Αποτελέσματα αναζήτησης - "цитоплазматическая мужская стерильность (ЦМС)"

1

Academic Journal

Morphogenetic peculiarities of reproductive biology in sugar beet (Beta vulgaris L.) breeding ; Морфогенетические особенности репродуктивной биологии в селекции сахарной свеклы (Beta vulgaris L.)

Συγγραφείς: T. P. Zhuzhzhalova, A. A. Nalbandyan, E. N. Vasilchenko, N. N. Cherkasova, Т. П. Жужжалова, А. А. Налбандян, Е. Н. Васильченко, Н. Н. Черкасова

Πηγή: Vavilov Journal of Genetics and Breeding; Том 27, № 3 (2023); 207-217 ; Вавиловский журнал генетики и селекции; Том 27, № 3 (2023); 207-217 ; 2500-3259 ; 10.18699/VJGB-23-24

Θεματικοί όροι: апомиксис, reproduction, morphogenesis, embryoidogeny, molecular markers, self-incompatibility, cytoplasmic male sterility (CMS), apomixis, репродукция, морфогенез, эмбриоидогения, молекулярные маркеры, самонесовместимость, цитоплазматическая мужская стерильность (ЦМС)

Περιγραφή αρχείου: application/pdf

Relation: https://vavilov.elpub.ru/jour/article/view/3732/1700; 1. Agafonov N.S., Bogomolov M.A., Zhuzhzhalova T.P., Kornienko A.V., Fedulova T.P., Popova I.R. Method for obtaining sugar beet homozygous lines. Inventor’s certificate 1708210 USSR. MKI АОLH 1/04. No. 4818227/13. Applied 12.03.90.; Published 30.01.92. Bulletin No. 4. 1992. (in Russian) Atanasov A. Biotechnology in Plant Industry. Novosibirsk, 1993. (in Russian); Balkov I.Ya., Karakotov S.D., Logvinov A.V., Logvinov V.A., Mishchenko V.N. Evolution of Sugar Beet: from Garden Forms to Modern Profitable Hybrids. Shchelkovo, 2017. (in Russian); Banzal K.C., Lenka S.K., Mondal T.K. Genomic resources for breeding crops with enhanced abiotic stress tolerance. Plant Breed. 2014; 133(1):1-11. DOI 10.1111/pbr.12117.; Bartenev I.I., Gavrin D.S., Nechaeva O.M., Senyutin A.A. Heterogeneity of seed plant populations and quality indicators of sugar beet seeds. Sakhar = Sugar. 2018;10:46-49. (in Russian); Barykina R.P., Veselova T.D., Devyatov A.G., Dzhalilova Kh.Kh., Ilyina G.M., Chubatova N.V. Handbook of Botanical Microprocedures: Grounds and Methods. Moscow: Moscow State University Publ., 2004. (in Russian); Batygina T.B. Nontraditional views of reproduction types and methods. Phenomenon of embryoidogeny, a new way of flowering plant propagation. In: Developmental Biology: Morphogenesis of Reproductive Structures and the Role of Somatic and Stem Cells in Development and Evolution: Proc. Intern. Conf., Dedicated to the 50th Anniversary of the Laboratory of Embryology and Reproductive Biology. St. Petersburg, December 13-16, 2010. Moscow, 2010;26-31. (in Russian); Batygina T.B., Vinogradova G.Yu. Phenomenon of polyembriony. Genetic heterogeneity of seeds. Russ. J. Dev. Biol. 2007; 38:126-151. DOI 10.1134/S1062360407030022.; Bednarska E. The effect of intracellular calcium level regulators on the synthesis of pollen tube callose in Oenothera bien nis L. Acte Soc. Bot. Pol. 1989;58(2):199-210. DOI 10.5586/asbp.1989.016.; Bogomolov M.A. Induced apomixis and its use in sugar beet breeding. In: Encyclopedia of the Beta Genus: Biology, Genetics, and Breeding of Beet. Novosibirsk: Sova Publ., 2010; 504-513. (in Russian); Bogomolova N.M., Zhuzhzhalova T.P. Study of somatic embryoidogenesis in sugar beet (B. vulgaris L.). In: Issues of Botanical Sciences at the Turn of the 21st Century. V. 1. St. Petersburg: Botanical Institute RAS Publ., 1998;103. (in Russian); Bragin A.G., Ivanov M.K., Fedoseeva L.A., Dymshits G.M. Analysis of mitochondrial DNA heteroplasmy in fertile and owen CMS sugar beet (Beta vulgaris) plants. Vavilivskii Zhurnal Genetiki i Selektsii = Vavilov Journal of Genetics and Breeding. 2011;15(3): 524-530. (in Russian); Cherkasova N.N., Zhuzhzhalova T.P., Kolesnikova E.O. Development of a technology to select sugar beet in vitro regenerants for tolerance of acidity and drought. Sakhar = Sugar. 2018;10:43-45. (in Russian); Cherkasova N.N., Zhuzhzhalova T.P., Kolesnikova E.O. Influence of ionic toxicity on morphological development of sugar beet regenerants. Sakharnaya Svekla = Sugar Beet. 2020;5: 33-35. DOI 10.25802/SB.2020.94.56.003. (in Russian); Cherkasova N.N., Zhuzhzhalova T.P., Tkachenko O.V. Increasing the resistance of sugar beet plants to drought in vitro conditions. Sakharnaya Svekla = Sugar Beet. 2021;8:12-14. DOI 10.25802/SB.2021.52.25.002. (in Russian); Dubrovna O.V. In vitro selection of wheat for resistance to abiotic stress factors. Fiziologiya Rastenij i Genetika = Plant Physiology and Genetics. 