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None of the genes discussed in these sections occur in isolation: one individual dog would have all the genes for color, hair structure, and hemoglobin (dogs can get hemophilia too). Genes interact together to produce the overall phenotype of the individual.

Example 1: Sugar

For example, look at Sugar in Figure 26. She has short hair that is mostly white. The colored portion of her hair is the tiger-striped pattern termed “brindle.”

12.sugar

Figure 26: Sugar has short hair with colored spots. (Credit: Lisa Bartee)

The difference between short and long hair in dogs is caused by different alleles of a gene called FGF5. This gene produces a protein that is important in regulating the hair growth cycle. When the protein doesn’t function correctly, the growth phase of the hair cycle is longer, resulting in long hair. Short hair is the dominant trait. Since Sugar has short hair, we know she has at least one dominant allele of FGF5. We can use the letter “S” for short hair. Sugar’s genotype for FGF5 is therefore “S-“, meaning she has one dominant allele and we can’t tell by looking at her what her second allele is.

Sugar’s hair is also straight, which means that she has two straight alleles of KRT71. Her genotype would be K+K+.

Sugar is more than 50% white with irregular splashes of color, which means that her genotype for MITF (the gene that controls white spotting) is sise.

The brindle pattern is caused by the kbr allele at the K locus. Sugar can’t have the KB allele or she would have solid color instead of the brindle pattern because KB is dominant over kbr and ky. She could have either the genotype kbrkbr or kbrky, since the kbr allele is dominant over the yellow allele (ky).

Sugar has black eumelanin pigment in her hair and nose. This means she has the dominant phenotype for TYPR1, so her genotype would be “B-“. Because she has eumelanin and not pheomelanin in her coat, she has the dominant phenotype for MC1R, so her genotype would be “E-“.

Sugar is a female dog who does not have hemophilia. This means that her genotype would be either XHXH or XHXh.

Putting all these together, we could say that Sugar’s overall coat genotype is S- K+KsisB- E- XHX

We could potentially determine some of the unknown alleles in her genotype if we knew anything about her parents, but Sugar was adopted from the Multnomah County Animal Shelter after being picked up as a stray. Therefore, her ancestry is unknown.

Example 2: Rags

Rags
Figure 27: Rags is similar in color to Sugar, but has a very different fur type. (Credit: Lisa Bartee)

Rags has “furnishings”, a term used to describe his beard and mustache. Furnishings are caused by a mutation in the RSPO2 gene. This gene produces a protein that is involved in establishing hair follicles. The allele that leads to furnishings is dominant over the allele for no furnishings. Rags must therefore have the genotype “F-” at RSPO2. This allele also causes the long-ish hair on his legs and tail.

Gene Genotype Phenotype
RSPO2 FF or Ff has furnishings
FGF5 SS or Ss short fur (his longer fur is caused by the furnishings allele)
KRT71 K+K+ straight fur
MITF sise more than 50% white
K locus KBKB, KBkbr, or KBky Solid color, not brindle or yellow.
TYRP1 BB or Bb Produces black eumelanin, not brown
MC1R EE or Ee Produces eumelanin instead of pheomelanin
F8 XHY Male, no hemophilia

Example 3: Black poodle

12.Pudel_Grossschwarz
Figure : Black poodle. (Credit: B. Schoener from Wikimedia)
Gene Genotype Phenotype
RSPO2 ff no furnishings
FGF5 ss long fur
KRT71 KcKc curly fur
MITF SS entirely solid color
K locus KBKB, KBkbr, or KBky Solid color, not brindle or yellow.
TYRP1 BB or Bb Produces black eumelanin, not brown
MC1R EE or Ee Produces eumelanin instead of pheomelanin

EXAMPLE 4: GOLDEN RETRIEVER

12.Golden_Retriever_Carlos_(10581910556)
Figure : Golden Retriever. (Credit: Dirk Vorderstraße)
Gene Genotype Phenotype
RSPO2 ff no furnishings
FGF5 ss long fur
KRT71 K+K+ straight fur
MITF SS entirely solid color
K locus KBKB, KBkbr, or KBky Solid color, not brindle or yellow.
TYRP1 BB or Bb Produces black eumelanin, not brown (seen in the nose)
MC1R ee Produces pheomelanin instead of eumelanin, so appears yellow

References

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MHCC Biology 112: Biology for Health Professions Copyright © 2019 by Lisa Bartee is licensed under a Creative Commons Attribution 4.0 International License, except where otherwise noted.

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