Genetic effects of long-term captive breeding on the endangered pygmy hog

Purohit, Deepanwita; Manu, Shivakumara; Ram, Muthuvarmadam Subramanian; Sharma, Smita; Patnaik, Harika Chinchilam; Deka, Parag; Narayan, Goutam; Umapathy, Govindhaswamy

doi:10.7717/peerj.12212

Cited by 7 publications

(3 citation statements)

References 50 publications

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“…The composition of MHC alleles in old and new urban and rural populations of wild waterbirds depends on the level of anthropogenic disturbance ( Pikus et al., 2021 ). The diversity of MHC in pigmy hogs that reproduce in captivity is reduced after only eight generations ( Purohit et al., 2021 ).…”

Section: Selective Breeding Genetic Improvement and Genetic Variabili...mentioning

confidence: 99%

Evolutionary pressures rendered by animal husbandry practices for avian influenza viruses to adapt to humans

Camargo¹,

Caetano²,

Santos³

2022

iScience

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Section: Selective Breeding Genetic Improvement and Genetic Variabili...mentioning

confidence: 99%

Evolutionary pressures rendered by animal husbandry practices for avian influenza viruses to adapt to humans

Camargo¹,

Caetano²,

Santos³

2022

iScience

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“…The release of individuals from a captive population with high homozygosity can also reduce the genetic variation of the species in the wild. Therefore, genetic variation of captive animals should also be concerned (Purohit et al 2021). Reduction in genetic diversity has been associated with an increased risk of extinction (Saccheri et al 1998).…”

Section: Introductionmentioning

confidence: 99%

Genetic Variation Within Four Captive Chital (<i>Axis axis</i>) Populations in Indonesia

Pratama

Rohmah²,

Arisuryanti³

2023

J.Tropical Biodiversity Biotechnology

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Chital is a native animal from South Asia. Chital had been introduced to many countries, including Indonesia. Chital was first introduced to Indonesia in 1811 at Bogor Palace and since had been kept captive around Indonesia. Currently, no research had been done concerning the genetic variation of Indonesian chital. Therefore, the purpose of this research was to analyze genetic variation and phylogenetic relationship of chital from Pusat Inovasi Agroteknologi Universitas Gadjah Mada (PIAT UGM), Prambanan Temple, Gembira Loka Zoo, and Bogor Palace, based on mitochondrial D-loop fragment. This study used a Polymerase Chain Reaction (PCR) method. DNA was extracted from faecal samples and amplified with L15995 and H16498 primers. The analysis used for this research were genetic variations, haplotype networking, and phylogenetic relationships between populations. This study detected 5 haplotypes out of 20 sequences with 10 polymorphic sites and 2 indels. The haplotype diversity and the nucleotide diversity were 0.443 and 0.002 respectively, and the genetic distance was between 0 and 2.03% (average 0.55%). This research also showed one main haplotype, labelled as haplotype 1, which consisted of all individuals from PIAT and Prambanan Temple, four individuals from Bogor Palace, and one individual from Gembira Loka. This grouping proves that the majority of chital population in Indonesia came from Bogor Palace. One individual from Gembira Loka has a considerable genetic divergence from the rest of the samples, which might indicate it originated from a different source population.

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“…Given that conserving genetic diversity and minimising inbreeding are important goals of most if not all captive breeding programmes 27,28 and reduced genetic diversity has been associated with increased extinction risk and reduced adaptive potential 29,30,31 , knowledge of the effects of captive breeding on genetic diversity is crucial. However, genetic time-series data are still uncommon for both captive and wild populations 32,33,34,35 . Temporal data can be especially informative about changes in key genetic characteristics of a population such as allelic richness, heterozygosity and the effective population size (N e ); measures that re ect a combination of the speed of allele frequency change through genetic drift, the e cacy of selection and expected genetic diversity levels for selectively neutral loci 36,37 .…”

Section: Introductionmentioning

confidence: 99%

The genetic consequences of captive breeding, environmental change and human exploitation in the endangered peninsular pronghorn

Klimova¹,

Sánchez-Sotomayor²,

Rivera³

et al. 2022

Preprint

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Endangered species with small population sizes are susceptible to genetic erosion, which can be detrimental to long-term persistence. Consequently, monitoring and mitigating the loss of genetic diversity are key to successful conservation. The peninsular pronghorn (Antilocapra americana peninsularis) is an endangered pronghorn subspecies that is almost entirely held in captivity. Captive breeding has increased the number of pronghorns from 25 founders in 1997 to around 700 individuals today, but it is unclear how the genetic diversity of the captive herd may have changed over time. We therefore generated and analysed microsatellite data spanning 2009–2021. We found a decline in heterozygosity and an increase in the proportion of inbred individuals over time. However, these trends appear to have abated in response to a genetically informed selective breeding attempt undertaken in 2018. We also reconstructed the recent demographic history of the peninsular pronghorn, revealing two sequential population declines putatively linked to the desertification of the Baja California peninsula around 6,000 years ago, and hunting and habitat loss around 500 years ago. Our results provide insights into the genetic diversity of an endangered antelope and highlight the potential for selective breeding to have positive conservation outcomes.

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Genetic effects of long-term captive breeding on the endangered pygmy hog

Cited by 7 publications

References 50 publications

Evolutionary pressures rendered by animal husbandry practices for avian influenza viruses to adapt to humans

Evolutionary pressures rendered by animal husbandry practices for avian influenza viruses to adapt to humans

Genetic Variation Within Four Captive Chital (<i>Axis axis</i>) Populations in Indonesia

The genetic consequences of captive breeding, environmental change and human exploitation in the endangered peninsular pronghorn

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