上位性位点产生的累加和超显性效应是水稻杂种优势的主要遗传基础。

Additive and over-dominant effects resulting from epistatic loci are the primary genetic basis of heterosis in rice.

机构信息

Department of Plant Genetics and Breeding and State Key Laboratory of Plant Physiology and Biochemistry, China Agricultural University, Beijing 100193, China.

出版信息

J Integr Plant Biol. 2009 Apr;51(4):393-408. doi: 10.1111/j.1744-7909.2008.00807.x.

DOI:10.1111/j.1744-7909.2008.00807.x

PMID:21452591

Abstract

A set of 148 F9 recombinant inbred lines (RILs) was developed from the cross of an indica cultivar 93-11 and japonica cultivar DT713, showing strong F1 heterosis. Subsequently, two backcross F1 (BCF1) populations were constructed by backcrossing these 148 RILs to two parents, 93-11 and DT713. These three related populations (281BCF1 lines, 148 RILs) were phenotyped for six yield-related traits in two locations. Significant inbreeding depression was detected in the population of RILS and a high level of heterosis was observed in the two BCF1 populations. A total of 42 main-effect quantitative trait loci (M-QTLs) and 109 epistatic effect QTL pairs (E-QTLs) were detected in the three related populations using the mixed model approach. By comparing the genetic effects of these QTLs detected in the RILs, BCF1 performance and mid-parental heterosis (HMP), we found that, in both BCF1 populations, the QTLs detected could be classified into two predominant types: additive and over-dominant loci, which indicated that the additive and over-dominant effect were more important than complete or partially dominance for M-QTLs and E-QTLs. Further, we found that the E-QTLs detected collectively explained a larger portion of the total phenotypic variation than the M-QTLs in both RILs and BCF1 populations. All of these results suggest that additive and over-dominance resulting from epistatic loci might be the primary genetic basis of heterosis in rice.

摘要

一套由籼稻品种 93-11 和粳稻品种 DT713 杂交形成的 148 个重组自交系（RILs）表现出强烈的 F1 杂种优势。随后，通过回交这 148 个 RILs 到两个亲本 93-11 和 DT713，构建了两个回交 F1（BCF1）群体。这三个相关群体（281 个 BCF1 系，148 个 RILs）在两个地点对六个与产量相关的性状进行了表型分析。在 RILs 群体中检测到明显的近交衰退，而在两个 BCF1 群体中观察到高水平的杂种优势。在三个相关群体中，使用混合模型方法共检测到 42 个主效数量性状位点（M-QTLs）和 109 个上位性效应 QTL 对（E-QTLs）。通过比较这些在 RILs 中检测到的 QTL 的遗传效应、BCF1 表现和中亲杂种优势（HMP），我们发现，在两个 BCF1 群体中，检测到的 QTLs 可分为两种主要类型：加性和超显性位点，这表明在 M-QTLs 和 E-QTLs 中，加性和超显性效应比完全或部分显性更为重要。此外，我们发现，在 RILs 和 BCF1 群体中，检测到的 E-QTLs 共同解释了比 M-QTLs 更大的总表型变异部分。所有这些结果表明，由上位性位点产生的加性和超显性可能是水稻杂种优势的主要遗传基础。

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上位性位点产生的累加和超显性效应是水稻杂种优势的主要遗传基础。

Additive and over-dominant effects resulting from epistatic loci are the primary genetic basis of heterosis in rice.

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