Evolutionary Study of a Potential Selection Target Region in the Pig

Overview

Journal Heredity (Edinb)

Specialty Genetics

Date 2010 May 27

PMID 20502482

Citations 11

Authors

A Ojeda

S E Ramos-Onsins

D Marletta

L S Huang

J M Folch

M Perez-Enciso

Affiliations

Soon will be listed here.

Abstract

Domestication, modern breeding and artificial selection have shaped dramatically the genomic variability of domestic animals. In livestock, the so-called FAT1 quantitative trait locus (QTL) in porcine chromosome 4 was the first QTL uncovered although, to date, its precise molecular nature has remained elusive. Here, we characterize the nucleotide variability of 13 fragments of ∼500 bp equally spaced in a 2 Mb region in the vicinity of the FAT1 region in a wide-diversity panel of 32 pigs. Asian and European animals, including local Mediterranean and international pig breeds, were sequenced. Patterns of genetic variability were very complex and varied largely across loci and populations; they did not reveal overall a clear signal of a selective sweep in any breed, although FABP4 fragment showed a significantly higher diversity. We used an approximate Bayesian computation approach to infer the evolutionary history of this SSC4 region. Notably, we found that European pig populations have a much lower effective size than their Asian counterparts: in the order of hundreds vs hundreds of thousands. We show also an important part of extant European variability is actually due to introgression of Asian germplasm into Europe. This study shows how a potential loss in diversity caused by bottlenecks and possible selective sweeps associated with domestication and artificial selection can be counterbalanced by migration, making it much more difficult the identification of selection footprints based on naive demographic assumptions. Given the small fragment analyzed here, it remains to be studied how these conclusions apply to the rest of the genome.

Citing Articles

A 20-SNP Panel as a Tool for Genetic Authentication and Traceability of Pig Breeds.

Moretti R, Criscione A, Turri F, Bordonaro S, Marletta D, Castiglioni B Animals (Basel). 2022; 12(11).

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Porcine Y-chromosome variation is consistent with the occurrence of paternal gene flow from non-Asian to Asian populations.

Guirao-Rico S, Ramirez O, Ojeda A, Amills M, Ramos-Onsins S Heredity (Edinb). 2017; 120(1):63-76.

PMID: 29234173 PMC: 5837104. DOI: 10.1038/s41437-017-0002-9.

MicroRNA in sperm from Duroc, Landrace and Yorkshire boars.

Kasimanickam V, Kastelic J Sci Rep. 2016; 6:32954.

PMID: 27597569 PMC: 5011730. DOI: 10.1038/srep32954.

Possible introgression of the VRTN mutation increasing vertebral number, carcass length and teat number from Chinese pigs into European pigs.

Yang J, Huang L, Yang M, Fan Y, Li L, Fang S Sci Rep. 2016; 6:19240.

PMID: 26781738 PMC: 4726066. DOI: 10.1038/srep19240.

Genome data from a sixteenth century pig illuminate modern breed relationships.

Ramirez O, Burgos-Paz W, Casas E, Ballester M, Bianco E, Olalde I Heredity (Edinb). 2014; 114(2):175-84.

PMID: 25204303 PMC: 4815627. DOI: 10.1038/hdy.2014.81.

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