2017;49(4):279-292. (in Russian); Dymshits E.M., Bragin A.G., Ivanov M.K. Molecular aspects of cytoplasmic male sterility. In: Encyclopedia of the Beta Genus. Biology, Genetics, and Breeding of Beet. Novosibirsk: Sova Publ., 2010;228-247. (in Russian); Dzhavakhia V., Filippov A., Skryabin K., Voinova T., Kouznetsova M., Shulga O., Shumilina D., Kromina K., Pridanniko M., Battchikova N., Korpela T. Proteins inducing multiple resistance of plants to phytopathogens and pests. US patent No. WO 2005061533. Intern. Filing Date 17.12.2004. Publ. Date 07.07.2005.; Fedulova T.P., Nalbandyan A.A., Duvanova T.N. Screening of sugar beet parental materials for the presence of TRs minisatellite loci associated with CMS. Sakhar = Sugar. 2022;3: 38-41. DOI 10.24412/2413-5518-2022-3-38-41. (in Russian); Fomenko N.P., Zhuzhzhalova T.P., Fedulova T.P., Bogomolov M.A. Cytoembryological and morphological characterization of plants in apomictic gamma lines of sugar beet. In: Factors of the Experimental Evolution of Organisms. Kiev: Agrarnaya Nauka Publ., 2003; 212-217. (in Russian); Hohmann U., Jacobs G., Jung C. An EMC mutagenesis protocol for sugar beet and isolation non-bolting mutants. Plant Breed. 2005;124(4):317-321. DOI 10.1111/j.1439-0523.2005.01126.x.; Ilyenko I.I. Microclonal propagation and maintainance of sugar beet breeding material in in vitro culture. Fiziologiya i Bio khimiya Kulturnykh Rasteniy = Physiology and Biochemistry of Cultivated Plants. 1983;15(4):351-355. (in Russian); Karakotov S.D., Apasov I.V., Nalbandyan A.A., Vasilchenko E.N., Fedulova T.P. Modern issues of sugar beet (Beta vulgaris L.) hybrid breeding. Vavilivskii Zhurnal Genetiki i Selektsii = Vavilov Journal of Genetics and Breeding. 2021; 25(4):394-400. DOI 10.18699/VJ2.043. (in Russian); Katayeva N.V., Butenko R.G. Clonal Micropropagation of Plants. Moscow: Nauka Publ., 1983. (in Russian); Khlestkina E.K. Molecular markers in genetic studies and breeding. Vavilivskii Zhurnal Genetiki i Selektsii = Vavilov Journal of Genetics and Breeding. 2013;17(4/2):1044-1054. (in Russian); Khussein A.S., Mikheeva N.R., Nalbandyan A.A., Cherkasova N.N. Screening of sugar beet regenerants for the heavy metal resistance MTP4 gene. Biotekhnologiya = Biotechno logy. 2021;37(4):14-19. DOI 10.21519/0234-2758-2021-37-4-14-19. (in Russian); Khussein A.S., Nalbandyan A.A., Bogacheva N.N., Vasilchenko E.N., Fedulova T.P. Microsatellite analysis of transgenic forms of sugar beet. Doklady Rossiyskoy Akademii Sel’skokhozyaystvennykh Nauk = Proceedings of the Russian Academy of Agricultural Sciences. 2013;2:17-20. (in Russian); Kikindonov G., Kikindonov Tz., Erchev S. Economical qualities of crosses between doubled haploid sugar beet lines. Agric. Sci. Technol. 2016;8(2):107-110. DOI 10.15547/ast2016.02.018.; Kolesnikova E.O., Zhuzhzhalova T.P. Microcloning and maintenance of lines material in sugar beet breeding process. In: Proc. of IV (XII) Int. Botanical Conf. of Young Scientists in St. Petersburg, April 22–28, 2018. St. Petersburg: Komarov Botanical Institute of the RAS, 2018;267-268.; Kornienko A.V., Podvigina O.A., Zhuzhzhalova T.P., Fedulova T.P., Bogomolov M.A., Oshevnev V.P., Butorina A.K. High-priority research directions in genetics and the breeding of the sugar beet (Beta vulgaris L.) in the 21st century. Russ. J. Genet. 2014;50(11):1137-1148. DOI 10.1134/S1022795414110064.; Kornienko A.V., Znamenskaya V.V. New Methods for Obtaining Sugar Beet Parent Material. Ramon’, 2001. (in Russian); Kourelis J., van der Hoorn R.A.L. Defended to the nines: 25 years of resistance gene cloning identifies nine mechanisms for R protein function. Plant Cell. 2018;30(2):285299. DOI 10.1105/tpc.17.00579.; Kovaleva L.V. Intercellular interactions of the pollen-pistil system in the progamic phase of fertilization. Uspekhi Sovremennoj Biologii = Advances in Current Biology. 