Impact of High Temperature and Drought Stresses on Chickpea Production
Abstract
:1. Introduction
2. Effect of Drought on Chickpea
3. Effect of Heat Stress on Chickpea
4. Adaptation Mechanisms of Chickpea Plants to Extreme Events of Climate Change
4.1. Drought Escape and Avoidance
4.2. Heat Escape and Avoidance
5. Strategies to Improve Breeding for Tolerance to Extreme Events of Climate
6. Conclusions and Strategic Approaches to Develop Resilient Cultivars
- Development of simple screening methods to identify drought and heat tolerance chickpea genotypes to the selected environments.
- Determination of physiological and biochemical responses of genotypes to stress and underlying genetic basis of these traits.
- Identification of molecular markers linked to major QTLs that elucidate variation in drought and heat tolerance.
Funding
Conflicts of Interest
References
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Stress | Phenology, Physiological, Biochemical Changes and Stress Tolerance Index | References |
---|---|---|
Drought | Root length density | [12] |
Chlorophyll loss, low water potential | [23] | |
Shoot biomass and grain yield | [13] | |
Drought tolerance index | [13] | |
Early flowering | [24] | |
Carbon (Δ13C) isotope discrimination during the photosynthetic activity | [25] | |
High osmatic adjustment with low water potential to maintain turgor | [26] | |
High water-soluble carbohydrate content in stressed plants | [27] | |
Higher catalase activity under drought which inhibits the osmatic stress | [27] | |
Small leaf area with less water loss by transpiration | [19,28] | |
Reduced pollen viability, pistil function and pod set | [29] | |
Canopy temperature depression during mid-reproductive stage | [22] | |
Heat | Pod number per plant, harvest index | [30] |
Heat tolerance index | [30] | |
Grain yield | [7] | |
Application of abscisic acid (ABA) induces heat tolerance | [31] | |
Reduced pollen viability | [11,31] | |
Failure of fertilization due to oxidative stress | [31] | |
Early flowering, filled pod number per plant | [32] | |
Canopy temperature depression during reproductive stage | [32] | |
Reduced enzyme activity (Rubisco, sucrose phosphate synthase, sucrose synthesising enzyme) due to stress | [33] | |
Reduced pollen function due to lower sucrose level in pollen | [33] |
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Devasirvatham, V.; Tan, D.K.Y. Impact of High Temperature and Drought Stresses on Chickpea Production. Agronomy 2018, 8, 145. https://doi.org/10.3390/agronomy8080145
Devasirvatham V, Tan DKY. Impact of High Temperature and Drought Stresses on Chickpea Production. Agronomy. 2018; 8(8):145. https://doi.org/10.3390/agronomy8080145
Chicago/Turabian StyleDevasirvatham, Viola, and Daniel K. Y. Tan. 2018. "Impact of High Temperature and Drought Stresses on Chickpea Production" Agronomy 8, no. 8: 145. https://doi.org/10.3390/agronomy8080145
APA StyleDevasirvatham, V., & Tan, D. K. Y. (2018). Impact of High Temperature and Drought Stresses on Chickpea Production. Agronomy, 8(8), 145. https://doi.org/10.3390/agronomy8080145