Abstract
Kengyilia is a group of allohexaploid species that arose from two hybridization events followed by genome doubling of three ancestral diploid species with different genomes St, Y, and P in the Triticeae. Estimating the phylogenetic relationship in resolution of the maternal lineages has been difficult, owing to the extremely low rate of sequence divergence. Here, phylogenetic reconstructions based on the plastome sequences were used to explore the role of maternal progenitors in the establishment of Kengyilia polyploid species. The plastome sequences of 11 Kengyilia species were analyzed together with 12 tetraploid species (PP, StP, and StY) and 33 diploid taxa representing 20 basic genomes in the Triticeae. Phylogenomic analysis and genetic divergence patterns suggested that (1) Kengyilia is closely related to Roegneria, Pseudoroegneria, Agropyron, Lophopyrum, Thinopyrum, and Dasypyrum; (2) both the StY genome Roegneria tetraploids and the PP genome Agropyron tetraploids served as the maternal donors during the speciation of Kengyilia species; (3) the different Kengyilia species derived their StY genome from different Roegneria species. Multiple origins of species via independent polyploidization events have occurred in the genus Kengyilia, resulting in a maternal haplotype polymorphism. This helps explain the rich diversity and wide adaptation of polyploid species in the genus Kengyilia.
Highlights
Polyploidy, defined as the possession of two or more sets of homologous chromosomes following whole-genome duplication, is a major mechanism in plant evolution and speciation (Otto, 2007; Spoelhof et al, 2017)
Assemblies in the genus Kengyilia averaged 135,113 bp, with an estimated 0.064% insertion data; genus Roegneria assemblies averaged just less than 135,079 bp (0.039% estimated insertion data, compared to P. libanotica reference)
10 species of Kengyilia (K. alatavica, K. hirsuta, K. laxiflora, K. batalinii, K. kokonorica, K. thoroldiana, K. grandiglumis, K. mutica, K. stenachyra, and K. rigidula), Roegneria, and Pseudoroegneria were in one group with consistent support, indicating that Pseudoroegneria is likely to be the maternal donor of these 10 StYP genome Kengyilia species and the sampled StY genome Roegneria species
Summary
Polyploidy, defined as the possession of two or more sets of homologous chromosomes following whole-genome duplication, is a major mechanism in plant evolution and speciation (Otto, 2007; Spoelhof et al, 2017). Recent studies even suggested that multiple origins (including independent origin) of polyploid species are the rule rather than the exception (Soltis and Soltis, 2000; Symonds et al, 2010; Fan et al, 2013; Sha et al, 2017a). Polyploidy promotes variability through the change in the chromosomal number per se, increased genetic diversity, and genomic reorganization, Plastome Phylogenomics in Kengyilia leading to benefits in new phenotypes and evolutionary innovation in physiological and ecological flexibility (Ramsey and Ramsey, 2014; Sha et al, 2017b). Kengyilia species exhibit variation with high (K. grandiglumis) to low (K. thoroldiana) plants, lax (K. rigidula) to dense (K. hirsuta) spikes, adnate (K. longilumis) to incohesive (K. stenachyra) spikelets attached to the rachis, and yellow (K. gobicola) to black (K. melanthera) anthers
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