TY - JOUR
T1 - Heat stress in grain legumes during reproductive and grain-filling phases
AU - Farooq, Muhammad
AU - Nadeem, Faisal
AU - Gogoi, Nirmali
AU - Ullah, Aman
AU - Alghamdi, Salem S.
AU - Nayyar, Harsh
AU - Siddique, Kadambot H. M.
PY - 2017
Y1 - 2017
N2 - Thermal stress during reproductive development and grain-filling phases is a serious threat to the quality and productivity of grain legumes. The optimum temperature range for grain legume crops is 10-36 degrees C, above which severe losses in grain yield can occur. Various climatic models have simulated that the temperature near the earth's surface will increase (by up to 4 degrees C) by the end of this century, which will intensify the chances of heat stress in crop plants. The magnitude of damage or injury posed by a high-temperature stress mainly depends on the defence response of the crop and the specific growth stage of the crop at the time of exposure to the high temperature. Heat stress affects grain development in grain legumes because it disintegrates the tapetum layer, which reduces nutrient supply to microspores leading to premature anther dehiscence; hampers the synthesis and distribution of carbohydrates to grain, curtailing the grain-filling duration leading to low grain weight; induces poor pod development and fractured embryos; all of which ultimately reduce grain yield. The most prominent effects of heat stress include a substantial reduction in net photosynthetic rate, disintegration of photosynthetic apparatus and increased leaf senescence. To curb the catastrophic effect of heat stress, it is important to improve heat tolerance in grain legumes through improved breeding and genetic engineering tools and crop management strategies. In this review, we discuss the impact of heat stress on leaf senescence, photosynthetic machinery, assimilate translocation, water relations, grain quality and development processes. Furthermore, innovative breeding, genetic, molecular and management strategies are discussed to improve the tolerance against heat stress in grain legumes.
AB - Thermal stress during reproductive development and grain-filling phases is a serious threat to the quality and productivity of grain legumes. The optimum temperature range for grain legume crops is 10-36 degrees C, above which severe losses in grain yield can occur. Various climatic models have simulated that the temperature near the earth's surface will increase (by up to 4 degrees C) by the end of this century, which will intensify the chances of heat stress in crop plants. The magnitude of damage or injury posed by a high-temperature stress mainly depends on the defence response of the crop and the specific growth stage of the crop at the time of exposure to the high temperature. Heat stress affects grain development in grain legumes because it disintegrates the tapetum layer, which reduces nutrient supply to microspores leading to premature anther dehiscence; hampers the synthesis and distribution of carbohydrates to grain, curtailing the grain-filling duration leading to low grain weight; induces poor pod development and fractured embryos; all of which ultimately reduce grain yield. The most prominent effects of heat stress include a substantial reduction in net photosynthetic rate, disintegration of photosynthetic apparatus and increased leaf senescence. To curb the catastrophic effect of heat stress, it is important to improve heat tolerance in grain legumes through improved breeding and genetic engineering tools and crop management strategies. In this review, we discuss the impact of heat stress on leaf senescence, photosynthetic machinery, assimilate translocation, water relations, grain quality and development processes. Furthermore, innovative breeding, genetic, molecular and management strategies are discussed to improve the tolerance against heat stress in grain legumes.
KW - breeding
KW - grain development
KW - grain legumes
KW - photosynthesis
KW - CHICKPEA CICER-ARIETINUM
KW - HIGH-TEMPERATURE STRESS
KW - COWPEA VIGNA-UNGUICULATA
KW - VICIA-FABA L.
KW - QUANTITATIVE TRAIT LOCI
KW - CARBON-DIOXIDE
KW - VULGARIS L
KW - MOLECULAR CHARACTERIZATION
KW - MEMBRANE THERMOSTABILITY
KW - CHLOROPHYLL FLUORESCENCE
U2 - 10.1071/CP17012
DO - 10.1071/CP17012
M3 - Review article
SN - 1836-0947
VL - 68
SP - 985
EP - 1005
JO - Crop & Pasture Science
JF - Crop & Pasture Science
IS - 10-11
ER -