Resources, Taking Account of its Inftuence on Eco- logical, Physical-geographical, anJ Social-economic Processes" has been approved by the USSR State Committee for 5cience and Technology, it has not yet been given the priority water resources deserve. It is the task of the USSR Academy of Sciences and the USSR Ministry of Water Management to function as the organizing center of such research. Water problems are not the responsibility of the Earth Sciences Section alone but of the whole Academy of Sciences. - 68 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR nFFtCIAL U5E ONI,Y We will not digCU55 here muny dther problemg that dre cloaely linked td ngriculture, in particular prnblpms of the study of enrCh frum Spt1Ce (the uae of spgcpcraft und nircraft ro gtudy the stgte of agriCUlturnl landg, soil moiseure, and crop yieid esttmateg), ngricultural weather fnrecadt- ing, nnd so on. 'i'hese are problemg being dealt with by rhe institutes of the Earth Sciettces Seceion of the USSR Acrademy OE SCiEt1c@S nnd the republic academies and the USSR AGademy of SCiennes Institute of Spgce Rpsearch. We will merely note ChaC these effnrts muse be gtepped up considprably, requiring broader cooperatidn between sCienCists nnd prnducCion wnrkers. Scientists of the Earth Sciences Seceion of the US5E2 Academy of Sciences understand the importance of the easks ehe party nnd the governmene have assigned eo them, and they will use ell their strength, knnwledge, and experience ro resolve the national taak of boosting the Soviet Union's ngriculCurgl production. 6854 CSO: 1870 69 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOtt 0FFYCTAL USE ONLY UbC 621 BIOLOGICAL NI'CROGEN AND ITS IMPORTANCE IN AGRICULTUItE Moscow VESTNIK AKADBMII NAUK 5SSIt in Russien No 31 1979 pp 59-67 [Report by Academician Ye. N. Mishustin] [Text] The July 1978 CC CPSU Plenum, commenting on the scientlfic sound- ness and vital strength of the Leninist agrarian policy of the CPSU, seressed the necessity of continuing to keep strictly to the course oE action mapped out at the March 1965 CC CPSU Plenum and subsequent plenums and party congresses. That plenum mapped out the ways oE further agricut- tural dcvelopment, in particular stresaing the necessity of strengthening chemicalization, which must become one of che main levers for boosting farm productiv:ty. The effectiveness of chemicalization is indisputable. In the past ten years of extensive use of chemical fertilizers, farm crop yields hnve risen by 1.5 times; the 1978 grain crop set a record. The volume of chemicalization must be increased intensively, but we must keep in mind that in many cases, especially with regard to supplying nitrogen for agriculture, the chemical industry's task can be made much easier by biology. At the end of the 18th century, a prestigious commission of French scien- tists which included Lavoisier announced that a basic constituent of atr is "nitrogen," which means "lifeless" in Greek. It turned.out,.however, that nitrogen compounds are essential for plants, animals, and humans to exist. Mineral compounds especially determine crop yield levels for most farm crops. Organic compounds of nitrogen, especially pro- teins, are essential for man and animals. As a rule, however, there is not enough protein. The "protein deficiency" syndrome is a frightening phenomenon of the 20th century for many countries. The population oE the USSR has enough vegetable protein but not enough animal protein. Livestock animals do not have enough feed protein, especially complete protein. This brings about considerable overconsumption of feeds and 70 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR aFFrctni, ust, ortLY reducpg livegeack prdductivity. 'Che tnCa1 proCein drficteycy fdr humans and farm animalg in ehig rountry pXCehdS 9.5 millidn rnng. Ag a prartieal matCer, gasedus, mdlecular nitrogen is inaccessibte to higher organismg gnd cannot be ngsimilated by them. Uut chrtdin prn- cpsges Can ennvert this inere gns ineo fixed cnmpnunds that can bp assimilated by animals and plnnes. Thus, the world prndurrion nf Earm crops annuglly takes nut of ehe sdit abdut ild million tnns nf nitrogen. 'Che world'g chemieal industry mnkeg it pogsible to ineroduce ineo the soil about 44 millinn Cons of nitrogen fprtilizer (Calculgted gg N2), the utilization coeEficient of which does not excred 50 percenc. Thus, about 90 million tons of nitrogpn come fram sompplace else--Chiefly, bio- logiral fixntion of ehe nir's nitrogen. 2n soil ehat has not been agriculturally developed, the plants do not get nitrdgen fertiliaers and do not grow well, consuming nttrogen that has been built up binlogicglly. A greae vartety of free-living microorggnisms gnd symbiotic miCrobes that generally live in.the plgnt's root system can fix molecular nitrogen from Che air. These nirrogen-fixing microorganisms hgve nn enzyme complex called nitrogenase which makes it possible for them to assimilete N. One widely-used source oE nitrogen in farming practice ts legume crops that are in symbiosis with 12hizobium bacteria. There are other planCs which also assimilate molecular nitrogen in symbiosis with particular micro- organisms (so far these grassy and woody plants have not been put to agricultural use). Without participation by the microorganisms, the higher plants could not assimilate molecular nitrogen. This is generally acknowledged, although there have been attempts to prove the opposite. In the 19th century, for example, during the time of Napoleon III, his favorite chemist Georges Ville claimed that NZ is accessible to higher plants. It should be pointed out that the same view was held by the Soviet scientist F. V. Turchin, whose experiments however, were impossible to duplicate. In our times, Professor M. I. Volskty went even further. He claimed that not only the higher plants but also man and animals, even without the participation of microorganisms, can assimilate gaseous nitrogen in quantities that are more than enough for nitrogen exchange. M. I. Volskiy even attempted to have his stidies registered as the discovery of the phenomenon of assimi- lation of gaseous nitrogen by all higher organisms. A special commission of the USSR Academy oE Sciences, after precise verifi- cation experiments, declared that the conclusions oE M. I. Volskiy were erroneous. The same conclusions have been announced by a number of foreign researchers (J. Costa et al, 1974; D. Pierce, 1974, and others). Many researchers have wondered whether man and animals might not be � supplied with fixed nitrogen by free-living nitrogen-Eixing organisms liv- ing in their gastrointestinal tract (there are nc+ mass accumulations of microorganisms in the other organs). 