Description

The genotypes of the animals provided may not reflect those discussed in the strain description or the mating scheme utilized by The Jackson Laboratory prior to cryopreservation. Please inquire for possible genotypes for this specific strain.

Strain Information

Former Names AKXD-15/TyJ    (Changed: 15-DEC-04 ) Type Recombinant Inbred (RI); Additional information on Recombinant Inbred Mice. Visit our online Nomenclature tutorial. Species laboratory mouse RI progenitor AKR/J DBA/2J H2 Haplotype k

Appearance
albino
Related Genotype: Tyr^c/Tyr^c

Related Strains

AKXD Strains

001005	AKXD1/TyJ
001017	AKXD10/TyJ
001003	AKXD11/TyJ
000765	AKXD13/TyJ
000779	AKXD14/TyJ
000958	AKXD16/TyJ
001093	AKXD18/TyJ
000776	AKXD2/TyJ
001001	AKXD20/TyJ
001062	AKXD21/TyJ
000947	AKXD22/TyJ
000780	AKXD23/TyJ
000969	AKXD24/TyJ
000949	AKXD25/TyJ
000764	AKXD27/TyJ
000957	AKXD28/TyJ
000959	AKXD3/TyJ
000777	AKXD6/TyJ
000763	AKXD9/TyJ

View AKXD Strains     (19 strains)

Strains carrying   Emv3^a allele

000765	AKXD13/TyJ
000779	AKXD14/TyJ
001093	AKXD18/TyJ
000947	AKXD22/TyJ
000764	AKXD27/TyJ
000959	AKXD3/TyJ

View Strains carrying   Emv3^a     (6 strains)

Strains carrying   Myo5a^d allele

001005	AKXD1/TyJ
001003	AKXD11/TyJ
000765	AKXD13/TyJ
000779	AKXD14/TyJ
001093	AKXD18/TyJ
000776	AKXD2/TyJ
001062	AKXD21/TyJ
000947	AKXD22/TyJ
000949	AKXD25/TyJ
000764	AKXD27/TyJ
000959	AKXD3/TyJ
000285	B6.Cg-Rorasg + +/+ Myo5ad Bmp5se/J
000652	BDP/J
000036	BXD1/TyJ
000013	BXD16/TyJ
000015	BXD18/TyJ
000010	BXD19/TyJ
000077	BXD21/TyJ
000043	BXD22/TyJ
000081	BXD25/TyJ
006255	BXD25/TyJRwwJ
000029	BXD29-Tlr4lps-2J/J
010981	BXD29/Ty
000037	BXD5/TyJ
000007	BXD6/TyJ
000084	BXD8/TyJ
000105	BXD9/TyJ
000284	CWD/LeJ
000670	DBA/1J
000671	DBA/2J
000963	DBA/2J-Myo5ad+17J/Myo5ad/J
000964	DBA/2J-Myo5ad+18J/Myo5ad/J
000067	DBA/2J-Myo5ad+2J/Myo5ad/J
000673	HRS/J
000674	I/LnJ
001850	MEV-Q/TyJ
001855	MEV-V/TyJ
003345	MEV/2Ty-Emv64/J
000679	P/J
000644	SEA/GnJ
000390	STOCK Myo5ad Ds/J
000994	STOCK a Myo5ad Mregdsu/J
000286	STOCK a/a Myo5ad fd/+ +/J

View Strains carrying   Myo5a^d     (43 strains)

Strains carrying   Rmcf^r allele

000690	129P3/J
000765	AKXD13/TyJ
001093	AKXD18/TyJ
000947	AKXD22/TyJ
000763	AKXD9/TyJ
000654	CBA/CaJ
000670	DBA/1J

View Strains carrying   Rmcf^r     (7 strains)

Strains carrying   Tyr^c allele

001017	AKXD10/TyJ
000765	AKXD13/TyJ
000958	AKXD16/TyJ
001093	AKXD18/TyJ
001062	AKXD21/TyJ
000947	AKXD22/TyJ
000969	AKXD24/TyJ
000777	AKXD6/TyJ
000763	AKXD9/TyJ
000409	B10.129P-H1b Hbbd Tyrc Ea7a/(5M)oSnJ
000418	B10.129P-H1b Tyrc Hbbd/(5M)nSnJ
000432	B10.C-H1b Hbbd Tyrc/(41N)SnJ
000383	B6.C-Tyrc H1b Hbbd/ByJ
001759	STOCK A Tyrc Sha/J
000006	STOCK Hk Tyrc/J

View Strains carrying   Tyr^c     (15 strains)

