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Heterogeneous patterns of heterozygosity loss in isolated populations of the threatened eastern barred bandicoot (Perameles gunnii)

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posted on 2024-10-25, 01:00 authored by John G Black, ARJ van Rooyen, Dean HeinzeDean Heinze, Robbie Gaffney, Ary A Hoffmann, Thomas L Schmidt, Andrew R Weeks
Identifying and analysing isolated populations is critical for conservation. Isolation can make populations vulnerable to local extinction due to increased genetic drift and inbreeding, both of which should leave imprints of decreased genome-wide heterozygosity. While decreases in heterozygosity among populations are frequently investigated, fewer studies have analysed how heterozygosity varies among individuals, including whether heterozygosity varies geographically along lines of discrete population structure or with continuous patterns analogous to isolation by distance. Here we explore geographical patterns of differentiation and individual heterozygosity in the threatened eastern barred bandicoot (Perameles gunnii) in Tasmania, Australia, using genomic data from 85 samples collected between 2008 and 2011. Our analyses identified two isolated demes undergoing significant genetic drift, and several areas of fine-scale differentiation across Tasmania. We observed discrete genetic structures across geographical barriers and continuous patterns of isolation by distance, with little evidence of recent or historical migration. Using a recently developed analytical pipeline for estimating autosomal heterozygosity, we found individual heterozygosities varied within demes by up to a factor of two, and demes with low-heterozygosity individuals also still contained those with high heterozygosity. Spatial interpolation of heterozygosity scores clarified these patterns and identified the isolated Tasman Peninsula as a location where low-heterozygosity individuals were more common than elsewhere. Our results provide novel insights into the relationship between isolation-driven genetic structure and local heterozygosity patterns. These may help improve translocation efforts, by identifying populations in need of assistance, and by providing an individualised metric for identifying source animals for translocation.

Funding

Funding for genetic analysis of samples was provided by Cesar Australia. John Black was funded by a PhD scholarship from the University of Melbourne. Thomas L Schmidt was funded by an ARC DECRA Fellowship (DE230100257). Andrew Weeks and Ary Hoffmann received financial support from the National Environment Science Program Threatened Species Recovery Hub (Federal Department of Environment and Energy) and the Australian Research Council Discovery grant scheme (DP160100661) for sequencing and assembling the genome scaffold for P. gunnii with ethics approval 1613835.1.

History

Publication Date

2024-10-01

Journal

Molecular Ecology

Volume

33

Issue

20

Article Number

17224

Pagination

16p.

Publisher

Wiley

ISSN

0962-1083

Rights Statement

This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. © 2023 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.

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