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

Type Congenic; Mutant Strain; Additional information on Genetically Engineered and Mutant Mice. Visit our online Nomenclature tutorial. Additional information on Congenic nomenclature. Species laboratory mouse Background Strain DBA/2J Donor Strain C57BL/6J Generation N20F31+7p (20-JUN-04)

Appearance
dilute brown
Related Genotype: a/a Tyrp1^b/Tyrp1^b Myo5a^d/Myo5a^d

Control Information

	Control
	000671 DBA/2J
Considerations for Choosing Controls

Related Strains

Strains carrying   Ahr^b-1 allele

000136	B6.C-H34c/(HW22)ByJ
000664	C57BL/6J
000669	C58/J
000351	CXB1/ByJ
000356	CXB6/ByJ
000677	MA/MyJ

View Strains carrying   Ahr^b-1     (6 strains)

Strains carrying other alleles of Ahr

000645	A/HeJ
000646	A/J
000648	AKR/J
002920	B6(D2N).Spretus-Ahrb-3/J
006203	B6.129(FVB)-Ahrtm3.1Bra/J
002831	B6.129-Ahrtm1Bra/J
000130	B6.C-H17c/(HW14)ByJ
000370	B6.C-H38c/(HW119)ByJ
002921	B6.D2N-Ahrd/J
002727	B6;129-Ahrtm1Bra/J
001026	BALB/cByJ
000659	C3H/HeJ
000926	CAROLI/EiJ
000352	CXB2/ByJ
000353	CXB3/ByJ
000354	CXB4/ByJ
000355	CXB5/ByJ
000357	CXB7/ByJ
000671	DBA/2J
000550	MOLF/EiJ
001146	SPRET/EiJ

View Strains carrying other alleles of Ahr     (21 strains)

Phenotype

Phenotype Information

View Mammalian Phenotype Terms

Mammalian Phenotype Terms

      assigned by genotype

The following phenotype information may relate to a genetic background differing from this JAX^® Mice strain.

Ahr^b-1/Ahr^b-1

        C57BL/6J

• life span-post-weaning/aging
• increased sensitivity to xenobiotic induced morbidity/mortality (MGI Ref ID J:26440)
  • mice are susceptible to DMBA induced lethality
• homeostasis/metabolism phenotype
• *normal* homeostasis/metabolism phenotype (MGI Ref ID J:5387)
  • topical application of the polycyclic hydrocarbon DMBA induced hepatic aryl hydrocarbon hydroxylase activity
• increased physiological sensitivity to xenobiotics (MGI Ref ID J:132380)
  • mice are susepctible to the teratogenic effects of TCDD with 100% of mice developing cleft palates and 90% of mice developing severe hydronephrosis
  • mice are susceptible to the pathological effects of DMBA and exhibit lethality, weight loss, peritonitis, decreased spleen weight, and decreased thymus weight
  • mice exposed to DMBA exhibit decreased lymphocyte counts, increased polymorphic cells, decreased bone marrow cell counts and ascites formation
• increased sensitivity to xenobiotic induced morbidity/mortality (MGI Ref ID J:26440)
  • mice are susceptible to DMBA induced lethality
• immune system phenotype
• increased inflammatory response (MGI Ref ID J:5244)
  • topical application of the polycyclic hydrocarbon DMBA produced skin inflammation and ulceration
  • topical application of DMBA produced skin inflammation and ulceration

Ahr^b-1/Ahr^b-1

        involves: C57BL/6J * DBA/2J

• homeostasis/metabolism phenotype
• *normal* homeostasis/metabolism phenotype (MGI Ref ID J:5387)
  • i.p. injection of the polycyclic hydrocarbon 3-methylcholanthrene induced hepatic aryl hydrocarbon hydroxylase activity unlike in strains homozygous for the unresponsive allele
• immune system phenotype
• abnormal immune system physiology (MGI Ref ID J:5387)
  • i.p. injection of the polycyclic hydrocarbon 3MC produced skin inflammation and skin ulcers

