Abstract
Modification of a species range is one of many consequences of climate change and is driving the emergence of Lyme disease in eastern Canada. The primary reservoir host of the bacteria responsible for Lyme disease, Borrelia burgdorferi, is the white-footed mouse (Peromyscus leucopus), whose range is rapidly shifting north into southern Québec. The deer mouse, P. maniculatus, is occurring over most Québec province and is a less competent host for B. burgdorferi. Here, we compared the phylogeographic structure of both Peromyscus species in Québec. Using a combination of multiple mitochondrial DNA markers and phylogeographic methods, we detected an ongoing and rapid expansion of P. leucopus, while P. maniculatus appears more stable. Haplotype and populations networks indicated that populations of P. maniculatus exhibit more genetic structure than P. leucopus across the study area. Furthermore, significant and consistent genetic divergences between populations of the two species on both sides of the St. Lawrence River suggest that distinct lineages of P. leucopus and P. maniculatus with different ancestral origins colonized Southern Québec following the Last Glacial Maximum. The phylogeographic structure of pathogens is expected to mirror the structure observed in their reservoir hosts. As different strains of Borrelia burgdorferi may be associated with different levels of pathogenicity and immune responses of their hosts, our results are helpful at better understanding the pattern of spread of Lyme disease in a zone of emergence, and associated risk for human populations.
Highlights
Climate change is occurring at a rate unprecedented in Earth history [1], and in the Northern Hemisphere, we are witnessing increasing global average temperature, shorter winters, and more abundant precipitations [2]
The numbers of parsimony-informative sites and segregating sites were larger in P. maniculatus for all markers, except for the D-Loop, which exhibited a reverse pattern
Haplotypes were more closely related in the white-footed mouse, with phylogeographic trees exhibiting a better resolution in Region D-Loop Cytochrome B (Cyt B) ATP8
Summary
Climate change is occurring at a rate unprecedented in Earth history [1], and in the Northern Hemisphere, we are witnessing increasing global average temperature, shorter winters, and more abundant precipitations [2]. Species may alter their geographical range to track changes in environmental conditions. Climate change is thought to be the driver of northern range expansion or range shifts in a number of species, which in turn is affecting the composition.
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