Identification of a novel missense mutation in the fibroblast growth factor 5 gene associated with longhair in the Maine Coon Cat.

Hair length can be a highly variable trait within the Felis catus species, varying between and within different cat breeds. Previous research has demonstrated this variability is due to recessive mutations within the fibroblast growth factor 5 (FGF5) gene. Following a genetic screen, four longhaired Maine Coons were identified that had only one copy of a known FGF5 mutation. We performed DNA sequencing on samples from two of these Maine Coons and identified a missense mutation in FGF5 c.577G > A p.Ala193Thr. Genetic screening via restriction digest was then performed on samples from the other two Maine Coons and an additional 273 cats of various breeds. This screening found that only the two additional Maine Coons were heterozygous for the novel variant. Furthermore, the novel variant was not identified after in silico analysis of 68 whole genome cat sequences from various breeds, demonstrating that this novel mutation is most likely a breed-specific variant for the Maine Coon, contributing to the longhair phenotype in about 3% of these cats.

The PMEL gene and merle (dapple) in the dachshund: cryptic, hidden, and mosaic variants demonstrate the need for genetic testing prior to breeding.

One of the most unique coat color patterns in the domestic dog is merle (also known as dapple in the dachshund breed), characterized by patches of normal pigmentation surrounded by diluted eumelanin pigment. In dogs, this striking variegated pattern is caused by an insertion of a SINE element into the PMEL gene. Differences in the length of the SINE insertion [due to a variable-length poly(A)-tail] has been associated with variation in the merle coat color and patterning. We previously performed a systematic evaluation of merle in 175 Australian shepherds and related breeds and correlated the length of the merle insertion variants with four broad phenotypic clusters designated as "cryptic", "atypical", "classic", and "harlequin" merle. In this study, we evaluated the SINE insertions in 140 dachshunds and identified the same major merle phenotypic clusters with only slight variation between breeds. Specifically, we identified numerous cases of true "hidden" merle in dachshunds with light/red (pheomelanin) coats with little to no black/brown pigment (eumelanin) and thus minimal or no observable merle phenotype. In addition, we identified somatic and gonadal mosaicism, with one dog having a large insertion in the harlequin size range of M281 that had no merle phenotype and unintentionally produced a double merle puppy with anophthalmia. The frequent identification of cryptic, hidden, and mosaic merle variants, which can be undetectable by phenotypic inspection, should be of particular concern to breeders and illustrates the critical need for genetic testing for merle prior to breeding to avoid producing dogs with serious health problems.

Radiographical Survey of Osteochondrodysplasia in Scottish Fold Cats caused by the TRPV4 gene variant.

The unique appearance of Scottish Fold cats is caused by a single gene variant in TRPV4, which impacts the development of cartilage. This results in the ears folding forward and variable effects on articular cartilage and bone. While some find this appearance desirable, early work demonstrated that homozygous cats with two copies of this variant develop severe radiographic consequences. Subsequent breeding programs have mated heterozygous cats with straight-eared cats to ensure an equal mix of heterozygous (fold) and wild-type (nonfolded) offspring, in the hope of raising healthy cats. More recent radiological surveys suggest that these heterozygous cats may also have medical problems consisting of deformed distal extremities in the worst cases and accelerated onset of osteoarthritis. However, these previous studies were undermined by selection biases, lack of controls, unblinded assessment and lack of known genotypes. Our aim was to determine if heterozygous cats exhibit radiological abnormalities when controlling for these limitations. Specifically, DNA and radiographs were acquired for 22 Scottish Fold cats. Four reviewers, blinded to the ear phenotype, assessed the lateral radiographs. Genotyping showed that all 10 folded-ear cats were heterozygous, and none of the straight-ear cats (n = 12) had the abnormal TRPV4 variant. Although each reviewer, on average, gave a numerically worse 'severity score' to folded-ear cats relative to straight-ear cats, the images in heterozygous cats showed much milder radiological signs than previously published. This study provides additional information to be considered in the complicated debate as to whether cats with the TRPV4 variant should be bred for folded ears given the potential comorbidities.

The PMEL Gene and Merle in the Domestic Dog: A Continuum of Insertion Lengths Leads to a Spectrum of Coat Color Variations in Australian Shepherds and Related Breeds.

Merle is a distinct coat color and pattern found in numerous species, including the domestic dog, characterized by patches of diluted eumelanin (black pigment) interspersed among areas of normal pigmentation. In dogs, this variegated pattern is caused by an insertion of a SINE element into the canine PMEL gene. Although variation in the length of the SINE insertion - due to a variable-length poly(A) tail - has been observed to be associated with variation in merle coat color and patterning, no systematic evaluation of this correlation has been conducted and published in the scientific literature. We performed high-resolution analysis of the SINE insertion lengths in 175 dogs (99 Australian shepherds, 45 miniature Australian shepherds, and 31 miniature American shepherds) and compared the genotypes with the coat phenotypes (when available). SINE insertion lengths varied from 201 to 277 bp, indicating that merle insertion variants can occur in virtually any size along the entire continuum. Genotype-phenotype correlation of 126 dogs with only a single SINE insertion (m/M) identified at least 4 major phenotypic clusters designated as "cryptic," "atypical," "classic," and "harlequin" merle. However, we found several phenotypic outliers that did not cluster within these major groupings, suggesting that insertion size is not the only factor responsible for merle phenotypic variability. In addition, we detected 25 dogs with 2 SINE insertions (M/M) and 24 dogs with more than 2 PMEL (merle) alleles, indicating mosaicism. Genotype-phenotype correlation of M/M dogs suggests that cryptic merle alleles often act like non-merle (m) alleles when combined with atypical, classic, and harlequin-sized alleles. The finding of mosaicism has important implications for the dog's phenotype and the ability to potentially transmit various alleles to its offspring. Furthermore, we identified examples of the SINE insertion poly(A)-tail expansion and contraction between generations, which also has important implications for breeding practices and determining mating pairs to avoid producing double merle dogs. These data demonstrate that there is a continuum of merle insertion lengths associated with a spectrum of coat color and patterns and that genotype-phenotype exceptions and overlap make it difficult to strictly assign certain insertion sizes with an expected coat color, although some generalizations are possible.