What are Redline? Redline are derived from Australian Lowline. After isolating the wild allele, which already occurred in the Lowline herd, we have be able to join wild allele carrying animals to wild allele carrying animals and thus produce, with a one in four chance, a red animal. Whilst the Australian Lowline Cattle Association does not accept the colour red the American Lowline Registry does which means that all our Redline are recorded and registered in the USA herd book.
Why Red? Red is the most populous colour of cattle breeds’ worldwide. Red is more heat tolerant than black. The majority of the world’s cattle are in areas that need heat tolerance, so the red colour is definitely an advantage. Red gives greater resistance to eye cancer and sun burned udders
Vitulus sells its first RedLine progeny for export. With the new export protocol to the USA Vitulus is now able to sell cattle directly to those countries. That's great news for those American breeders wanting show quality fullblood red lowlines because the first two progeny ( a heifer and bull) are already on the way and will be shown in 2008.
RedLine stock now available.Vitulus has a limited number of wild allele carrying young stock for sale as well as Redline semen. It is hoped that RedLine will be shown at a number of shows in Queensland in 2008 and will definitely be on display at again at Beef 2009.
RedLine embryos now available. In a world first Vitulus Lowline Stud has been able to flush a red lowline cow to a red lowline bull. 10 A grade embryos were all produced. SORRY ALL SOLD. More will be available in 2008.
RedLine Makes it debut at Beef 2006 winning Reserve Calf Champion in Boutique Breeds.
Red VS Black. Red and black are probably the two most common
coat colors in cattle. They occur as an either/or in breeds such
as Angus and Holstein. In other breeds, modifier genes change
the shades of these colors to a much wider range of possibilities.
Red is more popular in some countries and black in others but
both are common throughout the world.
All animals, including people, carry two copies of each gene-one from the mother and one from the father. These genes are unique sequences of DNA, each of which codes for a unique protein. Changes in the DNA code (called mutations) changes the structure of the protein produced by the gene and as a result change the way the protein works. When an animal has two different copies of a gene they are said to be Heterozygous for the gene and if one copy is hidden by the other, the hidden copy is said to be Recessive. If both copies of a gene are the same then the animal is Homozygous.
Before we go into the detail of how coat colour occurs it should be known that any red Lowline that have been born to date does not carry the red allele (e). Even though they are red in colour all the DNA testing has shown that they are homozygous for the wild-type allele (E+). According to recent correspondence with Professor Sheila Schmutz the American and Canadian Angus associations have both published that E+ exists in their Angus. The Australian Angus Society also is aware of the E+ allele within some member's herds. Included in the bottom of the page is a probability chart showing the possible outcomes of joining homozygous and heterozygous black animals. It needs to be noted that if the animal is heterozygous for the dominant black allele then this infers that the animal is also heterozygous for the wild-type allele (E+).
The gene causing red/black is the Melanocyte Stimulating
Hormone Receptor Gene (MSHr), also called the Melanocortin Receptor
1 gene (MC1r). This gene has two common alleles ED
and e. In addition, a less common allele, E+, also
called "wild type" occurs. When ED is present
in an animal, it is black. This is the dominant allele in the
series. Cattle that are ee are red and this is the recessive genotype.
However E+ appears to be a "neutral"
allele in most breeds and we think ED E+
cattle are black and E+e cattle are red. E+E+
cattle can be almost any color since other genes take over in
dictating what pigments are produced, such as the Agouti locus.
Given the diversity of colours seen in all breeds
of cattle, many people are surprised that there are just two different
pigments that produce all of the hair colours in cattle (and for
that matter, all mammals). These two pigments are eumelanin (black)
and Phaeomelanin (red). Eumelanin is a black pigment, but also
looks brown or grey in lower concentrations. Phaeomelanin is a
red pigment, but can look orange or yellow in lower concentrations.
If neither pigment is produced, then hair is white. The distribution
of these two pigments is controlled by a large number of different
genes, which makes the inheritance of the two pigments somewhat
complex.
The best-studied gene related to colour is the
gene that controls the relative degree of eumelanin and Phaeomelanin
production. This gene (known as the Extension gene) regulates
the levels of an enzyme called tyrosinase. Low levels of tyrosinase
result in Phaeomelanin (red pigment) production, and high levels
of tyrosinase result in production of eumelanin (black pigment).
The wild aurochs of Europe (the ancestors of Texas Longhorns,
as well as other breeds of Bos taurus) are thought to
have had a single common allele for this gene, which is referred
to as the “wild-type” allele. The wild-type allele
results in variable but typically intermediate amounts of tyrosinase.
This means that both eumelanin and Phaeomelanin are produced,
and the ratio and distribution of the two pigments may be modified
by other genes. Longhorns that have two copies (one from each
parent) of the wild-type allele at the Extension gene
are typically some shade of reddish brown at birth, but often
grow darker as they grow older (and may appear black as adults).
The relative expression of eumelanin appears to be related to
the sex of the animal, and males (with wild type alleles at the
Extension gene) are more likely to be black as adults
than are females. However, the muzzle ring of these individuals
is usually light tan or brown rather than pure black (this is
often called “mealy-mouthed,” because it looks as
if the animals have been eating corn meal). Other individuals
with the wild-type allele may be dark brown (including Parker
brown), medium brown, or a mixture of brown and black or red and
black (and many of the other unusual colourations of cattle breeds).
