植物铜胁迫响应的生理与分子机制研究进展

doi:10.11924/j.issn.1000-6850.casb2022-0555

中国农学通报 ›› 2023, Vol. 39 ›› Issue (11): 18-28.doi: 10.11924/j.issn.1000-6850.casb2022-0555

植物铜胁迫响应的生理与分子机制研究进展

李佳¹^,²^,³(), 杜瑞英¹^,²^,³, 王旭¹^,²^,³, 陈光¹^,²^,³()

¹ 广东省农业科学院农业质量标准与监测技术研究所，广州 510640
² 广东省农产品质量安全风险评估重点实验室，广州 510640
³ 农业农村部农产品质量安全检测与评价重点实验室，广州 510640

收稿日期:2022-07-07 修回日期:2022-10-27 出版日期:2023-04-15 发布日期:2023-04-10
通讯作者: 陈光，男，1986年出生，上海人，青年研究员，博士，研究方向：植物营养与环境胁迫。通信地址：510640 广州市天河区金颖路20号广东省农业科学院农业质量标准与监测技术研究所，Tel：020-85161203，E-mail：chenguang0066@126.com。
作者简介:
李佳，女，1995年出生，硕士，研究方向：植物营养与环境胁迫。通信地址：510640 广州市天河区金颖路20号广东省农业科学院农业质量标准与监测技术研究所，Tel：020-85161203，E-mail：lij697495@163.com。
基金资助:
科技创新战略专项资金(高水平农科院建设)(R2021YJ-QG006); 科技创新战略专项资金(高水平农科院建设)(R2022PY-QY006); 广州市基础与应用基础研究项目(202201010032); 国家自然科学基金(32072662); “珠江人才计划”青年拔尖人才(2021QN02N297); 广东省基础与应用基础研究基金(2022A1515012580); 广东省农业科学院农业质量标准与监测技术研究所所长基金项目(DWJJ-202113); 广东省农业科学院农业质量标准与监测技术研究所所长基金项目(DWJJ-202209); 广东省农产品质量安全风险评估重点实验室(2019年度)(2019B121203009)

Physiological and Molecular Mechanism of Plants Response to Copper Stress: A Review

LI Jia¹^,²^,³(), DU Ruiying¹^,²^,³, WANG Xu¹^,²^,³, CHEN Guang¹^,²^,³()

¹ Institute of Quality Standard and Monitoring Technology for Agro-products, Guangdong Academy of Agricultural Sciences, Guangzhou 510640
² Guangdong Provincial Key Laboratory of Quality & Safety Risk Assessment for Agro-products, Guangzhou 510640
³ Key Laboratory of Testing and Evaluation for Agro-product Safety and Quality, Ministry of Agriculture and Rural Affairs, Guangzhou 510640

Received:2022-07-07 Revised:2022-10-27 Online:2023-04-15 Published:2023-04-10

摘要/Abstract

摘要：

铜(Cu)是人体和动植物必需的金属，参与多种形态、生理和生化过程；铜是多种酶的辅因子，在光合、呼吸作用和电子传递链中起重要作用，也是防御基因的结构组成部分。为了给今后植物铜胁迫的研究提供更系统的理论参考，基于前期研究的过量铜对植物萌发、生长、光合作用和抗氧化等生理过程的不利影响的基础上，综述了铜的生物学功能；过量铜对植物生长发育的毒害；铜转运、伴侣蛋白的作用以及植物对铜胁迫的耐受机制。展望了未来的研究方向，为制定合理维持铜稳态的有效策略提供依据。

关键词: 铜毒害, 铜稳态, 吸收, 转运, 耐受机制

Abstract:

Copper (Cu) is an essential metal for human body, animals and plants, and participates in various morphological, physiological and biochemical processes. Copper is a cofactor of many enzymes and plays an important role in photosynthesis, respiration and electron transport chain. It is also a structural component of defense genes. In order to provide more systematic theoretical reference for the future study of copper stress on plants, based on the adverse effects of excessive copper on physiological processes such as plant germination, growth, photosynthesis and anti-oxidation summarized in previous studies, this paper reviews the biological functions of copper, the toxicity of excessive copper to plant growth and development, the role of copper transporters and chaperone proteins, and the tolerance mechanism of plants to copper stress. The future research direction is prospected, which provides a basis for formulating effective strategies to maintain copper homeostasis.

Key words: copper toxicity, copper homeostasis, absorption, transport, tolerance mechanism

李佳, 杜瑞英, 王旭, 陈光. 植物铜胁迫响应的生理与分子机制研究进展[J]. 中国农学通报, 2023, 39(11): 18-28.

LI Jia, DU Ruiying, WANG Xu, CHEN Guang. Physiological and Molecular Mechanism of Plants Response to Copper Stress: A Review[J]. Chinese Agricultural Science Bulletin, 2023, 39(11): 18-28.

