Your search keyword '"genetic structures"' showing total 5 results

1. Low Genetic Diversity of Vector-Borne Haemoparasites in Dogs and Their Ticks Revealed Local and Long-Range Transmission in Peninsular Malaysia.

Author

Sipin, Quincie, Mustaffa-Kamal, Farina, Watanabe, Malaika, Abdul Rani, Puteri Azaziah Megat, and Aziz, Nor Azlina Abdul

Subjects

*BABESIA, *GENETIC variation, *DOGS, *TICKS, *CANIS, *HAPLOTYPES, *ANAPLASMA, *EHRLICHIA

Abstract

Molecular methods coupled with phylogenetic analysis are sensitive tools for detecting and classifying parasites. This study used nuclear and mitochondrial gene markers to investigate the host-vector interaction of the vector-borne haemoparasites. The population genetic structures of important vector-borne haemoparasites in dogs, namely, Anaplasma platys, Ehrlichia canis, Babesia vogeli, and Babesia gibsoni, were determined from the nuclear gene of 16S or 18S rRNA gene, gltA and groESL and mitochondrial gene of COX1 across dogs and vector ticks. A total of 220 blood samples and 140 ticks were collected from shelter dogs in Peninsular Malaysia. Out of the positive samples for the vector-borne haemoparasites, 28 positive blood isolates and six tick isolates were selected and characterised. There was a low diversity in tick sequences, while varying degree of variability was observed in dogs' sequences. Overlapped haplotypes were observed in sequences of dogs and ticks, revealing the possibility of the same infection origin. No regional separation was detected, but similar haplotypes from different regions were observed. These findings contribute to the epidemiology of vector-borne haemoparasites in dogs in Malaysia. [ABSTRACT FROM AUTHOR]

Published

2023

2. Brown banded bamboo shark (Chiloscyllium punctatum) shows high genetic diversity and differentiation in Malaysian waters.

Author

Lim KC, Then AY, Wee AKS, Sade A, Rumpet R, and Loh KH

Subjects

Animals, Borneo, China, Conservation of Natural Resources, DNA, Mitochondrial genetics, Ecosystem, Gene Flow, Genetic Structures, Geography, Malaysia, NADH Dehydrogenase genetics, Genetic Variation genetics, Genetics, Population, Seawater, Sharks genetics

Abstract

The demersal brown banded bamboo shark Chiloscyllium punctatum is a major component of sharks landed in Malaysia. However, little is known about their population structure and the effect of high fishing pressure on these weak swimming sharks. Both mitochondrial DNA control region (1072 bp) and NADH dehydrogenase subunit 2 (1044 bp) were used to elucidate the genetic structure and connectivity of C. punctatum among five major areas within the Sundaland region. Our findings revealed (i) strong genetic structure with little present day mixing between the major areas, (ii) high intra-population genetic diversity with unique haplotypes, (iii) significant correlation between genetic differentiation and geographical distance coupled with detectable presence of fine scale geographical barriers (i.e. the South China Sea), (iv) historical directional gene flow from the east coast of Peninsular Malaysia towards the west coast and Borneo, and (v) no detectable genetic differentiation along the coastline of east Peninsular Malaysia. Genetic patterns inferred from the mitochondrial DNA loci were consistent with the strong coastal shelf association in this species, the presence of contemporary barriers shaped by benthic features, and limited current-driven egg dispersal. Fine scale population structure of C. punctatum highlights the need to improve genetic understanding for fishery management and conservation of other small-sized sharks., (© 2021. The Author(s).)

Published

2021

3. Dispersal and genetic structure in a tropical small mammal, the Bornean tree shrew (Tupaia longipes), in a fragmented landscape along the Kinabatangan River, Sabah, Malaysia.

Author

Brunke J, Russo IM, Orozco-terWengel P, Zimmermann E, Bruford MW, Goossens B, and Radespiel U

Subjects

Animals, Ecosystem, Female, Gene Flow genetics, Genetic Markers genetics, Haplotypes genetics, Malaysia, Male, Mammals, Rivers, Genetic Structures, Genetic Variation, Tupaia genetics