Strains carrying other alleles of Emv11

000779	AKXD14/TyJ
001093	AKXD18/TyJ
000947	AKXD22/TyJ
000780	AKXD23/TyJ
000959	AKXD3/TyJ
000777	AKXD6/TyJ
001885	NFS.AK-Emv11/J

View Strains carrying other alleles of Emv11     (7 strains)

Strains carrying other alleles of Myo5a

005012	A.B6 Tyr+-Myo5ad-l31J/J
001013	B10.D2/nSnJ-Myo5ad-n/J
000502	B6 x B6CBCa Aw-J/A-Myo5aflr Gnb5flr/J
000963	DBA/2J-Myo5ad+17J/Myo5ad/J
000964	DBA/2J-Myo5ad+18J/Myo5ad/J
000067	DBA/2J-Myo5ad+2J/Myo5ad/J
000253	DLS/LeJ

View Strains carrying other alleles of Myo5a     (7 strains)

Strains carrying other alleles of Rmcf

000646	A/J
000648	AKR/J
000779	AKXD14/TyJ
000780	AKXD23/TyJ
000764	AKXD27/TyJ
000777	AKXD6/TyJ
000667	C57BR/cdJ
000668	C57L/J
000669	C58/J
000682	RF/J
000644	SEA/GnJ
000686	SJL/J
000688	ST/bJ

View Strains carrying other alleles of Rmcf     (13 strains)

Strains carrying other alleles of Tyr

000090	129S1/Sv-Oca2+ Tyr+ KitlSl-J/J
000091	129T1/Sv-Oca2+ Tyrc-ch Dnd1Ter/J
001279	129T1/Sv-Oca2+ Tyrc-ch-Aft/J
005445	A.B6 Tyr+-Cybanmf333/J
005012	A.B6 Tyr+-Myo5ad-l31J/J
002565	A.B6-Tyr+/J
000580	B10.D2/nSn-Tyrc-4J/J
000822	B6 x 129S1/SvEi Oca2+ Tyr+-Vsx2or-J/J
000578	B6 x STOCK Tyrc-ch Bmp5se +/+ Myo6sv/J
000058	B6(Cg)-Tyrc-2J/J
007484	B6.Cg-Tyrc-2J Tg(Tyr)3412ARpw Tg(Sry-EGFP)92Ei/EiJ
000035	B6.Cg-Tyrc-J/J
000104	B6.Cg-Tyrc-h/J
000054	B6.D2-Tyrc-p/J
000899	C.B6-Tyr+ Hbbs/J
000339	C3H/HeJ-Tyrc-9J/J
001294	C3H/HeJ-Tyrc-a/J
001002	C57BL/10SnJ-Tyrc-11J/J
001006	CBA/J-Tyrc-10J/J
000657	CE/J
000619	FS/EiJ
004828	FVB.129P2-Pde6b+ Tyrc-ch/AntJ
007483	FVB.Cg-Tg(Tyr)3412ARpw Tg(Sry-EGFP)92Ei/EiJ
000494	J.Cg-Oca2+ Tyr+ Lystbg/J
002281	NFS.C58-Tyr+/J
004304	NOD.CBALs-Tyr+/LtJ
005115	NOD.FVB-Tg(INS-MT2A,Tyr)1Pne/PneJ
005114	NOD.FVB-Tg(Ins1-Cat,Tyr)25Pne/PneJ
000271	SH1/LeJ
000306	STOCK Dll3pu + Tyrc-ch/+ Oca2p Tyrc-ch/J
000206	STOCK a/a Tyrc-h/J

View Strains carrying other alleles of Tyr     (31 strains)

Phenotype

Phenotype Information

View Phenotypic Data

Phenotypic Data

Mouse Phenome Database
Wellcome Trust Centre for Human Genetics: Mouse Recombinant Inbred Line (RIL) Genotype Data for AKXD RI Line

View Mammalian Phenotype Terms

Mammalian Phenotype Terms

      assigned by genotype

       

• tumorigenesis
• histiocytic sarcoma (MGI Ref ID J:69716)
  • 4 of 19 characterized lymphomas
• lymphoma (MGI Ref ID J:20300)
  • propensity to develop lymphoma with mean age of onset 471 days
• B cell derived lymphoma (MGI Ref ID J:4179)
  • assessment of 9 lymphomas from 20 female mice shows 56% are B cell derived
  • 3 of 19 characterized lymphomas are diffuse large cell lymphomas
• follicular lymphoma (MGI Ref ID J:69716)
  • 2 of 19 characterized lymphomas
• splenic marginal zone lymphoma (MGI Ref ID J:69716)
  • 3 of 19 characterized lymphomas
• T cell derived lymphoma (MGI Ref ID J:4179)
  • assessment of 9 lymphomas from 20 female mice shows 33% are T cell derived
• lymphoblastic lymphoma (MGI Ref ID J:69716)
  • of 19 characterized lymphomas 6 are pre-T cell lymphoblastic lymphomas