1991;111(5):782796. (in Russian); Kovaleva L.V., Zakharova E.V., Voronkov A.S., Timofeyeva G.V., Minkina Yu.V. Plant hormones and polar growth of pollen tubes. In: Embryology, Genetics, and Biotechnology. Proceedings of the 5th International School for Young Scientists (St. Petersburg, October 9-14, 2016). St. Petersburg: Levsha Publ., 2016;107.; Lamaoui M., Jemo M., Datla R., Bekkaoui F. Heat and drought stresses in crops and approaches for their mitigation. Front. Chem. 2018;6: 26. DOI 10.3389/fchem.2018.00026.; Larsen K. Self-incompatibility in Beta vulgaris L. Four gametophytic, complementary S-loci in sugar beet. Hereditas. 1977; 85(2):227-248. DOI 10.1111/j.1601-5223.1977.tb00971.x.; Leyke G., Labes R., Ertel K., Peteresdorf M. Using of Tissue and Organ Cultures in Plant Breeding and Planting Material Production. Moscow: Kolos Publ., 1980. (in Russian); Lutova L.A., Ezhova T.A., Dodueva I.E., Osipova M.A. Genetics of Plant Development. St. Petersburg: N-L Publ., 2010. (in Russian); Mahmoud K., Najar A., Jedid E., Jemai N., Jemmali A. Tissue culture techniques for clonal propagation, viral sanitation and germplasm improvement in strawberry (Fragaria × ananas sa Duch.). J. New Sci. 2017;47(2):2564-2576.; Maletskaya E.I., Maletskiy S.I. Haploidy in apozygotic progeny of sugar beet. In: Encyclopedia of the Beta Genus: Biology, Genetics, and Breeding of Beet. Novosibirsk: Sova Publ., 2010;466-472. (in Russian); Maletskiy S.I. Evolution Biology. Dictionary of Terms. Novosibirsk: ICG SB RAS Publ., 2005. (in Russian); Maletskii S.I., Maletskaya E.I. Self-fertility and agamospermy in sugar beet (Beta vulgaris L.). Russ. J. Genet. 1996;32(12): 1431-1437.; Maletskiy S.I., Maletskaya E.I., Yudanova S.S. New technology of seeds reproduction in sugar beets (parthenogenetic mode). Trudy Kubanskogo Gosudarstvennogo Agrarnogo Universiteta = Works of the Kuban State Agrarian Univer sity. 2015;3(54):204-213. (in Russian); Mazlumov A.L. Sugar Beet Breeding. Moscow: Kolos Publ., 1970. (in Russian); McCallum C.M., Comai L., Greene E.A., Henikoff S. Targeting induced local lesions in genomes (TILLING) for plant functional genomics. Plant Physiol. 2000;123(2):439-442. DOI 10.1104/pp.123.2.439.; Murashige T. Plant propagation through tissue cultures. Ann. Rev. Plant Physiol. 1974;25:135-166. DOI 10.1146/annurev.pp.25.060174.001031.; Nalbandyan A.A., Fedulova T.P., Cherepukhina I.V., Kryukova T.I., Oshevnev V.P., Gribanova N.P. DNA markers in sugar beet breeding. Sakharnaya Svekla = Sugar Beet. 2021;2:1014. DOI 10.25802/SB.2021.57.87.001. (in Russian); Nalbandyan A.A., Fedulova T.P., Khussein A.S. Molecular selection of sugar beet breeding material with genes of resistance to biotic stresses. Rossiyskaya Sel’skokhozyaystvennaya Nauka = Russian Agricultural Science. 2019;1:16-20. DOI 10.31857/S2500-26272019116-20. (in Russian); Nalbandyan A.A., Khussein A.S., Fedulova T.P., Cherepukhina I.V., Kryukova T.I., Rudenko T.S., Mikheeva N.R., Moiseenko A.V. Differentiation of sugar beet cultivars by SSR markers to create promising hybrids. Rossiyskaya Sel’skokho zyaystvennaya Nauka = Russian Agricultural Science. 2020; 4:18-21. DOI 10.31857/S2500262720040043. (in Russian); Nishizawa S., Kubo T., Mikami T. Variable number of tandem repeat loci in the mitochondrial genomes of beets. Curr. Ge net. 2000; 37(1):34-38. DOI 101007/s002940050005.; Oshevnev V.P., Cherepukhin E.I., Balkov I.Ya. Use of the selfincompatibility trait in sugar beet breeding on the CMS base. Sel’skokhozyaystvennaya Biologiya = Agricultural Biology. 1986a;21(8):90-92. (in Russian); Oshevnev V.P., Gribanova N.P. Breeding of O-type self-compatible pollinators in sugar beet. In: Encyclopedia of the Beta Genus: Biology, Genetics, and Breeding of Beet. Novosibirsk: Sova Publ., 2010;542-554. (in Russian); Oshevnev V.P., Gribanova N.P., Zhuzhzhalova T.P., Cherepukhin E.I. Formation of pistillodes in sugar beet. Genetika = Genetics. 1986b;22(4):889-891. (in Russian); Owen F.V. Mendelian male sterility in sugar beets. Am. Soc. Sugar Beet Technol.1952;7:371-376.; Paesold S., Borchardt D., Schmidt T., Dechyeva D. A sugar beet (Beta vulgaris L.) reference FISH karyotype for chromosome and chromosome-arm identification, integration of genetic linkage groups and analysis of major repeat family distribution. Plant J. 2012;72(4):600-611. DOI 10.1111/j.1365-313X.2012.05102.x.; Pazuki A., Aflaki F., Gürel E., Ergül A., Gürel S. Gynogenesis induction in sugar beet (Beta vulgaris) improved by 6-benzylaminopurine (BAP) and synergized with cold pretreatment. Sugar Tech. 2018;20:69-77. DOI 10.1007/s12355-0170522-x.; Podvigina O.A. In vitro induction of haploidy from unfertilized sugar beet ovules. In: Encyclopedia of the Beta Genus: Biology, Genetics, and Breeding of Beet. Novosibirsk: Sova Publ., 2010;455-465. (in Russian); Rusea I., Popescu A., Valentina I., Hoza D. Micropropagation of strawberry cv. Magic. Ann. Univ. Craiova. 