There are two well-studied alleles (forms of a
gene) that differ from the wild-type allele at the Extension
gene in cattle. These alleles resulted from small mutations in
the DNA sequences for this gene that were selected by early humans
during the domestication of cattle (probably to make breeds more
distinguishable). Mutations in DNA can take several forms, including
substitutions (replacing one “letter” in the DNA sequence
with another) and deletions (removing a letter from the sequence).
Substitutions often change the function of a gene, but may not
render it functionless. Deletions, on the other hand, often destroy
the function of a gene. One of the alleles at the Extension
gene differs from the wild-type allele by a single substitution.
This simple change results in a small change in function, which
in turn results in an excess production of black pigment in skin
and hair cells. Because the hairs have an excess of eumelanin,
any coloured hairs will be black at birth (other genes may keep
some of the hairs from expressing any pigment, so the calf is
often black and white). Even if a calf inherits just one copy
of this allele, almost any hair that is pigmented will be coloured
black. Thus, if a bull (or cow) has inherited copies of this black
allele from both its mother and its father, then all of its own
offspring will also express black (no matter what gene is inherited
from the other parent). This is how some breeders can guarantee
that their bulls will always produce calves with black coloration:
the bull has been tested and found to be homozygous for the black
allele at the Extension gene (which simply means that
both of its copies of this gene are the dominant black allele).
The other common allele at the Extension
gene in cattle is a deletion mutation (a single nucleotide has
been lost), which results in a non-functional gene. If an animal
has two copies of this allele, then that animal lacks the ability
to produce eumelanin. Phaeomelanin (red pigment) is still produced,
however, so any pigmented hairs have a basic red coloration. If
an animal has only one copy of the red allele and one of the wild-type
allele, then there is still enough tyrosinase produced for the
coloration to appear just like a homozygous wild-type individual
(i.e., some mixture of black and red pigment, but typically darkening
with age, especially in males). Thus, the wild-type allele is
said to be dominant over the red allele, since an animal with
both alleles will show the wild-type coloration. On the other
hand, the black allele is dominant over both the wild-type and
red alleles, since even one copy will result in an over-abundance
of eumelanin. Therefore, a cow or bull that is black at birth
may be homozygous black, or heterozygous black and wild-type,
or heterozygous black and red (any of these combinations will
simply look black). A calf with wild-type coloration may
be homozygous wild-type, or heterozygous wild-type and red, will
be red. Finally, a true red calf is always homozygous for the
red allele.
The “black” allele is abbreviated ED
(the E stands for Extension, and the subscript
D stands for dominant black), the wild-type allele is
abbreviated E+ (the superscript + symbol is
used to designate the wild-type allele at any given gene), and
the red allele is abbreviated e (lower case is used to
indicate that this allele is recessive to the other two alleles).
Geneticists usually indicate the dominance order of these three
alleles by writing ED > E+ > e.
With this shorthand, we can indicate a homozygous black bull by
writing that its genotype is ED /ED,
whereas as heterozygous wild-type/red bull would be said to have
the genotype E+/e.
http://skyway.usask.ca/~schmutz/colors.html#Red%20versus%20Black
– July 2005
http://home.austin.rr.com/doublehelix/colorPart1.html
- July 2005
RedLine History
Trangie Animals (bred and imported) that our research indicates would have carried the wild or red allele genes. This information if obtained from Angus Society Herd Book Vol.11
1. Trangie Gera 13th. (Red) HB No. 7645 Born Oct. 1944
Sire: Trangie Revolution 2nd. HB No. 524
Dam: Trangie Gera 2nd. HB No. 3043
2. Trangie Joan 5th. (Red) HB No. 7650 Born Jan. 1942
Sire: Trangie Edward 4th. HB No. 595
Dam: Trangie Joan 2nd. HB No. 4656
3. Trangie Poatina. (Red) HB No. NDAU15+U75 Born April
1975
Sire: Trangie Viking. HB No. NDAS119+73
Dam: Trangie Prima Donna 6th HB No. NDAJ04+65
4. Erison of Harviestoun (Trangie IMP) Produced
Red Calves, main source of the red gene in Australia
Sire: Janric of Dalmeny
Dam: Erissa of Harviestoun
The information relating to Erison of Harviestoun who appears in lowline pedigrees and the Lowline Foundation Herd Book can be found at http://www.redangus.org.au/ - History of Red angus in Australia - In Australia as overseas, some Red calves appeared in black herds. It is generally acknowledged that Baraon Beppo and Erison of Harviestoun, Grandeur of Fordhouse and Benes of Gaidrew were the main source of the Red gene, but a study of the full pedigrees of early cattle coming to Australia and New Zealand, indicate that many other would also have carried the red gene.
Examples of Animals with Coat Colour Alleles and their
combinations:
 |
 |
| (e/e Homozygous Red) |
(E+/E+
Homozygous Wild-Allele) |
|
|
| (ED /ED Homozygous
Black) |
(ED /E+ Heterozygous
Black/Heterozygous Wild-Type) |
|
|
| (E+/e - Heterozygous
Wild-Type/Heterozygous Red) |
(ED /e Heterozygous Black/Heterozygous
Red) |