71 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt OFFICIAI. USC dNt,Y On the bagis of gCUdieg by many investigatorg we mgy cdngider ie an egtablighed fac:e ChaC in gome inaeCtg whinh feed primarily on hydro- carbong (gphida, borers, termites, and so on) the nierogpn-Eixing mierobes living in the inreseinal trace play g vital role in the or- genism's niCrngen balgnce. HuC ehis finding Cgnndt be extended to mgn and furm animals. Acnording eo R. F. Hardy, onp of the leading Ameriran speciglists in nierogen f.ixation, nitrdgen-fixers in the gastroinCegtinal Crect df Earm gnimals are cgpable of providing the orggnism wieh only abo!it 0.1 peraenC nf the proCein iC nepds. The beneficial influence on soil fertiliey by symbiotic nitrogen fixers-- legume plgnts--hgs been well known gincp ancient rimes. This is known frum the wrieings of Theiphrastus, Virgil, pliny, Cato, and Cnlumelt8. At the end of the 18th century, the Auatrian monarch Joseph II elevaeed the agronomist I. Schubare to the Court for introducing clover to culti- vetion, leading to a sharp increase in yields of other farm crops. The Bprlin Academy of 5ciences awarded Schubart prizes Eor his wnrk on the development of feed grasses. In the 19th century, G. Schulze from Lupitze became famous in Germany for cultivating heath lands, using lupine as green ferrilizer. After conversion Erom the Chree-field sys- tem to crop roCaCion cycles with clover, yields were doubled in Europe _ between 1840 and 1910. In Russia, the firsC legume crop was clover. Introduced in 1776 from England, it was first grown in gardens. Even then, the first Ctussian scienCific egronomist A. T. Bolotov advocated and promoted the idea oE using clover as a feed. In the 1820's, I. I. Samarin introduced clover sowing into Russia on large planted areas and developed the valunble Kanishchevskiy variety, which was further developed into today's Moskov- skiy-1 variety. The Zemstvos and the Zemstvos agronomists advocated the sowing of clover. In his lecture "Sources of Plant Nitrogen" (1890), K. A. Timiryazev mentioned the names A. A. 2ubrilin and V. G. Bazhayev. By the late 19th century and early 20th century, clover was already widely cultivated in this country. Before World War I, Russia was ex- porting up to 500,000 poods of clover seed. At present, many countries are making extensive use of legume crops, in particular soy, to boost soil fertility and produce protein. Ttie exceptional value of legumes as a rich source of protein accounts for the fact that in the United 5tates the area planted in soy was increa5ed from one million hectares in 1935 to 23.5 million in 1977 (the country has a total plowed land area of 140 million hectares). Large areas in the United States are also planted in alfalfa and other legumes (about 15 million hectares). It is worth noting that 80 percent of the income from United States farm product exports comes from soy, which is pur- chased by many countries in Europe and Asia. Other countries in the Western Hemisphere are also increasing their areas planted in legumes (Argentina, Hrazil, and others), frequently at the expense of coEfee plantations. 72 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR orFrcIAL usc aNLY Lngumeg havp a number oE valuable prnperCles. Their abundance oE protein is evidencgd by compgraCive daea given in Table 1. Tablp 1. CO11e111NqHt10 ~Jn6nnwe trytlbrypw CoAep~aulte 8lpIt0Y1JA NyJtbTyalt OE11N9. % OO11HA~ % M pq (7) 0 (88pH0 nym'~yua ?0NtLO090C (eoPeo) (8) ConoNa 7,0 Jlmttng (aoplfo ~ 9 3Z,0 10,0 Cott (GoGwy 13,0-15,0 Ceno Cono~sa (12) 1S.C P,.; , Y1~ Key: 1. Grain Crops 2. Protein Content, percent 3. Legumes 4. Protein Content, percent 5. ltice (grain) 6. Corn (grain) 7. ldhear, rye, oats (grain) 8. Straw 9. Lupine (grain) 10. Soy (beans) 11. Nay 12. Straw Legume protein is more complete than grain proeein, and in terms of amino acid composition it surpasses grain protein in solubility (Table 2). Legumes, especially perennials, leave rich post-harvest residues in the field and serve as excellent predecessors for other farm crops. They fre- quently function as sanitizing agents preventing plant diseases. A1falEa, for example, clears the soil of the verticillium agent of cotton wilt. Alfalfa-cotton rotation cycles make it possible to combat this disease, which devastates-mnnocutture:cotton. Many tegumes can be used as green fertilizer. another important factor is that legume protein is cheap. It is ten times cheaper than cereal grain protein and several dozen times cheaper than animal protein; feed yeast protein is also more costly than legume protein. In his report at the July 1978 CC CPSU Plenum, CC CPSU General Secretary and USSR General Supreme Soviet Presidium Chairman Comrade L. I. Brezhnev focused specially on the protein problem. He spoke of plans to expand crop areas and increase the legume crop harvest. L. I. Brezhnev said that soy is a valuable crop and that it is necessary to seek out ways to expand crop areas and perfect the technology of soy cultivation. 73 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 Table 2. ( 1), ltYnbrypm ~i) ~ $epgoswe: ~ j e s a ( 11 1 o enbu 8 p nm nqueab (eepno) 1 S060swe: (14 awnaa aopuo) 1 S� ~ ; cua (606m) aauopaa ceno) FOlt OFFTC:[AL USE qNLY 2 COAOpNtUdNO 9M11II0KHUOT. f/k1 A a9~a I MernouxIt I u~ orI+u ~s ( 8,8 9,9 5,5 18,9 2i,0 11,6 Key: 1. Crop 2. Amino Acid Content g/kg 3. Lysine 4. Methionine 5. Cystine 6. TrypCophan 7. Total 8. Protein Solubiltty, percent Pacrao- NMOCTb Dcero enw~ !b 2,! 1,6 0,5 7,6 31 2,2 2,0 1,8 9,9 60 2,2 1,9 1,7 !!,8 50 4,2 4,6 8,8 3l,5 90 4,8 5,3 4,8 383 85 2,3 3,8 8,2 25,9 90 9. Grains: 10. Corn (grains) 11. Wheat (grain) 12. Barley (grain) 13. Legumes 14. Lupine (grain) 15. Soy (beans) 16. Alfalfa (hay) The theoretical and practical significance of the nitrogen-fixation pro- cess is such that international conferences ere held every year to deal with the problem. In the United States, some privar-_ organizations (the DuPont Company, the Kettering Fund, and others) have special laboratories studying the problem of biological air nirrogen fixation. Nitrogen fixation has drawn the attention of many outstanding foreign and Soviet scientists, in particular D. I. Mendeleyev, K. A. Timiryazev, D. N Pryanishnikov, and others. In 1690, K. A. Timiryazev stated in his public lecture "Sources of Plant Nitrogen" that there are few phenomena in nature whose scientific study is more closely linked to practice than nitrogen assimilation and the cultivation of legumes. The founder of our agrochemistry, D. N. Pryanishnikov, emphasized that it is wrong to set the use of mineral fertilizers off against the use of biological nitrogen: they complement one another, but they cannot com- pletely substitute for one another. To this we may add that the effective- ness of mineral fertilizers increases strongly on backgrounds cultivated with legumes. 