2020;XXIV(LX): 218-223.; Seman I., Farago J. Research biotechnological methods in sugar beet breeding in the research and breeding institute at Bucany. Potsdam. Forsh. B. 1988;57:51-56.; Shevelukha V.S. Plant Growth and its Regulation in Ontogenesis. Moscow: Nauka Publ., 1992. (in Russian); Simko I., Eujayl I., van Hintum T.J. Empirical evaluation of DArT, SNP, and SSR marker-systems for genotyping, clustering, and assigning sugar beet hybrid varieties into populations. Plant Sci. 2012;184: 54-62. DOI 10.1016/j.plantsci.2011.12.009.; Stevanato P., Trebbi D., Panella L., Richardson K., Droccanelo C., Pakish L., Fenwick A., Saccomani M. Identification and validation of a SNP marker linked to the gene HsBvm1 for nematode resistance in sugar beet. Plant Mol. Biol. Rep. 2015;33:474-479. DOI 10.1007/s11105-014-0763-8.; Titov A.F., Talanova V.V., Kaznina N.M., Laydinen G.F. Heavy metal tolerance in plants. Petrozavodsk: Karelian Scientific Centre Publ., 2007. (in Russian); Tomaszevska-Sowa M., Figas A.S., Gatz A. Histological analysis of organogenesis and somatic embryogenesis during shoot formation in sugar beet (B. vulgaris L.) via gynogenesis. Po lish J. Nat. Sci. 2017;32(4);705-717.; Vaisman N.Ya., Zhuzhzhalova T.P., Agafonov N.S. Cytology of incompatibility in sugar beet. In: Sugar Beet Genetics. Novosibirsk: Nauka Publ., 1984;121-129. (in Russian); Vasilchenko E.N., Zhuzhzhalova T.P., Fedorin D.N., Dzhavakhiya V.G. Use of the MF2 gene for transformation of sugar beet plants. In: Modern Immunology Studies and Their Role in Development of New Varieties and Intensification of Plant Growing. Bolshie Vyazemy, 2009;162-168. (in Russian); Vasilchenko E.N., Zhuzhzhalova T.P., Fedorin D.N., Zemlyanukhina O.A. Molecular and biochemical properties of transgenic sugar beet plants. In: Proceedings of the 5th All-Russian Symposium “Transgenic Plants: Development Technologies, Biochemical Properties, Use, and Biosafety”. Moscow. December 1-4, 2014. Moscow, 2014;63-66. (in Russian); Vasilchenko E.N., Zhuzhzhalova T.P., Kolesnikova E.O. Rapid raise of new sugar beet (B. vulgaris L.) homozygous lines. Sakhar = Shugar. 2020a;2:30-32. DOI 10.24411/2413-5518-2020-10203. (in Russian); Vasilchenko E.N., Zhuzhzhalova T.P., Tkachenko O.V. Changes in morphological characteristics of sugar beet under the action of ethylmethanesulphonate. Sakharnaya Svekla = Sugar Beet. 2020b;8:2-6. DOI 10.25802/SB.2020.52.38.001. (in Russian); Vishnyakova M.A. Possible ways of structural mechanisms underlying the evolution of self-incompatibility reaction in angiosperm plants. In: Issues of Botanical Sciences at the Turn of the 21st Century. St. Petersburg: Botanical Institute RAS Publ., 1998;107-108. (in Russian); Yarmolyuk G.I., Shiryaeva E.I., Kulik A.G. Endospermal embryony, a new form of apomixis in sugar beet. Doklady VASKHNIL = Reports of the Academy of Agricultural Sci ences. 1990;3-4:8-11. (in Russian); Zaykovskaya N.E., Peretyat’ko N.A. Apomictic development of sugar beet seeds. In: Fundamentals and Practical Methods of the Growing of Sugar Beet and Other Crops. Kiev: All-Ukraine Institute of Breeding, 1977;19-21. (in Russian); Zaykovskaya N.E., Zhuzhzhalova T.P. Development of pollen tubes in isolated self-fertile and self-sterile sugar beet lines. Tsitologiya i Genetika = Cytology and Genetics. 1976; 10(1):57-61. (in Russian); Zhuzhzhalova T.P., Znamenskaya V.V., Podvigina O.A., Yarmolyuk G.I. Reproduction Biology of Sugar Beet. Voronezh: Sotrudnichestvo Publ., 2007. (in Russian); Znamenskaya V.V. In vitro microcloning as a method of maintenance and propagation of sugar beet lines. In: Encyclopedia of the Beta Genus: Biology, Genetics, and Breeding of Beet. Novosibirsk: Sova Publ., 2010;420-437. (in Russian); Znamenskaya V.V., Zhuzhzhalova T.P. Use of microclonal propagation and maintainance of valuable sugar beet genotypes to accelerate breeding. In: Use of Biotechnological Methods in Sugar Beet Breeding. Kiev, 1989;52-58. (in Russian); https://vavilov.elpub.ru/jour/article/view/3732