View Research Applications

Research Applications

This mouse can be used to support research in many areas including:

Research Tools
Cancer Research
      genes regulating lymphoma development
Genetics Research
      Gene Mapping: Tools for QTL Mapping, Segregation and Linkage Analysis

Myo5a^d related

Dermatology Research
Color and White Spotting Defects

Mouse/Human Gene Homologs
Griscelli Syndrome

Tyr^c related

Dermatology Research
Color and White Spotting Defects
      oculocutaneous albinism, type I

Mouse/Human Gene Homologs
albinism, tyrosine negative

Genes & Alleles

Gene & Allele Information

Allele Symbol		Emv3a
Allele Name		endogenous ecotropic MuLV 3, present
Allele Type		Not Applicable
Gene Symbol and Name		Emv3, endogenous ecotropic MuLV 3
Chromosome		9
Gene Common Name(s)		Emv-3; Sev-1;
General Note		The provirus is present in the following strains: BDP/J, DBA/1J, DBA/2DeJ, DBA/2J, HRS/J, I/LnJ, P/J, and SEA/GnJ.
Allele Symbol		Myo5ad
Allele Name		dilute
Allele Type		Spontaneous
Common Name(s)		d; dv; maltese dilution;
Strain of Origin		old mutant of the mouse fancy
Gene Symbol and Name		Myo5a, myosin VA
Chromosome		9
Gene Common Name(s)		9630007J19Rik; AI413174; AI661011; D; Dbv; Dop; GS1; MVa; MYH12; MYO5; MYR12; Myo5; MyoVA; RIKEN cDNA 9630007J19 gene; d; dilute; expressed sequence AI413174; expressed sequence AI661011; flail; flailer; flr; myosin V; nmf244;
General Note		Mutations at the Myo5a locus lighten coat color through an abnormal morphology of melanocytes that causes uneven pigmentation of the hair shaft (J:11005). Most of these mutations also cause severe neurological defects; in some mutant forms, these defectslead to early death (J:12978), while in others life span is normal, but convulsions and loss of equilibrium occur after about four months of age (J:16915). Maltese dilution, as this mutation was originally called, is an old mutation of the mouse fancy. The blue-gray color of the hair produced by this mutation in nonagouti (a/a) mice is caused by clumping of the melanin pigment into a few large masses (J:12958). The melanocytes are misshapen, with fewer and thinner dendritic processes than wild-type melanocytes, and melanin granules are largely clumped around the nucleus (J:12970). Incorporation of tyrosine into melanin proceeds at a normal rate (J:12173), and the fine structure of the melanin granules is normal (J:5346). Cultured primary melanocytesfrom dilute homozygotes are normal in morphology but display clustering of melanosomes (J:37976). Griscelli disease (Chediak-Higashi-like syndrome, OMIM 214450) is a human autosomal recessive disorder whose symptoms include pigment dilution, immunodeficiency, and acute lethal lymphocyte and macrophage activation. Melanocyte malformation is characteristic of the pigment abnormality. The immunological abnormality includes absence of cutaneous hypersensitivity and impaired function of natural-killer cells. Griscelli disease resembles the dilute-lethal mouse mutant, except for the neurological disorder in the mouse. The locus for Griscelli disease colocalizes with the locus for myosin Va, which is mutated in at least some Griscelli patients. Griscelli disease is thus the homolog of mouse Maltese dilution (J:41253). The original Myo5ad mutation which identified the locuswas caused by insertion of an ecotropic murine leukemia virus (see Emv3) (J:6844, J:6587). All other mutations examined lack the virus. Reversions of Myo5ad to wild-type, which have been reported frequently, are caused by excision of the virusleaving exactly one long terminal repeat in place (J:7092). The virus is integrated into a noncoding region of the DNA (J:7751).
Molecular Note		This mutation is the result of the integration of the ecotropic murine leukemia virus Emv-3 into the normal Myo5ad gene. [MGI Ref ID J:6587]
Allele Symbol		Rmcfr
Allele Name		MCF resistant
Allele Type		Spontaneous
Strain of Origin		multiple strains
Gene Symbol and Name		Rmcf, resistance to MCF virus
Chromosome		5
