Roan is a coat color found in many animals, notably horses, cattle and dogs. It is defined generally as an even mixture of white and pigmented hairs that does not "gray out" or fade as the animal ages. There are a variety of genetic conditions which produce the colors described as "roan" in various species.
A horse with intermixed white and colored hairs of any color is usually called a roan. However, such mixtures, which can appear superficially similar, are caused by a number of separate genetic factors. Identifiable types of roans include true or classic roan, varnish roan, and rabicano, though other currently unknown factors may be responsible for ambiguous "roaning." Gray horses, which become lighter as they age until their hair coat is nearly completely white, may be confused with roans when they are young. Duns, which are solid-colored horses affected by the dun dilution factor on their bodies but with darker points, are also sometimes confused with roans, but they do not have the intermixed white and colored hairs of a roan.
Horses with the classic or true roan pattern may be any base color which is intermingled with unpigmented white hairs on the body. Except for white markings under the control of other genes, the head, mane, tail, and lower legs are dark. Roan is a simple dominant trait symbolized by the Rn allele. The University of California, Davis School of Veterinary Medicine's genetics services have developed a DNA test that uses genetic markers to indirectly determine the number of Rn or rn alleles a horse has. The mutation responsible for true roan has not yet been identified exactly, but been assigned to equine chromosome 21 (ECA21) in the KIT sequence. The overall effect is that of a silver or lightened appearance to the affected part of the coat.
Descriptions of roan coat colors are as follows:
- Red Roan or Strawberry Roan describes true or classic roan on a chestnut base coat. The mane and tail remain red or have only a few white hairs, while the body ranges from nearly chestnut to pinkish. Geneticists prefer the term "chestnut roan," but this term is not in common use.
- Bay Roan is true roan on a bay coat. The particular shade depends on the underlying shade of bay; but the mane, tail, and lower legs are black, and the reddish body is intermingled with white hairs. The head is usually red. Formerly, bay roans were lumped together with chestnut roans and both called "red roans."
- Blue Roan is true roan on a black coat. The mane, tail, head, and legs remain black, while the body takes on a grayish or bluish appearance. Blue roans are sometimes mistaken for grays or grullos. However, Grays fade with age, while roans do not; and grullos are blue duns and possess dun markings but not intermingled white hairs.
Any other coat color may also be affected by roaning. Few combinations have the same unique terminology applied to the common roan colors, although palomino roans are sometimes called honey roans.
A varnish roan is not a true roan; it is actually one of the leopard complex coat patterns associated with Appaloosa, Knabstrupper, Noriker horse and related breeds. Rabicano is a white pattern that falls into the category of roaning or scattered white hairs, the genetics of which are not yet fully understood. Sometimes called ticking, rabicano is common even in breeds that do not have true or classic roan, including Arabians and Thoroughbreds. This pattern usually takes the form of scattered white hairs around the junction of the stifle and flank, and peculiar rings of white hairs near the base of the tail. This trait is called a coon tail or skunk tail. Some forms of sabino, which is a pinto pattern, have roaning along the edges of other white spots or markings A roan horse horse may not fit into any of the traditional categories as there is much still to be learned about the genetics of roan. The existence of other types of roaning conditions not covered by those mentioned here is possible and likely.
The genetics behind roan dogs are still unclear, and at present candidate genes have been ruled out. There remains a great deal of ambiguity in terminology regarding mottled dogs, which are called roan, ticked, mottled and belton depending on the context. The roan or ticked color is described in many breeds of gundogs such as English Cocker Spaniels, American Cocker Spaniels, English Springer Spaniels, Field Spaniels and Brittanys, German Shorthaired Pointers, Spinoni Italiani, Lagotto Romagnolos and English Setters, as well as Border Collies and many other breeds.
