The merger of divergent genomes, via hybridization or allopolyploidization, frequently results in a 'genomic shock' that induces a series of rapid genetic and epigenetic modifications as a result of conflicts between parental genomes. This conflict among the subgenomes routinely leads one subgenome to become dominant over the other subgenome(s), resulting in subgenome biases in gene content and expression. Recent advances in methods to analyze hybrid and polyploid genomes with comparisons to extant parental progenitors have allowed for major strides in understanding the mechanistic basis for subgenome dominance. In particular, our understanding of the role that homoeologous exchange might play in subgenome dominance and genome evolution is quickly growing. Here I present novel work in several polyploid species investigating the biological and evolution impact of polyploidy and the evolution of these polyploid species. The first chapter introduces concepts like whole-genome duplication and describes advances in genomic sequencing technology that have accelerated the study of polyploid genomes. The second chapter reviews subgenome dominance and recent breakthroughs in understanding its causes and implications for genome evolution. The third chapter explores the repeatability of subgenome dominance in independently resynthesized Brassica napus. The fourth chapter investigates the extent to which genomic rearrangements from chromosomal duplications and deletions and homoeologous exchange can bias the analysis of subgenome expression dominance from RNAseq data. The fifth chapter explores the prevalence and impact of homoeologous exchange on independently resynthesized Brassica napus, providing novel evidence that gene dosage changes from homoeologous exchange are constrained by the need to maintain dosage balance of gene products. The sixth chapter explores the origins and admixture of wild octoploid strawberries Fragaria virgniana and Fragaria chiloensis with newly generated genomic resources applied to global collections.
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