Plant Adaptation and Tolerance to Heat Stress: Advance Approaches and Future Aspects
植物对热胁迫的适应与耐受:先进方法与未来展望
📄 英文摘要 English Abstract
Abstract:
Heat stress impacts plant growth at all phases of development, although the particular threshold for heat tolerance varies significantly across different developmental stages. During seed germination, elevated temperatures can either impede or completely halt the process, contingent upon the plant type and the severity of the stress. During advanced stages, high temperatures can have a negative impact on photosynthesis, respiration, water balance, and membrane integrity. Additionally, they can also influence the levels of hormones and primary and secondary metabolites. In addition, during the growth and development of plants, there is an increased expression of various heat shock proteins, as well as other proteins related to stress, and the generation of reactive oxygen species (ROS). These are significant plant responses to heat stress. Plants employ several strategies to deal with heat stress, such as maintaining the stability of their cell membranes, removing harmful reactive oxygen species (ROS), producing antioxidants, accumulating and adjusting compatible solutes, activating mitogen-activated protein kinase (MAPK) and calcium-dependent protein kinase (CDPK) cascades, and, crucially, signaling through chaperones and activating transcription. These molecular-level systems boost the ability of plants to flourish in heat stress. Potential genetic methods to enhance plant heat stress resistance encompass old and modern molecular breeding techniques and transgenic approaches, all of which rely on a comprehensive comprehension of these systems. Although several plants exhibit enhanced heat tolerance through traditional breeding methods, the effectiveness of genetic transformation techniques has been somewhat restricted. The latter results from the current constraints in our understanding and access to genes that have known impacts on plant heat stress tolerance. However, these challenges may be overcome in the future. Besides genetic methods, crops' heat tolerance can be improved through the pre-treatment of plants with various environmental challenges or the external application of osmoprotectants such as glycine betaine and proline. Thermotolerance is achieved through an active process in which plants allocate significant energy to maintain their structure and function to avoid damage induced by heat stress. The practice of nanoparticles has been shown to upgrade both the standard and the quantity of produce when crops are under heat stress. This review provides information on the effects of heat stress on plants and explores the importance of nanoparticles, transgenics, and genomic techniques in reducing the negative consequences of heat stress. Furthermore, it explores how plants might adapt to heat stress by modifying their biochemical, physiological, and molecular reactions.
📄 中文摘要 Chinese Abstract
📋 英文结构化总结 English Structured Summary
摘要整理
Header:
Background Heat stress impacts plant growth at all phases of development, although the particular threshold for heat tolerance varies significantly across different developmental stages. During seed germination, elevated temperatures can either impede or completely halt the process, contingent upon the plant type and the severity of the stress. During advanced stages, high temperatures can have a negative impact on photosynthesis, respiration, water balance, and membrane integrity. Additionally, they can also influence the levels of hormones and primary and secondary metabolites.
Header:
Methods N/A - Review article
Header:
Results During the growth and development of plants, there is an increased expression of various heat shock proteins, as well as other proteins related to stress, and the generation of reactive oxygen species (ROS). These are significant plant responses to heat stress. Plants employ several strategies to deal with heat stress, such as maintaining the stability of their cell membranes, removing harmful reactive oxygen species (ROS), producing antioxidants, accumulating and adjusting compatible solutes, activating mitogen-activated protein kinase (MAPK) and calcium-dependent protein kinase (CDPK) cascades, and, crucially, signaling through chaperones and activating transcription. These molecular-level systems boost the ability of plants to flourish in heat stress.
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Data Summary Potential genetic methods to enhance plant heat stress resistance encompass old and modern molecular breeding techniques and transgenic approaches, all of which rely on a comprehensive comprehension of these systems. Although several plants exhibit enhanced heat tolerance through traditional breeding methods, the effectiveness of genetic transformation techniques has been somewhat restricted. The latter results from the current constraints in our understanding and access to genes that have known impacts on plant heat stress tolerance.
Header:
Conclusions Besides genetic methods, crops' heat tolerance can be improved through the pre-treatment of plants with various environmental challenges or the external application of osmoprotectants such as glycine betaine and proline. Thermotolerance is achieved through an active process in which plants allocate significant energy to maintain their structure and function to avoid damage induced by heat stress. The practice of nanoparticles has been shown to upgrade both the standard and the quantity of produce when crops are under heat stress.
Header:
Practical Significance This review provides information on the effects of heat stress on plants and explores the importance of nanoparticles, transgenics, and genomic techniques in reducing the negative consequences of heat stress. Furthermore, it explores how plants might adapt to heat stress by modifying their biochemical, physiological, and molecular reactions.
📋 中文结构化总结 Chinese Structured Summary
背景:
热胁迫影响植物生长发育的各个阶段,但不同发育阶段的热耐受阈值存在显著差异。在种子萌发阶段,高温可能阻碍或完全终止该过程,具体取决于植物种类和胁迫严重程度。在发育后期,高温会对光合作用、呼吸作用、水分平衡和膜完整性产生负面影响。此外,高温还会影响激素水平以及初生和次生代谢物的含量。
方法:
不适用——综述文章
结果:
在植物生长发育过程中,多种热激蛋白及其他胁迫相关蛋白的表达增加,同时产生活性氧(ROS)。这些是植物应对热胁迫的重要响应。植物采用多种策略来应对热胁迫,例如维持细胞膜稳定性、清除有害活性氧(ROS)、产生抗氧化剂、积累和调节相容性溶质、激活丝裂原活化蛋白激酶(MAPK)和钙依赖性蛋白激酶(CDPK)级联反应,以及关键地通过分子伴侣信号传导和转录激活。这些分子层面的系统增强了植物在热胁迫下正常生长的能力。
**数据总结**
提高植物热胁迫抗性的潜在遗传方法包括传统和现代分子育种技术及转基因方法,所有这些方法均依赖于对这些系统的全面理解。尽管一些植物通过传统育种方法表现出增强的热耐受性,但遗传转化技术的效果相对有限。后者源于我们目前对已知影响植物热胁迫耐受性的基因的了解和获取仍存在局限。
**结论**
除遗传方法外,通过用各种环境挑战对植物进行预处理或外源施用渗透保护剂(如甘氨酸甜菜碱和脯氨酸)可提高作物的热耐受性。热耐受性是通过一个主动过程实现的,在此过程中植物分配大量能量以维持其结构和功能,从而避免热胁迫引起的损伤。研究表明,纳米颗粒的应用可提高热胁迫下作物的品质和产量。
**实际意义**
本综述提供了热胁迫对植物影响的相关信息,并探讨了纳米颗粒、转基因和基因组技术在减轻热胁迫负面影响方面的重要性。此外,综述还探讨了植物如何通过改变其生化、生理和分子反应来适应热胁迫。