Διαθεσιμότητα: https://vavilov.elpub.ru/jour/article/view/3732
https://doi.org/10.18699/VJGB-23-27

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2

Academic Journal

The study of the combining ability of the inbred lines of winter rye according to top-crossing method

Συγγραφείς: A. A. Goncharenko, S. A. Ermakov, A. V. Makarov, T. V. Semenova, V. N. Tochilin, O. V. Krakhmaleva

Πηγή: Зерновое хозяйство России, Vol 0, Iss 5, Pp 1-8 (2018)

Θεματικοί όροι: озимая рожь, инбредные линии, цитоплазматическая мужская стерильность (цмс), тестер, гибрид, урожайность, общая и специфическая комбинационная способность, winter rye, inbred lines, cytoplasmic male sterility (cms), tester, hybrid, productivity, general and specific combining ability, Agriculture (General), S1-972

Περιγραφή αρχείου: electronic resource

Relation: https://www.zhros.ru/jour/article/view/91; https://doaj.org/toc/2079-8725; https://doaj.org/toc/2079-8733

Σύνδεσμος πρόσβασης: https://doaj.org/article/05f0bf0519b34822b4d56954fb8dfcb9

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3

Academic Journal

Search for cytoplasmic male sterility plants and its maintainer plants of carrots in Rogneda variety ; Поиск закрепителей стерильности моркови столовой в сорте Рогнеда

Συγγραφείς: A. V. Kornev, A. N. Khovrin, V. I. Leunov, S. N. Derevschukov, L. V. Sycheva, А. В. Корнев, А. Н. Ховрин, В. И. Леунов, С. Н. Деревщюков, Л. В. Сычева

Πηγή: Vegetable crops of Russia; № 4 (2020); 42-44 ; Овощи России; № 4 (2020); 42-44 ; 2618-7132 ; 2072-9146

