FAM83G/Fam83g genetic variants affect canine and murine hair formation.

FAM83G/Fam83g genetic variants have been described in dogs, mice and recently also in humans. They are associated with palmoplantar keratoderma and altered hair or coat phenotype, reported as wooly phenotype in mice. FAM83G/Fam83g is an unexplored effector of temporally and spatially coordinated Wnt and BMP signalling which are key pathways in pre- and postnatal hair follicle morphogenesis and differentiation. The aim of this study was to unravel phenotypic consequences of FAM83G/Fam83g variants on hair coat formation in dogs and mice. Our results show differences in hair types and hair shaft structures in both species. Additionally, mice exhibit deregulated hair cycle progression which timely correlates with defective Wnt signalling (Axin2) and Bmp2/4 expression. These results affirm the involvement of FAM83G in hair morphogenesis, hair follicle differentiation and cycling.

Palmoplantar hyperkeratosis in Irish terriers: evidence of autosomal recessive inheritance.

An abnormal development of the epidermis of the footpad was observed in Irish terriers. At the age of six months, the affected animals developed smooth parchment-like footpads. The pad epidermis then hardened and grew lateral cone-like protrusions of up to 5 mm in diameter. Fissures and cracks developed and these predisposed the animal to secondary infection. The repeated occurrence in subsequent generations led to the assumption of a hereditary form of hyperkeratosis. Evidence for an autosomal recessive mode of inheritance was derived from a retrospective analysis of the breeder's records. The clinical, histopathological and ultrastructural features of the disease are presented and the genetic transmission and its implications discussed.

Chromosomal assignment of two putative canine keratin gene clusters.

Mutations in keratin genes account for a number of inherited keratodermas in humans. The groups of basic and acidic keratin genes are clustered on human chromosomes 12 and 17, respectively. The present authors have assigned the two putative keratin gene clusters to canine chromosomes using canine cosmid clones. Successful fluorescence in situ hybridization mapped the putative cluster of canine acidic genes to dog chromosome 20 and the putative cluster of basic keratin genes to a small autosome not yet included in the partial canine standard karyotype.

Identification and analysis of the dog keratin 9 (KRT9) gene.

We have identified the gene coding for the canine ortholog of the human keratin 9 protein using the inverse-polymerase chain reaction (PCR) strategy. Sequence comparison and structure analysis of the gene show marked similarity with the human gene. This gene spans about 7 kb and spreads over eight exons. In the dog gene, the reading frame is extended by 20 codons, the first in-frame stop codon being in exon 8 in the dog rather than in exon 7 as in humans. Alignment of human and dog predicted amino acid sequences confirms the high analogy, reaching 75% identity and 95% similarity in the rod domain. Interestingly, the glycine-loop motif number in the C-terminal V2 variable subdomain of the protein increases from 19 in human to 43 in dog, generating a size difference of 12 kDa between the two proteins. Due to its restricted expression pattern in mammalian epidermis, dog keratin 9 gene was a good candidate gene for the genetic palmoplantar hyperkeratosis observed in the Dogue de Bordeaux. However, no polymorphism associated with the pathology was detected within an affected Dogue de Bordeaux pedigree ruling out this hypothesis.