Mousekateers
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Aggression |
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Bicolor Chart |
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Birthing Kittens |
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Breeding Methods |
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Cat Colors |
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Cat Safety |
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Cattery Management |
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Claws |
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Feline Urologic Syndrome |
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Frequently Asked Questions |
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General Information |
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Genetic Glossary |
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Grooming for Show |
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Kitten Growth |
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Piebald Gene |
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Polycystic Kidney Disease |
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Purring |
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Respiratory Infections |
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Righting Reflex |
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Ringworm |
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Shipping - USA |
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Shipping - Overseas |
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Tabby Patterns |
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Tabby Chart |
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The Runt |
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Vaccines |
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Visit a Cat Show |
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Visit the Cattery |
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Worming |
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Disclaimer |
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Normal:
Except
for the XY, there is a pair of genes for each function located at the same
loci on sister chromosomes. One pair of normal genes is represented
as dots on a homologous pair of chromosomes.
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Dominant:
A single mutant (changed) gene is dominant if it causes an evident abnormality. The chance of inheritance of the mutant gene (left) is the same as the chance of inheriting a particular chromosome of the pair: 50%. |
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Heterozygous
recessive:
A single mutant gene is recessive (left) if it causes no evident abnormality, the function being well covered by the normal partner gene (its allele). Such a cat may be referred to as a heterozygous carrier. |
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Homozygous
recessive:
When both genes are a recessive mutant, the abnormal effect is expressed. The parents are generally carriers, and their risk of having another affected offspring is the chance of receiving the mutant from one parent (50%) times the chance from the other parent (50%), or 25 % for each offspring. |
X Y |
X-linked
recessive:
An X-linked recessive will be expressed in the male because he has no normal partner gene. His daughters, receiving the X, will all be born carriers, and his sons, receiving the Y, will all be normal. |
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X X |
X-linked
recessive:
An X-linked recessive will not show overt expression in the female because at least part of her "active" X's will contain the normal gene. The risk for affected sons and carrier daughters will each be 50%. |
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| A
(agouti) Tabby coat pattern |
a
(non-agouti) Black coat masks tabby pattern |
AA
Aa aa |
(Homozygous
agouti)
(Heterozygous agouti) (Homozygous non-agouti) |
Visible
tabby pattern
Visible tabby pattern Solid coat color, tabby pattern is masked |
| B
(black) |
b
(chocolate) bl (cinnamon) |
BB
Bb Bbl
blbl |
(Homozygous
black)
(Heterozygous black, chocolate carrier) (Heterozygous black, cinnamon carrier) (Homozygous chocolate) (Heterozygous chocolate, cinnamon carrier) (Homozygous cinnamon) |
Black
Black Black Chocolate
Cinnamon |
| C
(full color) |
ca
(albino, blue-eyed) c
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CC
Cca Ccb Cc Ccs caca cac cbca cbcb cbc cc csca cscb cscs |
(Homozygous
full )
(Heterozygous full, albino carrier) (Heterozygous full, Burmese carrier) (Heterozygous full, albino carrier) (Heterozygous full, Siamese carrier) (Homozygous albino) (Heterozygous albino) (Heterozygous Burmese) (Homozygous Burmese) (Heterozygous Burmese) (Homozygous albino) (Heterozygous Siamese) (Heterozygous siamese) (Homozygous siamese) |
Full
coat color
Full coat color Full coat color Full coat color Full coat color Albino Albino Burmese Burmese Burmese Pink-eyed albino Tonkinese Siamese Siamese |
| Cu
(curled ears) |
cu
(straight ears) |
CuCu
Cucu cucu |
(Homozygous
curled ears)
(Heterozygous curled ears) (Homozygous straight ears) |
American
Curl
American Curl Straight ears |
| D
(non-diluted) |
d
(diluted coat) |
DD
Dd dd |
(Homozygous
non-diluted coat)
(Heterozygous non-diluted coat) (Homozygous diluted coat) |
Black,
chocolate,
cinnamon, red Black, chocolate, cinnamon, red Blue, liliac, fawn, cream |
| Fd
(folded ears) |
fd
(straight ears) |
FdFd
Fdfd fdfd |
(Homozygous
folded ears)
(Heterozygous folded ears) (Homozygous straight ears) |
Scottish
Fold
Scottish Fold Straight ears |
| Hr
(normal coat) |
hr
(hairless coat) |
HrHr
Hrhr hrhr |
(Homozygous
normal coat)
(Heterozygous normal coat) (Homozygous hairless coat) |
Normal
coat
Normal coat Sphynx |
| I
(inhibitor coat pigment - affects the undercoat) |
i
(coat pigment non-inhibited) |
II
Ii ii |
(Homozygous
inhibited)
(Heterozygous
inhibited, carriers
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Silver
(Chinchilla, Shell,
Shaded, Smoke) Silver (Chinchilla, Shell, Shaded, Smoke) Solid coat |
| L