Θεματικοί όροι: беккроссы, cytoplasmic male sterility (CMS), maintainer of sterility, backcrosses, цитоплазматическая мужская стерильность (ЦМС), закрепитель стерильности

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Relation: https://www.vegetables.su/jour/article/view/1102/753; Коновалов Ю.Б., Пыльнев В.В. и др. Общая селекция растений: учебник. М.: Изд-во РГАУ-МСХА имени К.А. Тимирязева. 2011. 395 с.; Liu B., Ou C., Chen S. et al. Differentially Expressed Genes between Carrot Petaloid Cytoplasmic Male Sterile and Maintainer during Floral Development. Sci Rep 9. 17384 (2019). https://doi.org/10.1038/s41598019-53717-x; Леунов В.И., Ховрин А.Н., Корнев А.В. и др. Производство, селекция и семеноводство моркови. Картофель и овощи. 2014;(3):34-36.; Чистова А.В. Применение метода молекулярно-генетического анализа для выявления растений моркови с цитоплазмой типа «петалоид». Картофель и овощи. 2018;(9):33-35. DOI:10.25630/PAV.2018.9.18333; Bach I.C., Olesen A., Simon P.W. PCR-based markers to differentiate the mitochondrial genomes of petaloid and male fertile carrot (Daucus carota L.). Euphytica. 2002;(127):353-365.; https://www.vegetables.su/jour/article/view/1102

Διαθεσιμότητα: https://www.vegetables.su/jour/article/view/1102
https://doi.org/10.18619/2072-9146-2020-4-42-44

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4

Academic Journal

Breeding and problems of cultivation of winter rye F1 heterosis hybrids in the Republic of Belarus ; Селекция и проблемы возделывания гетерозисных гибридов F1 озимой ржи в Республике Беларусь

Συγγραφείς: E. P Urban, S. I. Gordei, Э. П. Урбан, С. И. Гордей

Πηγή: Proceedings of the National Academy of Sciences of Belarus. Agrarian Series; Том 56, № 4 (2018); 448-455 ; Известия Национальной академии наук Беларуси. Серия аграрных наук; Том 56, № 4 (2018); 448-455 ; 1817-7239 ; 1817-7204 ; 10.29235/1817-7204-2018-56-4

