000			02167nab|a22004097a|4500
999			_c64282 _d64274
001			64282
003			MX-TxCIM
005			20240919021231.0
008			202101s2021||||xxu|||p|op||||00||0|eng|d
022			_a2641-6573 (Online)
024	8		_ahttps://doi.org/10.1002/ggn2.202100017
040			_aMX-TxCIM
041			_aeng
100	1		_aVarshney, R.K. _95901
245	1	0	_aBreeding custom-designed crops for improved drought adaptation
260			_aUSA : _bWiley, _c2021.
500			_aPeer review
500			_aOpen Access
520			_aThe current pace of crop improvement is inadequate to feed the burgeoning human population by 2050. Higher, more stable, and sustainable crop production is required against a backdrop of drought stress, which causes significant losses in crop yields. Tailoring crops for drought adaptation may hold the key to address these challenges and provide resilient production systems for future harvests. Understanding the genetic and molecular landscape of the functionality of alleles associated with adaptive traits will make designer crop breeding the prospective approach for crop improvement. Here, we highlight the potential of genomics technologies combined with crop physiology for high-throughput identification of the genetic architecture of key drought-adaptive traits and explore innovative genomic breeding strategies for designing future crops.
546			_aText in English
650		7	_aOptimization Methods _2AGROVOC _98900
650		7	_aDrought _2AGROVOC _91080
650		7	_aGene editing _2AGROVOC _923072
650		7	_aPlant breeding _gAGROVOC _2 _91203
650		7	_aRoot systems _2AGROVOC _911634
700	1		_aBarmukh, R. _923410
700	1		_aRoorkiwal, M. _96147
700	0		_aYiping Qi _923411
700	1		_aKholova, J. _97497
700	1		_aTuberosa, R. _92806
700	1		_aReynolds, M.P. _gGlobal Wheat Program _8INT1511 _9831
700	1		_aTardieu, F. _97276
700	1		_aSiddique, K.H.M. _910337
773	0		_t Advanced genetics _gv. 2, no. 3, e202100017 _dUSA : Wiley, 2021. _x2641-6573
856	4		_yOpen Access through DSpace _uhttps://hdl.handle.net/10883/21674
942			_cJA _n0 _2ddc