拟南芥中的色氨酸突变体：色氨酸合酶β基因重复的后果。

Tryptophan mutants in Arabidopsis: the consequences of duplicated tryptophan synthase beta genes.

作者信息

Last R L, Bissinger P H, Mahoney D J, Radwanski E R, Fink G R

机构信息

Boyce Thompson Institute for Plant Research, Cornell University, Ithaca, New York 14853-1801.

出版信息

Plant Cell. 1991 Apr;3(4):345-58. doi: 10.1105/tpc.3.4.345.

DOI:10.1105/tpc.3.4.345

PMID:1840915

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC160005/

Abstract

The cruciferous plant Arabidopsis thaliana has two closely related, nonallelic tryptophan synthase beta genes (TSB1 and TSB2), each containing four introns and a chloroplast leader sequence. Both genes are transcribed, although TSB1 produces greater than 90% of tryptophan synthase beta mRNA in leaf tissue. A tryptophan-requiring mutant, trp2-1, has been identified that has about 10% of the wild-type tryptophan synthase beta activity. The trp2-1 mutation is complemented by the TSB1 transgene and is linked genetically to a polymorphism in the TSB1 gene, strongly suggesting that trp2-1 is a mutation in TSB1. The trp2-1 mutants are conditional: they require tryptophan for growth under standard illumination but not under very low light conditions. Presumably, under low light the poorly expressed gene, TSB2, is capable of supporting growth. Genetic redundancy may be common to many aromatic amino acid biosynthetic enzymes in plants because mutants defective in two other genes (TRP1 and TRP3) also exhibit a conditional tryptophan auxotrophy. The existence of two tryptophan pathways has important consequences for tissue-specific regulation of amino acid and secondary metabolite biosynthesis.

摘要

十字花科植物拟南芥有两个密切相关的非等位色氨酸合酶β基因（TSB1和TSB2），每个基因都包含四个内含子和一个叶绿体前导序列。两个基因都被转录，尽管TSB1在叶片组织中产生超过90%的色氨酸合酶β mRNA。已鉴定出一个色氨酸需求突变体trp2-1，其色氨酸合酶β活性约为野生型的10%。trp2-1突变由TSB1转基因互补，并与TSB1基因中的一个多态性遗传连锁，强烈表明trp2-1是TSB1中的一个突变。trp2-1突变体是条件性的：在标准光照下生长需要色氨酸，但在极低光照条件下则不需要。据推测，在低光照下，表达不佳的基因TSB2能够支持生长。基因冗余可能在植物中许多芳香族氨基酸生物合成酶中很常见，因为另外两个基因（TRP1和TRP3）有缺陷的突变体也表现出条件性色氨酸营养缺陷。两条色氨酸途径的存在对氨基酸和次生代谢物生物合成的组织特异性调控具有重要影响。

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本文引用的文献

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