Abstract
Regulatory networks often increase in complexity during evolution through gene duplication and divergence of component proteins. Two models that explain this increase in complexity are: 1) adaptive changes after gene duplication, such as resolution of adaptive conflicts, and 2) non-adaptive processes such as duplication, degeneration and complementation. Both of these models predict complementary changes in the retained duplicates, but they can be distinguished by direct fitness measurements in organisms with short generation times. Previously, it has been observed that repeated duplication of an essential protein in the spindle checkpoint pathway has occurred multiple times over the eukaryotic tree of life, leading to convergent protein domain organization in its duplicates. Here, we replace the paralog pair in S. cerevisiae with a single-copy protein from a species that did not undergo gene duplication. Surprisingly, using quantitative fitness measurements in laboratory conditions stressful for the spindle-checkpoint pathway, we find no evidence that reorganization of protein function after gene duplication is beneficial. We then reconstruct several evolutionary intermediates from the inferred ancestral network to the extant one, and find that, at the resolution of our assay, there exist stepwise mutational paths from the single protein to the divergent pair of extant proteins with no apparent fitness defects. Parallel evolution has been taken as strong evidence for natural selection, but our results suggest that even in these cases, reorganization of protein function after gene duplication may be explained by neutral processes.
Highlights
Gene duplication and sub-/neo-functionalization are processes that both increase genomic complexity and are thought to be the major sources of genetic novelty in organisms [1]
Parallel evolution of protein domain organization following gene duplication has been demonstrated in the spindle checkpoint pathway leading to the hypothesis that this organization is likely to be adaptive
Consistent with this, we have identified at least one phylogenetic clade where the gene duplication in the ancestor of Saccharomyces reverted to the single-copy functional homolog: Vanderwaltozyma polysporus retains a single-copy protein with all the functional elements of Bub1 and Mad3 even though it diverged after the whole-genome duplication (S4 Fig)
Summary
Gene duplication and sub-/neo-functionalization are processes that both increase genomic complexity and are thought to be the major sources of genetic novelty in organisms [1]. Perhaps even more striking is that in each event, the duplication almost always leads to a Bub homolog, containing a kinase domain and a Mad homolog containing a pseudo-substrate APC inhibitor motif [3]. This reorganization of protein function has been thought to be adaptive, leading to a more complex spindle checkpoint pathway [3,4]. If degeneration and complementation of the ancestral bi-functional protein must always lead to Bub and Mad division of function (i.e., kinase function separated from the pseudo-substrate inhibitor motif), the repeated observation of Bub and Mad protein organization might be due to a rate of degeneration that is higher than the rate of reconstitution
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