74 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOtt OFrICiAL USL dNLY In thie CounCry, the sctentific lnstteuttons nE the U55R Academy oC ScienCes, the USSEt MiniStry af Agriculeure, VASKhNIL, and oCher depert- ments are doing a great deal of coordinating worlc on the problem of nitrogen fixaeion. 'Chey are studying the biology nnd physinldgy oE the nierogen fixers, the biochemisCry of the process, and the geneeics oE the nitrogen-fixing microbes and legume crops (ehis work nnw ries in with genetic engineering, aCtempCs are being made to transfer nitrogenase from nitrogen flxers to microbes that do not assimilaee N) and modeling the process of nitrogen fixaCion in order to find wgys ro2fix N2 under "soEr" conditions. In this case I will confine myself to juat one aspect oC the problem of biological nitrogen--irs practical aspect--explAining the role of the nitrogen EixaCion process in our land cultivaeion. First of all, a few comparaeive figures. According to 1977 data, the USSIt had 21.1 million hectares planted in perennial grasses and 15.8 million in annual grasses--a total of 41.9 million. From the aggregate data we can judge that legumes Cake up About 25.8 million hectares or about 11.4 percent of the plowed land. In the United States, legume crops take up 27.5 percent of the plowed land. Average yields there are higher than in this country, chiefly because of climatic conditions. Our rough calculations show that legume crops in this country produce about 21 percent of all the protein produced on-arahle -sofl. Table 3. shows the amount of protein produced from arable soil in 1917. Table 3. Ik07IN48� HOJl1f40- (7) ( 1) HeAo6oemo cTeo (6 1o6oeMO 1ryabrypU creo xp~brypw GenKa, 6oaKa, Mm r MAH� r s~3 3epso l Conoaia ~ 5 1 Ce$o 26,2 Fo6u (a) 5,2 Ceso: 3,0 a~uoroneircar xyn6TYp s10 OJ(1lOIIOTfIit!C ICyJILiyp (11~ 2,9 5,2 1�1 (12) Bcero I 34,4 Bcero (12) I . 9'2 Key: 1. Non-legume crops 2. Amount of Protein, millions of tons 3. Grain 4. Straw 5. Hay 6. Legume crops 7. Amount of protein, millions of tons 8. Beans 9. Hay: 10. Perennials 11. Annuals 12. Total 75 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 roR orFrciaL usL nNLY 'nce mcadnws of the 115S1t cati pruducr. hHy c'.untnlnliig ubuut: 3.0 mt l llon tuns of proteln, including about 0.8 millidn tons Erom legume grnsses. 'Chus, thc land area Ln agriculturnl of prntein, including 10.0 million abouC 1.5 million tons of protein). use can produce 46.6 millton tons from legumes (legume pastures produc:e In the United States, 140 million hectares of plowed land yield aboue 68 million tons of protein, with 36 millton cnming from grain and about 32 million from legume crops--that is, legumes produce 47 percent of the protein. In the world production of protein, according to FAO data, legume grains account for about 20 percent; in this country the figure is only 5.8 per- cent. The protein our livestock animals get in feeds is chiefly grain crop pro- tein. But these crops are poor in protein, thus accounting for consider- able feed overconsumption. of the total cereal grain harvest, the popu- lation consumes 35 to 37 million tons; livestock animals get at least four times as much. Available data make it possible to determine the approximate amount of molecular nitrogen fixed by legume crops on our fields under present conditions. The amounts of nitrogen fixation--that is, the amount of N2 fixed by legumes on all land aYeas--are given in Table 4. In compiling it, account was taken of differences in the amount and chemical makeup of after-harvest residues of perennial and annual legume crops, and it was assumed that 70 percent of the protein is built up by the legumes by fixing molecular nitrogen. Symbiotic fixation of N2 on agricultural lands yields a total of about 3.0 million tons of nitrogen. This means that at present prices on mineral fertilizers, our country's agriculture is getting about 0.7 billion rubles from legume crops. Income from legumes can be substan- tially increased if crop yields can be doubled. We have decertulned quite clearly what agronomic measures promote increased legume crop yields. These crops react very raell to phosphorus fertilizers and certain trace elements (molybdenum and Uoron); many of them require liming of the soil. It is useful to introduce small doses of nitrogen fertilizer for legume grain crops. Perennial legume grasses do not need nitrogen fertilizer, although sometimes relatively authoritative organi- zations have given the opposite recommendations; this is not only useless but also harmful, because mineral nitrogen suppresses nitrogen fixation. 76� FOR OFFICIAL USE ONLY , APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR OFF'TCYAL U5E ONLY Table 4. ` lin7uvir.rnn nouru, wmi, r oGiuero 'DIIui IInOBpIIHOPO ' 2 ) ua uuaayxn `g (4) IIaam Ypoacaii GoGonwx 1,5 9.1 Ttumrutum.ie OCTAThI( GUGOBLI:C I 9;5 I l'p (7)' E0T8CTD0IIL140 J!)+1'& II II&CT6IIIQU � (Cmio, cof,panuoe c nyroB, u rpa- 0,4 0,28 (g ~ na, norpeGucuHan )ltztnor- nwnut nprl nianoco (q) liop�Onble ocruTrn 606oBbIx 0,7 0,69 + II TCII, 4T0 6p6oauUi ItOMt10H@NT COCT8gA1l@T 12,5% MdCCW (10) Tpaeocron. , Key: 1. 2. 3. 4. 5. 6. Amount of Nitrogen, millions of tons Total Fixed from the Air Plowed Land Legume l.Yield After-harvest Legume Residue 7. Natural meadows nnd pastures * 8. Hay harvested from meadows and grasses consumed by gr.azing livestock 9. Legume Root Residues 10. *It is assumed rhat the legume companent consititutes 12.5 percent of the grass stand mass. Recently, plantings of Legumes have doubled in certain areas of the USSR: Odesskaya, Chernigovskaya, Kustanayskaya, Krasnodarskaya, and a few other oblasts. But not enough grain le$umes:are being planted. Our main crop is peas, but peas could be utilized to a greater extent. Areas planted in lupine and feed beans are inadequate. We must substantially increase plantings of soy beans in areas suitable for this crop. Green beans, which took up 160,000 hectares before the revolution, are now planted on a considerably smaller area. Land planted in lentils has been reduced by eight times since before the revolution (from 420,000 to 50,000 hectares). The total area planted in beans in recent years in the USSR has been de- clining, as seen in data preserted in Table 5, which shows the harvested area planted in certain bean crops (in millions of hectares). These are approximate data, because we have only generalized material on hand, and these do not always clearly define the status of individual crops. 