Your search keyword '"Tigers genetics"' showing total 5 results

1. Unraveling the genomic diversity and admixture history of captive tigers in the United States.

Author

Armstrong EE, Mooney JA, Solari KA, Kim BY, Barsh GS, Grant VB, Greenbaum G, Kaelin CB, Panchenko K, Pickrell JK, Rosenberg N, Ryder OA, Yokoyama T, Ramakrishnan U, Petrov DA, and Hadly EA

Subjects

Animals, United States, Phylogeny, Conservation of Natural Resources, Genomics methods, Genome genetics, Animals, Zoo genetics, Tigers genetics, Tigers classification, Genetic Variation, Endangered Species

Abstract

Genomic studies of endangered species have primarily focused on describing diversity patterns and resolving phylogenetic relationships, with the overarching goal of informing conservation efforts. However, few studies have investigated genomic diversity housed in captive populations. For tigers ( Panthera tigris ), captive individuals vastly outnumber those in the wild, but their diversity remains largely unexplored. Privately owned captive tiger populations have remained an enigma in the conservation community, with some believing that these individuals are severely inbred, while others believe they may be a source of now-extinct diversity. Here, we present a large-scale genetic study of the private (non-zoo) captive tiger population in the United States, also known as "Generic" tigers. We find that the Generic tiger population has an admixture fingerprint comprising all six extant wild tiger subspecies. Of the 138 Generic individuals sequenced for the purpose of this study, no individual had ancestry from only one subspecies. We show that the Generic tiger population has a comparable amount of genetic diversity relative to most wild subspecies, few private variants, and fewer deleterious mutations. We observe inbreeding coefficients similar to wild populations, although there are some individuals within both the Generic and wild populations that are substantially inbred. Additionally, we develop a reference panel for tigers that can be used with imputation to accurately distinguish individuals and assign ancestry with ultralow coverage (0.25×) data. By providing a cost-effective alternative to whole-genome sequencing (WGS), the reference panel provides a resource to assist in tiger conservation efforts for both ex- and in situ populations., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

2. Genome sequencing of captive white tigers from Bangladesh.

Author

Das A, Suvo MSH, Shaha M, and Gupta MD

Subjects

Animals, Bangladesh, Genome genetics, Genetic Variation genetics, Tigers genetics, Whole Genome Sequencing

Abstract

Objectives: The Bengal tiger Panthera tigris tigris, is an emblematic animal for Bangladesh. Despite being the apex predator in the wild, their number is decreasing due to anthropogenic activities such as hunting, urbanization, expansion of agriculture and deforestation. By contrast, captive tigers are flourishing due to practical conservation efforts. Breeding within the small captive population can produce inbreeding depression and genetic bottlenecks, which may limit the success of conservation efforts. Despite past decades of research, a comprehensive database on genetic variation in the captive and wild Bengal tigers in Bangladesh still needs to be included. Therefore, this research aimed to investigate the White Bengal tiger genome to create a resource for future studies to understand variation underlying important functional traits., Data Description: Blood samples from Chattogram Zoo were collected for three white Bengal tigers. Genomic DNA for all collected samples were extracted using a commercial DNA extraction kit. Whole genome sequencing was performed using a DNBseq platform. We generated 77 Gb of whole-genome sequencing (WGS) data for three white Bengal tigers (Average 11X coverage/sample). The data we generated will establish a paradigm for tiger research in Bangladesh by providing a genomic resource for future functional studies on the Bengal white tiger., (© 2024. The Author(s).)

Published

2024

3. Haplotype-resolved and chromosome-scale genomes provide insights into co-adaptation between the Amur tiger and Amur leopard.

Author

Li HM, Liu BY, Shi MH, Zhang L, Yang SC, Sahu SK, Cui LY, Liu SL, Dussex N, Ma Y, Liu D, Kong WY, Lu HR, Zhao Y, Dalén L, Liu H, Lan TM, Jiang GS, and Xu YC

Subjects

Animals, Haplotypes, Genome, Chromosomes genetics, Panthera genetics, Tigers genetics

Published

2024

4. The genetic status and rescue measure for a geographically isolated population of Amur tigers.

Author

Ning Y, Liu D, Gu J, Zhang Y, Roberts NJ, Guskov VY, Sun J, Liu D, Gong M, Qi J, He Z, Shi C, and Jiang G

Subjects

Animals, Female, Endangered Species, Heterozygote, Population Density, Microsatellite Repeats genetics, Conservation of Natural Resources, Genetic Variation, Tigers genetics, Lions genetics

Abstract

The Amur tiger is currently confronted with challenges of anthropogenic development, leading to its population becoming fragmented into two geographically isolated groups: smaller and larger ones. Small and isolated populations frequently face a greater extinction risk, yet the small tiger population's genetic status and survival potential have not been assessed. Here, a total of 210 samples of suspected Amur tiger feces were collected from this small population, and the genetic background and population survival potentials were assessed by using 14 microsatellite loci. Our results demonstrated that the mean number of alleles in all loci was 3.7 and expected heterozygosity was 0.6, indicating a comparatively lower level of population genetic diversity compared to previously reported studies on other subspecies. The genetic estimates of effective population size (Ne) and the Ne/N ratio were merely 7.6 and 0.152, respectively, representing lower values in comparison to the Amur tiger population in Sikhote-Alin (the larger group). However, multiple methods have indicated the possibility of genetic divergence within our isolated population under study. Meanwhile, the maximum kinship recorded was 0.441, and the mean inbreeding coefficient stood at 0.0868, both of which are higher than those observed in other endangered species, such as the African lion and the grey wolf. Additionally, we have identified a significant risk of future extinction if the lethal equivalents were to reach 6.26, which is higher than that of other large carnivores. Further, our simulation results indicated that an increase in the number of breeding females would enhance the prospects of this population. In summary, our findings provide a critical theoretical basis for further bailout strategies concerning Amur tigers., (© 2024. The Author(s).)

Published

2024

5. Insights for the Captive Management of South China Tigers Based on a Large-Scale Genetic Survey.

Author

Zhang W, Lin K, Fu W, Xie J, Fan X, Zhang M, Luo H, Yin Y, Guo Q, Huang H, Chen T, Lin X, Yuan Y, Huang C, and Du S

Subjects

Animals, China, Genetic Variation, Inbreeding, Female, Male, Conservation of Natural Resources methods, Breeding, Tigers genetics, Microsatellite Repeats genetics, Endangered Species

Abstract

There is an urgent need to find a way to improve the genetic diversity of captive South China tiger (SCT, Panthera tigris amoyensis ), the most critically endangered taxon of living tigers, facing inbreeding depression. The genomes showed that 13 hybrid SCTs from Meihuashan were divided into two groups; one group included three individuals who had a closer relationship with pureblood SCTs than another group. The three individuals shared more that 40% of their genome with pureblood SCTs and might be potential individuals for genetic rescuing in SCTs. A large-scale genetic survey based on 319 pureblood SCTs showed that the mean microsatellite inbreeding coefficient of pureblood SCTs decreased significantly from 0.1789 to 0.0600 ( p = 0.000009) and the ratio of heterozygous loci increased significantly from 38.5% to 43.2% ( p = 0.02) after one individual of the Chongqing line joined the Suzhou line and began to breed in the mid-1980s, which is a reason why the current SCTs keep a moderate level of microsatellite heterozygosity and nucleotide diversity. However, it is important to establish a back-up population based on the three individuals through introducing one pureblood SCT into the back-up population every year. The back-up population should be an important reserve in case the pureblood SCTs are in danger in the future.

Published

2024