- Bay (horse)
The black areas of a bay horse's hair coat are called "black points," and without them, a horse cannot be a bay. Black points may sometimes be covered by white markings, however such markings do not alter a horse's classification as "bay." Bay horses have dark skin, except under white markings, where the skin is pink.
Bay is genetically a base color and the addition of other genes creates many additional coat colors. While the basic concepts behind bay coloring are fairly simple, the genes themselves and the mechanisms that cause shade variations within the bay family are quite complex and, at times, disputed.
Color variations and terminology
There are many terms that are used to describe particular shades and qualities of a bay coat. Some shade variations can be related to nutrition and grooming, but most appear to be caused by inherited factors not yet fully understood.
Bay horses range in color from a light copper red, to a rich red "blood bay" (the best-known variety of bay horse) to a very dark red or brown called "dark bay," "mahogany bay," "black-bay," or "brown" (occasionally "seal brown"). The dark, brown, shades of bay are referred to in other languages by words meaning "black-and-tan." Dark bays/browns may be so dark as to have nearly-black coats, with brownish-red hairs visible only under the eyes, around the muzzle, behind the elbow, and in front of the stifle. Dark bay should not be confused with "Liver" chestnut, which is also a very dark brown color, but a liver chestnut has a brown mane, tail and legs; no black points.
The pigment in a bay horse's coat, regardless of shade, is rich and fully-saturated. This makes bays particularly lustrous in the sun if properly cared for. Some bay horses exhibit "dappling", which is caused by textured, concentric rings within the coat. Dapples on a bay horse suggest good condition and care, though many well-cared for horses never dapple. The tendency to dapple may also be, to some extent, genetic.
Bays often have a two-toned hair shaft, which, if shaved too closely (such as when body-clipping for a
horse show), may cause the horse to appear several shades lighter, a somewhat dull orange-gold, almost like a dun. However, as the hair grows out, it will darken again to the proper shade. This phenomenon is part of bay color genetics, but usually not seen in darker shades of bay because there is less red in the hair shaft.("See:" "Inheritance and expression," below")
The palest shades, which lack specific English terminology found in other languages, are called "wild bays". Wild bays are true bays with fully-pigmented reddish coat color and black manes and tails, but the black points only extend up to the
pasternor fetlock. Wild bay is often found in conjunction with a trait called "pangare" that produces pale color on the underbelly and soft areas, such as near the stifle and around the muzzle.cite book | last = Sponenberg | first = Dan Phillip | title = Equine Color Genetics 2e | publisher = Blackwell | date = 2003 | isbn = 081380759X]
Bay horses have black skin and dark eyes, except for the skin under markings, which is pink. Skin color can help an observer distinguish between a bay horse with white markings and a horse which resembles bay but is not.
Ambiguity of "brown"
Some breed registries (including the Jockey Club
Thoroughbredregistry) use the term "brown" to describe dark bays. However, "liver" chestnuts, horses with a red or brown mane and tail as well as a dark brownish body coat, are also sometimes called "seal brown" in some colloquial contexts. Therefore, "brown" can be an ambiguous term for describing horse coat color. It may be clearer to refer to dark-colored horses as dark bays or liver chestnuts.
Effect of gray gene
foals are born bay, but carry the dominant gene for graying, and thus will turn gray as they mature until eventually their hair coat is completely white. Foals that are going to become gray must have one parent that is gray. Some foals may be born with a few white hairs already visible around the eyes, muzzle, and other fine-haired, thin-skinned areas, but others may not show signs of graying until they are several months old.
Colors confused with bay
:"For description of other coat colors, see
Equine coat color."
*Chestnuts, sometimes called "Sorrels," have a reddish body coat similar to a bay, but no black points. Their legs and ear edges are the same color as the rest of their body (unless they have white markings) and their manes and tails are the same shade as their body color or even a few shades lighter.
*Black are occasionally confused with dark bays and liver chestnuts because some black horses "sunburn," that is, when kept out in the sun, they develop a bleached-out coat that looks brownish, particularly in the fine-haired areas around the flanks. However, a true black can be recognized by looking at the fine hairs around the muzzle and eyes. These hairs are always black on a black horse, but are reddish, brownish, or even a light gold on a bay or chestnut.
Bay is considered to be one of the "hard" or "base" coat colors in horses.Fact|date=March 2008 The two others in this category are chestnut and black. The effects of additional equine coat color genes on a bay template alter the basic color into other shades or patterns:
*Buckskin horses have a black mane and tail, but instead of a red or brown coat, they have a cream or gold coat. Though once called a "Sandy" bay in older texts on horse color, the genetic distinction created by the
cream geneis significant. They are a bay horse that is also heterozygousfor the dominant creme (CCr) allele. The black pigment remains largely unchanged, but any red pigment in the coat is diluted to gold. Buckskins are seldom mistaken for bays because their coats are significantly lighter and have no hint of a red or orange tint.