77 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 Fox nFFicint, cr5E Orrt.v Table 5. ItfnlaypM 1000 r, 013 r, 1070 r, I971 r, 2) Hce 6u6oeme 20.0 20,7 23,3 25,8 4 ~ B roII vecao; stuoronornNO Tpauw f3,0 14,8 l4,2 fb,i S oAnnno*nNO rpauLc (6) nepuoGoGoniaa (c coaA) 7,2 9,7 7,9 7,3 2,8 0,3 4,b aA Key: t. Crops - 2. All Legumes 3. lncluding: 4. Perennial Grasseg 5. Annual Crnsses 6. Cereal Legumes (including soy) Legumes Eix niCrogen properly only if their root system is infesthd with bacteria-forming nodules. For this reason, when sowing legumes it is recommended thnt they be inoculated with rhizobia. Our country produces a compound of such bacteria, nitragin, which must be applied when snwing legumes on land new to them. Nowever, the situation is nut very good with respect to the manuEacture oE nitragin. In 1978, agriculture received 0.5 million tiectare batches of nitragin versus requirements of about 4 to 5 million. We are now taking steps to boost production, but so far industry's nitragin tnrget has not been specified. Expansion of the cultivation of legumes In our couritry is being hampered by a number of objective difficulties (lack of seed, fertilizers, tier- bicides, new systems of machinery, and so on). But it seems the maiti diEEiculty here is that some leading agrochemists claim that the nitro- gen problem i-i our land cultivation can be resolved only on the ba5is of using mineral fertilizers. For example, Professor V. K. Prokoshev, speaking at the Pryanishnikov Lectures in 1975, declared that legumes have outlived their usefulness. He recommended that high doses of nitrogen be applied to grain crops and that the resulting straw be used to feed livestock. Nitrogen ferti- lizer tncreases the protein content in the grain and straw oE cereal crops, but nevertheless this "rationalization" of the feeding of live- scock is doubtful. 78 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt UFFICIAL U5E ()NLY Wrong Idr.im ,ibout tlir ItnporCancr of IrKumrs ;ire ba4rd dn n numbrr ul vrror!;. tn pnrL[rular, it ly uttrii clatmvd t.hat thv countrtrs ol wVHlvrii I:urnpr du nuC c:ulLlvratr lrkumrs dn a Iarge ticulr. tfut tlirsr cuuiitrlrs purchuyv cnormoun qunnt[tlr5 nC soy in the Un(ted 5tntcs. ir, ior rxnmplc, thr 1'{tC wanc.cd tn produce the lpgumes tt nEeds nn i.tq nwn it wnuld have to usV h.711 of it5 urablr latd. D. N. Pryantshniknv emphasized thet to resolve ngriculturul problems it is riecrtisary to procrrd on the bnsis of nur own cnuntry's intereqts and noC btlndly copy forrign pr+ictlc:e. This {s true nlso of the nitrogen problem. At preseiit, the U55tt M[nistry of Agrlc:ulture, Implementing the decree of thr CC CI'SU and thr US512 Council of Mtnisters "Measures to Jncreasr thr i'raduc t I on and Irnprove Lhe clua 1 t ty of Feeds," pub I t shed un 1 l Ju ly 1978 pluns to c,irry nut ;i riuuihur of esSentlal mrasurrs des[Knrd, in pnrtirulnr, t" r>:pniid lvgume plniitingy and bodst crnp yfrlds. Uur cnlcul.7ttons show thnt the role o[ legumes in protein productinn wlll tncrvase strongly. in 1977, legumes accounted Eor about 20 perCent of the vrket;ablr protein produced by this country's agriculture; in 1980 the fig- urr should reach 24 perCent, and In 1985--28 percent. 'Chis is [ully con- sistent with the decisions of the 28th CEMA Sesston in 1977, which rec- ommended that CEMA.countries txpand land areas planted tn cereat legumes, in p.7rticular soy.` N Itecr.ntly VASKhNIL E'resident Academtcian P. P. Vavilov and Candidate of Agricultural 5ctences C. S. Posypanlv published an article titled "Legumes, Nitrogen, and the ['rote{n l'roblem." The authors are of the opinion that evrn[ually area planted in cereal legumes in this country should reach 20 tn 25 millton hectares. Even in this case, however, there will not br enough complete protetn (about 2.5 to 3.0 million tons) considertng tlie growth of livestock farming plannvd by the USSR Ministry of Agricul- L"rr. c11 rours~~. llir ~ rf iciency in complr[V pro[ein can be made up partially by m(rrnl,i;il synchotiiti. Nevcrthrless, in our opinion, for boosting [he produrcion of protetn it is advisable to make morr intensive usc of tLc lrgume componen[ on natural meadows and pastures. So far, only 50 million our of 380 million hectares of such land have been cultivatcd. Pfost of this area, in essence, is virgin land, the development of which is quice promising but rc�quires subs[an[ial efEorts. In this connection wc recall [he heroic era on the virgin lands of Kazakhstan, so brilliantly described by CC CP5U Cenerai Secretary and USSR Supreme Soviet Presidium c:hairman Comrade L. 1. Brezhnev in his work "Tselina" [Virgin Lands]. All soil5 h,1vc many frce-ltving nitrogen-fixing microorganisms. These are mostly bac[eria feeding on organic substances. Inhabiting the plants' root zone, where che roots release various organic compounds, the bacteria 79 FOR OFFICL'U, USE (1N1.5' APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 Fox OrFICtAI. usE oNLY can �ccumulatc y c:ertain qugntity of nit.rogen. Cxpertmentul datu indicIIte thae amounts of :;uch iiitrdgen accumulntion are not gre,yt ind hava nn sub= tnnttA l. tnfluenc:e nn the size o[ rhe crop. 'Co Fi greciter rxtent the nc:tivity of the nitrogen-fixer:i i5 deCermiiicd by thc sotl.'s orgnntc compounds and plant residues. Until recently it was belleved thar thrsr sources of nitrogcn-ftxer nutriti.an wcrc 'llso Ln- capublc nE cnyurtng adequatcly htgh nitrogpn accumulation tn thp soil (tlot more than 6 kg of nitrogen per hectare of sotl per year), but a c:ycle of research rarrled out in eecent yeurs abr.ohd and iri the USSk compcl us to c:hange thts potnt o[ view. l'able 6 shows d1ta on atnounts of nitrogen ftxation by frrr-living miCrobrs utiltziig p1nnt resl.dues and, in part, products of humus mincrbllzatton, in differenL solls of thc USSK (ktlograms per hectare per year). '1'ab l c 6. (2) Aaormrkcaqan 31 88 CqCT (4) ~ 5~ ~ TIO~IbN ~1pOx)'K100 A C4QT ~IItI1P~~0:1N38� qllH f}'YyCa nACiHTEJt6- 1114% OC78TNOB ecero 6 ~ ; 7 Tlepnono-noAaoagcnte 1,8-8,0 5-7 6,8-13 Cepmo nocsa~e ~ ~ ~ 4e uoaeYm 3,D-9,0 18 0 0 0 i5-20 8 35 18-29 3 p CQl K , - , - 2 7-53 aMTaeosbte (10) C 3.0--10,0 f5-20 18-30 epoaeum 3,040 15-20 18-29 Kry: I . Soil 6. 2. Plitrogen Fixation 7� 3. From Products of }lumus 8. htineralization y� 4. F'rom Plant Residues 10. 5. Tocal Soddy-Podzolic Grey Forest Chernozems Chesr.nut Serozems Appruximaccly the samc data are citeJ by other investigators (i. G. 