Your search keyword '"Tigers genetics"' showing total 7 results

1. A call for tiger management using "reserves" of genetic diversity.

Author

Bay RA, Ramakrishnan U, and Hadly EA

Subjects

Animals, Computer Simulation, DNA, Mitochondrial analysis, Demography, Endangered Species, Gene Flow, Likelihood Functions, Tigers classification, Conservation of Natural Resources methods, DNA, Mitochondrial genetics, Genetic Fitness genetics, Genetic Variation, Tigers genetics

Abstract

Tigers (Panthera tigris), like many large carnivores, are threatened by anthropogenic impacts, primarily habitat loss and poaching. Current conservation plans for tigers focus on population expansion, with the goal of doubling census size in the next 10 years. Previous studies have shown that because the demographic decline was recent, tiger populations still retain a large amount of genetic diversity. Although maintaining this diversity is extremely important to avoid deleterious effects of inbreeding, management plans have yet to consider predictive genetic models. We used coalescent simulations based on previously sequenced mitochondrial fragments (n = 125) from 5 of 6 extant subspecies to predict the population growth needed to maintain current genetic diversity over the next 150 years. We found that the level of gene flow between populations has a large effect on the local population growth necessary to maintain genetic diversity, without which tigers may face decreases in fitness. In the absence of gene flow, we demonstrate that maintaining genetic diversity is impossible based on known demographic parameters for the species. Thus, managing for the genetic diversity of the species should be prioritized over the riskier preservation of distinct subspecies. These predictive simulations provide unique management insights, hitherto not possible using existing analytical methods.

Published

2014

2. The development and validation of a single SNaPshot multiplex for tiger species and subspecies identification--implications for forensic purposes.

Author

Kitpipit T, Tobe SS, Kitchener AC, Gill P, and Linacre A

Subjects

Animals, Commerce legislation & jurisprudence, Crime legislation & jurisprudence, Databases, Nucleic Acid, Endangered Species legislation & jurisprudence, Sensitivity and Specificity, Sequence Analysis, DNA, Species Specificity, DNA Fingerprinting methods, DNA, Mitochondrial genetics, Multiplex Polymerase Chain Reaction, Polymorphism, Single Nucleotide, Tigers genetics

Abstract

The tiger (Panthera tigris) is currently listed on Appendix I of the Convention on the International Trade in Endangered Species of Wild Fauna and Flora; this affords it the highest level of international protection. To aid in the investigation of alleged illegal trade in tiger body parts and derivatives, molecular approaches have been developed to identify biological material as being of tiger in origin. Some countries also require knowledge of the exact tiger subspecies present in order to prosecute anyone alleged to be trading in tiger products. In this study we aimed to develop and validate a reliable single assay to identify tiger species and subspecies simultaneously; this test is based on identification of single nucleotide polymorphisms (SNPs) within the tiger mitochondrial genome. The mitochondrial DNA sequence from four of the five extant putative tiger subspecies that currently exist in the wild were obtained and combined with DNA sequence data from 492 tiger and 349 other mammalian species available on GenBank. From the sequence data a total of 11 SNP loci were identified as suitable for further analyses. Five SNPs were species-specific for tiger and six amplify one of the tiger subspecies-specific SNPs, three of which were specific to P. t. sumatrae and the other three were specific to P. t. tigris. The multiplex assay was able to reliably identify 15 voucher tiger samples. The sensitivity of the test was 15,000 mitochondrial DNA copies (approximately 0.26 pg), indicating that it will work on trace amounts of tissue, bone or hair samples. This simple test will add to the DNA-based methods currently being used to identify the presence of tiger within mixed samples., (Copyright © 2011 Elsevier Ireland Ltd. All rights reserved.)

