中国水稻科学 ›› 2023, Vol. 37 ›› Issue (1): 1-15.DOI: 10.16819/j.1001-7216.2023.220404
• 综述与专论 • 下一篇
刘淑丽1, 张瑞1, 王洋1, 陈英龙1, 韦还和1, 侯红燕2, 戴其根1()
收稿日期:
2022-04-08
修回日期:
2022-09-29
出版日期:
2023-01-10
发布日期:
2023-01-10
通讯作者:
戴其根
基金资助:
LIU Shuli1, ZHANG Rui1, Shahid HUSSAIN1, WANG Yang1, CHEN Yinglong1, WEI Huanhe1, HOU Hongyan2, DAI Qigen1()
Received:
2022-04-08
Revised:
2022-09-29
Online:
2023-01-10
Published:
2023-01-10
Contact:
DAI Qigen
摘要:
盐胁迫是影响水稻生长发育和产量的主要非生物因素之一,外源物质能有效缓解盐对水稻的毒害作用并增加水稻产量。本文主要综述了不同外源物质(生长素、赤霉素、细胞分裂素、脱落酸、乙烯、褪黑素、水杨酸、多胺、油菜素类固醇、茉莉酸类外源生长调节物质以及钙、硅离子类外源物)对盐胁迫下水稻生长的不同调控机理及其缓解效应,并进一步对外源物质在水稻耐盐上的利用与研究工作进行了展望,以期为改善盐渍土环境下水稻的生长发育以及提高产量和品质提供理论依据。
刘淑丽, 张瑞, 王洋, 陈英龙, 韦还和, 侯红燕, 戴其根. 外源物质对水稻盐胁迫缓解效应研究进展[J]. 中国水稻科学, 2023, 37(1): 1-15.
LIU Shuli, ZHANG Rui, Shahid HUSSAIN, WANG Yang, CHEN Yinglong, WEI Huanhe, HOU Hongyan, DAI Qigen. Research Progress in Alleviating Effects of Exogenous Substances on Salt Stress in Rice[J]. Chinese Journal OF Rice Science, 2023, 37(1): 1-15.
外源物质 Exogenous substances | 表型影响 Phenotypic effects | 生理生化影响 Physiological and biochemical effects | 分子水平影响 Molecular level effects |
脱落酸 Abscisic acid | 提高秧苗存活率[ Increase seedling survival rate | 缓解类胡萝卜素减少引起的强光损伤[ 性蛋白及抗氧化酶活性[ Alleviate the damage caused by reduced carotenoid; enhance the content of soluble protein and antioxidant enzymes activities | 转录因子OsSAE1可作水稻种子萌发和耐盐性的正调控因子[ OsSAE1 could be a positive regulator of seed germination and salt tolerance in rice |
乙烯 Ethylene | 萌发阶段克服种子休眠[ 生长[ 系生长[ Overcome seed dormancy during germination; inhibit growth from booting to maturity; promote seedling root growth | 增加根系抗氧化活性,提高渗透调节物质含量[ Increase root antioxidant activity, increase the content of osmotic regulating substances | 通过SNL1(SIN3-like 1)和SNL2(SIN3-like 2)负调控ABA信号[ ABA signaling is negatively regulated by SNL1(SIN3-like 1) and SNL2(SIN3-like 2) |
茉莉酸类物质 Jasmonates | 低浓度促进、高浓度抑制的“双重效应”[ " Double effects", promoting at low concentration and inhibiting at high concentration | 维持叶绿素和K+含量,增加抗氧化酶活性[ 光系统II(PSII)活性的降低和离子胁迫与渗透胁迫[ Maintain the contents of chlorophyll and K+ , increase the activitises of antioxidant enzymes; alleviate the reduction of photosystem II(PSII) activity, alleviate ionic and osmotic stress; regulate endogenous hormone levels in plants | TaFBA-2A负调控JA的生物合成[ TaFBA-2A negatively regulates JA biosynthesis; OSPP65 can negatively regulate salt tolerance of rice by regulating JA and ABA signaling pathways and raffinose metabolism pathway; Jasmonate biosynthetic gene OsOPR7 alleviates salt stress |
生长素 Indole acetic acid | 促进种子萌发[ Promote seed germination; improve seedling morphology; boost plant growth; increase grain yield | 促进细胞分裂、生长与分化,提高代谢产物含量[ Promote cell division, growth and differentiation, increase metabolite contents | |
赤霉素 Gibberellin | 维持光合系统的稳定[ Maintain the stability of the photosynthetic system; promote starch synthesis | 作为GA的负调控因子,盐胁迫下DELLA蛋白的积累可以诱导ABA合成基因的表达,抑制植物生长的同时提高抗逆性[ As a negative regulator of GA, DELLA protein accumulation under salt stress can induce the expression of ABA synthesis genes, inhibit plant growth, and improve stress tolerance | |
细胞分裂素 Cytokinin | 增强叶片光合速率[ Enhance leaf photosynthetic rate | ||