图/表 2

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物种		基因		表达模式	亚细胞定位	参考文献
拟南芥 Arabidopisis thaliana		AtCOPT1		大多数组织、根、生殖组织	质膜	[30-31]
		AtCOPT2		大多数组织、根	质膜	[31-32]
		AtCOPT3		生殖组织	质膜	[30]
		AtCOPT5		大多数组织、根、生殖组织	液泡	[32]
		AtCOPT6		生殖组织、木质部和韧皮部维管组织	质膜	[32]
		AtHMA1		绿色组织	叶绿体包膜	[33]
		AtHMA5		根、花	质膜	[34]
		AtHMA6		根、芽	叶绿体	[35]
		AtHMA7		根、花	内质网	[36]
		AtHMA8		地上部分	类囊体膜	[37]
		AtYSL1		大多数组织、根	质膜	[38]
		AtYSL2		大多数组织、根、茎	质膜、导管	[39]
		AtYSL3		幼叶、根、茎	质膜	[39]
		AtZIP2		根	细胞膜	[40]
		AtZIP4		根	—	[40]
水稻 Oryza sativa		OsCOPT1		大多数组织、根、茎	质膜	[41]
		OsCOPT2		大多数组织、根	质膜	[42]
		OsHMA5		节点处维管束的木质部区域、花梗、叶柄	质膜	[34]
		OsHMA9		木质部和韧皮部维管组织	质膜	[43]
		OsYSL16		根、茎、叶片的韧皮部和维管组织	质膜	[44]
蒺藜苜蓿 Medicago truncatula		MtCOPT1		根	质膜	[31]
		MtCOPT3		根瘤	—	[31]
		MtCOPT4		根	—	[31]
		MtCOPT5		根	—	[31]
		MtCOPT8		根、木质部和韧皮部维管组织	—	[31]
葡萄 Vitis vinifera		VvCTr1		木质部和韧皮部维管组织、叶、根	液泡膜	[45]
		VvCTr2		——	—	[46]
		VvCTr8		——	—	[46]
小麦 Triticum aestivum	TaCT1		木质部和韧皮部维管组织、根、穗		高尔基体	[47]
油菜 Brassica napus	BnHMA1		叶		—	[48]
油菜 Brassica napus	BnCOPT2		根		—	[48]
大豆 Glycine max	GmHMA8		叶		类囊体膜	[49]
大麦 Hordeum vulgare	HvHMA1		叶、籽粒		叶绿体包膜	[50]
大麦 Hordeum vulgare	HvYSL2		茎、幼叶、根内胚层		—	[51]
花生 Arachis hypogaea	AhYSL3.1		根、茎、幼叶、老叶		质膜	[52]
花生 Arachis hypogaea	AhYSL3.2		根、茎、幼叶、老叶		—	[52]

物种		基因		表达模式	亚细胞定位	参考文献
拟南芥 Arabidopisis thaliana		AtCOPT1		大多数组织、根、生殖组织	质膜	[30-31]
		AtCOPT2		大多数组织、根	质膜	[31-32]
		AtCOPT3		生殖组织	质膜	[30]
		AtCOPT5		大多数组织、根、生殖组织	液泡	[32]
		AtCOPT6		生殖组织、木质部和韧皮部维管组织	质膜	[32]
		AtHMA1		绿色组织	叶绿体包膜	[33]
		AtHMA5		根、花	质膜	[34]
		AtHMA6		根、芽	叶绿体	[35]
		AtHMA7		根、花	内质网	[36]
		AtHMA8		地上部分	类囊体膜	[37]
		AtYSL1		大多数组织、根	质膜	[38]
		AtYSL2		大多数组织、根、茎	质膜、导管	[39]
		AtYSL3		幼叶、根、茎	质膜	[39]
		AtZIP2		根	细胞膜	[40]
		AtZIP4		根	—	[40]
水稻 Oryza sativa		OsCOPT1		大多数组织、根、茎	质膜	[41]
		OsCOPT2		大多数组织、根	质膜	[42]
		OsHMA5		节点处维管束的木质部区域、花梗、叶柄	质膜	[34]
		OsHMA9		木质部和韧皮部维管组织	质膜	[43]
		OsYSL16		根、茎、叶片的韧皮部和维管组织	质膜	[44]
蒺藜苜蓿 Medicago truncatula		MtCOPT1		根	质膜	[31]
		MtCOPT3		根瘤	—	[31]
		MtCOPT4		根	—	[31]
		MtCOPT5		根	—	[31]
		MtCOPT8		根、木质部和韧皮部维管组织	—	[31]
葡萄 Vitis vinifera		VvCTr1		木质部和韧皮部维管组织、叶、根	液泡膜	[45]
		VvCTr2		——	—	[46]
		VvCTr8		——	—	[46]
小麦 Triticum aestivum	TaCT1		木质部和韧皮部维管组织、根、穗		高尔基体	[47]
油菜 Brassica napus	BnHMA1		叶		—	[48]
油菜 Brassica napus	BnCOPT2		根		—	[48]
大豆 Glycine max	GmHMA8		叶		类囊体膜	[49]
大麦 Hordeum vulgare	HvHMA1		叶、籽粒		叶绿体包膜	[50]
大麦 Hordeum vulgare	HvYSL2		茎、幼叶、根内胚层		—	[51]
花生 Arachis hypogaea	AhYSL3.1		根、茎、幼叶、老叶		质膜	[52]
花生 Arachis hypogaea	AhYSL3.2		根、茎、幼叶、老叶		—	[52]

植物铜胁迫响应的生理与分子机制研究进展

Physiological and Molecular Mechanism of Plants Response to Copper Stress: A Review

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