Published

2012

3. Analysis of variable sites between two complete South China tiger (Panthera tigris amoyensis) mitochondrial genomes.

Author

Zhang W, Yue B, Wang X, Zhang X, Xie Z, Liu N, Fu W, Yuan Y, Chen D, Fu D, Zhao B, Yin Y, Yan X, Wang X, Zhang R, Liu J, Li M, Tang Y, Hou R, and Zhang Z

Subjects

Animals, Base Composition genetics, Base Sequence, Cell Nucleus genetics, China, Molecular Sequence Data, Sequence Alignment, Sequence Analysis, DNA, DNA, Mitochondrial genetics, Genome, Mitochondrial genetics, Tigers genetics

Abstract

In order to investigate the mitochondrial genome of Panthera tigris amoyensis, two South China tigers (P25 and P27) were analyzed following 15 cymt-specific primer sets. The entire mtDNA sequence was found to be 16,957 bp and 17,001 bp long for P25 and P27 respectively, and this difference in length between P25 and P27 occurred in the number of tandem repeats in the RS-3 segment of the control region. The structural characteristics of complete P. t. amoyensis mitochondrial genomes were also highly similar to those of P. uncia. Additionally, the rate of point mutation was only 0.3% and a total of 59 variable sites between P25 and P27 were found. Out of the 59 variable sites, 6 were located in 6 different tRNA genes, 6 in the 2 rRNA genes, 7 in non-coding regions (one located between tRNA-Asn and tRNA-Tyr and six in the D-loop), and 40 in 10 protein-coding genes. COI held the largest amount of variable sites (9 sites) and Cytb contained the highest variable rate (0.7%) in the complete sequences. Moreover, out of the 40 variable sites located in 10 protein-coding genes, 12 sites were nonsynonymous.

Published

2011

4. Applying molecular genetic tools to tiger conservation.

Author

Luo SJ, Johnson WE, and O'Brien SJ

Subjects

Animals, Endangered Species, Genotype, Phylogeography, Conservation of Natural Resources methods, DNA, Mitochondrial genetics, Tigers genetics

Abstract

The utility of molecular genetic approaches in conservation of endangered taxa is now commonly recognized. Over the past decade, conservation genetic analyses based on mitochondrial DNA sequencing and microsatellite genotyping have provided powerful tools to resolve taxonomy uncertainty of tiger subspecies, to define conservation units, to reconstruct phylogeography and demographic history, to examine the genetic ancestry of extinct subspecies, to assess population genetic status non-invasively, and to verify genetic background of captive tigers worldwide. The genetic status of tiger subspecies and populations and implications for developing strategies for the survival of this charismatic species both in situ and ex situ are discussed., (© 2010 ISZS, Blackwell Publishing and IOZ/CAS.)

Published

2010

5. A new method for DNA extraction from feces and hair shafts of the South China tiger (Panthera tigris amoyensis).

Author

Zhang W, Zhang Z, Xu X, Wei K, Wang X, Liang X, Zhang L, Shen F, Hou R, and Yue B

Subjects

Animals, DNA Fingerprinting methods, DNA Primers, DNA, Mitochondrial standards, Genotype, Grooming, Microsatellite Repeats, Polymerase Chain Reaction, DNA, Mitochondrial isolation & purification, Feces, Hair, Tigers genetics

Abstract

It is commonly known that tigers (Panthera tigris) groom themselves by licking their coats, which leads to an abundance of hairs in their feces. These hairs are designated specially as "fecal hairs". In our study, in order to explore fecal hairs potential as a DNA source for genetic analysis, 55 fecal hair samples were collected from 23 captive South China tigers (P. t. amoyensis). According to the amplification of mitochondrial primers loop F and loop R, DNA quality of noninvasive samples were grouped into three grades: grade I-the highest-quality DNA, grade II--high-quality DNA, and grade III--poor-quality DNA. No failed amplifications on microsatellite primers and only 0.27% genotyping errors occurred with grade I fecal hair DNA, as compared with 9.4% failed amplifications on microsatellite primers and 9.5% genotyping errors with grade II fecal hair DNA. It was found that 25.45% of fecal hair DNA was grade I and 65.45 and 10.00% of fecal hair DNA were grades II and III, respectively, as compared with 4.35% grade I fecal DNA and 34.78 and 60.87% grades II and III fecal DNA, respectively. Thus, higher-quality DNA can be extracted from fecal hairs than feces. In addition, DNA could be extracted from hair shafts of tigers and a minimum of 2000 hair shafts were required for visible DNA bands on a 1% agarose gel. These findings demonstrate that fecal hairs may serve as a convenient and reliable genomic DNA source for genotype analysis.

