Multiple origins of BBCC allopolyploid species in the rice genus (Oryza)

In the rice genus (Oryza), about one half of the species are allopolyploids. These species are not only important resources for rice breeding but also provide a unique opportunity for studying evolution of polyploid species. In the present study, we sequenced four biparentally inherited nuclear loci and three maternally inherited chloroplast fragments from all diploid and tetraploid species with the B- and C-genome types in this genus. We detected at least three independent origins of three BC-genome tetraploid species. Specifically, the diploid O. punctata (B-genome) and O. officinalis (C-genome) were the parental progenitors of O. minuta and O. malampuzhaensis with O. punctata being the maternal donors, whereas the diploid O. punctata and O. eichingeri (C-genome) were the progenitors of tetraploid O. punctata with O. punctata being the paternal donor. Our relaxed clock analyses suggest that all the BBCC species originated within the last one million years, which is coincident with the severe climate oscillations occurred during the last ice age, implying the potential impact of climate change on their formations and dispersals. In addition, our results support previous taxonomic arguments that the tetraploid O. punctata might be better treated as a separate species (O. schweinfurthiana)

Extensive reprogramming of cytosine methylation in Oryza allotetraploids

Cytosine methylation is a prominent epigenetic modification in plants and it has been proposed to as causative for silencing some duplicates derived by polyploidization. Several synthetic polyploids have shown there is a dynamic epigenetic change following hybridization and genome doubling. Relatively few studies, however, have focused on wild natural polyploids. In this study, using a methylation-sensitive amplified fragment length polymorphism method, we investigated the levels and types of cytosine methylation in three Oryza CCDD genome allotetraploids and their related diploids with CC and EE genomes. We show an overall minor increase in methylation level in the allopolyploids, but extensive methylation reprogramming (70 %), with almost equivalently increased (22-26 %) and decreased methylation (25-27 %). Our study reveals a complicated epigenetic change in natural polyploids. The information presented in the study will be of some utility to molecular taxonomists and also rice breeders working on wide-hybridization