Expression evolution of Mammalian duplicate genes and the mechanisms

Abstract

Liao's talk will be composed of two sections: (A) A new model for the expression evolution of Mammalian duplicate genes and (B) the underlying mechanisms.(A) Although evolutionary theories predict functional divergence between duplicate genes, many old duplicates still maintain a high degree of functional similarity and are synthetically lethal or sick, an observation that has puzzled many geneticists. We propose that expression reduction, a special type of subfunctionalization, facilitates the retention of duplicates and the conservation of their ancestral functions. Consistent with this hypothesis, gene expression data from both yeasts and mammals show a substantial decrease in the level of gene expression after duplication. Whereas the majority of the expression reductions are likely to be neutral, some are apparently beneficial to rebalancing gene dosage after duplication.(B) Although gene duplication plays a major role in organismal evolution, it may also lead to gene dosage imbalance, thereby having an immediate adverse effect on an organism's fitness. Investigating the evolution of the expression patterns of genes that duplicated after the divergence of rodents and primates, we confirm that adaptive evolution has been involved in dosage rebalance after gene duplication. To understand mechanisms underlying this process, we examined 1) microRNA (miRNA)-mediated gene regulation, 2) cis-regulatory sequence modifications, and 3) DNA methylation. Neither miRNA-mediated regulation nor cis-regulatory changes was found to be associated with expression reduction of duplicate genes. By contrast, duplicate genes, especially lowly expressed copies, were heavily methylated in the upstream region. However, for duplicate genes encoding proteins that are members of macromolecular complexes, heavy methylation in the genic region was not consistently observed. This result held after controlling potential confounding factors, such as enrichment in functional categories. Our results suggest that during mammalian evolution, DNA methylation plays a dominant role in dosage rebalance after gene duplication by inhibiting transcription initiation of duplicate genes.