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水稻中多酚氧化酶功能的独立丧失:亚种间谷粒变色的差异以及驯化过程中正选择的作用

Independent losses of function in a polyphenol oxidase in rice: differentiation in grain discoloration between subspecies and the role of positive selection under domestication.

作者信息

Yu Yanchun, Tang Tian, Qian Qian, Wang Yonghong, Yan Meixian, Zeng Dali, Han Bin, Wu Chung-I, Shi Suhua, Li Jiayang

机构信息

State Key Laboratory of Plant Genomics and National Center for Plant Gene Research, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China.

出版信息

Plant Cell. 2008 Nov;20(11):2946-59. doi: 10.1105/tpc.108.060426. Epub 2008 Nov 25.

DOI:10.1105/tpc.108.060426
PMID:19033526
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2613672/
Abstract

Asian rice (Oryza sativa) cultivars originated from wild rice and can be divided into two subspecies by several criteria, one of which is the phenol reaction (PHR) phenotype. Grains of indica cultivars turn brown in a phenol solution that accelerates a similar process that occurs during prolonged storage. By contrast, the grains of japonica do not discolor. This distinction may reflect the divergent domestication of these two subspecies. The PHR is controlled by a single gene, Phr1; here, we report the cloning of Phr1, which encodes a polyphenol oxidase. The Phr1 gene is indeed responsible for the PHR phenotype, as transformation with a functional Phr1 can complement a PHR negative cultivar. Phr1 is defective in all japonica lines but functional in nearly all indica and wild strains. Phylogenetic analysis showed that the defects in Phr1 arose independently three times. The multiple recent origins and rapid spread of phr1 in japonica suggest the action of positive selection, which is further supported by several population genetic tests. This case may hence represent an example of artificial selection driving the differentiation among domesticated varieties.

摘要

亚洲栽培稻(Oryza sativa)品种起源于野生稻,可根据多种标准分为两个亚种,其中之一是酚反应(PHR)表型。籼稻品种的谷粒在酚溶液中会变成褐色,这加速了长时间储存过程中发生的类似过程。相比之下,粳稻的谷粒不会变色。这种差异可能反映了这两个亚种在驯化过程中的分歧。PHR由单个基因Phr1控制;在此,我们报告了Phr1的克隆,它编码一种多酚氧化酶。Phr1基因确实导致了PHR表型,因为用功能性Phr1进行转化可以互补PHR阴性品种。Phr1在所有粳稻品系中存在缺陷,但在几乎所有籼稻和野生菌株中具有功能。系统发育分析表明,Phr1的缺陷独立出现了三次。phr1在粳稻中的多个近期起源和快速传播表明存在正选择作用,这得到了多项群体遗传学测试的进一步支持。因此,这个案例可能代表了人工选择推动驯化品种分化的一个例子。

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