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A shift to metapopulation genetic management for persistence of a species threatened by fragmentation: the case of an endangered Australian freshwater fish
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  • Alexandra Pavlova,
  • Zeb Tonkin,
  • Luke Pearce,
  • Diana Robledo-Ruiz,
  • Mark Lintermans,
  • Brett Ingram,
  • Jarod Lyon,
  • Matt Beitzel,
  • Ben Broadhurst,
  • Meaghan Rourke,
  • Felicity Sturgiss,
  • Erin Lake,
  • Jesús Castrejón-Figueroa,
  • Jerom Stocks,
  • Paul Sunnucks
Alexandra Pavlova
Monash University

Corresponding Author:alexandra.pavlova@monash.edu

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Zeb Tonkin
Arthur Rylah Institute for Environmental Research
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Luke Pearce
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Diana Robledo-Ruiz
Monash University
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Mark Lintermans
Fish Fondler Pty Ltd
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Brett Ingram
Victorian Fisheries Authority
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Jarod Lyon
Arthur Rylah Institute for Environmental Research
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Matt Beitzel
Environment, Planning & Sustainable Development Directorate (ACT Government)
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Ben Broadhurst
University of Canberra
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Meaghan Rourke
New South Wales Department of Primary Industries Agriculture
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Felicity Sturgiss
NSW Local Land Services
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Jesús Castrejón-Figueroa
University of New South Wales School of Biotechnology and Biomolecular Sciences
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Jerom Stocks
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Paul Sunnucks
Monash University
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Abstract

In a world where habitats are degrading and the climate is warming and becoming increasingly unpredictable, biodiversity conservation efforts and funding remain grossly inadequate. There is a clear need to shift from preserving small, remnant populations to a model of genetically connecting populations that recreate larger and more diverse populations in climate-secure environments. This is crucial to harness key evolutionary processes to promote species’ ability to adapt to changing environments and to increase the likelihood of population persistence. Here, we use the endangered Macquarie perch (Macquaria australasica) as a case study to develop a genetic strategy for metapopulation management aimed at promoting population growth and persistence. Macquarie perch habitat has been highly fragmented and remaining habitat is at risk of catastrophic degradation due to climate change. We integrate results of new and existing genetic analyses to illustrate how genetically depauperate populations can benefit from admixture, and how the outcomes of management interventions can be quantified through genetic monitoring. We also develop the pipeline JeDi (https://github.com/drobledoruiz/JeDi) for estimating unbiased genetic heterozygosity for individuals and populations (nucleotide diversity) from reduced-representation genome sequencing data. We use this pipeline to estimate baseline data for monitoring of Macquarie perch populations and show that combining two genetic sources of migrants during population restoration resulted in doubling of nucleotide diversity compared to either source. Genetic diversity estimated using our pipeline is comparable across studies, datasets and species, and suitable for evaluating the rate of global biodiversity change.
01 Oct 2024Submitted to Molecular Ecology
04 Oct 2024Submission Checks Completed
04 Oct 2024Assigned to Editor
04 Oct 2024Review(s) Completed, Editorial Evaluation Pending
07 Oct 2024Reviewer(s) Assigned
17 Nov 2024Editorial Decision: Revise Minor