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Interactions among gene regulation and expression, sequence deletion, and purifying selection following whole genome duplications in flowering plants

Authors :
Schnable, James Carey
Freeling, Michael1
Schnable, James Carey
Schnable, James Carey
Freeling, Michael1
Schnable, James Carey
Publication Year :
2012

Abstract

Polyploidy, or whole genome duplication, is rampant among both extant and ancient flowering plant species. Whole genome duplications create simultaneous copies of all genes contained within a genome as well as associated regulatory sequences. These duplication and the subsequent deletions of redundant coding and noncoding sequence both shape the natural evolution of plant genomes and provide a unique opportunity for researchers to characterize the regulatory sequences which determine when, in which cells and in what quantities the mRNA encoded for by particular genes will be produced. This dissertation describes a model for explaining both bias in gene loss between parental subgenomes and the escape from preferential retention of duplicated genes between sequential whole genome duplications. Bias in gene deletion between individual duplicated segments had been previously observed by the publication of the sorghum and maize genomes provided an opportunity to demonstrate this bias was a consistent mark distinguishing whole pairs of ancestral chromosomes, and that ongoing gene loss remains consistently biased between high and low gene loss subgenomes millions of generations after a whole genome duplication. Bias in both ancestral and ongoing gene loss is shown to be correlated with biased gene expression between parental subgenomes with genes on the low gene loss subgenome tending to show higher expression levels than duplicate copies of the same genes on the high gene loss subgenome. This phenomena, originally referred to as genome dominance, although the literature has since become somewhat confused, provides an explanation both for biased gene loss between parental subgenomes and for the escape of deletion-resistant genes from the ratchet of ever increasing copy numbers through continued whole genome duplications. This dissertation also demonstrates the use of polyploid lineage - in this case maize - as a deletion machine to rapidly characterize the function of regu

Details

Database :
OAIster
Notes :
application/pdf, English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1287407515
Document Type :
Electronic Resource