Grain cereals such as wheat, barley, rice, and maize are the nutritional basis of humans and animals worldwide. Thus, these crop plants are essential in terms of global food security. We conducted a bibliometric assessment of scientific documents and patents related to wheat and barley through the Scopus database. The number of documents published per year, their affiliation and corresponding scientific areas, the publishing journals, document types and languages were metricized. The main keywords included in research publications concerning these crops were also analysed globally and clustered in thematic groups. In the case of keywords related to agronomy or genetics and molecular biology, we considered documents dated up to 1999, and from 2000 to 2018, separately. Comparison of the results obtained for wheat and barley revealed some remarkable different trends, for which the underlying reasons are further discussed.
Each species had a unique environmental niche though there were multiple niche overlapping areas for the diploids across time, suggesting the potential existence of several hybrid zones during the Pleistocene and the Holocene. No evidence of niche divergence was found, suggesting that species diversification was not driven by ecological speciation but by evolutionary history, though it could be associated to distinct environmental adaptations.
Intergenomic translocation breakpoints are frequently mapped to SSR-rich chromosomal regions in the allopolyploid species examined, suggesting that microsatellite repeated DNA sequences might facilitate the formation of those chromosomal rearrangements. The (ACG)(n) and (GAA)(n) SSR motifs serve as additional chromosome markers for the karyotypic analysis of UM genome Aegilops species.
The small, annual grass Brachypodium distachyon (L.) Beauv., a close relative of wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.), is a powerful model system for cereals and bioenergy grasses. Genome-wide association studies (GWAS) of natural variation can elucidate the genetic basis of complex traits but have been so far limited in B. distachyon by the lack of large numbers of well-characterized and sufficiently diverse accessions. Here, we report on genotyping-by-sequencing (GBS) of 84 B. distachyon, seven B. hybridum, and three B. stacei accessions with diverse geographic origins including Albania, Armenia, Georgia, Italy, Spain, and Turkey. Over 90,000 high-quality single-nucleotide polymorphisms (SNPs) distributed across the Bd21 reference genome were identified. Our results confirm the hybrid nature of the B. hybridum genome, which appears as a mosaic of B. distachyon-like and B. stacei-like sequences. Analysis of more than 50,000 SNPs for the B. distachyon accessions revealed three distinct, genetically defined populations. Surprisingly, these genomic profiles are associated with differences in flowering time rather than with broad geographic origin. High levels of differentiation in loci associated with floral development support the differences in flowering phenology between B. distachyon populations. Genome-wide association studies combining genotypic and phenotypic data also suggest the presence of one or more photoperiodism, circadian clock, and vernalization genes in loci associated with flowering time variation within B. distachyon populations. Our characterization elucidates genes underlying population differences, expands the germplasm resources available for Brachypodium, and illustrates the feasibility and limitations of GWAS in this model grass.
Core Ideas• Genotyping diverse Brachypodium accessions expands research tools for grasses.• The B. hybridum genome is a mosaic of B. distachyonand B. stacei-like sequences.• Three distinct, genetically defined populations of B. distachyon were identified.• Flowering time, more than geography, distinguishes B. distachyon populations.• Results support the feasibility of genome-wide association studies in a model grass.
Karyotypic analysis of wheat lines with different genotypes for the homoeologous-pairing loci Ph1 and Ph2 was carried out by means of a genomic in situ hybridization method that allowed unequivocal identification of the A, B and D genomes. Chromosomal rearrangements mainly affecting the A and D genomes were found in all plants of allohexaploid wheat (AABBDD) lacking Ph1 activity. The frequency of intergenomic exchanges per plant in ph1b mutant and nulli-5B lines was 4.31 and 3.40, respectively. In addition, an unbalanced genomic constitution was found in a few plants, some even showing a euploid chromosomal number. By contrast, rearranged karyotypes were detected neither in the ph1 mutant line (ph1c) of allotetraploid wheat (AABB) nor in the allohexaploid wheat lines lacking Ph2 activity, namely ph2b mutant and nulli-3D lines. These results were compared with the chromosomal pairing behaviour displayed by mutant lines ph1c, ph1b and ph2b at first meiotic metaphase. Despite the finding of standard, nonrearranged karyotypes in the phlc tetraploid mutant, the frequency of A-B homoeologous metaphase I association was similar to that observed in the ph1b hexaploid mutant. The results presented clearly demonstrate that inactivity of the Ph1 locus induces karyotypic instability in wheat. Intergenomic exchanges have probably been accumulating since the original ph1 mutant and aneuploid lines were obtained, which should be taken into account when it is planned to use these lines for basic research on Ph1 function or in applied wheat breeding programmes.
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