General Note		This locus controls resistance and susceptibility of cells in tissue culture to infection by mink cell focus-forming murine leukemia viruses. The allele Rmcfr determines resistance and occurs in strains DBA/1, DBA/2, and CBA/Ca; the allele Rmcfs determines susceptibility and occurs in strains AKR/J, C57BL/6, BALB/c, CBA/J, NFS, NZB, 129/J, and many others. Heterozygotes are as resistant as the resistant parent or nearly so. Rmcf is different from and independent of Fv1,a locus that controls susceptibility to infection by ecotropic viruses. Rmcf is located on Chr 5 close to Hm near the centromeric end (J:7108). Rmcfr protects (AKR x CBA/Ca)F1 and (AKR x DBA/2)F1 hybrids from development of spontaneous thymic lymphomas and reduces the incidence of MCF-induced thymic lymphomas (J:7175). It also reduces susceptibility of cells of Sxvs/Sxvr mice to exogenous xenotropic viruses (J:7951). In addition, in strains susceptible to Friend virus-induced erythroleukemia, a condition thought to be due to the replication of MCF virus, Rmcfr increases resistance to the virus-induced erythroleukemia. It may cause resistance by coding for or regulating the production of an MCF-related envelope glycoprotein that blocks the receptor for MCF viruses (J:8074). This conclusion is reinforced by the findings of Buller et al. (J:8497), who showed that the Rmcfr allele contains an endogenous MCF gp70 env gene and that theRmcfs allele, at least in some strains (C57BL/6, CBA/J, and A/WySn), contains a xenotropic gp70 env gene. Presumably the MCF gp70 inhibits exogenous MCF infection in vitro by a mechanism of viral interference.
Molecular Note		This locus controls resistance of cells to infection by mink cell focus-forming murine leukemia viruses. The dominant r (resistance) allele is found in strains DBA/1, DBA/2 and CBA/Ca.
Allele Symbol		Tyrc
Allele Name		albino
Allele Type		Spontaneous
Common Name(s)		c;
Strain of Origin		old mutant of the mouse fancy
Gene Symbol and Name		Tyr, tyrosinase
Chromosome		7
Gene Common Name(s)		C; OCA1A; OCAIA; SHEP3; albino; c; skc35; skin/coat color 35;
General Note		Tyrc, albino. This very old mutant was already known in Greek and Roman times. Hair and eyes are completely devoid of pigment (J:5436, J:5001, J:30725). The albino mutation affects the amount of tyrosinase, and thus of melanin, in pigment cells, but does not interfere with the production of pigment cells themselves (J:12173, J:13092). Melanocytes with melanosomes showing normal fine structure occur in the retina and hair follicles. Pigment granules are smaller and fewer than normal and completely lack melanin (J:5346, J:5001, J:30725). Tyrosinase is almost absent (J:12173).Although Tyr is the structural gene for tyrosinase, some albino mutations may affect tyrosinase enzyme regulation rather than structure (J:6611), suggesting that these mutations affect tyrosinase inhibition (J:5346), presumably via control regions of the gene. All the mutant alleles are recessive to wild-type in phenotype, but heterozygotes with wild-type produce intermediate amounts of tyrosinase (J:12173).Albino-locus mutants with lightly pigmented eyes have a reduced number of fibers of the optic nerve going to the ipsilateral lateral geniculate nucleus of the brain. This is probably a secondary effect of reduced tyrosinase activity or amount of pigment in the pigmentepithelium, since genes at other loci that reduce eye pigmentation also cause the same anomaly (J:5436, J:6064).Abnormal retinal pathways disrupted at the optic chiasm that occur in albinism can be corrected with a Tyr normal transgene (J:22320).Lipofuscin is a terminal oxidation product pigment that accumulates with age. In a cross of C57BL/6J and BALB/cJ, which differ in cardiac deposition of the pigment, this trait segregated with albinism, and is controlled by the Tyr locus (J:15460).Tyrc homozygotes do not perform as well as normal in a number of behavioral tests. It is likely that this effect is mediated, at least in part, by defective vision resulting from lack of retinal pigment (J:5470, J:5360, J:5378).
Molecular Note		The specific mutation in the albino allele is a G to C transversion causing an amino acid change from cysteine to serine. This mutation introduces a DdeI enzyme restriction site. [MGI Ref ID J:10889] [MGI Ref ID J:40223]
Gene Symbol and Name		Emv11, endogenous ecotropic MuLV 11
Chromosome		7
Gene Common Name(s)		AKR leukemia virus inducer 1; Akv-1; Emv-11;

Genotyping

Genotyping Information

This strain will not have a genotyping protocol or one is not currently available.

