Abstract
The extensive interaction between mitochondrial-encoded and nuclear-encoded subunits of electron transport system (ETS) enzymes in mitochondria is expected to lead to intergenomic coadaptation. Whether this coadaptation results from adaptation to the environment or from fixation of deleterious mtDNA mutations followed by compensatory nuclear gene evolution is unknown. The intertidal copepod Tigriopus californicus shows extreme divergence in mtDNA sequence and provides an excellent model system for study of intergenomic coadaptation. Here, we examine genes encoding subunits of complex III of the ETS, including the mtDNA-encoded cytochrome b (CYTB), the nuclear-encoded rieske iron-sulfur protein (RISP), and cytochrome c(1) (CYC1). We compare levels of polymorphism within populations and divergence between populations in these genes to begin to untangle the selective forces that have shaped evolution in these genes. CYTB displays dramatic divergence between populations, but sequence analysis shows no evidence for positive selection driving this divergence. CYC1 and RISP have lower levels of sequence divergence between populations than CYTB, but, again, sequence analysis gives no evidence for positive selection acting on them. However, an examination of variation at cytochrome c (CYC), a nuclear-encoded protein that transfers electrons between complex III and complex IV provides evidence for selective divergence. Hence, it appears that rapid evolution in mitochondrial-encoded subunits is not always associated with rapid divergence in interacting subunits (CYC1 and RISP), but can be in some cases (CYC). Finally, a comparison of nuclear-encoded and mitochondrial-encoded genes from T. californicus suggests that substitution rates in the mitochondrial-encoded genes are dramatically increased relative to nuclear genes.
Highlights
The 13 proteins encoded by mitochondrial DNA in animals are subunits of the electron transport system (ETS) and, together with some 65 nuclear-encoded subunits, comprise the oligomeric enzyme complexes of the ETS
The well-supported Tigriopus clade has comparatively long branches, suggesting rapid amino acid evolution in this group. This impression is supported by relative rates comparisons with other arthropods: T. californicus is 2.03fold faster when compared with Daphnia pulex, 2.7-fold
Fisher’s exact test was used to calculate the probability that observed changes differ from the neutral expectation. a Numbers do not match those in table 7 because some polymorphic sites were found in noncoding regions with alignment gaps between populations and were excluded. b Polymorphism in H1 is taken from sequences from AB, San Diego (SD), and Santa Cruz (SC) populations previously obtained (Burton and Lee 1994; Burton 1998)
Summary
The 13 proteins encoded by mitochondrial DNA (mtDNA) in animals are subunits of the electron transport system (ETS) and, together with some 65 nuclear-encoded subunits, comprise the oligomeric enzyme complexes of the ETS. Two different scenarios of selection/drift could generate intergenomic coadaptation: (1) Selection pressure on ETS enzymes could be generated by the adaptation of a species (or population) to its environment (i.e., thermal environment for ectotherms) leading to changes in both nuclearencoded and mitochondrial-encoded subunits of ETS complexes. (2) High mutation rates in mtDNA, especially when coupled with fluctuating population sizes, may lead to fixation of deleterious amino acid substitutions and provide selection pressure for subsequent compensatory changes in nuclear genes, a two-step process that could drive evolution of coadaptation in ETS enzymes. 3 Ó Society for Molecular Biology and Evolution 2004; all rights reserved
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