野生大豆耐逆分子调控机制研究进展

doi:10.11983/CBB20144

摘要/Abstract

摘要： 野生大豆(Glycine soja)起源于中国, 是栽培大豆(G. max)的近缘祖先, 逆境适应能力强, 是研究耐逆分子机制和挖掘耐逆关键调控基因的优良材料。该文综述了野生大豆耐逆基因组、转录组和蛋白质组等组学研究进展, 总结了近年来类受体蛋白激酶、转录因子、离子通道和氧化还原在野生大豆耐逆应答中的调控作用及机制, 为耐逆作物新品种培育提供了新思路。

关键词: 逆境胁迫, 离子通道, 组学, 蛋白激酶, 氧化还原, 转录因子, 野生大豆

Abstract: Wild soybeans (Glycine soja) originated in China, which was the closest ancestor of soybean. Because of the remarkable adaptability to adverse conditions, wild soybean has become an ideal material for the study of key genes in regulating stress tolerance. In this review, we provided an overview on the genome, transcriptome and proteome of wild soybean in stress tolerance. Meanwhile, we summarized current research progress on the protein kinases, transcription factors, ion channels and redox regulation in response to stress, which will provide new ideas for the cultivation of stress- tolerant crops in the future.

Key words: stress, ion channel, omics, protein kinase, redox, transcription factor, wild soybean

王研, 贾博为, 孙明哲, 孙晓丽. 野生大豆耐逆分子调控机制研究进展. 植物学报, 2021, 56(1): 104-115.

Yan Wang, Bowei Jia, Mingzhe Sun, Xiaoli Sun. Advances in Molecular Mechanisms of Stress Tolerance in Wild Soybean. Chinese Bulletin of Botany, 2021, 56(1): 104-115.

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链接本文: https://www.chinbullbotany.com/CN/10.11983/CBB20144

https://www.chinbullbotany.com/CN/Y2021/V56/I1/104

图/表 4

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编号	基因	编码蛋白	胁迫类型	参考文献
1	GsLRPK	LRR类受体蛋白激酶	冷、干旱、盐和ABA胁迫	杨靓等, 2012; Yang et al., 2014
2	GsRLCK	胞浆类受体蛋白激酶	ABA、盐、碱和干旱胁迫	Sun et al., 2013a
3	GsCBRLK	Ca²⁺/CaM结合类受体蛋白激酶	冷、盐、干旱和ABA胁迫	Yang et al., 2010; Bai et al., 2013; 赵阳等, 2014
4	GsSRK	G型凝集素类受体蛋白激酶	ABA、盐和干旱胁迫	Sun et al., 2013b, 2018
5	GsAPK	不依赖Ca²⁺的丝/苏氨酸类蛋白激酶	冷、盐、干旱和ABA胁迫	Yang et al., 2012
6	GsPPCK1	磷酸烯醇式丙酮酸羧化酶激酶	碱胁迫	魏正巍等, 2013
7	GsPPCK3	磷酸烯醇式丙酮酸羧化酶激酶	碱胁迫	Sun et al., 2014a

编号	基因	编码蛋白	胁迫类型	参考文献
1	GsLRPK	LRR类受体蛋白激酶	冷、干旱、盐和ABA胁迫	杨靓等, 2012; Yang et al., 2014
2	GsRLCK	胞浆类受体蛋白激酶	ABA、盐、碱和干旱胁迫	Sun et al., 2013a
3	GsCBRLK	Ca²⁺/CaM结合类受体蛋白激酶	冷、盐、干旱和ABA胁迫	Yang et al., 2010; Bai et al., 2013; 赵阳等, 2014
4	GsSRK	G型凝集素类受体蛋白激酶	ABA、盐和干旱胁迫	Sun et al., 2013b, 2018
5	GsAPK	不依赖Ca²⁺的丝/苏氨酸类蛋白激酶	冷、盐、干旱和ABA胁迫	Yang et al., 2012
6	GsPPCK1	磷酸烯醇式丙酮酸羧化酶激酶	碱胁迫	魏正巍等, 2013
7	GsPPCK3	磷酸烯醇式丙酮酸羧化酶激酶	碱胁迫	Sun et al., 2014a

