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HORSE COLOR GENETICS |
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D. Phillip Sponenberg, DVM, PhD. |
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| Horse color genetics is a complicated
subject, and it is impossible to deny that the complexities can make it
difficult to understand. By breaking down the subject into smaller pieces it
is possible to begin to understand how the interactions of different factors
result in the vast array of color in horses. A first step is to separate out
white spots or hairs, and only concentrate on color. Following an
appreciation of how the colors arise it is possible to add the white, and
thereby understand the final combinations. Color is
the result of interaction of eleven or so different factors. Some of these
are single genes, others are unknown genetically. Each unique combination
results in a single color, so there are many, many possibilities. Some are
common, some are rare, and some depend on the breed involved.
GENETIC CONTROL OF COLOR (IGNORE THE WHITE!)
The three main colors of horses are bay, chestnut, and
black. All other colors can be built from these three, so understanding
these three is the foundation for all of the others. 2. For the non-chestnut horses, bay (A+ ) is dominant to black (Aa ). This relationship is tricky. Chestnut, though recessive, masks whether a horse would have been black or bay. A mating of chestnut and black horses can result in bay foals, even though both chestnut and black are recessive to bay. 3. "Shade" is a complicated trait that is probably controlled by several genes rather than a few. "Shade", for convenience, can be considered to make the base color dark, medium or light. It interacts with the basic coat colors to produce more designations: |
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4. "Sooty" is a factor that adds black hairs into the base color. This changes the appearance from a clear color to a sooty color, and in some systems of color names will change names of some colors.
The interaction of sooty and shade provide many, many different nuances of color. 5. The mane and tail color on chestnut horses is variable. It ranges from a dark brown that is close to black, through bright reds, and on to the very pale flaxen colors that are nearly white. These changes are related to many, many different genes and are complicated. 6. Mealy is a single, dominant gene (Pa+ ) which causes lighter areas on the belly, muzzle, inner legs, and over the eyes. It is usually ignored in color description, except for changing black to seal brown, and changing chestnut to sorrel for breeders of draft horses.
7. The cremello gene (Crcr ) in one dose dilutes red to yellow, and leaves black unaffected. With two doses it changes both red pigment and black pigment to cream, with pink skin and blue eyes.
8. The line backed dun gene (Dn+ ) is dominant, and lightens body color, leaving a stripe down the back, bars on the legs, and frequently a stripe on the withers.
9. The silver dapple gene (ZZ ) is a dominant that acts to lighten black areas, and leaves red areas unchanged. It is rare, but increasing in frequency in some breeds. It results in colors that are frequently confused with chestnut, but that lack the redness of chestnut. It lightens manes, tails, and lower legs to flaxen, or can leave them relatively unchanged.
10. The champagne gene (ChC ) is a dominant that is rare. Lightens black areas to flat light chocolate, and red to light red or yellow. Skin to be pink or mottled, and eyes hazel.
11. The final color interaction is brindle. This is rare indeed, and reorganizes the sooty counter shading into vertical stripes.
PATTERNS OF WHITE HAIRS AND WHITE PATCHES: The patterns of white hairs and patches do not interact as do the color factors. Instead, each is independent and as a result they can occur in any and all combinations. 1. Grey is a dominant gene (GG ) that causes white hairs to progressively grow into the coat. Grey foals are born colored, usually dark, and then lighten with age to white or nearly so, with pigmented skin. Subtypes of grey include dappled, iron (non-dappled), fleabitten (small flecks of color), porcelain (white), and blood marked (large patches of color). 2. Roan is a dominant gene (RnRn ) that is lethal to homozygous embryos, so only heterozygotes exist. Roan is a mixture of white hairs into the body coat, but usually does not involve the mane, tail, lower legs, and head. The roan pattern changes black to blue roan, brown to purple roan, bay to red roan, dark chestnuts to lilac roan, lighter chestnut and sorrel to strawberry roan. 3. Frosty is similar to roan, only the mane and tail are also roaned. 4. Ticked (RaRa ) is probably a dominant gene. This pattern involves roan hairs in the flanks and at the base of the tail. 5. Paint or Pinto spotting is characterized as nonsymmetrical white areas on the body of the horse. Several distinct patterns are characteristic of this group. A. Tobiano, (ToTo ) is a dominant that causes white on the legs, and vertical white spots on the body that cross the topline somewhere between ears and tail. The heads are usually colored, and eyes are usually dark. B. Frame overo (OvFF ) is a dominant that causes horizontal white marks on the body and neck, lots of facial white as well as blue eyes, and usually leaves the feet colored. C. Sabino may well be polygenic and causes abundant white on the legs, and then creeps up as belly spots and body spots that are usually flecked and roaned. Usually the head is largely white, as well. D. Splashed white (SplSpl ) is a dominant that causes very crisp white areas. Usually the head, legs, and lower body of the horse are white, as if they had been dipped in white paint. Subtypes of spotting patterns can occur with some of these genes. The Medicine Hat pattern is one of these, and the horses are largely white, with color remaining on the ears, tail base, chest, and flank. War Bonnets are whiter, with colored ears and very little else. 6, Leopard complex spotting is typical of the Appaloosa, and many other, breeds worldwide. This is due to a dominant gene (LpOp ). Heterozygous horses, on average, have less white than do homozygotes. Patterns include mottled, snowflake, blanket, leopard, few spot leopard, varnish roan, and frost. 7. White (WW ) is a dominant gene that is lethal to homozygous embryos. True white horses are white with pink skin and dark eyes. Some have a few small spots of color in skin or hair, but most do not. 8. Bird catcher spots are small white spots scattered randomly over the coat of some horses. These are not known to be genetic, and occur in many breeds. 9. White face and leg marks occur in most breeds. These are controlled by many, many individual genes all contributing a little bit to the final marks. The various marks do have different names:
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Copyright © D. Phillip Sponenberg, DVM, PhD. Please do not reprint without permission. Site Map |