'Lakhar- rlirnku, C. S. Pirozhrnko, 1970; J. Day et al., 1975; I. S. Shatiluv, 1478; .iid othersl on the basis of anal}tzing many years of fteld experi- Iill'I1tS. NitroKen Itxed by tree- living microo:ganisms sliould be vicwed as a soil rcplenisliment: it is consumed more slowly than mincral nitrogcn. I( we ;lssume rather modes[ amounts of nitrogen fixation by tree-living microbes (15 kilograms per hec[are per year for arable soi1, 6 for cultivated meadows, iind 2 Cor virgin meadows), the nitrogen accumulation on agri- culturatly developed land in the USSR will be expres~,ed in thc f.ollowinc; 80 FOR OFFICIAL USE ONLY 4 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 rnn nFFtcrnI, USL ONLY nmounts (calCUlated tnr N): 3.5 mlllton tnns nE ntCrngen per year Edr ardble sdil) 1.0 millidn idr meadowg and pngture Lat1d5, r.dtal 4.5 millinn. Thp equivnlenC mmounC of minernl fertilizers Cd5tg 1.2 billion rubleg. The questinn Hrl.ge5 as to whether ?.e is nne rdglilble to strengthen Chp soil gctiviey of the frpe-living nitrdgen-fixers7 Thty can be accom- plished by inCroducing nrgnnic matCer intr, thp snil. Most Epnsible for Chis purpoge is thp use of strgw, the mmounr of whLch in the USSR comes Co more than 100 millinn tons nnnually. As n rulp, this straw is burned. There is e relucCancp Co plow ir inro the snil, bpcause strgw C8U508 fixation of minernl niCrogen end thus Y'edUC05 crop yields. However, techniques have been worked oue for avoiding this unfavorable effect of straw and making it possible even in Che first year to obtain positive results Erom its introductinn. The positive effecCs of straw are alsn apparent in the next one or two years. 5traw can be used successfully as gn organic ferCilizer for rice, legumes, and grgins. In- troduced into the soil as a Eertilizer, 100 million tons of straw are equivalent to 0.5 million tons of nitrogen. Soil microorganisms fixing N2 can fix at leasr five kilograms of nitrogen for every ton of strAw tFiat is introduced. This results in another 0.5 million tong of Eixed nitrogen. Consequently, 100 million tons of straw put into the soil will enrich it with compounds containing 1 million tons of nitrogen which can be used by the farm crops. The only cost will ye otitlays on plowing the straw in. In terms of the coefficient of assimilation by the plants, nitrogen fixed by microbes is approximately equal to mineral Eertilizers. If we compare the amount of nitrogen produced in this country by the chemical industry and by biological means, it turns out that the contri- bution of biological nicrogen to agriculture is quite substantial. According to data from 1977, the chemical industry supplied agriculture with 7.7 million tons of nitrogen calculated as N2, while soil nitrogen- fixers supplied about 7.5 million tons (about 3.0 miIliori tons from sym- biotic and 4.5 willion tons from Eree-li.ving nitrogen-fixers). The importance of mineral nitrogen as a more effective factor in boost- ing crop yields will undoubtedly increase, but we cannot ignore bio- logical nitrogen. It is essential to find ways to make more extensive use of it. The academic institutions must determine the possibility of using not only legumes but also other plants capable of fixing N2 in symbiosis with microorganisms; they must determine the symbionts of these plants, find out what factors determine the energy fixation of molecular nitro- gen, determine the structure of nitrogenase, expand efforts on the genetic engineering of nitrogen-fixers, and resolve a number of other tasks. 81 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOit OFFICIAL U5C nNi-1t Thp regeerch ingriCUtiong of ehe US312 Minigtry of Agziculture, VASKhNIi., and other deparementg must determine whae xaneg atie guitable Eor culti- vnting legumps, develop varieties ChgC efEicientty Eix nitrogen under certain conditions, gnd develop equipment for their cultivation and harvesting. Glavmikrnbioprom will have to subgCgneially expand the production of bacterial i:ertilizers. LeC us hope that these reaponsible projects will be carried nue. FOOTNOTES 1. See P. P. Vavilov and G. S. Posypanov, VESTNIK SEL'SKOKH02YAY5TVENNOY NAUKI, No 9, 1978. 2. 5ee Kh. Goranov, MEZHDUNAR09NYY SEL'SKdKHbZAYSTVENNYY ZHURNAL, No 4, 1977. 3. See VESTNIK SEL'SKOKHOZYA.'iSTVENNOY NAUKI, No 9, 1978. 6854 CSO: 1870 ~ 82 FOR OFFICIAI. USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoR nrFzcrnL vs r. nNLY UDC 630:54 FOR'THCOMING TASK5 OF AGFtICULTUttE CHEMICALIZATION Moscow VESTNIK AKADEMII NAUK S5SR in Russian No 3, 1979 pp 68-75 [Report by Academician S. I. Vol'fkovich] [xext] The chemicali~.ation of agriculture in the USS[2 in recent years has been developing on a steadily rising scale and at an increasingly faster pace. In 1973, the 5oviet chemical industry emerged in first place in the world in terms of total volume of mineral fertilizer production. In terms of ~ the output of synthetic carbamide, potassium salts, and feed phosphates, our country holds a leading place; the Qroduction of pesticides and the number of physiologically active substances is not developing fast  enough. With each passing year, especially since 1965, there has been an incrPas- ` ingly marked rise in the number of integrated measures to intensify farm production, to chemicalize, mechanize, electr,ify, and reclaim the land, to improve the quality of land cultivation, all factors which strengthen one another. An analysis of toclay's status of chemicalization indicates that in addition to substantial progress in this area there are also somi shortcomings. The level of agricultural development is not yet keeping pace with our rapidly rising needs, and requires further vigorous efforts to buost it. One of the most important scientific-technical and economic tasks facing our nation today in the area of the production and use of mineral ferti- lizers and livestock feeds is that of raising the level of use oF natural raw materials and combating significant mechanical, chemic.al, and bio- logical losses of products. Over the next few years, plans call for major capital investments in building mining and cher:;ical enterprises to pro- duce mineral Lertilizers. And increasing levels of production and larger amounts of capital outlays make increasingly intolerable enormous losses of raw minerals containing nutrients, aspecially phosphates and potassium salts. � 83 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt OFFICIAL USE qNI.Y Naturnl minergl resourcpa nre limited and non_renewable. Meanwhile, irrr- trlevHbla lnsses Eire yn grent that evr.ryone invnlvr.d In rhr minings pro- crsying, nnd utlllznttun oC feretllzer ln ngrtculture must urgenrly Und vigorously tgckle the tgsk oE gubstantigtly haosting tlir etEtcienry index of both raw maCerials and fertilizers. Industrial experience indicates that from 25 eo 50 percent of the minernl is lcft in the ground when mining natural phosphates. Up to 30 tn 40 per- cent of the mineral is lost in the process of primgry and secondary con- centrgtion of phosphorite ore (washing, crushing, grinding, flotation, and so on). After flotation concentration of the apatite-nepheline ores oE the Khibiny deposirs, the phosphate has been reduced by six to eight per- cent. With mechanical and chemical operations in the processing oL natural phosphates for phosphoric acid or concentrated fertilizers, five to eix percent of the phoaphorus is lost. Phosphorus losses are also great in the soil, because of retrogradation (the binding of easily soluble, mohiie torms of phosphorus to forms thar are insoluble or