Perlinos are bay horses who are homozygousfor the dominant creme (CCr) allele. Both black and red pigment are diluted to some shade of creme, though the formerly-black points often have a stronger reddish cast. The skin is a slightly pigmented pink and the eyes are blue.
*Bay duns are bay horses with at least one dominant dun
allele. Red and black pigment at the extremities remains largely unchanged, but on the body, black pigment is diluted to slate and red pigment is diluted to a dustier shade. The effect is similar to buckskin, but the coat of a bay dun is a flatter tan rather than bronze, and all duns have some form of primitive markingsthat include a dorsal stripe along the backbone, and sometimes faint horizontal striping at the back of the front legs.
*Amber champagne refers to a bay horse with at least one dominant champagne allele. Black pigment is diluted to warm brown and red pigment to gold. The effect is similar to buckskin, but the points of an amber champagne do not remain black, and the skin is mottled. Amber champagnes also have hazel eyes rather than brown.
*Silver bays are bay horse with at least one dominant silver (Z) allele. Red pigment is unaffected, but black pigment in the short coat is diluted to dark, flat, brown-gray while the longer hairs are diluted to silver. The overall effect on a bay is that of a chocolate-colored horse with a pale mane and tail.
*Bay Roan horses are bays with at least one dominant roan (Rn) allele. The roan gene creates an effect of white hairs intermingled with the red body coat. This color was formerly lumped together with chestnut or "strawberry" roans and called "red roan."
*Bay pintos are bay horses with any number of white spotting genes, including but not limited to
tobiano, frame or splash overo, and so on. The pattern has no bearing on whether or not the horse is bay. Pinto horses also may have a bay base coat overlaid by white spots. Sometimes the term Skewbaldor "Tricolor" is used, especially in the UK, to refer to bay pintos.
**Sabino is a color pattern in the pinto family, but in some cases, the gene may be minimally expressed in the form of very bold white markings or slight body spotting and such horses will be registered by their owners as "bay," particularly in
breed registriesthat do not have a category for pinto.
*Bay Leopards are horses that carry the leopard (Lp) gene or gene complex characteristic of the
Appaloosaand other breeds. This gene also produces secondary characteristics that include mottled skin, a white scleraaround the eye, and striped hooves.
*A few bay horses may carry the
rabicanogene, which either produces faint roaning on only some parts of the body or can cause some white or cream hairs to appear in the mane or tail, sometimes creating a "skunk" effect. Most bays with rabicano are registered as either bays or as bay roans.
The various shades of bay may be genetically produced by multiple factors, but a simple explanation of bay genetics is that "red" color, seen in the chestnut horse, represented by the
recessive"e" allele; and black color, represented by the dominant"E" allele, are the two most basic coat color genes. All other colors are produced by the action of additional alleles acting on these two base colors.
A bay horse carries both the Extension (E) allele and a suppression gene known as the
agouti gene(A). The agouti gene, dominant over the black gene, limits or suppresses the black coloring to black points, allowing the underlying red coat color to come through. Unlike other types of "point" coloring, such as that seen in Siamese cats, the black points characteristic of bay coloring are not produced by a dilution or albinism gene.
Because the extension (E) gene and agouti (A) gene can be either heterozygous or homozygous, the extent to which a bay passes on its color varies widely from one horse to another depending on its genotype and that of its mate. Also, a chestnut may carry the Agouti gene, which will be "masked" or not manifest until the horse is bred to a horse with the E allele and produces offspring with both genes.
Inheritance and expression
The bay family of coat colors is dependent on two autosomal simple dominant
genes: Extension and Agouti. The role of the Extension gene is to produce a proteincalled Melanocortin 1 receptoror "Mc1r". "Mc1r" allows the black pigment eumelaninto form in hair. Closely tied to this process, the role of the Agouti gene is to produce Agouti signalling peptide"Asip", which disables "Mc1r", effectively allowing the red pigment phaeomelaninto "show through." However, this disabling does not occur throughout the coat; it occurs only in pulses on the body coat and not at all on the extremities or "points".
If a horse does not possess a functional, dominant copy of the wildtype E-
alleleat the Extension locus, then "Mc1r" cannot be produced. Without this protein, the black pigment eumelanin cannot form in the hair. Such horses, having two copies of the recessive mutation, have eumelanin-free, phaeomelanin-rich coats; they are red, or chestnut. In summary, unless a horse has at least one functional E-allele, it cannot be bay.