In dogs, roan manifests itself only in unpigmented areas, the presence and shape of which are determined by other genes. This is in stark contrast to true roan horses and roan cattle, which are roan only in pigmented regions of their coat and may have white markings. Instead, dogs with roaning or ticking are born with clear, open white markings which begin to fill in with flecking in the subsequent weeks and continue to darken with age. Most breed standards use the terms "ticked" and "roan" interchangeably, with the former referring to clearly-defined flecks on a white background and the latter to flecks so closely-spaced that the mixture appears even. The terminology that relates the underlying coat color with the roan modifier is often breed-specific, but most standards call a black dog with roaning blue. In breeds that are characterized by roaning and ticking such as the Large Munsterlander, clear white-marked individuals may be called plated. The term belton is reserved for English Setters.
In 1957, Little suggested that roan and ticking were controlled separately, and postulated that roan may have been homologous to "silvered" coat in mice. This condition in mice is actually homologous to merle, which might be described by some as "roan." In 2007, the gene responsible for roan cattle (KITLG) was refuted as a possible cause of roan in dogs. Neither roan nor ticking, if they are independently-caused, appear to be recessive.
Breeds of cattle known for roans are the Belgian Blue and Shorthorn. Among the former, coat color may be solid black, solid white, or blue roan; the latter may be solid red, solid white, or red roan. Belgian Blues also typically exhibit spotting patterns, which are genetically separate from roan. As a result, most roan cows exhibit blotches of clearly colored and clearly white hair, with roan patches. Some "cryptic" roan cattle appear solid, but upon close inspection reveal a small roan patch. Roan cattle cannot "breed true" but breeding white cattle to a solid mate will always yield a roan calf. The white color typical of Charolais and White Park breeds is not related to roan.
Roan in Shorthorns and Belgian Blues is controlled by the mast cell growth factor (MGF) gene, also called the steel locus, on bovine chromosome 5. Part of the KIT ligand, this region is involved in many cell differentiation processes. Mast cell growth factor promotes pigment production by pigment cells , and without it, skin and hair cells lack pigment. With two functional MGF genes (homozygous dominant), cattle are fully-pigmented; without any functional MGF genes (homozygous recessive), they are white. MGF-controlled roan occurs when cattle possess one functional and one non-functional MGF gene (heterozygous), resulting in a roughly even mixture of white regions and colored regions.
The reproductive condition "White Heifer Disease," associated with the MGF gene, is characterized by homozygous MGF-white heifers with incomplete reproductive tracts.
Roan Guinea Pigs
The roan coloration of Guinea pigs is linked to microphthalmia. The allele that controls roaning in guinea pigs is incompletely dominant: an animal with one copy of the allele will have varying amounts of white hair scattered through its coat, particularly on the back and sides. This is not to be confused with the 'Magpie' variety, which is a brindled guinea pig lacking red pigment due to the "chinchilla" allele also responsible for self white and silver agouti coloration.
About 25% of guinea pigs born to a mating of two roans are completely white, with a constellation of deformities called lethal white syndrome, although it has no relation to Overo Lethal White Syndrome in horses or double merle syndrome in dogs. These symptoms include:
- Partial or complete blindness
- Partial or complete deafness
- Microphthalmia or anophthalmia
- Unpigmented eyes
- Missing or deformed incisors
- Deformed molars
- Elongated tooth roots
- Malabsorption in the small intestine, due in some cases to lack of intestinal villi
- Increased susceptibility to illness
It is worth noting that, unlike anophthalmic hamsters, lethal white guinea pigs are not sterile. Females may be unable to deliver live young.
Lethal white guinea pigs have a decreased lifespan in general, although individuals have reportedly lived to 6 or 7 years. Many die shortly after birth or at weaning age. With hand-feeding and regular dental care, lethals can live 2–3 years.
- ↑ "roan, a. and n.1" Oxford English Dictionary. 2nd edition 1989. OED Online. Oxford University Press. 3 June 2008. .>
- ↑ 2.0 2.1 2.2 2.3 2.4 Veterinary Genetics Laboratory. "Introduction to Coat Color Genetics". The Regents of the University of California. http://www.vgl.ucdavis.edu/services/coatcolor.php. Retrieved 2008-06-04.
