Diversity and structure of Bettongia tropica: using population genetics to guide reintroduction and help prevent the extinction of an endangered Australian marsupial

Todd, Stephanie J.; McKnight, Donald T.; Congdon, Bradley C.; Pierson, Jennifer C.; Fischer, Manuela; Abell-Davis, Sandra E.; Koleck, Jessica

doi:10.1007/s10592-023-01533-2

Cited by 2 publications

(1 citation statement)

References 81 publications

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“…Additionally, a higher proportion of the recaptured population were hybrids ($28%, compared to 6.45% and 16.67% of released Avoca and Campaspe cohorts, respectively), potentially suggesting that genetic mixing may improve individual survivability. The higher levels of hybridization in F1 cohorts likely contributed to the maintenance of heterozygosity, as reintroduced populations from mixed sources may have moderately higher heterozygosity than their respective source populations (Huff et al, 2010;McKnight et al, 2023). While genetic mixing may result in the loss of unique genetic variation from the source populations due to homogenization, the low genetic diversity of-and strong genetic drift and limited adaptive differentiation between-upland populations (Brauer et al, 2016) suggests that mixing is a more effective conservation strategy than maintaining genetic "uniqueness" (Ralls et al, 2018;Weeks et al, 2016).…”

Section: Genetic Components Of Reintroduction and Managementmentioning

confidence: 99%

A community‐driven captive‐breeding and reintroduction program maintains genetic diversity in a threatened freshwater fish

Buckley,

Brauer,

Lamin

et al. 2023

Conservat Sci and Prac

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Collaborative approaches to conservation management are critical to respond to the ongoing biodiversity crisis. However, local community involvement in many conservation actions is lacking, especially within translocation and reintroduction programs. Similarly, rapid integration of genetic information into collaborative programs with local communities is rarely conducted. Here, we describe a community‐based and collaborative reintroduction program for a threatened Australian freshwater fish, the southern pygmy perch (Nannoperca australis). We integrate on‐the‐ground translocation efforts by volunteers from local communities, captive breeding by a private aquarium business, and genetic analyses done by a research institution to provide a holistic framework for the reintroduction of southern pygmy perch. We evaluated genetic diversity, population structure, relatedness, and inbreeding across the duration of the reintroduction program using data from neutral and adaptive genomic markers. This allowed us to assess the ability of such a program to minimize inbreeding and retain genomic variation, and to promote adaptive potential of the reintroduced population. While genetic variation for the source populations was very low, we found no decrease in genetic diversity or increase in inbreeding across the program. These genetic findings support the efforts made by local communities and will further inform future reintroductions as part of a collaborative conservation framework. We expand on our empirical case study by describing a theoretical framework for integrating conservation genomics research with community‐led conservation management programs and identifying the benefits of such a collaboration. Our study highlights the importance of multifaceted and integrated conservation management approaches to effectively protect and manage threatened species.

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Section: Genetic Components Of Reintroduction and Managementmentioning

confidence: 99%

A community‐driven captive‐breeding and reintroduction program maintains genetic diversity in a threatened freshwater fish

Buckley,

Brauer,

Lamin

et al. 2023

Conservat Sci and Prac

View full text Add to dashboard Cite

show abstract

Estimates of heterozygosity from single nucleotide polymorphism markers are context‐dependent and often wrong

Sopniewski,

Catullo

2024

Molecular Ecology Resources

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Genetic diversity is frequently described using heterozygosity, particularly in a conservation context. Often, it is estimated using single nucleotide polymorphisms (SNPs); however, it has been shown that heterozygosity values calculated from SNPs can be biased by both study design and filtering parameters. Though solutions have been proposed to address these issues, our own work has found them to be inadequate in some circumstances. Here, we aimed to improve the reliability and comparability of heterozygosity estimates, specifically by investigating how sample size and missing data thresholds influenced the calculation of autosomal heterozygosity (heterozygosity calculated from across the genome, i.e. fixed and variable sites). We also explored how the standard practice of tri‐ and tetra‐allelic site exclusion could bias heterozygosity estimates and influence eventual conclusions relating to genetic diversity. Across three distinct taxa (a frog, Litoria rubella; a tree, Eucalyptus microcarpa; and a grasshopper, Keyacris scurra), we found heterozygosity estimates to be meaningfully affected by sample size and missing data thresholds, partly due to the exclusion of tri‐ and tetra‐allelic sites. These biases were inconsistent both between species and populations, with more diverse populations tending to have their estimates more severely affected, thus having potential to dramatically alter interpretations of genetic diversity. We propose a modified framework for calculating heterozygosity that reduces bias and improves the utility of heterozygosity as a measure of genetic diversity, whilst also highlighting the need for existing population genetic pipelines to be adjusted such that tri‐ and tetra‐allelic sites be included in calculations.

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Diversity and structure of Bettongia tropica: using population genetics to guide reintroduction and help prevent the extinction of an endangered Australian marsupial

Cited by 2 publications

References 81 publications

A community‐driven captive‐breeding and reintroduction program maintains genetic diversity in a threatened freshwater fish

A community‐driven captive‐breeding and reintroduction program maintains genetic diversity in a threatened freshwater fish

Estimates of heterozygosity from single nucleotide polymorphism markers are context‐dependent and often wrong

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