Abstract

Background: Constraints in migratory capabilities, such as the disruption of gene flow and genetic connectivity caused by habitat fragmentation, are known to affect genetic diversity and the long-term persistence of populations. Although negative population trends due to ongoing forest loss are widespread, the consequence of habitat fragmentation on genetic diversity, gene flow and genetic structure has rarely been investigated in Bornean small mammals. To fill this gap in knowledge, we used nuclear and mitochondrial DNA markers to assess genetic diversity, gene flow and the genetic structure in the Bornean tree shrew, Tupaia longipes, that inhabits forest fragments of the Lower Kinabatangan Wildlife Sanctuary, Sabah. Furthermore, we used these markers to assess dispersal regimes in male and female T. longipes., Results: In addition to the Kinabatangan River, a known barrier for dispersal in tree shrews, the heterogeneous landscape along the riverbanks affected the genetic structure in this species. Specifically, while in larger connected forest fragments along the northern riverbank genetic connectivity was relatively undisturbed, patterns of genetic differentiation and the distribution of mitochondrial haplotypes in a local scale indicated reduced migration on the strongly fragmented southern riverside. Especially, oil palm plantations seem to negatively affect dispersal in T. longipes. Clear sex-biased dispersal was not detected based on relatedness, assignment tests, and haplotype diversity., Conclusion: This study revealed the importance of landscape connectivity to maintain migration and gene flow between fragmented populations, and to ensure the long-term persistence of species in anthropogenically disturbed landscapes.

Published

2020

4. The population genomic landscape of human genetic structure, admixture history and local adaptation in Peninsular Malaysia.

Author

Deng L, Hoh BP, Lu D, Fu R, Phipps ME, Li S, Nur-Shafawati AR, Hatin WI, Ismail E, Mokhtar SS, Jin L, Zilfalil BA, Marshall CR, Scherer SW, Al-Mulla F, and Xu S

Subjects

Adaptation, Physiological, Asian People ethnology, Evolution, Molecular, Genetic Structures, Genetics, Population, Genome-Wide Association Study, Genotype, Haplotypes, Heterozygote, Humans, Malaysia ethnology, Polymorphism, Single Nucleotide, Population Groups ethnology, Time Factors, Asian People genetics, Genetic Variation, Population Groups genetics

Abstract

Peninsular Malaysia is a strategic region which might have played an important role in the initial peopling and subsequent human migrations in Asia. However, the genetic diversity and history of human populations--especially indigenous populations--inhabiting this area remain poorly understood. Here, we conducted a genome-wide study using over 900,000 single nucleotide polymorphisms (SNPs) in four major Malaysian ethnic groups (MEGs; Malay, Proto-Malay, Senoi and Negrito), and made comparisons of 17 world-wide populations. Our data revealed that Peninsular Malaysia has greater genetic diversity corresponding to its role as a contact zone of both early and recent human migrations in Asia. However, each single Orang Asli (indigenous) group was less diverse with a smaller effective population size (N(e)) than a European or an East Asian population, indicating a substantial isolation of some duration for these groups. All four MEGs were genetically more similar to Asian populations than to other continental groups, and the divergence time between MEGs and East Asian populations (12,000--6,000 years ago) was also much shorter than that between East Asians and Europeans. Thus, Malaysian Orang Asli groups, despite their significantly different features, may share a common origin with the other Asian groups. Nevertheless, we identified traces of recent gene flow from non-Asians to MEGs. Finally, natural selection signatures were detected in a batch of genes associated with immune response, human height, skin pigmentation, hair and facial morphology and blood pressure in MEGs. Notable examples include SYN3 which is associated with human height in all Orang Asli groups, a height-related gene (PNPT1) and two blood pressure-related genes (CDH13 and PAX5) in Negritos. We conclude that a long isolation period, subsequent gene flow and local adaptations have jointly shaped the genetic architectures of MEGs, and this study provides insight into the peopling and human migration history in Southeast Asia.

Published

2014

5. Admixture patterns and genetic differentiation in negrito groups from West Malaysia estimated from genome-wide SNP data.

Author

Jinam TA, Phipps ME, and Saitou N

Subjects

Asian People ethnology, Genetic Drift, Genetic Structures, Genetic Variation, Genome-Wide Association Study, Genotype, Haplotypes, Humans, Malaysia ethnology, Software, Asian People genetics, Evolution, Molecular, Genetics, Population, Polymorphism, Single Nucleotide

Abstract

Southeast Asia houses various culturally and linguistically diverse ethnic groups. In Malaysia, where the Malay, Chinese, and Indian ethnic groups form the majority, there exist minority groups such as the "negritos" who are believed to be descendants of the earliest settlers of Southeast Asia. Here we report patterns of genetic substructure and admixture in two Malaysian negrito populations (Jehai and Kensiu), using ~50,000 genome-wide single-nucleotide polymorphism (SNP) data. We found traces of recent admixture in both the negrito populations, particularly in the Jehai, with the Malay through principal component analysis and STRUCTURE analysis software, which suggested that the admixture was as recent as one generation ago. We also identified significantly differentiated nonsynonymous SNPs and haplotype blocks related to intracellular transport, metabolic processes, and detection of stimulus. These results highlight the different levels of admixture experienced by the two Malaysian negritos. Delineating admixture and differentiated genomic regions should be of importance in designing and interpretation of molecular anthropology and disease association studies., (Copyright © 2013 Wayne State University Press, Detroit, Michigan 48201-1309.)

Published

2013