The time-dependent evolutionary rate of mitochondrial DNA in small mammals inferred from biogeographic calibration points with reference to the late Quaternary environmental changes in the Japanese archipelago

Mitochondrial DNA (mtDNA) sequences have long been the most popular marker for assessing phylogenetic relationships and uncovering population dynamics. However, the mechanism of the nucleotide substitution rate of mtDNA remains unclear. While the evolutionary rate over tens of thousands of years is thought to be time dependent, the overall picture is not fully understood. This article presents recent achievements related to the time-dependent evolutionary rate of mtDNA in small rodents in the Japanese archipelago. The method focuses on rapid expansion events during the late Quaternary, during which there was a prolonged severe cold period and repeated abrupt warm periods, providing multiple calibration points. The global sea level fluctuation and migration to islands help to specify the calibration points. For calibration points at 11000, 15000, 53000, and 130000 years ago, the evolutionary rates were approximately 0.11, 0.11, 0.047, and 0.029 substitutions/site/million years, respectively, in the mitochondrial cytochrome b gene (Cytb). Applying the higher rate to assess the evolutionary history of the commensal house mouse (Mus musculus) and complete mitochondrial genome sequences (~16000 bp) allowed us to trace prehistoric human culture development based on millet and rice agriculture. The pattern of time-dependent evolutionary rates presented here is likely applicable to other small rodents. The Japanese archipelago is ideal for assessing evolutionary rates with biogeographic calibration points in the late Quaternary in species with multiple genetically distinct local populations.