Heat tolerance in plants: An overview

Heat stress due to increased temperature is an agricultural problem in many areas in the world. Transitory or constantly high temperatures cause an array of morpho-anatomical, physiological and biochemical changes in plants, which affect plant growth and development and may lead to a drastic reducti...

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Bibliographic Details
Published in:Environmental and experimental botany 2007-12, Vol.61 (3), p.199-223
Main Authors: Wahid, A., Gelani, S., Ashraf, M., Foolad, M.R.
Format: Article
Language:English
Subjects:
acclimation
Adaptation to environment and cultivation conditions
Agronomy. Soil science and plant productions
Biological and medical sciences
chromosome mapping
crops
Fundamental and applied biological sciences. Psychology
genetic resistance
Genetics and breeding of economic plants
genotype
Heat shock proteins
Heat stress
Heat tolerance
High temperature
literature reviews
Molecular breeding
oxidative stress
phenotypic variation
plant adaptation
plant anatomy
plant breeding
plant development
plant growth
plant physiology
plants
protein kinases
quantitative trait loci
reactive oxygen species
Stress response
Thermotolerance
Tolerance mechanism
Transgenic plants
Varietal selection. Specialized plant breeding, plant breeding aims
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Summary:Heat stress due to increased temperature is an agricultural problem in many areas in the world. Transitory or constantly high temperatures cause an array of morpho-anatomical, physiological and biochemical changes in plants, which affect plant growth and development and may lead to a drastic reduction in economic yield. The adverse effects of heat stress can be mitigated by developing crop plants with improved thermotolerance using various genetic approaches. For this purpose, however, a thorough understanding of physiological responses of plants to high temperature, mechanisms of heat tolerance and possible strategies for improving crop thermotolerance is imperative. Heat stress affects plant growth throughout its ontogeny, though heat-threshold level varies considerably at different developmental stages. For instance, during seed germination, high temperature may slow down or totally inhibit germination, depending on plant species and the intensity of the stress. At later stages, high temperature may adversely affect photosynthesis, respiration, water relations and membrane stability, and also modulate levels of hormones and primary and secondary metabolites. Furthermore, throughout plant ontogeny, enhanced expression of a variety of heat shock proteins, other stress-related proteins, and production of reactive oxygen species (ROS) constitute major plant responses to heat stress. In order to cope with heat stress, plants implement various mechanisms, including maintenance of membrane stability, scavenging of ROS, production of antioxidants, accumulation and adjustment of compatible solutes, induction of mitogen-activated protein kinase (MAPK) and calcium-dependent protein kinase (CDPK) cascades, and, most importantly, chaperone signaling and transcriptional activation. All these mechanisms, which are regulated at the molecular level, enable plants to thrive under heat stress. Based on a complete understanding of such mechanisms, potential genetic strategies to improve plant heat-stress tolerance include traditional and contemporary molecular breeding protocols and transgenic approaches. While there are a few examples of plants with improved heat tolerance through the use of traditional breeding protocols, the success of genetic transformation approach has been thus far limited. The latter is due to limited knowledge and availability of genes with known effects on plant heat-stress tolerance, though these may not be insurmountable in future. In addition t
ISSN:0098-8472
1873-7307
DOI:10.1016/j.envexpbot.2007.05.011