Abstract
BackgroundPre-harvest sprouting frequently occurs in Triticum aestivum (wheat) and Hordeum vulgare (barley) at the end of the maturity period due to high rainfall, particularly in Asian monsoon areas. Seed dormancy is a major mechanism preventing pre-harvest sprouting in these crops.ResultsWe identified orthologous sequences of the major Hordeum vulgare (barley) seed dormancy gene Qsd1 in hexaploid wheat cv. Chinese Spring by performing genomic clone sequencing, followed by transcript sequencing. We detected 13 non-synonymous amino acid substitutions among the three sub-genomes of wheat and found that the Qsd1 sequence in the B sub-genome is most similar to that in barley. The Qsd1 sequence in A genome diploid wheat is highly similar to that in the hexaploid A sub-genome. Wheat orthologs of Qsd1 showed closer similarities to barley Qsd1 than did those of other accessions in the DNA database. Like barley Qsd1, all three wheat Qsd1s showed embryo-specific gene expression patterns, indicating that barley and wheat Qsd1 share an orthologous origin. The alignment of four hexaploid wheat cultivars indicated that the amino acid sequences of three spring cultivars, Chinese Spring, Haruyo Koi, and Fielder, are exactly the same in each sub-genome. Only Kitahonami has three amino acid substitutions at the B sub-genome.ConclusionsKitahonami has a longer seed dormancy period than does Chinese Spring. Sequence polymorphisms between Chiniese Spring and Kitahonami in the B sub-genome may underlie the phenotypic differences in seed dormancy between these hexaploid wheat cultivars.
Highlights
Pre-harvest sprouting frequently occurs in Triticum aestivum and Hordeum vulgare at the end of the maturity period due to high rainfall, in Asian monsoon areas
Sequence similarity of Qsd1 among wheat and barley accessions The AlaAT gene family has five members, as determined based on a similarity search for barley Qsd1 by Blastp in NCBI nr. These orthologous sequences are present in rice, Aegilops tauschii, and barley, only a partial sequence is currently available for barley (Hv5part) (Fig. 2)
Kitahonami; these differences may be investigated in the future for their role in longer dormancy
Summary
Pre-harvest sprouting frequently occurs in Triticum aestivum (wheat) and Hordeum vulgare (barley) at the end of the maturity period due to high rainfall, in Asian monsoon areas. Seed dormancy is a major mechanism preventing pre-harvest sprouting in these crops. Phytohormones, abscisic acid (ABA), have been shown to regulate seed dormancy in several plant. Onishi et al BMC Genomics (2017) 18:497 aminotransferase (AlaAT) family member, which has not hitherto been reported to function in dormancy in any plant species. Of the five AlaAT genes present in barley [9], only Qsd is expressed in embryos at maturation. A homolog of Qsd in rice shows embryo-specific gene expression, but has not been shown to be responsible for seed dormancy. The main function of AlaAT appears to be other than the control of seed dormancy [10, 11]
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