褪黑素 Melatonin | 改善光合作用和离子稳态[ 透调节能力[ 活TFs级联反应和植物激素信号等[ Improve photosynthesis and ion homeostasis; enhance antioxidant and osmotic adjustment ability; increase the accumulation of primary metabolites; activate TFs cascade and plant hormone signaling | 调节水稻钾离子转运蛋白OsHAK基因的表达[ Regulate the expression of K+ transporter OsHAK gene in rice; inhibit the expression of genes related to senescence; regulate the expression of ABA biosynthesis and decomposition genes | |
水杨酸 Salicylic acid | 诱导抗氧化防御系统,调控离子平衡、激素稳态和 代谢物质[ Induce antioxidant defense system, regulate ion balance, hormone homeostasis, and metabolic substances; maintain cell membrane stability | 诱导抗盐基因表达[ Induce the expression of salt resistance genes; regulate the expression of GA and ABA biosynthetic genes | |
多胺 Polyamines | 调节植物内源激素水平[ 化胁迫和渗透胁迫[ Regulate endogenous hormone levels in plants; Stabilize plasma membrane structure; alleviate oxidative stress and osmotic stress; increase photosynthetic pigment contents in plants | 调控ABA合成途径中关键基因NCED的表达[ Regulate the expression of NCED, a key gene in ABA synthesis pathway; inhibite photochemical reactions and down-regulate chloroplast coding genes | |
油菜素类固醇 Brassinosteroids | 提高核酸和可溶性蛋白水平[ 透平衡、增加抗氧化酶活性[ 生代谢功能[ Increase the levels of nucleic acid and soluble protein; maintain the osmotic balance of plant cells, increase the activities of antioxidant enzymes; activate secondary metabolic functions under salt stress; regulate IAA and GA levels | 上调OsBRI1基因的表达,下调OsDWF4基因的表达[ Up-regulate the expression of OsBRI1 gene and down-regulate OsDWF4 gene; up-regulate carotenoid and flavonoid pathway genes | |
钙 Calcium | 改善水稻幼苗的离子稳态、抗氧化防御及乙二醛酶 系统[ Improve ion homeostasis, antioxidant defense, and glyoxalase system in rice seedlings; maintain plant photosynthetic activity | ||
硅 Silicon | 维持光合系统稳定及离子平衡[ 性[ Maintain the stability of photosynthetic system and ion balance; increase the activity of antioxidant enzymes | 上调植物根中质膜水通道蛋白基因的表达[ Up-regulate expression of plasma membrane aquaporin gene in plant roots; up-regulate OsHAK family potassium uptake genes, rice sodium efflux (OsSOS1), sodium compartments (OsNHX1, OsNHX3 and OsNHX5) gene expression |
表1 外源物质缓解水稻盐胁迫的效应
Table 1. Effects of exogenous substances on alleviating salt stress in rice
外源物质 Exogenous substances | 表型影响 Phenotypic effects | 生理生化影响 Physiological and biochemical effects | 分子水平影响 Molecular level effects |
脱落酸 Abscisic acid | 提高秧苗存活率[ Increase seedling survival rate | 缓解类胡萝卜素减少引起的强光损伤[ 性蛋白及抗氧化酶活性[ Alleviate the damage caused by reduced carotenoid; enhance the content of soluble protein and antioxidant enzymes activities | 转录因子OsSAE1可作水稻种子萌发和耐盐性的正调控因子[ OsSAE1 could be a positive regulator of seed germination and salt tolerance in rice |
乙烯 Ethylene | 萌发阶段克服种子休眠[ 生长[ 系生长[ Overcome seed dormancy during germination; inhibit growth from booting to maturity; promote seedling root growth | 增加根系抗氧化活性,提高渗透调节物质含量[ Increase root antioxidant activity, increase the content of osmotic regulating substances | 通过SNL1(SIN3-like 1)和SNL2(SIN3-like 2)负调控ABA信号[ ABA signaling is negatively regulated by SNL1(SIN3-like 1) and SNL2(SIN3-like 2) |
