C128 - Canine Coat and Nose Color Test

The control of coat and pattern in mammals is complex. In dogs, several genes have been associated with coat colour including: A (agouti), B (brown), C (albino), D (blue dilution), E (extension), G (greying), M (merle), R (roaning), S (white spotting) and T (ticking). HealthGene Laboratory offers DNA tests for B and E color genes to determine the following colors in canines: black, brown or red. The gene responsible for red or black coat color is called the Melanocortin Receptor 1 gene (MC1R). This gene has two common forms (alleles) represented as E and e. When E (dominant allele) is present in a dog, it has some black or brown in its coat. Dogs that posses two mutated forms of the gene, represented as ee (recessive), are red or yellow in color depending on the breed. The gene responsible for brown color in dogs is known as Tyrosinase Related Protein 1 (TYRP1). The normal (B) form of this gene is dominant to the mutated (b) form. The TYRP1 gene is also affects the nose leather and pads. For example, in dogs that are yellow or red (genotype ee), TYRP1 mutations (bb) change the nose and pad colouration from black to brown.
Terminology for coat colors used by various dog breeders and associations varies considerably. Liver, chocolate and brown are all names used to describe various shades of deep brown. Orange, red, yellow, gold and apricot are all used for shades produced by the mutated MC1r gene. Occasionally, some owners use the term liver instead of orange. Another confusing example is the use of red for brown in the Australian Shepherd. Clearly, understanding the inheritance of coat color in some breeds has been complicated by the use of some terms which may not correlate with the different forms of the MC1R and TYRP1 genes.

Until recently, no definitive method for predicting a dog’s coat and nose color was available. Canine breeders could only guess the future color of puppies based on the coat and nose colors of the breeding parents. At best, this method provided breeders with an estimate as to the likelihood that a puppy would be a certain color. However, under specific circumstances (i.e. the sire and dame are of EeBb genotype), this method is of no value since two dogs (ex. Labrador Retriever) of the same coat and nose color (black) could potentially produce puppies of various colors (black, chocolate, yellow). This suggests that knowing a dog’s coat and nose color is of little use with regards to predicting a puppies future colors unless the hidden genetic color of the dog is also known.
Recently, advances in DNA technology have led to the discovery of two genes associated with canine coat and nose color. This discovery has led to a DNA-based test that enables breeders to determine the hidden colors of their dogs, and successfully predict the future coat and nose colors of their pups. This information can be crucial to satisfy breed standards for dog registration. Using this test, breeders can selectively choose breeding partners that are most likely to produce offspring with the desired coat and nose color.