Molecular and genomic tools provide a deeper understanding of the ecology and evolution of species and their capacity to adapt to changing selective pressures, where diversity is presumedly linked to higher fitness and evolutionary potential. Molecular tools can also illustrate how historical processes affect contemporary genetic variation to predict how current population trends may influence future genetic diversity. Genomic investigations increasingly extend beyond variation within host genomes to include diversity of their associated microbiomes, recognized to influence host/environment interactions and adaptation. Muskoxen (Ovibos moschatus) are iconic, Arctic herbivores of ecological, economic, and cultural significance. Demographically, most mainland muskox populations have remained stable or grown over the last century, yet the biggest herds, found on Victoria and Banks Islands (Nunavut and the Northwest Territories, Canada) have experienced recent and drastic population declines. These Arctic island population declines have been associated with warming trends leading to shifting ranges of forage biodiversity, and pathogen expansions directly associated with increased mortality. Genomic investigations have the potential to enhance understanding of these contrasting trends and the adaptive capacities of muskox to cope with rapid ecological change. In this thesis, I assess genetic, genomic, microbiome and diet diversity to better understand the ecology, and evolution of muskoxen. I found extremely low levels of genetic variation associated with population bottlenecks coinciding with major glaciation events and contemporarily low levels of gene flow among populations. Whole genome analyses identified signatures of selection between muskox populations, providing a genetic basis for the divergence of two previously proposed muskox subspecies. Significant differences in diversity, effective population size and inbreeding among subspecies suggests animals from Arctic islands and Greenland are more vulnerable to environmental change. Molecular investigations of diet and microbiome diversity reflected unique capacities of muskoxen to survive on high-fiber forage and exploit shifts in Arctic vegetation that may include continued shrubification. Overall, these data provide insight into the complex relationship between genetic diversity and changing environments, setting a foundation for expanded future investigations of muskox seeking to promote the future viability of this species.
Author Keywords: Genetic Diversity, Genome Assembly, Metabarcoding, Microsatellites, Muskox, Persistence