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拟南芥SOS基因家族与植物耐盐性研究进展 被引量:7

Research Development of SOS Gene Family Underlying Salt Tolerance in Plant
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摘要 SOS(Salt Overly Sensitive)信号转导途径是目前研究最清楚的耐盐机理之一,总结了SOS基因介导信号转导过程中的6个关键基因(SOS1、SOS2、SOS3、SOS4、SOS5、SOS6)的结构,并分析其与植物的耐盐性的分子机理,通过对SOS途径关键基因的结构及其功能进行分析,深刻剖析关键基因之间的互作关系,并对可能的基因功能及互作关系提出了假设,指出SOS途径网络调控模式,并对今后SOS调控网络研究方向进行了展望。 SOS (Salt Overly Sensitive) mediated signal transduction pathway was one of the most clearly studied mechanisms of salt tolerance, some of the plants under salt stress, six genes of SOS gene family were indifferent time and space to expression caused damage by salt. In this paper, SOS-mediated signal transduction process and its function were reviewed. The molecular mechanism of the six key genes was analyzed on Arabidopsis. And than, tryptophan-niacin relationship were analyzed among key genes in SOS metabolic pathway. The hypothesis was obtained about new functions and tryptophan-niacin relationship of key genes in SOS metabolic pathway. At same time, the model of network regulation was refereed in SOS metabolic pathway. At last, the research direction of network regulation was proposedd in future.
作者 马风勇 石晓霞 许兴 李占清 朱永兴
机构地区 宁夏农林科学院宁夏农业生物技术重点实验室 宁夏大学 平罗县农业综合开发办公室
出处 《中国农学通报》 CSCD 2013年第21期121-125,共5页 Chinese Agricultural Science Bulletin
基金 国家重点基础研究发展计划"973"计划项目"作物应答高盐 低温胁迫的分子调控机理"(G2006CB100106) 国家重点基础研究发展计划"973"计划项目"作物应答盐碱胁迫的分子调控机理"(G2011CB016411)
关键词 SOS基因 耐盐性 信号转导 SOS gene sah tolerance signal transduction
分类号 Q812 [生物学—生物工程]
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参考文献35

  • 1Tester M, Davenport R J. Na+tolerance and Na+transport in higherplants[J]. Ann Bot,2003(91):503-527.
  • 2Zhu J K. Cell signaling under salt,water and cold stresses [J]. CurrOpin Plant Biol,2001,4(5):401-406.
  • 3Zhu J K. Salt and drought stress signal transduction in plants[J].Annu Rev Plant Biol,2002(53):247-273.
  • 4Mahajan S, Girdhar K P, Narendra T. Calcium-and salt-stresssignaling in plants:Shedding light on SOS pathway. [J]Archives ofBiochemistry and Biophysics,2008(471):146-158.
  • 5Taji T, Komatsu K, Katori T, et al. Comparative genomic analysisof 1047 completely sequenced cDNAs from an Arabidopsis-relatedmodel halophyte, Thellungiella halophila[J].BMC Plant Biology,2010,1471-2229/10/261.
  • 6Feki K, Quintero F J, Pardo J M,et al. Regulation of durum wheatNa +/H+ exchanger TdSOSlby phosphorylation[J].Plant Mol Biol,2011(76):545-556.
  • 7Quintero FJ, Martinez-Atienza J, Villalta I,et al. Activation of theplasma membrane Na/H antiporter Salt-Overly-Sensitive 1 (SOS1)by phosphorylation of an auto-inhibitory C-terminal domain[J].PNAS,2011,6(108):2611-2616.
  • 8Chung J S,Zhu J K, Bressan R A, et al. Reactive oxygen speciesmediate Na+-induced S0S1 mRNA stability in Arabidopsis[J].PlantJ,2008,3(3):554-565.
  • 9Katiyar-Agarwal S, Morgan R, Dahlbeck D, et al. Apathogen-inducible endogenous siRNA in plant immunity Proc[J].Natl. Acad. Sci. USA,2006:18816-18821.
  • 10Ahlfors R, Ling S, Overmyer K, et al. ArabidopsisRADICAL-INDUCED CELL DEATH 1 belongs to the WWEprotein-protein interaction domain protein family and modulatesabscisic acid, ethylene, and methyl jasmonate responses[J]. PlantCell,2004,16(7):1925-1937.

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中国农学通报
2013年 第21期

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