assimilare slowly) and other processes t}iat are not _ fully studied. In the first year of application of phosphates to ehe soil, the plants assimilate 20 to 40 percent oE r.he phosphorus, depend- ing on the soil type and the fertilizer; in subsequent years the figure is even lower. But several dozen years of field experiments at the Uolgoprudnyy Experimental Station imeni D. N. Pryanishnikov (Moscow OblasL), Rothamstead Station (GreaC Britain), and elsewhere indicate that phosphates, especially in acid soils, continue to nourish the plants for a long time. Losses are also great in the mining and concentration of potassium salts, running as high as 30 to 40 percent; the shortage of chlorine-free po- tassium fertilizers reduces the quality of potatoes, buckwheat, grapes, . citrus, and other industrial crops. The storing, transporting, and use of ammonium nitrate also invotve sub- stantial losses. Rain and irrigation water convert the nitrate into soluttons which soak through the filtering soill down to depths that are inaccessible to the plant roots. To a lesser extent such losses, also hydrolysis releasing gaseous ammonia, occur in the use of carbamide (urea). In contrast to am,nonium niCrate, moreover, carbamide is not flammable or explosive when m~.xed with certain organic substances, and it contains eleven percent more nitrogen than ammonium nitrate. For this reason, the production of carbamide ought to be developed further, especially since the cost per unit of nitrogen in carbamide and ammnnium nitrate is now comparable in a number of plants;in some foreign plants, the cost of carbamide is even ten r.o fifteen percent lower. ' 84 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 rnR orrtCtnL usr nrri,Y Uinlogl.cnl ldwsry ot' nitrogr_n contiinrd {n frrt[l1.zer.:;, due tn prochysrs of nttriEtcation at,d aenitriricnr.ton of immonli, and thc use of ehe ciltr.n- gr.n by mic:rnorgantsms In the soil, ,71tr.r the origtnal acce:;gibtliey nt' the fertf 1 ixrry to rhr plnnty and cnuse th~ gnsrnus produrt4 01` itw c-orivrrsinii to vvrporaiLv. ltrsrrirch by I~, V. 'I'urchln fand uthrr riurachvmlst~ liiiw shawn thAt tol-nl losses of ntrrngcri run as hlgh as 15 ro 30 porcrnL. In the past ten ycars, thE 5oviee Union has created a substnntial network of agroChemicttl laborarories (more ehen 200) und a number of scientific- research instttutes of ugrochemtsrry and soils science and experimental _ stations; they have been doing considerable work on charting soils to determirte the sufFictcncy or defictency of nutrients in Ctie snil. What is astonishing is that Eor several Eive-year periods the planning orgnns httve been using rhe same Eertilizer effectiveness standnrd--1.1 quintal of grain yteld increase per quintal of terrilizer (in standard units). This Eigure ts lowcr than yields on many lcading lcolkhozes and sovkhozes, also farms in a number of Eoreign Cquntries, where yteld gains run as high as three to Eour quintals or more.` It must be stared, regretfully, that despite eFCorts to combat mechanical losses of fertilizers in transporting and iri ware}louse storage (10 to 15 percenr), these losses have remained practically unchanged Eor several years. Not enough Rttention is being focused on efEorts to combat losses of fertilizer nutrients due to their consumption by weeds. necause of poor weeding and inadequa::e use of herbicides, large qtiantities of fertiltzer never reach "their interAed recipient." Because of the variability, both in time and terms of varying climatic and soil conditions, of data concerning losses and inadequate utilization of fertilizer nutrients, it is difficult at present to calculate precisely the total eEficiency of fertilizer and total losses. We can state without exaggeration that the average practical efficiency of mineral fertilizers does not exceed 50 to 60 percent of the total nutrients conCained in the raw mineral. Consequently, enormous capieal investments in mining and chemical enterprises are not being fully utilized. If we could produce and use mi;ieral tertilizers on a completely scientific, systematic and thrifty basis, our national economy could save large anounts of capital investments and labor. In the future coe must make a deeper and more thorough analysis of the possibility of replacing some of the sulfuric acid with nitric acid in the production of phosphoric acid and fertilizers, also the possibility of developing thermal and alkalirie-thermal methods of production, in- cluding the hydrottiermal meehod using natural gas or fuel oil, and, as power engineering becomes further developed and electricity becomes cheaper, the use of electrothermy. Losses may also be reduced in the 85 FOR OFFICIML USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FnK OrrIc.IAL i15C UNLY Euture by working nn Chc production nE polymer phuqphorus t`rrttlizers that nre not fixed by the soil, und nitrogen fnrtlli7r-rs thnt arr ilot wnshed away by rain nnd irrigation wnter. In reccnt ycars, explor.ntory nnd thcorctical reshnrch has been carried nut to determine the pnssibility of Utnding the nitrogen oE the air (witli thti pnrtiriparion nE cnralysts) wirh various compounds inro ammonln and othrr compnunds, also the pnwstbtlity oE synthesiiing nmmnnix Frnm iiitragen ntid hydrogen at low temperatures and pressures. Plans call for developing the production oE carbamide And its derivitive5, ammonium polyphosphates, carboammophoska, potassium, polymetaphosp}iatr, phosphorus acid amides, and orher new economical coricentrnthd and inte- grated fertilizers; plans also call for substaneially developing the production of mineral fertilizer mixes. Also being studied is the possibility of mining potassium salts by dissolving them in the ground and carrying out integrated processing of potassium-containing salts. It is also possible to conserve in the production of fertilizers by using production wastes; phosphogypsum, fluoride gases, carbon monoxiae, slag, rare elements, and other substpnces. This is not only of economic but also oE great ecological importance. DraEt plans for the production of mineral fertilizers call for boosting their output to 135 to 140 million tons in 1985 (in standard computation), with production to be increased in the 13th Five-Year Plan. Attaining the necessary level of fertilizer production in the llth Five-Year Plan will require the inauguration of plants having a capacity of at least 40 million tons of fertilizer. Raw material and energy resources arc enough to accommodate the construction of nitrogen and potassium enter- prises of large capacity. The situation is different with the produc- tion of phosphorus fertilizers because of limited proven reserves of high-quality raw material. It is partly because of this that in recent times there have been difficulties in meeting the phosphorus fertili.zer production plan both in terms of quanti.ty and quality. Some of the phosphorites that are mined contain a low percentage of phosphorus and are distinguished by variegated composition. The shortage of phosphates, compared with nitrogen and potassium, is also due to the lack of th? mean ratio of nutrients in the soil, especially nitrogen and phosphorus, required by agrochemistry. The July 1978 decree of the CC CPSU F'lenum emphasizes the necessity of eliminating this disproportion and ensuring the necessary raw material for the production of phosphorus fertilizers. The shortage of phosphoric acids has made more ~irgent the task of pro- ducing phosphorus fertilizers by acid-Eree and waste-free methods. 