Multi-omic analysis reveals the genetic architecture of water-deficit stress in Phaseolus vulgaris
Bulut, M.; Wendenburg, R.; Bergmann, S.; Domingues Junior, A. P.; Bellucci, E.; Bitocchi, E.; Santamarina, C.; Nanni, L.; Vallarino, J. G.; Dahmani, I.; Koehl, K.; Papa, R.; Fernie, A. R.; Alseekh, S.
Show abstract
Common bean (Phaseolus vulgaris L.) is one of the most important grain legumes for direct human consumption. Currently, 60% of its production is estimated to be at risk due to drought. However, the genetic basis of common beans drought resistance is poorly understood. To this end, we assessed the genetic architecture of drought-responsive changes in a whole genome-sequenced population of 218 common bean accessions. Using multi-omics-based trait evaluation, including lipidomics, photosynthetic and agronomic traits, followed by multi-omics genome-wide association studies (moGWAS), yielded in the detection of a myriad of moQTL for photosynthesis and yield, as well as the levels of various lipids. QTL associated with glycolipids, which are integral to photosynthesis, since they constitute the major membrane components of chloroplasts, were identified. In addition, we molecularly validated several lipid-related candidate genes via P. vulgaris hairy root transformation as well as transient expression in tobacco. In particular, a lipoxygenase and an allene oxide synthase were identified as explaining the variation in triacylglycerol by oxylipin production. These data provide a blueprint for multi-omics-assisted improvement of crop water stress resilience.
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