Ahr^b-1/Ahr^b-1

        C58/J

• life span-post-weaning/aging
• increased sensitivity to xenobiotic induced morbidity/mortality (MGI Ref ID J:26440)
  • mice are susceptible to DMBA induced lethality
• homeostasis/metabolism phenotype
• increased physiological sensitivity to xenobiotics (MGI Ref ID J:26440)
  • mice are susceptible to the pathological effects of DMBA and exhibit lethality, weight loss, peritonitis, decreased spleen weight, and decreased thymus weight
• increased sensitivity to xenobiotic induced morbidity/mortality (MGI Ref ID J:26440)
  • mice are susceptible to DMBA induced lethality

Ahr^b-1/Ahr^b-1

        C57BL/6

• life span-post-weaning/aging
• increased sensitivity to xenobiotic induced morbidity/mortality (MGI Ref ID J:113285)
  • mice exhibit neonatal lethality in response to in utero exposure to cHBB unlike mice homozygous for the Ahr^d allele
• homeostasis/metabolism phenotype
• increased physiological sensitivity to xenobiotics (MGI Ref ID J:113285)
  • when mice are fostered by control C57BL/6 dams following in utero exposure to cHBB, 21% of neonates survive
  • mice exhibit neonatal lethality in response to in utero exposure to cHBB and decreased thymus and spleen weights compared to untreated mice
  • following exposure to cHBB in utero, neonates exhibit an increase in volume density of hematopoietic islands in the liver
• increased sensitivity to xenobiotic induced morbidity/mortality (MGI Ref ID J:113285)
  • mice exhibit neonatal lethality in response to in utero exposure to cHBB unlike mice homozygous for the Ahr^d allele

View Research Applications

Research Applications

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

Ahr^b-1 related

Metabolism Research

Research Tools
Toxicology Research

Genes & Alleles

Gene & Allele Information

Allele Symbol		Ahrb-1
Allele Name		b-1 variant
Allele Type		Not Applicable
Common Name(s)		Ah; Ahb-1; Ahb; Ahhi; Ahrb; In;
Strain of Origin		C57BL/6J
Gene Symbol and Name		Ahr, aryl-hydrocarbon receptor
Chromosome		12
Gene Common Name(s)		Ah; Ahh; Ahre; In; aromatic hydrocarbon responsiveness; aryl hydrocarbon hydroxylase; bHLHe76; dioxin receptor; inflammatory reactivity;
General Note		C57BL/6 carries the responsive Ahrb allele; DBA/2 carries nonresponsive Ahrd. Heterozygotes (Ahrb/Ahrd) are responsive (J:5282). Later work identified a second (J:8895) and later a third (J:22144) allele conferring response. Thus the allele in C57, C58, and MA/My strains is now Ahrb-1; Ahrb-2 is carried by BALB/cBy, A, and C3H; and Ahrb-3 by Mus spretus, M. caroli, and MOLF/Ei. The nonresponsive strains AKR, DBA/2, and 129 carry Ahrd (J:22144). Nucleotide and amino acid sequence differences between Ahrb-1 and Ahrd have been determined (J:17460). Strain of origin - this allele was found in C57BL/6, C58/J, C57BR, MA/My strains
Molecular Note		This allele encodes a high affinity, relatively heat stabile, 95 kDa receptor. PCR sequencing of cDNA revealed ten nucleotide differences between the coding sequences of the DBA/2J and C57BL/6J receptors. Five of the ten differences would cause amino acid changes. One of these, a C to T transition in exon 11 would change the arginine codon in the DBA/2J allele to an opal termination codon in the C57BL/6J allele. This change would prevent the 43 amino acid extension of mRNA translation predicted for the DBA/2J allele and account for the smaller size of the peptide produced by this allele (95 kDa vs 104 kDa for the DBA/2J allele). A second C to T transition changes a proline codon in the DBA/2J allele to leucine codon in the C57BL/6J allele, and would likely change secondary structure of the peptide and thus ligand affinity. [MGI Ref ID J:15153] [MGI Ref ID J:17460] [MGI Ref ID J:477]

