三种栽培芸薹属四倍体与蔊菜属二倍体的三基因组杂种衍生的异源六倍体的育性和减数分裂规律性不同。

Different fertility and meiotic regularity in allohexaploids derived from trigenomic hybrids between three cultivated Brassica allotetraploids and B. maurorum.

机构信息

National Key Laboratory of Crop Genetic Improvement, National Center of Crop Molecular Breeding Technology, Huazhong Agricultural University, College of Plant Science and Technology, Wuhan 430070, People's Republic of China.

出版信息

Plant Cell Rep. 2012 Apr;31(4):781-8. doi: 10.1007/s00299-011-1200-1. Epub 2011 Dec 7.

DOI:10.1007/s00299-011-1200-1

PMID:22147137

Abstract

The wild species Brassica maurorum Durieu (MM, 2n = 16) is useful for the improvement of Brassica crops. Herein, interspecific reciprocal crosses between B. maurorum and three cultivated Brassica allotetraploids were carried out with the aid of embryo rescue. Trigenomic hybrids with Brassica napus (AACC, 2n = 38) and Brassica carinata (BBCC, 2n = 34) were produced from reciprocal crosses, but the hybrids with Brassica juncea (AABB, 2n = 36) were obtained only when B. maurorum was used as female. All the hybrids were morphologically intermediate between their parents, and were male and female sterile. By in vitro chromosome doubling of the trigenomic hybrids, the allohexaploids (AACC.MM/MM.AACC, 2n = 54; BBCC.MM, 2n = 50; MM.AABB, 2n = 52) were established and characterized for their phenotype and cytology. The fertilities of three allohexaploids were different, for AACC.MM and MM.AACC failed to produce seeds by selfing, but BBCC.MM showed low seed-set and MM.AABB had good seed-set. They also expressed variable extents of male meiotic regularity as to chromosome pairing and segregation, with MM.AABB > BBCC.MM > AACC.MM/MM.AACC, the same order as their fertility. So their meiotic behavior contributed to the fertility. Finally, the potential of these allohexaploids as a bridge for genetic improvement of Brassica crops was discussed.

摘要

野生种 Brassica maurorum Durieu（MM，2n=16）可用于改良芸薹属作物。在此，借助胚拯救技术，进行了 B. maurorum 与三种栽培芸薹属 allotetraploids 之间的种间正反交。从正反交中产生了具有甘蓝型油菜（AACC，2n=38）和芥菜型油菜（BBCC，2n=34）的三生体杂种，但只有当 B. maurorum 作为母本时，才能获得具有芥菜型油菜（AABB，2n=36）的杂种。所有杂种在形态上均介于其亲本之间，且雄性和雌性均不育。通过对三生体杂种的离体染色体加倍，建立了异源六倍体（AACC.MM/MM.AACC，2n=54；BBCC.MM，2n=50；MM.AABB，2n=52），并对其表型和细胞学进行了特征描述。三种异源六倍体的育性不同，AACC.MM 和 MM.AACC 自交不能产生种子，但 BBCC.MM 表现出低结实率，MM.AABB 具有良好的结实率。它们的减数分裂也表现出不同程度的染色体配对和分离的规律性，MM.AABB>BBCC.MM>AACC.MM/MM.AACC，与它们的育性顺序相同。因此，它们的减数分裂行为有助于育性。最后，讨论了这些异源六倍体作为芸薹属作物遗传改良桥梁的潜力。

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本文引用的文献

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三种栽培芸薹属四倍体与蔊菜属二倍体的三基因组杂种衍生的异源六倍体的育性和减数分裂规律性不同。

Different fertility and meiotic regularity in allohexaploids derived from trigenomic hybrids between three cultivated Brassica allotetraploids and B. maurorum.

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