References

vavilov

Вавиловский журнал генетики и селекции

Vavilov Journal of Genetics and Breeding

2500-3259

Institute of Cytology and Genetics of Siberian Branch of the RAS

10.18699/VJ21.043

vavilov-3040

Research Article

Селекция масличных и сахароносов

Breeding of oil and sugar crops

Современные аспекты селекции гибридов сахарной свеклы (Beta vulgaris L.)

Modern issues of sugar beet (Beta vulgaris L.) hybrid breeding

Каракотов

С. Д.

Karakotov

S. D.

г. Щелково, Московская область

Shchelkovo, Moscow region

Апасов

И. В.

Apasov

I. V.

пос. ВНИИСС, Рамонский район, Воронежская область

vil. VNIISS, Ramonsky district, Voronezh region

https://orcid.org/0000-0001-5959-047X

Налбандян

А. А.

Nalbandyan

A. A.

пос. ВНИИСС, Рамонский район, Воронежская область

vil. VNIISS, Ramonsky district, Voronezh region

Васильченко

Е. Н.

Vasilchenko

E. N.

пос. ВНИИСС, Рамонский район, Воронежская область

vil. VNIISS, Ramonsky district, Voronezh region

Федулова

Т. П.

Fedulova

T. P.

пос. ВНИИСС, Рамонский район, Воронежская область

vil. VNIISS, Ramonsky district, Voronezh region

arpnal@rambler.ru

Акционерное общество «Щелково Агрохим»РоссияShchelkovo Agrokhim CompanyRussian Federation

Всероссийский научно-исследовательский институт сахарной свеклы и сахара им. А.Л. МазлумоваРоссияThe A.L. Mazlumov All-Russian Research Institute of Sugar Beet and SugarRussian Federation

2021

10072021

254394400

2021

Каракотов С.Д., Апасов И.В., Налбандян А.А., Васильченко Е.Н., Федулова Т.П.

Karakotov S.D., Apasov I.V., Nalbandyan A.A., Vasilchenko E.N., Fedulova T.P.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://vavilov.elpub.ru/jour/article/view/3040

Показаны высокая эффективность культивирования неоплодотворенных семязачатков растений сахарной свеклы и получение гаплоидных регенерантов (микроклонов) опылителей – закрепителей стерильности О-типа и МС-форм компонентов гибрида сахарной свеклы РМС 120. Предлагается технологический метод, который способствует уменьшению времени создания нового выровненного исходного материала, что ведет к ускорению селекционного процесса. Идентификация гаплоидных регенерантов со стерильной цитоплазмой из исходных популяций имеет важное теоретическое и практическое значение для селекции, так как облегчает задачу создания гомозиготных линий с цитоплазматической мужской стерильностью и высокопродуктивных гибридов на стерильной основе. По результатам проведенного молекулярно-генетического анализа, в митохондриальном геноме гаплоидных растений-регенерантов обнаружен ранее не описанный в литературе однонуклеотидный полиморфизм, позволивший идентифицировать данные микроклоны как фертильные и стерильные формы. Установлено, что ДНК-маркеры митохондриального генома сахарной свеклы, относящиеся к семейству минисателлитов TR (TR1 и TR3), дают возможность с высокой эффективностью выявлять гаплоидные микроклональные растения МСи О-типа. Установлена информативность маркера OP-S4 для определения раздельноплодных форм. При помощи метода культуры in vitro получены дигаплоидные линии (DH) мужско-стерильной формы и закрепителя стерильности О-типа гибрида сахарной свеклы РМС 120. Линии характеризуются высокой степенью выравненности по биоморфологическим признакам, что было подтверждено в полевых условиях.

High efficiency of the cultivation of unfertilized sugar beet ovules and preparation of haploid regenerants (microclones) of pollinators – maintainers of О-type sterility and MS forms of the RMS 120 hybrid components has been shown. A technological method that accelerates the creation of new uniform starting material is proposed. It speeds up the breeding process two to threefold. The identification of haploid regenerants with sterile cytoplasm in initial populations is of great theoretical and practical importance for breeding, as it facilitates the production of homozygous lines with cytoplasmic male sterility and high-performance hybrids on sterile basis. As shown by molecular analysis, a single-nucleotide polymorphism never reported hitherto is present in the mitochondrial genome of the haploid plant regenerants. It allows identification of microclones as fertile and sterile forms. It has been found that DNA markers of the sugar beet mitochondrial genome belonging to the TR minisatellite family (TR1 and TR3) enable reliable enough identification of haploid microclonal plants as MSor O-type forms. Fragments of 1000 bp in length have been detected in monogenic forms in the analysis of 11 sugar beet plants cultured in vitro by PCR with the OP-S4 random RAPD primer. Testing of the OP-S4 marker’s being in the same linkage group as the genes responsible for expression of the economically valuable trait monogermity demonstrates its relative reliability. By the proposed method, dihaploid lines (DH) of the male-sterile form and the О-type sterility maintainer of the RMS 120 sugar beet hybrid have been obtained in in vitro culture. These lines are highly uniform in biomorphological traits, as proven under field conditions.

сахарная свеклаодносемянностьцитоплазматическая мужская стерильностьгомозиготные гаплоидные линииПЦР-анализ

sugar beetmonogermitycytoplasmic male sterilityhomozygous haploid linesPCR analysis.

This study was conducted as part of the Federal Scientific and Technical Program for the Development of Agriculture in 2017–2025.

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The authors declare that there are no conflicts of interest present.