Genomic-Mediated Breeding Strategies for Global Warming in Chickpeas (Cicer arietinum L.)

IF 3.3 2区农林科学 Q1 AGRONOMY

Agriculture-Basel Pub Date : 2023-08-30 DOI:10.3390/agriculture13091721

S. K. Jain, E. Wettberg, S. Punia, A. Parihar, A. Lamichaney, J. Kumar, D. S. Gupta, Sarfraz Ahmad, N. Pant, G. P. Dixit, H. Sari, Duygu Sari, Amar Ma’ruf, Pelin Toker, C. Toker

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引用次数: 3

Abstract

Although chickpea (Cicer arietinum L.) has high yield potential, its seed yield is often low and unstable due to the impact of abiotic stresses, such as drought and heat. As a result of global warming, both drought and heat are estimated to be major yield constraints between one-quarter and one-third per annum. In the present review, genomic-mediated breeding strategies to increase resilience against global warming. Exacerbated drought and heat stresses have been examined to understand the latest advancement happening for better management of these challenges. Resistance mechanisms for drought and heat stresses consist of (i) escape via earliness, (ii) avoidance via morphological traits such as better root traits, compound leaves, or multipinnate leaves and double-/multiple-podded traits, and (iii) tolerance via molecular and physiological traits, such as special tissue and cellular abilities. Both stresses in chickpeas are quantitatively governed by minor genes and are profoundly influenced by edaphic and other environmental conditions. High-yield genotypes have traditionally been screened for resistance to drought and heat stresses in the target selection environment under stress conditions or in the simulacrum mediums under controlled conditions. There are many drought- and heat-tolerant genotypes among domestic and wild Cicer chickpeas, especially in accessions of C. reticulatum Ladiz., C. echinospermum P.H. Davis, and C. turcicum Toker, J. Berger, and Gokturk. The delineation of quantitative trait loci (QTLs) and genes allied to drought- and heat-related attributes have paved the way for designing stress-tolerant cultivars in chickpeas. Transgenic and “omics” technologies hold newer avenues for the basic understanding of background metabolic exchanges of QTLs/candidate genes for their further utilization. The overview of the effect of drought and heat stresses, its mechanisms/adaptive strategies, and markers linked to stress-related traits with their genetics and sources are pre-requisites for framing breeding programs of chickpeas with the intent of imparting drought tolerance. Ideotype chickpeas for resistance to drought and heat stresses were, therefore, developed directly using marker-aided selection over multiple locations. The current understanding of molecular breeding supported by functional genomics and omics technologies in developing drought- and heat-tolerant chickpea is discussed in this review.

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全球变暖对鹰嘴豆基因组介导育种策略的影响

鹰嘴豆(Cicer arietinum L.)虽然具有很高的产量潜力，但由于干旱和高温等非生物胁迫的影响，其种子产量往往较低且不稳定。由于全球变暖，干旱和高温估计是每年四分之一到三分之一的主要产量限制因素。在本综述中，基因组介导的育种策略，以提高抵御全球变暖的能力。已经研究了加剧的干旱和高温压力，以了解更好地管理这些挑战的最新进展。抵抗干旱和热胁迫的机制包括:(1)通过早熟来逃避，(2)通过形态特征(如更好的根性状、复叶、多羽叶和双/多荚果性状)来避免，以及(3)通过分子和生理特征(如特殊的组织和细胞能力)来耐受。鹰嘴豆的这两种胁迫在数量上都由次要基因控制，并受到土壤和其他环境条件的深刻影响。高产基因型传统上是在胁迫条件下的目标选择环境或受控条件下的模拟培养基中筛选抗旱性和耐热性的。在家养和野生的鹰嘴豆中有许多耐干旱和耐热的基因型，特别是在C. reticulatum Ladiz的品种中。C. echinospermum P.H. Davis, C. turcicum Toker, J. Berger, and Gokturk。定量性状位点(qtl)和与干旱和热相关属性相关的基因的描述为设计鹰嘴豆的抗逆性品种铺平了道路。转基因和“组学”技术为qtl /候选基因的背景代谢交换的基本认识提供了新的途径，为其进一步利用提供了基础。概述干旱和热胁迫的影响，其机制/适应策略，以及与胁迫相关性状及其遗传和来源相关的标记，是制定鹰嘴豆耐旱性育种计划的先决条件。因此，利用标记辅助选择在多个地点直接开发了抗干旱和热胁迫的理想型鹰嘴豆。本文综述了以功能基因组学和组学技术为支撑的分子育种在鹰嘴豆抗旱耐热育种中的研究进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Agriculture-Basel Agricultural and Biological Sciences-Food Science

CiteScore

4.90

自引率

13.90%

发文量

1793

审稿时长

11 weeks

期刊介绍： Agriculture (ISSN 2077-0472) is an international and cross-disciplinary scholarly and scientific open access journal on the science of cultivating the soil, growing, harvesting crops, and raising livestock. We will aim to look at production, processing, marketing and use of foods, fibers, plants and animals. The journal Agriculturewill publish reviews, regular research papers, communications and short notes, and there is no restriction on the length of the papers. Our aim is to encourage scientists to publish their experimental and theoretical research in as much detail as possible. Full experimental and/or methodical details must be provided for research articles.