玉米分支1与玉米的起源：上位性及显性进化的证据

teosinte branched1 and the origin of maize: evidence for epistasis and the evolution of dominance.

作者信息

Doebley J, Stec A, Gustus C

机构信息

Department of Plant Biology, University of Minnesota, St. Paul 55108, USA.

出版信息

Genetics. 1995 Sep;141(1):333-46. doi: 10.1093/genetics/141.1.333.

DOI:10.1093/genetics/141.1.333

PMID:8536981

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1206731/

Abstract

Two quantitative trait loci (QTL) controlling differences in plant and inflorescence architecture between maize and its progenitor (teosinte) were analyzed. Complementation tests indicate that one of these, which is on chromosome arm 1L, is the locus for the maize mutant teosinte branched1 (tb1). This QTL has effects on inflorescence sex and the number and length of internodes in the lateral branches and inflorescences. This QTL has strong phenotypic effects in teosinte background but reduced effects in maize background. The second QTL, which is on chromosome arm 3L, affects the same traits as the QTL on 1L. We identify two candidate loci for this QTL. The effects of this QTL on several traits are reduced in both maize and teosinte background as compared to a maize-teosinte F2 population. Genetic background appears to affect gene action for both QTL. Analysis of a population in which both QTL were segregating revealed that they interact epistatically. Together, these two QTL substantially transform both plant and inflorescence architecture. We propose that tb1 is involved in the plant's response to local environment to produce either long or short branches and that maize evolution involved a change at this locus to produce short branches under all environments.

摘要

对控制玉米与其祖先（大刍草）之间植株和花序结构差异的两个数量性状基因座（QTL）进行了分析。互补测验表明，其中一个位于第1L染色体臂上的基因座是玉米突变体“大刍草分枝1”（tb1）的基因座。该QTL对花序性别以及侧枝和花序节间的数量与长度有影响。此QTL在大刍草背景下具有较强的表型效应，但在玉米背景下效应减弱。第二个QTL位于第3L染色体臂上，与位于1L上的QTL影响相同的性状。我们确定了该QTL的两个候选基因座。与玉米-大刍草F2群体相比，该QTL在玉米和大刍草背景下对多个性状的效应均减弱。遗传背景似乎影响这两个QTL的基因作用。对两个QTL均发生分离的群体进行分析发现，它们存在上位性相互作用。这两个QTL共同显著改变了植株和花序结构。我们提出，tb1参与了植株对局部环境的响应，以产生长枝或短枝，并且玉米的进化涉及该基因座的变化，从而在所有环境下都产生短枝。

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