Abstract
‘‘Synthetic” allopolyploids recreated by interspecific hybridization play an important role in providing novel genomic variation for crop improvement. Such synthetic allopolyploids often undergo rapid genomic structural variation (SV). However, how such SV arises, is inherited and fixed, and how it affects important traits, has rarely been comprehensively and quantitively studied in advanced generation synthetic lines. A better understanding of these processes will aid breeders in knowing how to best utilize synthetic allopolyploids in breeding programs. Here, we analyzed three genetic mapping populations (735 DH lines) derived from crosses between advanced synthetic and conventional Brassica napus (rapeseed) lines, using whole-genome sequencing to determine genome composition. We observed high tolerance of large structural variants, particularly toward the telomeres, and preferential selection for balanced homoeologous exchanges (duplication/deletion events between the A and C genomes resulting in retention of gene/chromosome dosage between homoeologous chromosome pairs), including stable events involving whole chromosomes (‘‘pseudoeuploidy”). Given the experimental design (all three populations shared a common parent), we were able to observe that parental SV was regularly inherited, showed genetic hitchhiking effects on segregation, and was one of the major factors inducing adjacent novel and larger SV. Surprisingly, novel SV occurred at low frequencies with no significant impacts on observed fertility and yield-related traits in the advanced generation synthetic lines. However, incorporating genome-wide SV in linkage mapping explained significantly more genetic variance for traits. Our results provide a framework for detecting and understanding the occurrence and inheritance of genomic SV in breeding programs, and support the use of synthetic parents as an important source of novel trait variation.
