Abstract
Functional divergence of duplicate genes, or paralogs, is an important driver of novelty in evolution. In the model yeast Saccharomyces cerevisiae, there are 547 paralog gene pairs that survive from an interspecies Whole Genome Hybridization (WGH) that occurred ~100MYA. In this work, we report that ~1/6th (110) of these WGH paralogs pairs (or ohnologs) are differentially expressed with a striking pattern upon Protein Kinase A (PKA) inhibition. One member of each pair in this group has low basal expression that increases upon PKA inhibition, while the other has moderate and unchanging expression. For these genes, expression of orthologs upon PKA inhibition in the non-WGH species Kluyveromyces lactis and for PKA-related stresses in other budding yeasts shows unchanging expression, suggesting that lack of responsiveness to PKA was likely the typical ancestral phenotype prior to duplication. Promoter sequence analysis across related budding yeast species further revealed that the subsequent emergence of PKA-dependence took different evolutionary routes. In some examples, regulation by PKA and differential expression appears to have arisen following the WGH, while in others, regulation by PKA appears to have arisen in one of the two parental lineages prior to the WGH. More broadly, our results illustrate the unique opportunities presented by a WGH event for generating functional divergence by bringing together two parental lineages with separately evolved regulation into one species. We propose that functional divergence of two ohnologs can be facilitated through such regulatory divergence.
Highlights
Gene duplication is considered an important source of novelty and adaptation in evolution (Ohno, 1970; Taylor and Raes, 2004; Hittinger and Carroll, 2007; Conant and Wolfe, 2008; Des Marais and Rausher, 2008)
Response to Protein Kinase A (PKA) Inhibition With That of Information about stress and carbon source availability is transduced within budding yeast cells through the second messenger cyclic adenosine monophosphate
Gene duplication is a major driver of innovation in evolution, and our findings from this study help to better understand the mechanisms that can drive this evolutionary innovation in the special case of an allopolyploidization or Whole Genome Hybridization (WGH)
Summary
Gene duplication is considered an important source of novelty and adaptation in evolution (Ohno, 1970; Taylor and Raes, 2004; Hittinger and Carroll, 2007; Conant and Wolfe, 2008; Des Marais and Rausher, 2008). Much of the understanding we have of WGD comes from work done on the model organism Saccharomyces cerevisiae, the first eukaryote to have its genome fully sequenced (Goffeau et al, 1996). Paralogs resulting from a WGD are known as “ohnologs,” and today S. cerevisiae retains 547 ohnologs from its WGD, comprising nearly 18% of its annotated protein coding genes (Byrne and Wolfe, 2005).
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