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Relation: https://vestiagr.belnauka.by/jour/article/view/317/313; Кобылянский, В. Д. Рожь. Генетические основы селекции / В. Д. Кобылянский. – М. : Колос, 1982. – 271 с.; Heterosis of factoral inter-pool-single cross among elite winter rye inbred lines / H. H. Geiger [et al.] // Proceedings of the EUCARPIA rye meeting, July 4–7, 2001, Radzików, Poland / Plant Breeding a. Acclimatization Inst.; ed. R. Osiński. – Radzików, 2002. – P. 19–22.; Geiger, H. H. Hybrid rye and heterosis / Н. Н. Geiger, T. Miedaner // The genetics and exploitation of heterosis in crops / ed.: J. G. Coors, S. Pandey. – Madison, 1999. – Р. 439–450. doi:10.2134/1999.geneticsandexploitation.c41; Костов, К. В. Перспективы селекции гибридов зерновых культур / К. В. Костов, С. В. Гончаров // Тр. Куб. гос. аграр. ун-та. – 2016. – № 59. – С. 209–216.; Корень, Л. В. Оценка влияния степени генетической дивергенции родительских форм на уровень гетерозиса F1 гибридов озимой тритикале / Л. В. Корень, О. А. Орловская, Л. В. Хотылева // Вес. Нац. акад. навук Беларусі. Сер. біял. навук. – 2013. – № 1. – С. 30–36.; Исмагилов, Р. В. Особенности формирования хлебопекарных свойств зерна озимой ржи / Р. В. Исмагилов // Новые методы селекции озимых колосовых культур : сб. науч. тр. / Башк. науч.-исслед. ин-т сел. хоз-ва; редкол.: И. Т. Шаяхметов [и др.]. – Уфа, 2001. – С. 36–40.; Oberforster, M. Erfolgreich mit Roggen, Triticale und Winterweizen / M. Oberforster, G. Marco // Fortschr. Landmirt. – 1998. – N 18. – P. 25–31.; Arseniuk, E. Rye production and breeding in Poland / E. Arseniuk, T. Oleksiak // Plant Breeding a. Seed Science. – 2003. – Vol. 47, N 1–2. – P. 7–16.; Кобылянский, В. Д. Использование доноров ценных признаков растений в селекции новых сортов озимой ржи / В. Д. Кобылянский, О. В. Солодухина // Достижения науки и техники АПК. – 2015. – № 7. – С. 7–12.; Пономарев, С. Н. Гетерозис у F1 гибридов озимой ржи, полученных с использованием ЦМС / С. Н. Пономарев, Ф. С. Кудряшева // Науч.-техн. бюл. Всерос. науч.-исслед. ин-та растениеводства им. Н. И. Вавилова. – СанктПетербург, 1992. – Вып. 223 : Генофонд культурных растений для целей селекции. – С. 24–26.; Пономарев, С. Н. Гетерозис у озимой ржи и пути его реализации / С. Н. Пономарев // Актуальные проблемы развития прикладных исследований и пути повышения их эффективности в сельскохозяйственном производстве : материалы междунар. науч.-практ. конф., Казань, 10–12 июля 2000 г. / Тат. науч.-исслед. ин-т сел. хоз-ва. – Казань, 2001. – С. 78–81.; Пономарев, С. Н. Проблемы и перспективы селекции озимой ржи на гетерозис / С. Н. Пономарев, М. Л. Пономарева // Вопросы селекции, семеноводства и технологии возделывания озимой ржи в России : тез. докл. Всерос. науч.-метод. совещ. / Самар. науч.-исслед. ин-т сел. хоз-ва; ред.: А. А. Гончаренко, С. Н. Шевченко. – Самара, 2000. – С. 41–42.; Новые сорта озимой ржи / А. А. Гончаренко [и др.] // Вестн. семеноводства в СНГ. – 2001. – № 3. – С. 16–17.; Урбан, Э. П. Озимая рожь в Беларуси (селекция, семеноводство, технология возделывания) / Э. П. Урбан. – Минск : Беларус. навука, 2009. – 269 с.; Geiger, H. H. Cytoplasmic male s terility i n r ye (Secale cereale L.) / H. H. Geiger, F. W. Schnell // Crop Science. – 1970. – Vol. 10, N 5. – P. 590–593. https://doi.org/10.2135/cropsci1970.0011183x001000050043x; Гордей, С. И. Селекционно-генетические аспекты использования эффекта гетерозиса у озимой ржи (Secale cereale L.) / С. И. Гордей // Вес. Нац. акад. навук Беларусi. Сер. бiял. навук. – 2002. – № 1. – С. 103–108.; Hardzei, S. Prospects and problems of hybrid rye breeding in Belarus / S. Hardzei, E. Urban // Plant Breeding a. Seed Science. – 2003. – Vol. 47, N 1–2. – P. 29–31.; Шлегель, Р. Селекция гибридных форм как стимул развития молекулярно-генетических исследований у ржи / Р. Шлегель // Вавил. журн. генетики и селекции. – 2015. – Т. 19, № 5. – С. 589–603. https://doi.org/10.18699/VJ15.076; Изучение комбинационной способности инбредных линий озимой ржи по методу топкросса / А. А. Гончаренко [и др.] // Зерновое хоз-во России. – 2017. – № 5. – С. 1–8.; Madej, L. Ocena plodnosci mieszancow zyta / L. Madej, R. Osinski, J. Jagodinski // Biul. Inst. Hodowli i Aklimatyzacji Roslin. – 1995. – N 195/196. – S. 283–290.; Melz, Gi. Genetics of a male-sterile rye of “G-type” with results of the first F1 hybrids / Gi. Melz, Gu. Melz, F. Hartmann // Proceedings of the EUCARPIA rye meeting, July 4–7, 2001, Radzików, Poland / Plant Breeding a. Acclimatization Inst.; ed. R. Osiński. – Radzików, 2002. – P. 43–50.; https://vestiagr.belnauka.by/jour/article/view/317

Διαθεσιμότητα: https://vestiagr.belnauka.by/jour/article/view/317
https://doi.org/10.29235/1817-7204-2018-56-4-448-455

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5

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Identification of cytoplasm types in accessions of the family Brassicaceae (Brassicaceae Burnett) with DNA markers ; Определение типа цитоплазмы у растений семейства Капустные (Brassicaceae Burnett) с помощью ДНК маркеров

Συγγραφείς: E. A. Domblides, A. S. Domblides, T. V. Zayachkovskaya, L. L. Bondareva, Е. А. Домблидес, А. С. Домблидес, Т. В. Заячковская, Л. Л. Бондарева

Πηγή: Vavilov Journal of Genetics and Breeding; Том 19, № 5 (2015); 529-537 ; Вавиловский журнал генетики и селекции; Том 19, № 5 (2015); 529-537 ; 2500-3259

Θεματικοί όροι: ПЦР, mitochondrial DNA (mtDNA), cytoplasmic male sterility (CMS), CMS Ogura, CMS Ogu-NWSUAF, orf138, PCR, митохондриальная ДНК (мтДНК), цитоплазматическая мужская стерильность (ЦМС), ЦМС Ogura, ЦМС Ogu-NWSUAF