Helpful Links

Genotyping resources and troubleshooting

References

References

Selected Reference(s)

Mucenski ML; Taylor BA; Jenkins NA; Copeland NG. 1986. AKXD recombinant inbred strains: models for studying the molecular genetic basis of murine lymphomas. Mol Cell Biol 6(12):4236-43. [PubMed: 3025647]  [MGI Ref ID J:20300]

Additional References

Jenkins NA; Copeland NG; Taylor BA; Lee BK. 1981. Dilute (d) coat colour mutation of DBA/2J mice is associated with the site of integration of an ecotropic MuLV genome. Nature 293(5831):370-4. [PubMed: 6268990]  [MGI Ref ID J:6587]

Emv3^a related

Jenkins NA; Copeland NG; Taylor BA; Lee BK. 1982. Organization, distribution, and stability of endogenous ecotropic murine leukemia virus DNA sequences in chromosomes of Mus musculus. J Virol 43(1):26-36. [PubMed: 6287001]  [MGI Ref ID J:6844]

Myo5a^d related

Coleman DL. 1962. Effect of genic substitution on the incorporation of tyrosine into the melanin of mouse skin. Arch Biochem Biophys 96:562-8. [PubMed: 13880466]  [MGI Ref ID J:12173]

Copeland NG; Hutchison KW; Jenkins NA. 1983. Excision of the DBA ecotropic provirus in dilute coat-color revertants of mice occurs by homologous recombination involving the viral LTRs. Cell 33(2):379-87. [PubMed: 6305507]  [MGI Ref ID J:7092]

Engle LJ; Kennett RH. 1994. Cloning, analysis, and chromosomal localization of myoxin (MYH12), the human homologue to the mouse dilute gene. Genomics 19(3):407-16. [PubMed: 8188282]  [MGI Ref ID J:16915]

Grobman AB; Charles DR. 1947. Mutant white mice. A new dominant autosomal mutant affecting coat color in Mus musculus. J Hered 38:381-384.  [MGI Ref ID J:13058]

Hearing VJ; Phillips P; Lutzner MA. 1973. The fine structure of melanogenesis in coat color mutants of the mouse. J Ultrastruct Res 43(1):88-106. [PubMed: 4634048]  [MGI Ref ID J:5346]

Hutchison KW; Copeland NG; Jenkins NA. 1984. Dilute-coat-color locus of mice: nucleotide sequence analysis of the d+2J and d+Ha revertant alleles. Mol Cell Biol 4(12):2899-904. [PubMed: 6098826]  [MGI Ref ID J:7751]

Jenkins NA; Copeland NG; Taylor BA; Lee BK. 1981. Dilute (d) coat colour mutation of DBA/2J mice is associated with the site of integration of an ecotropic MuLV genome. Nature 293(5831):370-4. [PubMed: 6268990]  [MGI Ref ID J:6587]

Jenkins NA; Copeland NG; Taylor BA; Lee BK. 1982. Organization, distribution, and stability of endogenous ecotropic murine leukemia virus DNA sequences in chromosomes of Mus musculus. J Virol 43(1):26-36. [PubMed: 6287001]  [MGI Ref ID J:6844]

Libby RT; Lillo C; Kitamoto J; Williams DS; Steel KP. 2004. Myosin Va is required for normal photoreceptor synaptic activity. J Cell Sci 117(Pt 19):4509-15. [PubMed: 15316067]  [MGI Ref ID J:92181]

Markert CL; Silvers WK. 1956. The Effects of Genotype and Cell Environment on Melanoblast Differentiation in the House Mouse. Genetics 41(3):429-50. [PubMed: 17247639]  [MGI Ref ID J:12970]

Mercer JA; Seperack PK; Strobel MC; Copeland NG; Jenkins NA. 1991. Novel myosin heavy chain encoded by murine dilute coat colour locus [published erratum appears in Nature 1991 Aug 8;352(6335):547] Nature 349(6311):709-13. [PubMed: 1996138]  [MGI Ref ID J:11005]

Moore KJ; Swing DA; Copeland NG; Jenkins NA. 1990. Interaction of the murine dilute suppressor gene (dsu) with fourteen coat color mutations [published erratum appears in Genetics 1990 Sep;126(1):285] Genetics 125(2):421-30. [PubMed: 2379821]  [MGI Ref ID J:29467]

Moore KJ; Swing DA; Copeland NG; Jenkins NA. 1994. The murine dilute suppressor gene encodes a cell autonomous suppressor. Genetics 138(2):491-7. [PubMed: 7828830]  [MGI Ref ID J:20796]

Moore KJ; Swing DA; Rinchik EM; Mucenski ML; Buchberg AM; Copeland NG; Jenkins NA. 1988. The murine dilute suppressor gene dsu suppresses the coat-color phenotype of three pigment mutations that alter melanocyte morphology, d, ash and ln. Genetics 119(4):933-41. [PubMed: 3410303]  [MGI Ref ID J:9309]

