Alignment of mitogenome sequences (FASTA file) for a paleogenomic investigation of overharvest implications in an endemic wild reindeer subspecies

Overharvest can severely reduce the abundance and distribution of a species and thereby impact its genetic diversity and threaten its future viability. Overharvest remains an ongoing issue for Arctic mammals, which due to climate change now also confront one of the fastest changing environments on E...

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Bibliographic Details
Main Author: Martin, Michael
Format: Other/Unknown Material
Language:unknown
Published: Zenodo 2024
Subjects:
conservation genomics
Svalbard reindeer
Ancient DNA
population genomics
genomic erosion
population bottleneck
Bottleneck
Climate change
Rangifer tarandus
Rangifer tarandus platyrhynchus
Svalbard
svalbard reindeer
Online Access:https://doi.org/10.5061/dryad.tht76hf5n
Description
Summary:Overharvest can severely reduce the abundance and distribution of a species and thereby impact its genetic diversity and threaten its future viability. Overharvest remains an ongoing issue for Arctic mammals, which due to climate change now also confront one of the fastest changing environments on Earth. The high-Arctic Svalbard reindeer ( Rangifer tarandus platyrhynchus ), endemic to Svalbard, experienced a harvest-induced demographic bottleneck that occurred during the 17–20th centuries. Here we investigate changes in genetic diversity, population structure, and gene-specific differentiation during and after this overharvesting event. Using whole-genome shotgun sequencing, we generated the first ancient and historical nuclear (n = 11) and mitochondrial (n = 18) genomes from Svalbard reindeer (up to 4000 BP) and integrated these data with a large collection of modern genome sequences (n = 90), to infer temporal changes. We show that hunting resulted in major genetic changes and restructuring in reindeer populations. Near-extirpation followed by pronounced genetic drift have altered the allele frequencies of important genes contributing to diverse biological functions. Median heterozygosity was reduced by 23%, while the mitochondrial genetic diversity was reduced only to a limited extent, likely due to already low pre-harvest diversity and a complex post-harvest recolonization process. Such genomic erosion and genetic isolation of populations due to past anthropogenic disturbance will likely play a major role in metapopulation dynamics (i.e., extirpation, recolonization) under further climate change. Our results from a high-arctic case study therefore emphasize the need to understand the long-term interplay of past, current, and future stressors in wildlife conservation. Funding provided by: The Research Council of Norway Crossref Funder Registry ID: https://ror.org/00epmv149 Award Number: 325589 Funding provided by: The Research Council of Norway Crossref Funder Registry ID: https://ror.org/00epmv149 Award ...

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