Published

2009

6. Mitochondrial phylogeography illuminates the origin of the extinct caspian tiger and its relationship to the amur tiger.

Author

Driscoll CA, Yamaguchi N, Bar-Gal GK, Roca AL, Luo S, Macdonald DW, and O'Brien SJ

Subjects

Animals, Asia, Central, China, Extinction, Biological, Geography, Haplotypes, Siberia, Tigers classification, Biological Evolution, DNA, Mitochondrial genetics, Phylogeny, Tigers genetics

Abstract

The Caspian tiger (Panthera tigris virgata) flourished in Central Asian riverine forest systems in a range disjunct from that of other tigers, but was driven to extinction in 1970 prior to a modern molecular evaluation. For over a century naturalists puzzled over the taxonomic validity, placement, and biogeographic origin of this enigmatic animal. Using ancient-DNA (aDNA) methodology, we generated composite mtDNA haplotypes from twenty wild Caspian tigers from throughout their historic range sampled from museum collections. We found that Caspian tigers carry a major mtDNA haplotype differing by only a single nucleotide from the monomorphic haplotype found across all contemporary Amur tigers (P. t. altaica). Phylogeographic analysis with extant tiger subspecies suggests that less than 10,000 years ago the Caspian/Amur tiger ancestor colonized Central Asia via the Gansu Corridor (Silk Road) from eastern China then subsequently traversed Siberia eastward to establish the Amur tiger in the Russian Far East. The conservation implications of these findings are far reaching, as the observed genetic depletion characteristic of modern Amur tigers likely reflects these founder migrations and therefore predates human influence. Also, due to their evolutionary propinquity, living Amur tigers offer an appropriate genetic source should reintroductions to the former range of the Caspian tiger be implemented.

Published

2009

7. Highly conserved D-loop-like nuclear mitochondrial sequences (Numts) in tiger (Panthera tigris).

Author

Zhang W, Zhang Z, Shen F, Hou R, Lv X, and Yue B

Subjects

Animals, Base Sequence, Cell Nucleus genetics, Complementarity Determining Regions, Conserved Sequence, Evolution, Molecular, Genetic Variation, Mitochondria genetics, Molecular Sequence Data, NADH Dehydrogenase genetics, Phylogeny, Sequence Alignment, Tigers classification, DNA, Mitochondrial chemistry, Tigers genetics

Abstract

Using oligonucleotide primers designed to match hypervariable segments I (HVS-1) of Panthera tigris mitochondrial DNA (mtDNA), we amplified two different PCR products (500 bp and 287 bp) in the tiger (Panthera tigris), but got only one PCR product (287 bp) in the leopard (Panthera pardus). Sequence analyses indicated that the sequence of 287 bp was a D-loop-like nuclear mitochondrial sequence (Numts), indicating a nuclear transfer that occurred approximately 4.8-17 million years ago in the tiger and 4.6-16 million years ago in the leopard. Although the mtDNA D-loop sequence has a rapid rate of evolution, the 287-bp Numts are highly conserved; they are nearly identical in tiger subspecies and only 1.742% different between tiger and leopard. Thus, such sequences represent molecular 'fossils' that can shed light on evolution of the mitochondrial genome and may be the most appropriate outgroup for phylogenetic analysis. This is also proved by comparing the phylogenetic trees reconstructed using the D-loop sequence of snow leopard and the 287-bp Numts as outgroup.

Published

2006