Mapping of quantitative trait loci on porcine chromosome 4.

@article{Walling1998MappingOQ,
  title={Mapping of quantitative trait loci on porcine chromosome 4.},
  author={Grant A. Walling and Alan L. Archibald and J A Cattermole and Amy C. Downing and Heather Finlayson and D. Nicholson and Peter M. Visscher and Catherine A. Walker and Chris S. Haley},
  journal={Animal genetics},
  year={1998},
  volume={29 6},
  pages={
          415-24
        }
}
A F2 population derived from a cross between European Large White and Chinese Meishan pigs was established in order to study the genetic basis of breed differences for growth and fat traits. Chromosome 4 was chosen for initial study as previous work had revealed quantitative trait loci (QTLs) on this chromosome affected growth and fat traits in a Wild Boar x Large White cross. Individuals in the F2 population were typed for nine markers spanning a region of approximately 124 CM. We found… 
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Combined analyses of data from quantitative trait loci mapping studies. Chromosome 4 effects on porcine growth and fatness.
TLDR
This study is the largest F(2) QTL analysis achieved in a livestock species and demonstrates the potential of joint analysis.
Quantitative trait loci (QTL) analysis in a Meishan x Göttingen cross population.
In order to locate the genetic regions in the swine genome that are responsible for economically important traits, a resource population has been constructed by mating two female Meishan pigs with a
Confirmed quantitative trait loci for fatness and growth on pig chromosome 4
TLDR
It is proposed that this confirmed QTL with a major effect on fatness is designated FAT1, and one or more QTLs on chromosome 4 affecting fatness and growth are confirmed.
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TLDR
The genome-wide QTL mapping in F2 families represents an essential starting point and is therefore significant for animal breeding, and requires further fine mapping of QTL intervals and a positional cloning.
Refined localization of the FAT1 quantitative trait locus on pig chromosome 4 by marker-assisted backcrossing
TLDR
The strategy to further refine the map position of this major QTL will be to type new markers in pigs that are recombinant in the QTL interval to perform Identity-By-Descent (IBD) mapping across breeds that have been strongly selected for lean growth.
Mapping of quantitative trait loci and confirmation of the FAT1 region on chromosome 4 in an F2 population of pigs
TLDR
Significant evidence for QTL was found for pig chromosome 4 regarding carcass and internal organ traits and all QTL were detected in the same region of the chromosome, designated FAT1.
Fine mapping and imprinting analysis for fatness trait QTLs in pigs
TLDR
The results suggest that this QTL is different from the previously reported paternally expressed QTL for muscle mass and fat deposition on the distal tip of SSC2p, and the location could be reduced to a 33-cM confidence interval.
A genome-wide linkage analysis for reproductive traits in F2 Large White × Meishan cross gilts
TLDR
This study analysed three cohorts of Large White × Meishan F2 cross-bred pigs to identify quantitative trait loci (QTL) with effects on reproductive traits, including ovulation rate, teat number, litter size, total born alive and prenatal survival.
Quantitative trait loci for production traits in pigs: a combined analysis of two Meishan x Large White populations.
TLDR
A genome-wide scan using combined data from two F(2) populations derived from a cross between Large White and Chinese Meishan pigs suggested that the QTL represent real genetic effects, but this was not the case for dominance or imprinting effects.
DETECTION OF QUANTITATIVE TRAIT LOCI (QTL) FOR GROWTH ON CHROMOSOME 4 IN PIGS
TLDR
The objetive of this study was to search the pig chromosome 4 for QTL affecting growth traits using a experimental F2 cross between Brazilian naturalized Piau and commercial pig breeds.
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