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SOS1,一个对耐盐性和钾离子吸收至关重要的基因座。

SOS1, a Genetic Locus Essential for Salt Tolerance and Potassium Acquisition.

作者信息

Wu S. J., Ding L., Zhu J. K.

机构信息

Department of Botany and Microbiology, Auburn University, Auburn, Alabama 36849.

出版信息

Plant Cell. 1996 Apr;8(4):617-627. doi: 10.1105/tpc.8.4.617.

DOI:10.1105/tpc.8.4.617
PMID:12239394
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC161124/
Abstract

To begin to determine which genes are essential for salt tolerance in higher plants, we identified four salt-hypersensitive mutants of Arabidopsis by using a root-bending assay on NaCl-containing agar plates. These mutants (sos1-1, sos1-2, sos1-3, and sos1-4) are allelic to each other and were caused by single recessive nuclear mutations. The SOS1 gene was mapped to chromosome 2 at 29.5 [plusmn] 6.1 centimorgans. The mutants showed no phenotypic changes except that their growth was >20 times more sensitive to inhibition by NaCl. Salt hypersensitivity is a basic cellular trait exhibited by the mutants at all developmental stages. The sos1 mutants are specifically hypersensitive to Na+ and Li+. The mutants were unable to grow on media containing low levels (below ~1 mM) of potassium. Uptake experiments using 86Rb showed that sos1 mutants are defective in high-affinity potassium uptake. sos1 plants became deficient in potassium when treated with NaCl. The results demonstrate that potassium acquisition is a critical process for salt tolerance in glycophytic plants.

摘要

为了开始确定哪些基因对高等植物的耐盐性至关重要,我们通过在含氯化钠的琼脂平板上进行根弯曲试验,鉴定出了拟南芥的四个盐敏感突变体。这些突变体(sos1-1、sos1-2、sos1-3和sos1-4)相互等位,由单隐性核突变引起。SOS1基因被定位到第2号染色体上29.5±6.1厘摩处。这些突变体除了生长对氯化钠抑制的敏感性比正常情况高20倍以上外,没有表现出表型变化。盐敏感性是突变体在所有发育阶段表现出的基本细胞特征。sos1突变体对Na+和Li+具有特异性敏感性。这些突变体在含有低水平(低于约1 mM)钾的培养基上无法生长。使用86Rb进行的吸收实验表明,sos1突变体在高亲和力钾吸收方面存在缺陷。用氯化钠处理时,sos1植物会出现钾缺乏。结果表明,获取钾是甜土植物耐盐性的关键过程。

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