| 000 | 01781nab|a22003017a|4500 | ||
|---|---|---|---|
| 999 |
_c62541 _d62533 |
||
| 001 | 62541 | ||
| 003 | MX-TxCIM | ||
| 005 | 20240919021229.0 | ||
| 008 | 200907s2015||||ne |||p|op||||00||0|eng|d | ||
| 022 | _a0958-1669 | ||
| 024 | 8 | _ahttps://doi.org/10.1016/j.copbio.2014.11.027 | |
| 040 | _aMX-TxCIM | ||
| 041 | _aeng | ||
| 100 | 1 |
_aLangridge, P. _98803 |
|
| 245 | 1 | 0 | _aGenomic tools to assist breeding for drought tolerance |
| 260 |
_aAmsterdam (Netherlands) : _bElsevier, _c2015. |
||
| 500 | _aPeer review | ||
| 520 | _aWater deficit or drought stress is a major limitation to crop production globally. Plant breeders have used a wide range of technologies to successfully breed varieties that perform well under the growth conditions for their target environments but they are always seeking new opportunities to enhance rates of genetic gain. Under drought, yield is determined by the integration of variable levels of water deficit across the developmental life of the crop. Genomics technologies were seen as a path to understand the genetic and environmental complexity of drought stress. To be relevant to breeding programs, genomic studies must consider the nature of drought stress in the target environment and use plant material and phenotyping techniques that relate to field conditions. | ||
| 546 | _aText in English | ||
| 591 | _aJiafa Chen : No CIMMYT Affiliation | ||
| 650 | 7 |
_aPlant breeding _gAGROVOC _2 _91203 |
|
| 650 | 7 |
_2AGROVOC _91082 _aDrought tolerance |
|
| 650 | 7 |
_2AGROVOC _91081 _aDrought stress |
|
| 650 | 7 |
_2AGROVOC _91132 _aGenomics |
|
| 700 | 1 |
_aReynolds, M.P. _gGlobal Wheat Program _8INT1511 _9831 |
|
| 773 | 0 |
_tCurrent Opinion in Biotechnology _gv. 32, p. 130-135 _dAmsterdam (Netherlands) : Elsevier, 2015. _x0958-1669 |
|
| 942 |
_cJA _n0 _2ddc |
||