86 FOR OFFICIAI. USE UNLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 roit nrrtc; CAL US1, Otvt,v In tk?e lase E'i[tecn years, thc 5oviet chemtCal Industry has, on rhe basis of Soviee scieneiEic-teChnicxl developments, created a sector Eor the produceton of teed phoaphAtes, CI1jCfly on the basis of whrat is known as the hydrnthermal or pyrnhydrolyttc process, ttlso whar gre known as Acid methods. In 1978, Eeed phosphates were betng produced by Lourteen Soviet chemLcal plants'. Mnny years of romprehensive re- senrch by the agroc:hemists have shnwn that melted defluorinated phos- , phaees made of Soviee raw materials, with bulk appLicaeion to the soil, is equnl in effectiveness ro superphosphate, a water-soluble fertilizer. Just as efEective are products trom celcing or Cusing phosphates with Alkn- line salts and natural nluminosilicates. To reduce nitrogen losses due to Che high solubility of ammonium nitrate and carbamide, meehods have been developed for fusing them with formalde- hyde, urotropin, or other substances in order to produce �ertilizers that dissolve slowly; these are especinlly effective in corton farming. To some extent, granulared fertilizers also help to accomplish the same pur- pose. Successful experiments have been carried out in modifying and capsulating fertili.zers, especially carbamide in composition with elec;.en- tary sulphur. For reducing losses of gaseous nitrogen oxides, the use of inhibitors has been proposed. As a result of many years of vegetative and field experirnents, we have now essentially proved the effecriveness not only of phosphorite meal of a cer- tain geological age, chtefly on acid soils, but also thermophosphates that have been defluorinated with stearti at high temperatures, and melted phos- phates. Because the p:-oduction of these fertilizers does not require acids, and the defluorination process does ciot require alkali, there is no fo:�ma- tion of many tons of production wastes. All of this indicates that the production of these types of fertilizers deserves substantial develop- ment. In the near future it will be necessary to develop mechanical fertilizer mixing in order to turn out products having a specified ratio of m�trients and required ph-ical and chemical properties. It is necessary to expand the output and u~e of liquid compound or mixed fertilizers. The produc- tion of these items is increasing too slowly despite the fact that there is no doubt about their technical and economic effectiveness and other advantages. Several years of industrial experience in the hydrothermal processing of phosphates in cyclone furnaces to make feed have demonstrated its economic advantages over acid processes. Among citrate-soluble phos- phorus fertilizers, many countries have long been using phosphate slag from steel production. In the USSR, phosphorus-containing iron ores from Kerch' annually yield sever.al hundred thousand tons of phospiiate slag. We also have other phosphorus-containing iron ore deposits a Lisakovskoye, Ayatskiye, and others~ The next vital task facing our metallurgists is that of producing phosphate slag frow these ores in order to increase reserves of phosphorus fertilizers. 87 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOR OFFICIAL U5L ONLY Because of rhe low perceneage of phosphorus in most Soviet phosphorites and the substantial amount of undesirable inpurities in them, we face the urgent task o� developing economical methods of concentrating low-grade phosphoriCes. ElecCrothermal merhods of processing phosphates intd fcrti- Lizers a re costly. IC is much more promising, as is indicaeed by 5oviet and foreign practice, to process nitric acid phosphates to produce com- pound nitrogen-phosphorus and nieruaen-phosphorus-potassium EerCiltzers. In addition to exploratory and more intensive chemical-technological re- search inCo Che use of low-grade phosphates, it is essential to srep up geologic al-exploration work in order to find abundant deposits of phos- phates and intensively develop effective processes of inechanical, thermal, and chemical phosphate concentration. An important technical-economic task facing the potassium industry is the use of e normous wastes of sodium chloride, magnesium chloride, and other substances formed in flotation or halurgical processes of making potassium chloride from sylvinite. Major forces must be mobilized to resolve rhis task, which is not only of economic but also ecological importance. Con- tests should be held for the best solution. Up to now we have not found satisfactory solutions to the task of process- ing compound potassium ore, which also contains sulphates, from deposits in the western Ukraine and the southern Urals. In the last few five-year periods, scientific-technical applications in the nitrogen industry have achieved substantial economic effectiveness thanks to the us^ of natural gas, improved equipment, a higher degree of utilization of energy in the synthesis of ammonia, and increased equip- ment unit capacity. It is essential to further develop the production of - carbamide and carbamide salt, including phosphates which are used not only as compound fertilizers but also as effective supplementary feed for live- stock. It is also necessary to expand work on introducing into complex and mixed fertilizers trace elements of particular composition and quantity, in accordance with the recommendations of the biochemists and agrochemicnl services. Also deserving support is work on the rational production oE m;.neralor4anic mixes which include peat, ::oal, and other types of raw material.~ Standing somewhat apart are problems of developing hydroponic plant hus- bandry and hothouse farming on closed ground. Despite the. already proven enormous technical and economic prospects of plant husbandry without the use of natural soil, and the presence in the USSR and other countries of many years of industrial and agrochemical experience, it seems to us that hydroponics is developing suprisingly slowly. Hydroponics provides continuous, year-round and round-the-clock 88 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FoK orrxcTnL usL OrtL,Y automxCed plant husbandry which does not depend on Climatic and sail conditinns--a genuirie product of ineegrarion of c:hemicalizntion and elecCriL�icarion of ineensive plant husbandry. Flydroponics makes it possible eo grow vegetables, berrtes, and cerCain Ceed nnd induserial crops not only in present farming areas, but also above the artic circle, in desert and tnountain areAS, and on waste land. klydroponic hothouses cen be multi.