Abstract
The molecular clock of mitochondrial DNA has been extensively used to date various genetic events. However, its substitution rate among humans appears to be higher than rates inferred from human-chimpanzee comparisons, limiting the potential of interspecies clock calibrations for intraspecific dating. It is not well understood how and why the substitution rate accelerates. We have analyzed a phylogenetic tree of 3057 publicly available human mitochondrial DNA coding region sequences for changes in the ratios of mutations belonging to different functional classes. The proportion of non-synonymous and RNA genes substitutions has reduced over hundreds of thousands of years. The highest mutation ratios corresponding to fast acceleration in the apparent substitution rate of the coding sequence have occurred after the end of the Last Ice Age. We recalibrate the molecular clock of human mtDNA as 7990 years per synonymous mutation over the mitochondrial genome. However, the distribution of substitutions at synonymous sites in human data significantly departs from a model assuming a single rate parameter and implies at least 3 different subclasses of sites. Neutral model with 3 synonymous substitution rates can explain most, if not all, of the apparent molecular clock difference between the intra- and interspecies levels. Our findings imply the sluggishness of purifying selection in removing the slightly deleterious mutations from the human as well as the Neandertal and chimpanzee populations. However, for humans, the weakness of purifying selection has been further exacerbated by the population expansions associated with the out-of Africa migration and the end of the Last Ice Age.
Highlights
The idea of genes accumulating new mutations in a clock-like manner provides a versatile tool for dating genetic events [1,2] even when the clock is stochastic and its rate variable [3]
Phylogeographic studies of human mitochondrial DNA, especially those based on complete mitochondrial genomes, have yielded many results of general interest concerning the origins of our species and population movements that are behind the genetic patterns seen today [5,6,7]
The phrase ‘‘accumulation of new mutations’’ can refer to different levels of genetic variation: it can be related to DNA replication errors left unrepaired in meiosis, in population studies it refers to the level of polymorphism and in interspecies comparisons to the number of fixed differences
Summary
The idea of genes accumulating new mutations in a clock-like manner provides a versatile tool for dating genetic events [1,2] even when the clock is stochastic and its rate variable [3]. Phylogeographic studies of human mitochondrial DNA (mtDNA), especially those based on complete mitochondrial genomes, have yielded many results of general interest concerning the origins of our species and population movements that are behind the genetic patterns seen today [5,6,7]. A linear molecular clock for the human mtDNA has been assumed and applied for dating the nodes of the tree [9]. Time-dependence of the rate of accumulation of new mutations has been proposed based on several lines of evidence [10,11,12,13,14,15,16]. Time-dependence of mtDNA clock derives from the apparent substitution rate differences observed between the pedigree, intra- and interspecies levels
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