Murray WS. 1934. The breeding behavior of the dilute brown stock of mice (Little dba) Am J Cancer 20:573-593.  [MGI Ref ID J:2464]

O'Sullivan TN; Wu XS; Rachel RA; Huang JD; Swing DA; Matesic LE; Hammer JA rd; Copeland NG; Jenkins NA. 2004. dsu functions in a MYO5A-independent pathway to suppress the coat color of dilute mice. Proc Natl Acad Sci U S A 101(48):16831-6. [PubMed: 15550542]  [MGI Ref ID J:94728]

PIERRO LJ; CHASE HB. 1963. Slate--a new coat color mutant in the mouse. J Hered 54:47-50. [PubMed: 13943454]  [MGI Ref ID J:25388]

Pastural E; Barrat FJ; Dufourcq-Lagelouse R; Certain S; Sanal O ; Jabado N ; Seger R ; Griscelli C ; Fischer A ; de Saint Basile G. 1997. Griscelli disease maps to chromosome 15q21 and is associated with mutations in the myosin-Va gene. Nat Genet 16(3):289-92. [PubMed: 9207796]  [MGI Ref ID J:41253]

Provance DW Jr; Wei M; Ipe V; Mercer JA. 1996. Cultured melanocytes from dilute mutant mice exhibit dendritic morphology and altered melanosome distribution. Proc Natl Acad Sci U S A 93(25):14554-8. [PubMed: 8962090]  [MGI Ref ID J:37976]

Quevedo WC Jr.; Chase HB. 1958. An analysis of the light mutation of coat color in mice. J Morphol 102:329-345.  [MGI Ref ID J:13094]

RIKEN BioResource Center/RIKEN Genomic Sciences Center. 2008. A Large Scale Mutagenesis Program in RIKEN GSC PhenoSITE, World Wide Web (URL: http://www.brc.riken.jp/lab/gsc/mouse/) :.  [MGI Ref ID J:133634]

RUSSELL ES. 1949. A quantitative histological study of the pigment found in the coat-color mutants of the house mouse; interdependence among the variable granule attributes. Genetics 34(2):133-45. [PubMed: 18117146]  [MGI Ref ID J:148461]

Russell ES. 1948. A Quantitative Histological Study of the Pigment Found in the Coat Color Mutants of the House Mouse. II. Estimates of the Total Volume of Pigment. Genetics 33(3):228-36. [PubMed: 17247280]  [MGI Ref ID J:148462]

Russell ES. 1946. A Quantitative Histological Study of the Pigment Found in the Coat-Color Mutants of the House Mouse. I. Variable Attributes of the Pigment Granules. Genetics 31(3):327-46. [PubMed: 17247200]  [MGI Ref ID J:148463]

Russell ES. 1949. A Quantitative Histological Study of the Pigment Found in the Coat-Color Mutants of the House Mouse. IV. the Nature of the Effects of Genic Substitution in Five Major Allelic Series. Genetics 34(2):146-66. [PubMed: 17247308]  [MGI Ref ID J:12958]

Sweet HO. 1983. Dilute suppressor, a new suppressor gene in the house mouse. J Hered 74(4):305-6. [PubMed: 6886377]  [MGI Ref ID J:7171]

Yoshimura A; Fujii R; Watanabe Y; Okabe S; Fukui K; Takumi T. 2006. Myosin-Va facilitates the accumulation of mRNA/protein complex in dendritic spines. Curr Biol 16(23):2345-51. [PubMed: 17141617]  [MGI Ref ID J:117928]

Rmcf^r related

Buller RS; Ahmed A; Portis JL. 1987. Identification of two forms of an endogenous murine retroviral env gene linked to the Rmcf locus. J Virol 61(1):29-34. [PubMed: 3023705]  [MGI Ref ID J:8497]

Buller RS; Sitbon M; Portis JL. 1988. The endogenous mink cell focus-forming (MCF) gp70 linked to the Rmcf gene restricts MCF virus replication in vivo and provides partial resistance to erythroleukemia induced by Friend murine leukemia virus. J Exp Med 167(5):1535-46. [PubMed: 2835418]  [MGI Ref ID J:27618]

Frankel WN; Stoye JP; Taylor BA; Coffin JM. 1989. Genetic identification of endogenous polytropic proviruses by using recombinant inbred mice. J Virol 63(9):3810-21. [PubMed: 2547997]  [MGI Ref ID J:9925]

Hartley JW; Yetter RA; Morse HC 3d. 1983. A mouse gene on chromosome 5 that restricts infectivity of mink cell focus-forming recombinant murine leukemia viruses. J Exp Med 158(1):16-24. [PubMed: 6306133]  [MGI Ref ID J:7108]