Περιγραφή αρχείου: application/pdf

Relation: https://vavilov.elpub.ru/jour/article/view/445/522; Бунин М.С. Новые овощные культуры России. М.: Росинформагротех, 2002.; Карлов Г.И. Молекулярно-генетические и молекулярно-цитогенетические подходы для ускоренного создания селекционного материала растений с заданными свойствами: Автореф. дис. … д-ра биол. наук. М., 2010.; Aldrich H.C., Gracen V.E., York D., Earle E.D., Yoder O.C. Ultrastructural effects of Helminthosporium maydis race T toxin on mitochondria of corn roots and protoplasts. Tissue Cell. 1977;9(1):167-177.; Bannerot H., Boulidard Y., Temp J. Transfer of cytoplasmic maie sterility from Raphanus sativus to Brassica oleraceae. Proc. EUCARPIA Meeting Cruciferae. Dundee, 1974.; Bellaoui M., Martin-Canadell A., Pelletier G., Budar F. Low-copynumber molecules are produced by recombination, actively maintained and can be amplified in the mitochondrial genome of Brassicaceae: relationship to reversion of the male sterile phenotype in some cybrids. Mol. Gen. Genet. 1998;257:177-185.; Bonnet A. Breeding in France of a radish hybrid obtained bybuse of cytoplasmic male sterility. Eucarpia Cruciferae Newslett. 1977;2:5-6.; Dieterich J.-H. Mitochondriale genom- und expressionsanalysen zur charakterisierung der CMS-systeme tournefortii, juncea und tokumasu des raps (Brassica napus L.). Dissertation Universität Hannover 2002.; Fu T.D. Production and research on rapeseed in the Peoples Republic in China. Cruciferae Newslett. 1981;6:6-7.; Giancola S., Rao Y., Chaillou S., Hiard S., Martin-Canadell A., Pelletier G., Budar F. Cytoplasmic suppression of Ogura cytoplasmic male sterility in European natural populations of Raphanus raphanistrum. Theor Appl. Genet. 2007;114(8):1333-1343.; Hu B. Sterility and variation resulting from the transfer of polima cytoplasmic male sterility from Brassica napus into Brassica chinensis. J. Agricult. Sei. 1997;128:299-301.; Heyn F.W. Transfer of restorer genes from Raphanus to cytoplasmic male sterile Brassica napus. Cruciferae Newslett. 1976;1:15-16.; L’Homme Y., Stahl R.J., Li X.-Q., Hameed A., Brown G.G. Brassica nap cytoplasmic male sterility is associated with expression of a mtDNA region containing a chimeric gene similar to the polCMS associated orf224 gene. Curr. Genet. 1997;31:325-335.; Landgren M., Zetterstrand M., Sundberg E., Glimelius K. Alloplasmic male-sterile Brassica lines containing B. tournefortii mitochondria express an ORF 3’ of the atp6 gene and a 32 kDa protein. Plant Mol Biol. 1996;32:879-890.; Liu Z., Liu P., Long F., Hong D., He Q., Yang G. Fine mapping and candidate gene analysis of the nuclear restorer gene Rfp for pol CMS in rapeseed (Brassica napus L.). Theor. Appl. Genet. 2012;125: 773-779.; Li D. Preliminary report on breeding of male sterile, maintainer and restorer lines in Brassica napus L. Shaanxi J. Agricultural Sci. 1980; 1:26-29.; Motegi T., Nou I.S., Zhou J., Kanno A., Kameya T., Hirata Y. Obtaining an Ogura-type CMS line from asymmetrical protoplast fusion between cabbage (fertile) and radish (fertile). Euphytica. 2003;129:319-323.; Niemela T., Jauhiainen S.L., Tulisalo U. Transfer of the Kosena Rfk1 gene, required in hybrid seed production, from oilseed rape to turnip rape. Euphytica. 2010;175:1-12.; Ogura H. Studies on the new male-sterility in Japanese radish, with special reference to the utilization of this sterility towards the practical raising of hybrid seeds. Mem. Fac. Agric. Kagoshima Univ. 1968;6:39-78.; Pradhan A., Mukhopadhyay A., Pental D. Identification of the putative cytoplasmic donor of a CMS system in Brassica juncea. Plant Breeding. 1991;106:204-208.; Pelletier G., Primard C., Vedel F., Chetrit P., Remy R., Rouselle P., Renard M. Intergeneric cytoplasmic hybridization in Cruciferae by protoplast fusion. Mol. Gen. 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Διαθεσιμότητα: https://vavilov.elpub.ru/jour/article/view/445
https://doi.org/10.18699/VJ15.069

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6

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