编号	基因	编码蛋白	胁迫类型	参考文献
1	GsZFP1	ZFP转录因子	冷、干旱、盐和ABA胁迫	罗晓等, 2012; Luo et al., 2012a, 2012b; Tang et al., 2013
2	GsWRKY20	WRKY转录因子	盐、冷、干旱和ABA胁迫	Luo et al., 2013a, 2013b
3	GsWRKY57	WRKY转录因子	干旱胁迫	王岩岩等, 2019
4	GsWRKY15	WRKY转录因子	碱胁迫	朱娉慧等, 2017
5	GsTIFY6b	TIFY转录因子	盐和碱胁迫	阎文飞等, 2018
6	GsTIFY10a	TIFY转录因子	盐和碱胁迫	Zhu et al., 2011, 2014
7	GsTIFY11b	TIFY转录因子	盐和碱胁迫	朱丹等, 2012
8	GsJAZ2	JAZ转录因子	盐和碱胁迫	Zhu et al., 2012
9	GsERF6	ERF转录因子	HCO₃^-胁迫	Yu et al., 2016
10	GsERF71	ERF转录因子	HCO₃^-胁迫	Yu et al., 2017
11	GsNAC20	NAC转录因子	盐、干旱和低温胁迫	才华等, 2011b
12	GsNAC019	NAC转录因子	ABA和碱胁迫	Cao et al., 2017
13	Gshdz4	Gshdz4转录因子	干旱胁迫	Cao et al., 2016
14	GsRAV3	RAV转录因子	碱和ABA胁迫	朱延明等, 2019
15	GsbZIP33	bZIP转录因子	盐胁迫	才华等, 2011a; 刘晶, 2012
16	GsbZIP67	bZIP转录因子	碱胁迫	Wu et al., 2018
17	HSFB2b	B类热激转录因子	盐胁迫	Bian et al., 2020
18	GsMYB15	MYB转录因子	盐、MeJA和SA胁迫	Shen et al., 2018

编号	基因	编码蛋白	胁迫类型	参考文献
1	GsZFP1	ZFP转录因子	冷、干旱、盐和ABA胁迫	罗晓等, 2012; Luo et al., 2012a, 2012b; Tang et al., 2013
2	GsWRKY20	WRKY转录因子	盐、冷、干旱和ABA胁迫	Luo et al., 2013a, 2013b
3	GsWRKY57	WRKY转录因子	干旱胁迫	王岩岩等, 2019
4	GsWRKY15	WRKY转录因子	碱胁迫	朱娉慧等, 2017
5	GsTIFY6b	TIFY转录因子	盐和碱胁迫	阎文飞等, 2018
6	GsTIFY10a	TIFY转录因子	盐和碱胁迫	Zhu et al., 2011, 2014
7	GsTIFY11b	TIFY转录因子	盐和碱胁迫	朱丹等, 2012
8	GsJAZ2	JAZ转录因子	盐和碱胁迫	Zhu et al., 2012
9	GsERF6	ERF转录因子	HCO₃^-胁迫	Yu et al., 2016
10	GsERF71	ERF转录因子	HCO₃^-胁迫	Yu et al., 2017
11	GsNAC20	NAC转录因子	盐、干旱和低温胁迫	才华等, 2011b
12	GsNAC019	NAC转录因子	ABA和碱胁迫	Cao et al., 2017
13	Gshdz4	Gshdz4转录因子	干旱胁迫	Cao et al., 2016
14	GsRAV3	RAV转录因子	碱和ABA胁迫	朱延明等, 2019
15	GsbZIP33	bZIP转录因子	盐胁迫	才华等, 2011a; 刘晶, 2012
16	GsbZIP67	bZIP转录因子	碱胁迫	Wu et al., 2018
17	HSFB2b	B类热激转录因子	盐胁迫	Bian et al., 2020
18	GsMYB15	MYB转录因子	盐、MeJA和SA胁迫	Shen et al., 2018

编号	基因	编码蛋白	胁迫类型	参考文献
1	GsACA1	Ca²⁺-ATPase	盐和碱胁迫	Sun et al., 2016a
2	GsCHX1	阳离子质子转运体	盐胁迫	Qi et al., 2014
3	GsCHX19.3	阳离子质子转运体	碱胁迫	Jia et al., 2017
4	GsSLAH3	慢型阴离子通道	碱胁迫	Duan et al., 2018b
5	GsBOR2	硼转运体	HCO₃^-胁迫	Duan et al., 2018a