- ↑ 3.0 3.1 3.2 "Roan Zygosity Test Information". Veterinary Genetics Laboratory Services. UC Davis. http://www.vgl.ucdavis.edu/services/Roan.php. Retrieved 2009-10-01.
- ↑ Marklund, S; M Moller, K Sandberg, L Andersson (1999). "Close association between sequence polymorphism in the KIT gene and the roan coat color in horses". Mammalian Genome 10: 283–288. doi:10.1007/s003359900987.
- ↑ Overton, Rebecca (2004-12-15). "In The Genes" (PDF). Quarter Horse News (American Quarter Horse Association): pp. 24–6. http://www.hancockhorses.com/article-roanQHNews.pdf. Retrieved 2008-06-04.
- ↑ 6.0 6.1 Schmutz, SM; TG Berryere (2007). "Genes affecting coat colour and pattern in domestic dogs: a review". Animal Genetics 38: 439–549. doi:10.1111/j.1365-2052.2007.01664.x.
- ↑ 7.0 7.1 Schmutz, Sheila (2007-11-12). "Spotted Patterns". Dog Coat Color Genetics. http://homepage.usask.ca/~schmutz/dogspots.html. Retrieved 2008-06-04.
- ↑ The Cocker Spaniel Club. "Roan". Cocker Spaniel Colours & Markings. http://www.thecockerspanielclub.co.uk/colours3.htm. Retrieved 2008-06-04.
- ↑ 9.0 9.1 Byrne, Georgina (1990) . "Gene Loci for Coat Colour and Pattern". Der Deutsch Kurzhaar, The German Shorthaired Pointer. Georgina & Michael Byrne. ISBN 1863070060. http://www.dogstuff.info/gene_loci_gsp_byrne.html. Retrieved 2008-06-04.
- ↑ Clark, LA; JM Wahl, CA Rees, KE Murphy. "Retrotransposon insertion in SILV is responsible for merle patterning of the domestic dog.". Proceedings of the National Academy of Sciences of the United States of America 103. pp. 1376–81.
- ↑ Ibsen, HL (1999). "Cattle inheritance.". Genetics 18: 441–482. "in Seitz et al. (1999)".
- ↑ Schmutz, Sheila (2004-02-17). "The Roan Pattern". Genetics of Coat Color Patterns in Cattle.. http://homepage.usask.ca/~schmutz/CowPatterns.html. Retrieved 2008-06-03.
- ↑ 13.0 13.1 13.2 Seitz, Jeffrey J.; Sheila M. Schmutz, Tracey D. Thue, Fiona C. Buchanan (1999). "A missense mutation in the bovine MGF gene is associated with the roan phenotype in Belgian Blue and Shorthorn cattle.". Mammalian Genome 10: 710–712. doi:10.1007/s003359901076.
- ↑ Charlier, C; Denys B, Belanche JI, Coppieters W, Grobet L (1996). "Microsatellite mapping of the bovine roan locus: a major determinant of White Heifer disease.". Mammalian Genome 7: 138–142. doi:10.1007/s003359900034. "in Seitz et al. (1999)".
- ↑ Longley, B. Jack; Greg S. Morganroth, Lynda Tyrrell, Tie Gang Ding, Dirk M. Anderson, Douglas E. Williams, Ruth Halaban (May 1993). "Altered Metabolism of Mast-Cell Growth Factor (c-kit Ligand) in Cutaneous Mastocytosis.". New England Journal of Medicine 328 (18): 1302–1307. doi:10.1056/NEJM199305063281803. PMID 7682288. http://content.nejm.org/cgi/content/abstract/328/18/1302. Retrieved 2008-06-03.
- ↑ Schmutz, Sheila (2004-02-13). "Conditions Associated with Coat Color". Genetics of Coat Color Patterns in Cattle.. http://homepage.usask.ca/~schmutz/conditions.html. Retrieved 2008-06-03.