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小分子热激蛋白的合成是种子后期成熟发育程序的一部分。

Synthesis of small heat-shock proteins is part of the developmental program of late seed maturation.

作者信息

Wehmeyer N, Hernandez L D, Finkelstein R R, Vierling E

机构信息

Department of Biochemistry, University of Arizona, Tucson 85721, USA.

出版信息

Plant Physiol. 1996 Oct;112(2):747-57. doi: 10.1104/pp.112.2.747.

DOI:10.1104/pp.112.2.747

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC157999/

Abstract

Small heat-shock proteins (sHSPs) accumulate in plants in response to high-temperature stress. Specific sHSPs, the cytosolic class I and class II proteins, are also expressed in the absence of stress in maturing seeds of several species, and a role for these proteins in desiccation tolerance, dormancy, or germination has been hypothesized. We demonstrate that class I sHSPs are expressed during Arabidopsis seed development in a pattern similar to that previously observed in other species: they are first detected during mid-maturation, are most abundant in dry seeds, and decline rapidly during germination. Although the class I sHSP family in Arabidopsis appears to consist of four genes, expression of a single gene, Athsp 17.4, accounts for the majority of sHSPs in maturing seeds. sHSP levels were also examined in seeds of several Arabidopsis mutants with reduced sensitivity to abscisic acid inhibition, including aba1, abi1, and abi2, abi3-1, abi3-6, abi4, and abi5-1. The abi3-1 mutant has 10-fold reduced levels of sHSPs; sHSPs are undetectable in the abi3-6 mutant. All other mutants were indistinguishable from wild type. These results suggest that sHSP expression in seeds is regulated by the ABI3 response pathway and wild-type levels of sHSPs are not sufficient for seed dormancy and not necessary for desiccation tolerance. However, roles in either process cannot be ruled out. In total the data indicate that the expression of sHSPs in seeds is part of the normal developmental program of late seed maturation and the presence of sHSPs has adaptive significance for plant reproduction.

摘要

小热激蛋白（sHSPs）在植物中会因高温胁迫而积累。特定的sHSPs，即胞质I类和II类蛋白，在几种植物成熟种子的非胁迫条件下也有表达，并且已推测这些蛋白在耐干燥性、休眠或萌发中发挥作用。我们证明，I类sHSPs在拟南芥种子发育过程中的表达模式与之前在其他物种中观察到的相似：它们在成熟中期首次被检测到，在干燥种子中含量最高，在萌发过程中迅速下降。虽然拟南芥中的I类sHSP家族似乎由四个基因组成，但单个基因Athsp 17.4的表达占成熟种子中sHSPs的大部分。我们还检测了几种对脱落酸抑制敏感性降低的拟南芥突变体种子中的sHSP水平，包括aba1、abi1和abi2、abi3-1、abi3-6、abi4和abi5-1。abi3-1突变体中sHSPs水平降低了10倍；在abi3-6突变体中未检测到sHSPs。所有其他突变体与野生型没有区别。这些结果表明，种子中sHSP的表达受ABI３反应途径调控，野生型水平的sHSPs对种子休眠来说并不充足，对耐干燥性来说也不是必需的。然而，不能排除其在这两个过程中的作用。总体而言，数据表明种子中sHSPs的表达是种子后期成熟正常发育程序的一部分，sHSPs的存在对植物繁殖具有适应性意义。