Origin of new Brassica types from a single intergeneric hybrid between B. rapa and Orychophragmus violaceus by rapid chromosome evolution and introgression.

Many novel lines were established from an intergeneric mixoploid between Brassica rapa (2n = 20) and Orychophragmus violaceus (2n = 24) through successive selections for fertility and viability. Pedigrees of individual F(2) plants were advanced to the 10th generation by selfing. Their breeding habit was self-compatible and different from the self-incompatibility of their female parent B. rapa, and these lines were reproductively isolated to different degrees from B. rapa and B. napus. The lines with high productivity showed not only a wide spectrum of phenotypes but also obvious variations in fatty acid profiles of seed oil and glucosinolate contents in seed meal. These lines had 2n = 36, 37, 38, 39 and 40, with 2n = 38 being most frequent (64.56%), and no intact O. violaceus chromosomes were detected by genomic in situ hybridization (GISH) analysis. Amplified fragment length polymorphism (AFLP) analyses revealed a high extent of variation in genomic compositions across all the lines. O. violaceus-specific bands, deleted bands in B. rapa and novel bands for two parents were detected in these lines, with novel bands being the most frequent. The morphological and genetic divergence of these novel types derived from a single hybrid is probably due to rapid chromosomal evolution and introgression, and provides new genetic resources for rapeseed breeding.

[Chromosomal behaviors in plant wide hybridizations and their genetic and evolutionary implications].

The wide hybridization and polyploidization play a significant role in the evolution of higher plants. On the contrary, the artificially synthesized allopolyploids are genetically unstable and fail to be used as crops. One reason for this situation may be that the allopolyploids in nature are the products of natural selection and evolution and it is difficult for human to repeat and perform the process in short periods. Another reason is that we know little about the interaction mechanisms between the genomes of different origins. So the genetics and epigenetics after allopolyploidizations are now studied by multidisciplinary approaches. The spatial separation of parental genomes in hybrid cells have been observed in some sexual and somatic hybrids, but the biological meanings remain to clarify. The abnormal chromosome behaviors in plant wide crosses, such as pseudogamy, semigamy, chromosome elimination and the mitotic and meiotic separation of parental genomes, may indicate the incompatibility of two parental species at gametic and chromosomal levels. The systematic studies at different levels on chromosomal behavior and genetics in plant hybridizations are needed to undermine the mechanisms responsible for the formation and evolution of new species.