-level and placed even on thc upper stories of large buildings. Hothouse installations ttre being used successFully both in the USSR and in other countries, in many enrerprises and around large cities and p1AnCs, especially in the North. Nydroponics represenls the next advance in indus- rrial hothouse fnrming. Because in hydroponics the soil is replaced wiCh gravel, sand, and othar mineral or organic materials of constant composi- tion that are insoluble in warer there is no worry about the composition of the eareh. ny means of automatic monitoring, the planes are periodi- cally irrigated with solueions of fertilizers of a given composition. Electric lighCing and heating are also dosed automatically. Hydroponics makes it possible to boost plant productivity considerably And to re- duce outlays of labor and consumption of water per unit of output. It is possible that some plants should be nourished with solutions of mineral- organic fertilizers with physiologically active substances (vitamins, growth regulators, and so on). Although capital outlays on hydroponic hothouses are higher than for ordinary ones, their technical-economic advantages over the larter are substnntial in operation. According to data of the Institute of Agrochemical Problems and Hydroponics of the Armenian SSR Acedemy of Sciences (rhe first Soviet institute of hydroponics), in the near future all nursery culti�-ation of fruit and in- dustrial crops should be converted to hydroponics, also year-round pro- duction of fresh green Leed for livestock and poultry. The institute has designed several such plants made up of several levels and sections with - six to eight day cycles for germinating fresh green feed from grain seeds. One installation can produce 250 to 300 kilograms of green grass per day, rich in enzymes and biologically active and mineral substances. IIecause of the importance of boosting livestock farming in our country it is appropriate here to cite data from the report of Armenian SSR Academy of Sciences Academician G. S. Davtyan in the State Committee for Science and Technology Council for Chemicalization of Agriculture (June 1978). One hydroponic installation is sufficient for the healthy feeding of 60 to 80 milk cows or about 800 suckling pigs or sheep, or 12,000 laying hens. Such installations are now operational for large poultry plants in Yerevan; they have a daily productivity of 500 to 600 kilograms of green mass. Capital investments for the6construction of such plants should be recouped in seven to eight months. 89 FOR OFFICIAL USI: ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 FOIt OFT'TCYAL USE dNt,Y Iri recommending the development of industrtal hydrnponics, at coursc, we are noe placing it in opposition to ordlnary Earm producrt.on; we ar.e vtew- ing it as A branch of plant husbandry which not only opens up promising economic prospects but nlyo makes ir possible ro grow cr.ops under condt- tions where ordinnry soil cultivaeion is impossiUle or not worrhwhlle. Recently, ttie Scientific-Research Institute for Cer.ellir.ers, lnsecticides, and Fungicides imeni Ya. V. 5amoylov And several laborar.ortes in other in- atitutes have worked out processes for producing warer-soluble Integrated fertilizers of varying composition for hydroponic and closed hothouses. Hydroponic installations of varying productivity are being, designed. Chemicalixarion of livestock farming began to develop later than chemicali- zation of plant husbandry. 'Phe experience of the leading livestock farms as well as biochemical and zootechnical research have shown that rhe use of chemical means of feeding and treating animals and poultry is very effective. Chemical and biological preservatinn of vegetable feeds along wirh drying, feed enr.ichment, and air conditioning in storage have become one of our . most urgent tasks, because improper procurement and storage of feeds 9 ause losses of nutrients in many cases to run as high as 23 to 50 percent. With chemical preservation of moist vegetable feeds (according to data of VASKhNIL's Institute of Animal Biochemistry and Physiology), nutrient losses do not exceed two to ten percent. _ According to the decree of the July 1978 CC CPSU Plenum, the production of supplementary mineral feeds in the llth Five-Year Ylan should be raised to 7 million tons per year. T.he assortment of supplementary feeds should also be expanded, including complex feeds containing not only phosphor.us, cal- cium, and nitrogen but also sulphur, magnesium, certain trace elements, and, possibly, other physiologically active compounds (vitami.ns, liormones, amino acids, and so on). It is these directions, also the development of veterinary means, that should be the focus of efforts of chemists, bio- chemists, microbiologists, collectives of enterprises of Glavmikrobioprom, and the medical and chem;.cal industry ministries. To intensify feeds production it is extremely important to improve the quality of vegetable feeds and enrich them with supplements. Up to now L we have not properly evaluated the nutritional effectiveness of compounds of magnesium, sulphur, silicon, and certain trace elements. Problems of protectin~; plants, animals, and the environment are linked by many strands to the use of fertilizers, feeds, and cropping techniques. With the development of chemicalization~and industrialization, thereEore, tliey have acquired great urgency and comolexity. As a result of the eff.orts of a number of authoritative commissions in the USSR Academy of Scienccs, the USSR State Committee for Science and Technology, VASKhNIL, and various 90 FOR UrFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000100060026-6 APPROVED FOR RELEASE: 2007/02/49: CIA-RDP82-44850R000100064426-6 roR orrIciAL usE orn,Y ministries, A number of decisions have been made on integrating chemical, biological, and mechanical (agrotechnical and zootechnical) methods of pru- tecting planes and animals; unforeunaeely, these decisions are not being implemented East enough. } It has been decided to subsCantially increase the amount and assortment of insecticides and fungicides, especially herbicides and compounds to use against plant diseases and pesrs that huve not yet been conquered. Along with empirical trials and screening it is necessary to develop Cheoretical work ro determine dependencies between the composition, propprtie