Research advances in molecular mechanisms regulating heat tolerance in cool-season turfgrasses

IF 2 3区 农林科学 Q2 AGRONOMY
Crop Science Pub Date : 2024-09-11 DOI:10.1002/csc2.21339
Stephanie Rossi, Bingru Huang
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Abstract

Cool-season turfgrasses widely used on golf courses, athletic fields, and other landscapes are environmentally and economically important, but they are functionally and aesthetically damaged under prolonged exposure to high temperatures because of their sensitivity to heat stress. Because the consequences of climate change include elevated global temperatures, it is necessary to understand mechanisms underlying heat tolerance in cool-season turfgrasses to improve heat tolerance and maintain high-quality turf during the summer, when heat stress is most severe. This paper identifies major metabolic pathways associated with genes differentially expressed in heat-tolerant cultivars or species of different turfgrasses by overviewing research from studies using comparative transcriptomics, proteomics, and biotechnological approaches and provides insight into progress toward elucidating the genetic and molecular factors regulating heat tolerance in cool-season turfgrasses. Key molecular factors and genes associated with heat tolerance in cool-season turfgrasses include those in the following cellular and metabolic processes or pathways: (1) cell cycle and DNA synthesis, replication, stability, and binding factors; (2) heat shock proteins for stress protection and protease enzymes controlling protein degradation or turnover; (3) carbohydrate metabolism for chloroplast development, chlorophyll degradation enzymes regulating the stay-green phenotype, photochemical efficiency, carboxylation, and cytochrome respiratory activities; (4) activation of antioxidant metabolism for oxidation protection; (5) modulation of lipid saturation and composition to maintain cellular membrane integrity; and (6) upregulation of secondary metabolism for stress defense. Understanding how these regulatory mechanisms cohesively operate during heat stress will facilitate the development of cool-season turfgrass germplasm with greater heat tolerance through breeding and biotechnological methods.

Abstract Image

冷季型草坪草耐热性分子调控机制的研究进展
在高尔夫球场、田径场和其他景观中广泛使用的冷季型草坪草在环境和经济上都具有重要意义,但由于它们对热胁迫的敏感性,在长期暴露于高温的情况下,它们的功能和美观都会受到损害。由于气候变化的后果包括全球气温升高,因此有必要了解冷季型草坪草耐热性的内在机制,以提高耐热性,并在热应力最严重的夏季保持优质草坪。本文通过概述利用比较转录组学、蛋白质组学和生物技术方法进行的研究,确定了与不同草坪草耐热栽培品种或物种中差异表达基因相关的主要代谢途径,并深入探讨了阐明冷季型草坪草耐热性遗传和分子调控因素的进展。与冷季型草坪草耐热性相关的关键分子因素和基因包括以下细胞和代谢过程或途径中的分子因素和基因:(1) 细胞周期和 DNA 合成、复制、稳定性和结合因子;(2) 保护胁迫的热休克蛋白和控制蛋白质降解或周转的蛋白酶;(3) 叶绿体发育的碳水化合物代谢、调节留绿表型的叶绿素降解酶、光化学效率、羧化和细胞色素呼吸活动;(4) 激活抗氧化代谢以保护氧化;(5) 调节脂质饱和度和组成以保持细胞膜完整性;以及 (6) 上调次生代谢以防御胁迫。了解这些调控机制在热胁迫期间是如何协同运作的,将有助于通过育种和生物技术方法培育耐热性更强的冷季型草坪草种质。
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来源期刊
Crop Science
Crop Science 农林科学-农艺学
CiteScore
4.50
自引率
8.70%
发文量
197
审稿时长
3 months
期刊介绍: Articles in Crop Science are of interest to researchers, policy makers, educators, and practitioners. The scope of articles in Crop Science includes crop breeding and genetics; crop physiology and metabolism; crop ecology, production, and management; seed physiology, production, and technology; turfgrass science; forage and grazing land ecology and management; genomics, molecular genetics, and biotechnology; germplasm collections and their use; and biomedical, health beneficial, and nutritionally enhanced plants. Crop Science publishes thematic collections of articles across its scope and includes topical Review and Interpretation, and Perspectives articles.
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