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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Sequence Analysis of PMEL17 as Candidate Gene for Causing Rat-Tail Syndrome in Cattle

Hecht, Benjamin C. 18 July 2006 (has links) (PDF)
Congenital hypotrichosis in cattle is commonly referred to as "rat-tail" syndrome and is characterized by a dilution of black coat color and morphological changes to the hair shaft and tail switch. Two loci are involved in the inheritance of the rat-tail phenotype, the "extension locus" (MC1R) and an unknown locus. In order to express the rat-tail phenotype the animal must inherit at least one black allele at MC1R and be heterozygous at the unknown locus. The rat-tail locus was previously mapped to an 8.7 cM region of Bos Taurus autosome (BTA) 5. Pmel17 is known to be involved in the expression of pigmentation and maps to the same region of BTA5 as the rat-tail locus. Cattle from a population segregating for the rat-tail syndrome were sequenced at Pmel17 in order to identify putative causative mutations. Two mutations were detected, a three base pair (bp) deletion in exon 1 at codon 18 removing a leucine residue, and a single nucleotide polymorphism (SNP) at codon 612 resulting in an amino acid substitution (A?E). The 3-bp deletion in exon 1 of Pmel17 is in 100% concordance with the rat-tail phenotype in this research population and may be causative of the rat-tail phenotype.
2

Dissecting Phenotypic Variation in Pigmentation using Forward and Reverse Genetics

Hellström, Anders R January 2010 (has links)
Coat color and patterning phenotypes have been extensively studied as a model for advancing our understanding of the relationship between genetic and phenotypic variation. In this thesis, genes of relevance for pigment cell biology were investigated. The dissertation is divided in two parts. Forward genetics was used in the first part (Paper I and II) to identify the genes controlling the Silver and Sex-linked barring loci in chicken. In the second part, reverse genetics was employed to create a mouse line in which the PMEL17 protein is inactivated (Paper III). In Paper I, we report five mutations in SLC45A2 causing plumage color variants in both chicken and Japanese quail. Normal function of the SLC45A2 gene has previously been shown to be essential for the synthesis of both red/yellow pigment (pheomelanin) and brown/black pigment (eumelanin) in numerous species, including humans. The major discovery in this paper is the specific inhibition of pheomelanin in Silver chickens, whilst null mutations at this locus cause an almost complete absence of both pheomelanin and eumelanin. In Paper II, we report that Sex-linked barring in chickens is controlled by the CDKN2A/B tumor suppressor locus. The locus encodes two proteins, INK4B and ARF. The genetic analysis indicates that missense mutations in ARF or mutations in the promoter region of the ARF transcript are causing Sex-linked barring. In previous studies, mutations inactivating the CDKN2A/B tumor suppressor locus, have been shown to be responsible for familiar forms of human melanoma. Here we propose that these mutations in chicken CDKN2A/B cause the premature cell death of melanocytes as opposed to the cell proliferation and tumor growth associated with loss-of-function alleles in humans. In Paper III, we created a mouse line in which the PMEL17 protein is inactivated. Missense mutations in the gene encoding PMEL17 have previously been shown to be associated with reduced levels of eumelanin in epidermal tissues in several vertebrate species. The knockout mice are viable, fertile, and display no obvious developmental defects. The eumelanosomes within the melanocytes of these mice are spherical in contrast to the cigar-like shaped eumelanosomes present in wild-type animals. PMEL17 protein inactivation has only a subtle diluting effect on the coat color phenotype in four different genetic backgrounds. This suggests that other previously described alleles in vertebrates with more striking effects on pigmentation are dominant-negative mutations.
3

Mapping Genes Affecting Phenotypic Traits in Chicken

Kerje, Susanne January 2003 (has links)
<p>The purpose of gene mapping is to understand the underlying genetics of simple and complex traits like plumage colour and growth. This thesis is based on a cross between the wild ancestor of the modern chicken, the red junglefowl, and a White Leghorn line selected for high egg mass. There are obvious phenotypic differences between these two breeds in several aspects such as growth, egg production and behaviour. These complex traits are often influenced by a number of genes or Quantitative Trait Loci (QTL) as well as environmental factors.</p><p>Identification of QTL regions involves testing of association between genetic markers and the phenotype of interest. The QTL identified in this study explain most of the difference in adult body weight between the red junglefowl and the White Leghorn, but less of the difference at earlier age. By applying a different method for detection of QTL, including gene interactions, epistasis, we can understand more of the genetics behind early growth. The allele coming from the red junglefowl is generally associated with lower weight, egg production and food consumption.</p><p>In this study we have also identified two genes explaining the difference in plumage colour in the cross. The <i>Extension</i> locus, encoded by the melanocortin receptor 1 (<i>MC1R</i>), controls the amount of pigment produced has shown to be associated with plumage colour. A mutation in the <i>MC1R</i> gene causes black pigmentation of the plumage. </p><p>We have also found association between the <i>PMEL17</i> gene, known to be involved in normal pigmentation, and the <i>Dominant white</i> phenotype present in the White Leghorn. After comparison of sequences from different alleles at the <i>Dominant white</i> locus, amino acid alteration caused by insertion and deletion in the transmembrane region of the <i>PMEL17</i> protein has been revealed. These mutations are associated with alleles representing different plumage colour variants.</p>
4

Mapping Genes Affecting Phenotypic Traits in Chicken

Kerje, Susanne January 2003 (has links)
The purpose of gene mapping is to understand the underlying genetics of simple and complex traits like plumage colour and growth. This thesis is based on a cross between the wild ancestor of the modern chicken, the red junglefowl, and a White Leghorn line selected for high egg mass. There are obvious phenotypic differences between these two breeds in several aspects such as growth, egg production and behaviour. These complex traits are often influenced by a number of genes or Quantitative Trait Loci (QTL) as well as environmental factors. Identification of QTL regions involves testing of association between genetic markers and the phenotype of interest. The QTL identified in this study explain most of the difference in adult body weight between the red junglefowl and the White Leghorn, but less of the difference at earlier age. By applying a different method for detection of QTL, including gene interactions, epistasis, we can understand more of the genetics behind early growth. The allele coming from the red junglefowl is generally associated with lower weight, egg production and food consumption. In this study we have also identified two genes explaining the difference in plumage colour in the cross. The Extension locus, encoded by the melanocortin receptor 1 (MC1R), controls the amount of pigment produced has shown to be associated with plumage colour. A mutation in the MC1R gene causes black pigmentation of the plumage. We have also found association between the PMEL17 gene, known to be involved in normal pigmentation, and the Dominant white phenotype present in the White Leghorn. After comparison of sequences from different alleles at the Dominant white locus, amino acid alteration caused by insertion and deletion in the transmembrane region of the PMEL17 protein has been revealed. These mutations are associated with alleles representing different plumage colour variants.

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