Jung YT; Lyu MS; Buckler-White A; Kozak CA. 2002. Characterization of a polytropic murine leukemia virus proviral sequence associated with the virus resistance gene Rmcf of DBA/2 mice. J Virol 76(16):8218-24. [PubMed: 12134027]  [MGI Ref ID J:78083]

Kozak CA. 1985. Susceptibility of wild mouse cells to exogenous infection with xenotropic leukemia viruses: control by a single dominant locus on chromosome 1. J Virol 55(3):690-5. [PubMed: 2991590]  [MGI Ref ID J:7951]

Rowe WP; Hartley JW. 1983. Genes affecting mink cell focus-inducing (MCF) murine leukemia virus infection and spontaneous lymphoma in AKR F1 hybrids. J Exp Med 158(2):353-64. [PubMed: 6224881]  [MGI Ref ID J:7175]

Tyr^c related

Bharti K; Liu W; Csermely T; Bertuzzi S; Arnheiter H. 2008. Alternative promoter use in eye development: the complex role and regulation of the transcription factor MITF. Development 135(6):1169-78. [PubMed: 18272592]  [MGI Ref ID J:132153]

Chen J; Reifsnyder PC; Scheuplein F; Schott WH; Mileikovsky M; Soodeen-Karamath S; Nagy A; Dosch MH; Ellis J; Koch-Nolte F; Leiter EH. 2005. 'Agouti NOD': identification of a CBA-derived Idd locus on Chromosome 7 and its use for chimera production with NOD embryonic stem cells. Mamm Genome 16(10):775-83. [PubMed: 16261419]  [MGI Ref ID J:102639]

Coleman DL. 1962. Effect of genic substitution on the incorporation of tyrosine into the melanin of mouse skin. Arch Biochem Biophys 96:562-8. [PubMed: 13880466]  [MGI Ref ID J:12173]

Detlefsen JA. 1921. A new mutation in the house mouse Am Naturalist 55:469-73.  [MGI Ref ID J:34484]

Dickie MM. 1966. Platinum Mouse News Lett 34:30.  [MGI Ref ID J:13442]

Guillery RW. 1974. Visual pathways in albinos. Sci Am 230(5):44-54. [PubMed: 4822986]  [MGI Ref ID J:5436]

Hearing VJ; Phillips P; Lutzner MA. 1973. The fine structure of melanogenesis in coat color mutants of the mouse. J Ultrastruct Res 43(1):88-106. [PubMed: 4634048]  [MGI Ref ID J:5346]

Hegmann JP; Kieso RA; Hartman HB. 1974. Gene differences influencing visual system function and behavior. Behav Genet 4(2):165-70. [PubMed: 4842093]  [MGI Ref ID J:5470]

Jackson IJ; Bennett DC. 1990. Identification of the albino mutation of mouse tyrosinase by analysis of an in vitro revertant. Proc Natl Acad Sci U S A 87(18):7010-4. [PubMed: 2119500]  [MGI Ref ID J:40223]

Jeffery G; Schutz G; Montoliu L. 1994. Correction of abnormal retinal pathways found with albinism by introduction of a functional tyrosinase gene in transgenic mice. Dev Biol 166(2):460-4. [PubMed: 7813769]  [MGI Ref ID J:22320]

Juriloff DM; Harris MJ; Wong V; Miller JE. 1992. Studies of a spontaneous lethal mutation at the albino locus in SELH/Bc mice. Genome 35(2):342-6. [PubMed: 1618394]  [MGI Ref ID J:62]

Karst SY; Ward-Bailey PF; Smith R; Washburn L; Bergstrom D; Johnson KR; Donahue LR; Davisson MT. 2009. Chick Yellow: a new mutation on Chromosome 3 causing eye and coat color phenotypes MGI Direct Data Submission :.  [MGI Ref ID J:149273]

Mouse Genome Informatics (MGI). 2005. Information obtained from the Oak Ridge National Laboratory Mutant Mouse Database (ORNL), Oak Ridge, TN (http://bio.lsd.ornl.gov/mouse/) :.  [MGI Ref ID J:100221]

Moyer FH. 1966. Genetic variations in the fine structure and ontogeny of mouse melanin granules. Am Zool 6(1):43-66. [PubMed: 5902512]  [MGI Ref ID J:5001]

Qiao JH; Welch CL; Xie PZ; Fishbein MC; Lusis AJ. 1993. Involvement of the tyrosinase gene in the deposition of cardiac lipofuscin in mice. Association with aortic fatty streak development. J Clin Invest 92(5):2386-93. [PubMed: 8227355]  [MGI Ref ID J:15460]

