Evaluation of alternative management strategies for maintenance of genetic variation in wildlife populations

Giglio, Rachael M; Ivy, Jamie A.; Jones, Lee; Latch, Emily K.

doi:10.1111/acv.12254

Cited by 22 publications

(22 citation statements)

References 54 publications

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“…There is an urgent need for research to quantify these risks and identify solutions, as well as to develop policies and regulations to manage these emerging threats. Genotyping methods could be implemented as valuable tools to monitor genetic changes in ungulate populations, maintenance of their original genetic structure and to perform more precise censuses, particularly in the case of rare or endangered species (Giglio et al 2016). …”

Section: Genetic Composition Of Ungulatesmentioning

confidence: 99%

Challenges and science-based implications for modern management and conservation of European ungulate populations

et al. 2017

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Wildlife management systems face growing challenges to cope with increasingly complex interactions between wildlife populations, the environment and human activities. In this position statement, we address the most important issues characterising current ungulate conservation and management in Europe. We present some key points arising from ecological research that may be critical for a reassessment of ungulate management in the future.

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Section: Genetic Composition Of Ungulatesmentioning

confidence: 99%

Challenges and science-based implications for modern management and conservation of European ungulate populations

et al. 2017

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“…Even in cases where the evidence for genetic adaptation is strong, management interventions should strive to conserve adaptive variation without eroding genomewide variation (Giglio, Ivy, Jones, & Latch, 2016; Haig, Ballou, & Derrickson, 1990; Spielman, Brook, & Frankham, 2004). Conversely, management actions designed to preserve genomewide variation may either involve risks of disrupting local adaptation to nonclimatic factors (e.g., biotic interactions, soils) if local adaptation is not well understood, or could result in outbreeding depression if individuals from long‐diverged populations are mixed and interbreed (see Frankham et al., 2011 for guidance on when this might occur).…”

Section: Introductionmentioning

confidence: 99%

Guidelines for planning genomic assessment and monitoring of locally adaptive variation to inform species conservation

Flanagan

Forester

Latch

et al. 2017

Evolutionary Applications

197

189

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Identifying and monitoring locally adaptive genetic variation can have direct utility for conserving species at risk, especially when management may include actions such as translocations for restoration, genetic rescue, or assisted gene flow. However, genomic studies of local adaptation require careful planning to be successful, and in some cases may not be a worthwhile use of resources. Here, we offer an adaptive management framework to help conservation biologists and managers decide when genomics is likely to be effective in detecting local adaptation, and how to plan assessment and monitoring of adaptive variation to address conservation objectives. Studies of adaptive variation using genomic tools will inform conservation actions in many cases, including applications such as assisted gene flow and identifying conservation units. In others, assessing genetic diversity, inbreeding, and demographics using selectively neutral genetic markers may be most useful. And in some cases, local adaptation may be assessed more efficiently using alternative approaches such as common garden experiments. Here, we identify key considerations of genomics studies of locally adaptive variation, provide a road map for successful collaborations with genomics experts including key issues for study design and data analysis, and offer guidelines for interpreting and using results from genomic assessments to inform monitoring programs and conservation actions.

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“…There is a possible overestimation of genetic diversity in the offspring when using the same markers for estimating relatedness in the breeders. However, reducing average relatedness in breeding groups has been theoretically and empirically demonstrated as an effective method to retain genetic diversity in captive breeding programmes without pedigree information (Sonesson 2001;Allendorf et al 2010;Ivy & Lacy 2012;Giglio et al 2016). Moreover, the use of genomic data (ddRAD, GBS, etc.)…”

Section: Simulation Analysismentioning

confidence: 99%

swinger: a user‐friendly computer program to establish captive breeding groups that minimize relatedness without pedigree information

Sandoval‐Castillo

Attard

Marri

et al. 2016

Molecular Ecology Resources

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Captive breeding programmes are often a necessity for the continued persistence of a population or species. They typically have the goal of maintaining genetic diversity and minimizing inbreeding. However, most captive breeding programmes have been based on the assumption that the founding breeders are unrelated and outbred, even though in situ anthropogenic impacts often mean these founders may have high relatedness and substantial inbreeding. In addition, polygamous group-breeding species in captivity often have uncertain pedigrees, making it difficult to select the group composition for subsequent breeding. Molecular-based estimates of relatedness and inbreeding may instead be used to select breeding groups (≥two individuals) that minimize relatedness and filter out inbred individuals. swinger constructs breeding groups based on molecular estimates of relatedness and inbreeding. The number of possible combinations of breeding groups quickly becomes intractable by hand. swinger was designed to overcome this major issue in ex situ conservation biology. The user can specify parameters within swinger to reach breeding solutions that suit the mating system of the target species and available resources. We provide evidence of the efficiency of the software with an empirical example and using simulations. The only data required are a typical molecular marker data set, such as a microsatellite or SNP data set, from which estimates of inbreeding and pairwise relatedness may be obtained. Such molecular data sets are becoming easier to gather from non-model organisms with next-generation sequencing technology. swinger is an open-source software with a user-friendly interface and is available at http://www.molecularecology.flinders.edu.au/molecular-ecology-lab/software/swinger/swinger/ and https://github.com/Yuma248/Swinger.

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Evaluation of alternative management strategies for maintenance of genetic variation in wildlife populations

Cited by 22 publications

References 54 publications

Challenges and science-based implications for modern management and conservation of European ungulate populations

Challenges and science-based implications for modern management and conservation of European ungulate populations

Guidelines for planning genomic assessment and monitoring of locally adaptive variation to inform species conservation

swinger: a user‐friendly computer program to establish captive breeding groups that minimize relatedness without pedigree information

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