茉莉酸类物质 Jasmonates | 低浓度促进、高浓度抑制的“双重效应”[ " Double effects", promoting at low concentration and inhibiting at high concentration | 维持叶绿素和K+含量,增加抗氧化酶活性[ 光系统II(PSII)活性的降低和离子胁迫与渗透胁迫[ Maintain the contents of chlorophyll and K+ , increase the activitises of antioxidant enzymes; alleviate the reduction of photosystem II(PSII) activity, alleviate ionic and osmotic stress; regulate endogenous hormone levels in plants | TaFBA-2A负调控JA的生物合成[ TaFBA-2A negatively regulates JA biosynthesis; OSPP65 can negatively regulate salt tolerance of rice by regulating JA and ABA signaling pathways and raffinose metabolism pathway; Jasmonate biosynthetic gene OsOPR7 alleviates salt stress |
生长素 Indole acetic acid | 促进种子萌发[ Promote seed germination; improve seedling morphology; boost plant growth; increase grain yield | 促进细胞分裂、生长与分化,提高代谢产物含量[ Promote cell division, growth and differentiation, increase metabolite contents | |
赤霉素 Gibberellin | 维持光合系统的稳定[ Maintain the stability of the photosynthetic system; promote starch synthesis | 作为GA的负调控因子,盐胁迫下DELLA蛋白的积累可以诱导ABA合成基因的表达,抑制植物生长的同时提高抗逆性[ As a negative regulator of GA, DELLA protein accumulation under salt stress can induce the expression of ABA synthesis genes, inhibit plant growth, and improve stress tolerance | |
细胞分裂素 Cytokinin | 增强叶片光合速率[ Enhance leaf photosynthetic rate | ||
褪黑素 Melatonin | 改善光合作用和离子稳态[ 透调节能力[ 活TFs级联反应和植物激素信号等[ Improve photosynthesis and ion homeostasis; enhance antioxidant and osmotic adjustment ability; increase the accumulation of primary metabolites; activate TFs cascade and plant hormone signaling | 调节水稻钾离子转运蛋白OsHAK基因的表达[ Regulate the expression of K+ transporter OsHAK gene in rice; inhibit the expression of genes related to senescence; regulate the expression of ABA biosynthesis and decomposition genes | |
水杨酸 Salicylic acid | 诱导抗氧化防御系统,调控离子平衡、激素稳态和 代谢物质[ Induce antioxidant defense system, regulate ion balance, hormone homeostasis, and metabolic substances; maintain cell membrane stability | 诱导抗盐基因表达[ Induce the expression of salt resistance genes; regulate the expression of GA and ABA biosynthetic genes | |
多胺 Polyamines | 调节植物内源激素水平[ 化胁迫和渗透胁迫[ Regulate endogenous hormone levels in plants; Stabilize plasma membrane structure; alleviate oxidative stress and osmotic stress; increase photosynthetic pigment contents in plants | 调控ABA合成途径中关键基因NCED的表达[ Regulate the expression of NCED, a key gene in ABA synthesis pathway; inhibite photochemical reactions and down-regulate chloroplast coding genes | |
油菜素类固醇 Brassinosteroids | 提高核酸和可溶性蛋白水平[ 透平衡、增加抗氧化酶活性[ 生代谢功能[ Increase the levels of nucleic acid and soluble protein; maintain the osmotic balance of plant cells, increase the activities of antioxidant enzymes; activate secondary metabolic functions under salt stress; regulate IAA and GA levels | 上调OsBRI1基因的表达,下调OsDWF4基因的表达[ Up-regulate the expression of OsBRI1 gene and down-regulate OsDWF4 gene; up-regulate carotenoid and flavonoid pathway genes | |
钙 Calcium | 改善水稻幼苗的离子稳态、抗氧化防御及乙二醛酶 系统[ Improve ion homeostasis, antioxidant defense, and glyoxalase system in rice seedlings; maintain plant photosynthetic activity | ||
硅 Silicon | 维持光合系统稳定及离子平衡[ 性[ Maintain the stability of photosynthetic system and ion balance; increase the activity of antioxidant enzymes | 上调植物根中质膜水通道蛋白基因的表达[ Up-regulate expression of plasma membrane aquaporin gene in plant roots; up-regulate OsHAK family potassium uptake genes, rice sodium efflux (OsSOS1), sodium compartments (OsNHX1, OsNHX3 and OsNHX5) gene expression |
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