(short hair) |
l
(long hair) |
LL
Ll ll |
(Homozygous
short hair)
Heterozygous short hair, long hair carrier) (Homozygous long hair) |
Short
hair
Short hair Long hair |
| M
(Manx tail) |
m
(normal tail) |
MM
Mm mm |
(Homozygous
manx tail)
(Heterozygous normal tail, carrier of manx tail gene) (Homozygous normal tail) |
Manx
Manx Normal tail |
| O
(X))
(orange gene, linked with the female X chromosome) "Phaeno-" melanin |
o
(X or Y)
(non-orange) "Eu-"
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OO
(XX)
Oo (XX) O- (XY) oo
(XX)
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(Homozygous
orange)
(Heterozygous orange, carrier of non-orange) (Heterozygous orange, carrier of non-orange) (Homozygous non-orange) (Homozygous non-orange) |
Red
female
Tortoiseshell female Red male Black
female
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| R
(straight hairs; guard, awn, and down) |
r
(curly hairs and lack of guard hairs) |
RR
Rr rr |
(Homozygous
straight hairs)
(Heterozygous straight hairs, carrier of curly hairs) (Homozygous curly hairs) |
Straight
hairs
Straight hairs Cornish Rex |
| Re
(straight hairs of all 3 types) |
re
(curly hairs of all 3 types) |
ReRe
Rere rere |
(Homozygous
straight hairs)
(Heterozygous straight hairs, carrier of curly hairs) (Homozygous curly hairs) |
Straight
hairs
Straight hairs Devon Rex |
| Ro
(straight hairs of all 3 types) |
ro
(curly hairs of all 3 types) |
RoRo
Roro roro |
(Homozygous
straight hairs)
(Heterozygous straight hairs, carrier of curly hairs) (Homozoygous curly hairs) |
Straight
hairs
Straight hairs Oregon Rex |
| S
(white piebald spotting) |
s
(no white spotting) |
SS
Ss ss |
(Homozygous
piebald spotting)
(Heterozygous piebald spotting, carrier of no-white spotting) (Homozygous no white spotting) |
Bicolor
Bicolor Solid |
| Se
(curly hairs of all 3 types) |
se
(straight hairs of all 3 types) |
SeSe
Sese sese |
(Homozygous
curly hairs)
(Heterozygous curly hairs, carrier of straight hairs) (Homozygous straight hairs) |
Selkirk
Rex
Selkirk Rex Straight hairs |
| Ta
(ticked tabby) (incomplete dominance) |
T
(mackerel tabby) tb (blotched tabby) Note:
Mackerel
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TaTa
TaT Tatb Ttb TT
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(Homozygous
ticked tabby)
(Heterozygous ticked tabby, carrier of mackeral tabby) (Heterozygous ticked tabby, carrier of blotched tabby) (Heterozygous mackerel tabby, carrier of blotched tabby) (Homozygous mackerel tabby) (Homozygous blotched tabby) |
Ticked
tabby
Ticked tabby Ticked tabby Mackerel tabby Mackerel
tabby
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| W
(white - color masking gene) |
w
(non-white, true color is not masked) |
WW
Ww ww |
(Homozygous
white)
(Heterozygous white, carrier of non-white color ) (Homozygous non-white) |
White
White Color other than white |
| Wh
(wire hair) |
wh
(straight hair) |
WhWh
Whwh whwh |
(Homozygous
wire hair)
(Heterozygous wire hair, carrier of straight hair) (Homozygous straight hair) |
American
Wirehair
American Wirehair Straight hair |
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| Examples:
Mother to son Father to daughter Brother to sister Grandchildren to grandparents |
Examples:
The mating of more distant relatives within the same bloodline. If much homozygosity is already established in the bloodline, it is still considered close inbreeding. Common ancestors of the parents must be found only in the very beginning of the breed's formation for it to be considered true line breeding. |
Examples:
The mating of good breed examples from one bloodline to good breed examples from another bloodline. The cats from one bloodline should compliment the cats from the other bloodline. If a cat from bloodline A has great boning but a poor ear set, it should be mated with a cat from bloodline B that has a great ear set, but average boning. |
Examples:
The mating of good breed examples from one breed to good breed examples of another breed. |
| Uses:
Fixes desired traits Increases homozygosity |
Uses:
Fixes desired traits Increases homozygosity Allows for some phenotypic and genotypic differences between individuals. This allows for greater subsequent genetic manipulations than inbreeding. |
Uses:
Produces exceptional show quality cats while maintaining vigor. |
Uses:
Produces new breeds such as the Ocicat (Abyssinian breed with Siamese). Also introduces new genes into a breed which was the base of the color point (Himalayan) Persian. Definitely increases hybrid vigor. (The offspring are genetically and physically healthier than their parents.) |
| Problems:
Brings out deleterious genes Loss of vigor Immunodeficiency becomes fixed |
Problems:
Brings out deleterious genes Loss of vigor Immunodeficiency becomes fixed |
Problems:
Requires thought and planning. Breeder must be patient because results are not seen as quickly as with inbreeding, or line breeding. |
Problems:
New breed committees must present a very unique cat that is consistent over many breedings. |
Signs of loss of vigor in your breeding program
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Bodmer, W.F., Cavalli-Sforza, L. Genetics and the Evolution of Man, San Francisco: W.H. Freeman; 1976
Brown T. Genetics. A Molecular Approach, 2nd ed. London: Chapman & Hall: 1992
Dorland's Illustrated Medical Dictionary. 28th Ed. Philadelphia: WB Saunders; 1994.
Emery AFH. Elements of Medical Genetics. 6th ed. Edinburgh: Churchill Livingstone; 1983
Lewin B. Genes V. Oxford: Oxford University Press; 1994
Rieger R., Michaelis A. Green MM. Glossary of Genetics and Cytogentics. 5th ed. Berlin: Springer Verlag; 1979
Robinson, R; Genetics for Cat Breeders, 3rd Ed., Pergamon Press, London, 1991
Smith, DW, Jones, K L; Recognizable Patterns of Human Malformation, 3d Ed., WB Saunders; 1982
Suzuki DT, Griffiths AGF, Miller JH, Lewontin RC. An Introduction to Genetic Analysis, New York: WH Freeman; 1986.
Watson JD. Molecular Biology of the Gene. 3rd ed. Menlo Park, California: W.A. Benjamin; 1976
Whitehouse HLK. Towards an Understanding of the Mechanisms of Heredity. 3rd ed. London: Edward Arnold; 1973.
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