Similarly, if a horse does not possess a functional, dominant copy of the A-allele at the Agouti locus, then "Asip" cannot be produced. Without "Asip", eumelanin is unreglated and the coat is wholly black. The regulation of black pigment, though, is dependent on its presence in the first place; a horse with the recessive Agouti genotype aa is indistinguishable from any other genotype in a horse with a eumelanin-free coat. When eumelanin is present, it is restricted in varying degrees by the action of "Asip".
The action of "Asip" can be observed in horses which have their winter coats clipped. When shaved close, the black tip is shorn off leaving the phaeomelanic bottom of the shaft. This produces a dull, orange-gold appearance on the body coat which is lost with the spring shed. This is not usually seen in dark bays, which have little red in the hair shaft.
The cause behind the various shades of bay, particularly the genetic factors responsible for wild bay and seal brown, have been contested for over 50 years. In 1951, zoologist
Miguel Odriozolapublished "A los colores del caballo" in which he suggested four possible alleles for the "A" gene. He described an order of dominance between the alleles and the associated phenotypes:
* "a", the least dominant, must be homozygous to be observed and is responsible for unrestricted black coat (non-agouti black),
* "At", only visible in the homozygous form or when paired with "a", is responsible for the black-and-tan seal brown coat,
* "A", visible when homozygous or when paired with "a" or "At", is responsible for the standard bay coat,
* "A+", dominant, is responsible for the wildtype wild bay coat.cite journal |last=Castle |first=W.E. |authorlink=no |coauthors=W.R. Singleton |year=1961 |month=September |title=The Palomino Horse |journal=Genetics |volume=46 |pages=1143–1150 |url=http://www.genetics.org/cgi/reprint/46/9/1143.pdf |accessdate= 2008-03-04]
This was accepted until the 1990's, when a new theory became popular.cite web |url=http://www.horsecolor.com/basics/starting_point.htm |title=Starting Point |work=The Horse Colors Site |author=B. Kostelnik |date=2007 |accessdate=2008-03-04] The new theory suggested that shades of bay were caused by many different genes, some which lightened the coat, some which darkened it. This theory also suggested that seal brown horses were black horses with a trait called "pangare". Pangare is an ancestral trait also called "mealy", which outlines the soft or communicative parts of the horse in buff tan.
The combination of black and pangare was dismissed as the cause of brown in 2001, when a French research team published "Mutations in the agouti (ASIP), the extension (MC1R), and the brown (TYRP1) loci and their association to coat color phenotypes in horses (Equus caballus)". This study used a DNA test to identify the recessive "a" allele on the Agouti locus, and found that none of the horses fitting the phenotype of seal brown were homozygous for the "a" allele.Fact|date=March 2008
Since 2001, the mechanisms of the variations within the "bay" category remain unclear. Ongoing research suggests that Odriozola's theories may have been correct,cite web |url=http://colormorgans.tripod.com/basecolors.htm |title=The Base Colors |work=Morgan Colors |author=Laura Behning |date=2008-02-05 |accessdate=2008-03-04] evidenced by a parallel condition in mice. Mice have more than six alleles at the Agouti locus, including At which produces black-and-tan.cite journal |last=Hustad |first=C.M. |authorlink=no |coauthors=W. L. Perry, L. D. Siracusa, C. Rasberry, L. Cobb, B. M. Cattanach, R. Kovatch, N. G. Copeland, and N. A. Jenkins |year=1995 |month=May |title=Molecular Genetic Characterization of Six Recessive Viable Alleles of the Mouse Agouti Locus |journal=Mammalian Genetics Laboratory |volume=140 |issue=1 |pages=255–65 |url=http://www.genetics.org/cgi/content/abstract/140/1/255 |accessdate= 2008-03-04 |pmid=7635290]
It is still likely that to some extent, the "shade" of coat color may be regulated by unrelated genes for traits like "sooty", and that the phenotypes of sooty or dark bays/browns may overlap.cite web |url=http://www.duncentralstation.com/BrownBayDun.html |title=Brown/Bay Dun |work=Dun Central Station |author=Nancy Castle |date=2008-03-01 |accessdate=2008-03-04]
Equine coat color genetics
Equine coat color
* [http://www.vgl.ucdavis.edu/services/coatcolor.php "Introduction to Coat Color Genetics"] "from" Veterinary Genetics Laboratory, School of Veterinary Medicine, University of California, Davis. Web Site accessed January 12, 2008
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