Genetic Variations and Dog Breed Identification Using Inter-simple Sequence Repeat Markers Coupled with High Resolution Melting Analysis

Overview

Journal PeerJ

Specialties Biology
Environmental Health
General Medicine

Date 2020 Nov 16

PMID 33194413

Citations 4

Authors

Wannapimol Kriangwanich

Korakot Nganvongpanit

Kittisak Buddhachat

Puntita Siengdee

Siriwadee Chomdej

Siriluck Ponsuksili

Chatchote Thitaram

Affiliations

Soon will be listed here.

Abstract

The identification of differing physical characteristics of dogs is an uncomplicated and straightforward way to categorize dog breeds. However, many dog owners and veterinarians still struggle to distinguish between pure breed and mixed variations in certain breeds of dogs. Presently, the absence of the tools and methods needed to confirm a pure breed dog is a significant problem since the only method available to validate pure or mongrel breeds is the official pedigree system. Inter-simple sequence repeat markers have been successfully used to assess genetic variations and differentiations. Notably, inter-simple sequence repeat markers coupled with high resolution melting analysis were effectively used for the breed identification of 43 breeds of dogs (total 463 dogs). The 10 primers chosen for analysis resulted in a range of 31-78.6% of breed discrimination when using one primer, while a combination of two primers was able to successfully discriminate between all of the 43 dog breeds (100%). Shannon's index information ( = 2.586 ± 0.034) and expected heterozygosity ( = 0.908 ± 0.003) indicated a high level of genetic diversity among breeds. The fixation index ( ) revealed a value of 10.4%, demonstrating that there was a high level of genetic subdivision between populations. This study showed that inter-simple sequence repeat marker analysis was effective in demonstrating high genetic diversity among varying breeds of dogs, while a combination of Inter-simple sequence repeat marker analysis and high resolution melting analysis could provide an optional technique for researchers to effectively identify breeds through genetic variations.

Citing Articles

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