返祖蛋白 ZmVPS29 可能通过依赖生长素的过程来调节玉米籽粒形态。

The retromer protein ZmVPS29 regulates maize kernel morphology likely through an auxin-dependent process(es).

机构信息

Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing, China.

School of Life Sciences, State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources, South China Agricultural University, Guangzhou, China.

出版信息

Plant Biotechnol J. 2020 Apr;18(4):1004-1014. doi: 10.1111/pbi.13267. Epub 2019 Oct 17.

DOI:10.1111/pbi.13267

PMID:31553822

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7061865/

Abstract

Kernel size and morphology are two important yield-determining traits in maize, but their molecular and genetic mechanisms are poorly characterized. Here, we identified a major QTL, qKM4.08, which explains approximately 24.20% of the kernel morphology variance in a recombinant population derived from two elite maize inbred lines, Huangzaosi (HZS, round kernel) and LV28 (slender kernel). Positional cloning and transgenic analysis revealed that qKM4.08 encodes ZmVPS29, a retromer complex component. Compared with the ZmVPS29 HZS allele, the ZmVPS29 LV28 allele showed higher expression in developing kernels. Overexpression of ZmVPS29 conferred a slender kernel morphology and increased the yield per plant in different maize genetic backgrounds. Sequence analysis revealed that ZmVPS29 has been under purifying selection during maize domestication. Association analyses identified two significant kernel morphology-associated polymorphic sites in the ZmVPS29 promoter region that were significantly enriched in modern maize breeding lines. Further study showed that ZmVPS29 increased auxin accumulation during early kernel development by enhancing auxin biosynthesis and transport and reducing auxin degradation and thereby improved kernel development. Our results suggest that ZmVPS29 regulates kernel morphology, most likely through an auxin-dependent process(es).

摘要

籽粒大小和形态是玉米的两个重要产量决定性状，但它们的分子和遗传机制还不清楚。在这里，我们鉴定了一个主要的 QTL，qKM4.08，它解释了两个优秀的玉米自交系黄早四（HZS，圆形籽粒）和 LV28（细长籽粒）衍生的重组群体中约 24.20%的籽粒形态变异。定位克隆和转基因分析表明，qKM4.08 编码 ZmVPS29，这是一个返体复合物的组成部分。与 ZmVPS29 HZS 等位基因相比，ZmVPS29 LV28 等位基因在发育中的籽粒中表达水平更高。过表达 ZmVPS29 赋予了细长的籽粒形态，并在不同的玉米遗传背景下增加了单株产量。序列分析表明，在玉米驯化过程中，ZmVPS29 一直受到纯化选择的作用。关联分析鉴定了 ZmVPS29 启动子区域内两个与籽粒形态显著相关的多态性位点，这些位点在现代玉米育种系中显著富集。进一步的研究表明，ZmVPS29 通过增强生长素的生物合成和运输，减少生长素的降解，从而增加早期籽粒发育过程中的生长素积累，从而改善籽粒发育。我们的结果表明，ZmVPS29 通过生长素依赖的过程调节籽粒形态。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/bc92/11386797/ab2b06e90273/PBI-18-1004-g002.jpg

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返祖蛋白 ZmVPS29 可能通过依赖生长素的过程来调节玉米籽粒形态。

The retromer protein ZmVPS29 regulates maize kernel morphology likely through an auxin-dependent process(es).

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