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水稻单个位点上涉及多个等位基因相互作用的性别独立传递比率畸变的进化

The evolution of sex-independent transmission ratio distortion involving multiple allelic interactions at a single locus in rice.

作者信息

Koide Yohei, Ikenaga Mitsunobu, Sawamura Noriko, Nishimoto Daisuke, Matsubara Kazuki, Onishi Kazumitsu, Kanazawa Akira, Sano Yoshio

机构信息

Plant Breeding Laboratory, Research Faculty of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan.

出版信息

Genetics. 2008 Sep;180(1):409-20. doi: 10.1534/genetics.108.090126. Epub 2008 Aug 24.

DOI:10.1534/genetics.108.090126
PMID:18723891
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2535691/
Abstract

Transmission ratio distortion (TRD) is frequently observed in inter- and intraspecific hybrids of plants, leading to a violation of Mendelian inheritance. Sex-independent TRD (siTRD) was detected in a hybrid between Asian cultivated rice and its wild ancestor. Here we examined how siTRD caused by an allelic interaction at a specific locus arose in Asian rice species. The siTRD is controlled by the S6 locus via a mechanism in which the S6 allele acts as a gamete eliminator, and both the male and female gametes possessing the opposite allele (S6a) are aborted only in heterozygotes (S6/S6a). Fine mapping revealed that the S6 locus is located near the centromere of chromosome 6. Testcross experiments using near-isogenic lines (NILs) carrying either the S6 or S6a alleles revealed that Asian rice strains frequently harbor an additional allele (S6n) the presence of which, in heterozygotic states (S6/S6n and S6a/S6n), does not result in siTRD. A prominent reduction in the nucleotide diversity of S6 or S6a carriers relative to that of S6n carriers was detected in the chromosomal region. These results suggest that the two incompatible alleles (S6 and S6a) arose independently from S6n and established genetically discontinuous relationships between limited constituents of the Asian rice population.

摘要

传递比失真(TRD)在植物种间和种内杂交种中经常被观察到,导致孟德尔遗传规律被打破。在亚洲栽培稻与其野生祖先的杂交种中检测到了与性别无关的TRD(siTRD)。在此,我们研究了亚洲稻种中由特定位点的等位基因相互作用引起的siTRD是如何产生的。siTRD由S6位点控制,其机制是S6等位基因作为配子消除因子,携带相反等位基因(S6a)的雄配子和雌配子仅在杂合子(S6/S6a)中败育。精细定位表明,S6位点位于第6号染色体着丝粒附近。使用携带S6或S6a等位基因的近等基因系(NIL)进行的测交实验表明,亚洲稻株系经常携带另一个等位基因(S6n),在杂合状态(S6/S6n和S6a/S6n)下,该等位基因的存在不会导致siTRD。在该染色体区域检测到,相对于S6n携带者,S6或S6a携带者的核苷酸多样性显著降低。这些结果表明,两个不相容的等位基因(S6和S6a)独立于S6n产生,并在亚洲稻群体的有限组成部分之间建立了遗传不连续关系。

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