Abstract
The common bean (Phaseolus vulgaris L.) is one of the most important food legumes, far ahead of other legumes. The average grain yield of the common bean worldwide is much lower than its potential yields, primarily due to drought in the field. However, the gene network that mediates plant responses to drought stress remains largely unknown in this species. The major goals of our study are to identify a large scale of genes involved in drought stress using RNA-seq. First, we assembled 270 million high-quality trimmed reads into a non-redundant set of 62,828 unigenes, representing approximately 49 Mb of unique transcriptome sequences. Of these unigenes, 26,501 (42.2%) common bean unigenes had significant similarity with unigenes/predicted proteins from other legumes or sequenced plants. All unigenes were functionally annotated within the GO, COG and KEGG pathways. The strategy for de novo assembly of transcriptome data generated here will be useful in other legume plant transcriptome studies. Second, we identified 10,482 SSRs and 4,099 SNPs in transcripts. The large number of genetic markers provides a resource for gene discovery and development of functional molecular markers. Finally, we found differential expression genes (DEGs) between terminal drought and optimal irrigation treatments and between the two different genotypes Long 22-0579 (drought tolerant) and Naihua (drought sensitive). DEGs were confirmed by quantitative real-time PCR assays, which indicated that these genes are functionally associated with the drought-stress response. These resources will be helpful for basic and applied research for genome analysis and crop drought resistance improvement in the common bean.
Highlights
The common bean (Phaseolus vulgaris L.), a legume native to America, is one of the most important crops worldwide and plays an important role in solving food shortages in poor areas and adjusting the diet structure in developed countries
Long 22-0579 in terms of yield under terminal drought was tolerant to optimal irrigation showed the highest drought resistance index (DRI) value (1.25) (Table S2)
These results indicate that the Long 22-0579 plants exhibit stronger drought tolerance than Naihua plants (Figure 1)
Summary
The common bean (Phaseolus vulgaris L.), a legume native to America, is one of the most important crops worldwide and plays an important role in solving food shortages in poor areas and adjusting the diet structure in developed countries. Improvement of drought resistance is a major goal for common bean breeders worldwide. Drought is an increasingly important constraint of crop productivity and stability worldwide due to climate change. It is a physiologically complex trait and involves complex cross-talk between different regulatory levels, including adjustment of metabolism and gene expression for physiological and morphological adaptation. Previous studies are mainly focused on the traits related to drought resistance in the common bean, such as flower, seed filling, number of pods and seeds, seed weight and days to maturity [3,4]. Common bean germplasm that exhibits improved levels of drought tolerance has been identified [6,7]. Physiological analysis of common bean cultivars uncovers characteristics related to terminal drought resistance [8]
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