Rios M; Habecker B; Sasaoka T; Eisenhofer G; Tian H; Landis S ; Chikaraishi D ; Roffler-Tarlov S. 1999. Catecholamine synthesis is mediated by tyrosinase in the absence of tyrosine hydroxylase. J Neurosci 19(9):3519-26. [PubMed: 10212311]  [MGI Ref ID J:54692]

Russell LB; Hunsicker PR; Cacheiro NL; Rinchik EM. 1992. Genetic, cytogenetic, and molecular analyses of mutations induced by melphalan demonstrate high frequencies of heritable deletions and other rearrangements from exposure of postspermatogonial stages of the mouse. Proc Natl Acad Sci U S A 89(13):6182-6. [PubMed: 1352884]  [MGI Ref ID J:24557]

SILVERS WK. 1958. Origin and identity of clear cells found in hair bulbs of albino mice. Anat Rec 130(2):135-44. [PubMed: 13545569]  [MGI Ref ID J:30725]

Silvers WK. 1956. Pigment cells: occurrence in hair follicles. J Morphol 99:41-55.  [MGI Ref ID J:13092]

Sweet HO. 1987. Acromelanic (c<a>) Mouse News Lett 78:56.  [MGI Ref ID J:14994]

Thiessen DD; Lindzey G; Owen K. 1970. Behavior and allelic variations in enzyme activity and coat color at the C locus of the mouse. Behav Genet 1(3):257-67. [PubMed: 5005683]  [MGI Ref ID J:5360]

Townsend D; Witkop CJ Jr; Mattson J. 1981. Tyrosinase subcellular distribution and kinetic parameters in wild type and C-locus mutant C57BL/6J mice. J Exp Zool 216(1):113-9. [PubMed: 6793688]  [MGI Ref ID J:6611]

Tyler PA. 1970. Coat color differences and runway learning in mice. Behav Genet 1(2):149-55. [PubMed: 5527659]  [MGI Ref ID J:5378]

Wakamatsu K; Hirobe T; Ito S. 2007. High levels of melanin-related metabolites in plasma from pink-eyed dilution mice. Pigment Cell Res 20(3):222-4. [PubMed: 17516930]  [MGI Ref ID J:148667]

Yokoyama T; Silversides DW; Waymire KG; Kwon BS; Takeuchi T; Overbeek PA. 1990. Conserved cysteine to serine mutation in tyrosinase is responsible for the classical albino mutation in laboratory mice. Nucleic Acids Res 18(24):7293-8. [PubMed: 2124349]  [MGI Ref ID J:10889]

Health & husbandry

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Currently there no information available for this strain. This may be due to the supply level of this strain.

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Cryopreserved. Ready for recovery. Please refer to pricing and supply notes for further information.

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Cryorecovery - Standard. We will fulfill your order by providing at least two pair of mice, at least one animal of each pair carrying the mutation of interest. The total number of animals provided, their gender and genotype will vary. Please inquire if larger numbers of animals with specific genotype and genders are needed. Animals typically ship between 13 and 16 weeks from the date of your order. If a second cryorecovery is needed in order to provide the minimum number of animals, animals will ship within 25 weeks. IMPORTANT NOTE: The genotypes of animals provided may not reflect the mating scheme utilized by The Jackson Laboratory prior to cryopreservation, or that discussed in the strain description. Please inquire about possible genotypes which will be recovered for this specific strain. The Jackson Laboratory cannot guarantee the reproductive success of mice shipped to your facility. If the mice are lost after the first three days (post-arrival) or do not produce progeny at your facility, a new order and fee will be necessary. Cryorecovery to establish a Dedicated Supply for greater quantities of mice. Mice recovered can be used to establish a dedicated colony to contractually supply you mice according to your requirements. Price by quotation. For more information on Dedicated Supply, please contact JAX® Services, Tel: 1-800-422-6423 (from U.S.A., Canada or Puerto Rico only) or 1-207-288-5845 (from any location). Genomic DNA is available for this strain from the Mouse DNA Resource.

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The Jackson Laboratory has rigorous genetic quality control and mutant gene genotyping programs to ensure the genetic background of JAX^® Mice strains as well as the genotypes of strains with identified molecular mutations. JAX^® Mice strains are only made available to researchers after meeting our standards. However, the phenotype of each strain may not be fully characterized and/or captured in the strain data sheets. Therefore, we cannot guarantee a strain's phenotype will meet all expectations. To ensure that JAX^® Mice will meet the needs of individual research projects or when requesting a strain that is new to your research, we suggest ordering and performing tests on a small number of mice to determine suitability for your particular project.

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