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

Additional References

Ahr^b-1 related

Benedict WF; Considine N; Nebert DW. 1973. Genetic differences in aryl hydrocarbon hydroxylase induction and benzo(a)pyrene-produced tumorigenesis in the mouse. Mol Pharmacol 9(2):266-77. [PubMed: 4123113]  [MGI Ref ID J:84312]

Boobis AR; Nebert DW. 1976. Genetic differences in the metabolism of carcinogens and in the binding of benzo (a) pyrene metabolites to DNA. Adv Enzyme Regul 15:339-62. [PubMed: 1030186]  [MGI Ref ID J:12156]

Bradfield CA; Glover E; Poland A. 1991. Purification and N-terminal amino acid sequence of the Ah receptor from the C57BL/6J mouse. Mol Pharmacol 39(1):13-9. [PubMed: 1846217]  [MGI Ref ID J:84440]

Burbach KM; Poland A; Bradfield CA. 1992. Cloning of the Ah-receptor cDNA reveals a distinctive ligand-activated transcription factor. Proc Natl Acad Sci U S A 89(17):8185-9. [PubMed: 1325649]  [MGI Ref ID J:2256]

Castro DJ; Lohr CV; Fischer KA; Pereira CB; Williams DE. 2008. Lymphoma and lung cancer in offspring born to pregnant mice dosed with dibenzo[a,l]pyrene: the importance of in utero vs. lactational exposure. Toxicol Appl Pharmacol 233(3):454-8. [PubMed: 18848954]  [MGI Ref ID J:143604]

Chang C; Smith DR; Prasad VS; Sidman CL; Nebert DW; Puga A. 1993. Ten nucleotide differences, five of which cause amino acid changes, are associated with the Ah receptor locus polymorphism of C57BL/6 and DBA/2 mice. Pharmacogenetics 3(6):312-21. [PubMed: 8148872]  [MGI Ref ID J:17460]

Curran CP; Miller KA; Dalton TP; Vorhees CV; Miller ML; Shertzer HG; Nebert DW. 2006. Genetic differences in lethality of newborn mice treated in utero with coplanar versus non-coplanar hexabromobiphenyl. Toxicol Sci 89(2):454-64. [PubMed: 16291824]  [MGI Ref ID J:113285]

Ema M; Sogawa K; Watanabe N; Chujoh Y; Matsushita N; Gotoh O; Funae Y; Fujii-Kuriyama Y. 1992. cDNA cloning and structure of mouse putative Ah receptor. Biochem Biophys Res Commun 184(1):246-53. [PubMed: 1314586]  [MGI Ref ID J:477]

Gielen JE; Goujon FM; Nebert DW. 1972. Genetic regulation of aryl hydrocarbon hydroxylase induction. II. Simple Mendelian expression in mouse tissues in vivo. J Biol Chem 247(4):1125-37. [PubMed: 4110756]  [MGI Ref ID J:84250]

Goujon FM; Nebert DW; Gielen JE. 1972. Genetic expression of aryl hydrocarbon hydroxylase induction. IV. Interaction of various compounds with different forms of cytochrome P-450 and the effect on benzo(a)pyrene metabolism in vitro. Mol Pharmacol 8(6):667-80. [PubMed: 4118365]  [MGI Ref ID J:84252]

Harper PA; Golas CL; Okey AB. 1991. Ah receptor in mice genetically nonresponsive for cytochrome P4501A1 induction: cytosolic Ah receptor, transformation to the nuclear binding state, and induction of aryl hydrocarbon hydroxylase by halogenated and nonhalogenated aromatic hydrocarbons in embryonic tissues and cells. Mol Pharmacol 40(5):818-26. [PubMed: 1658612]  [MGI Ref ID J:2134]

Kouri RE; Rude TH; Joglekar R; Dansette PM; Jerina DM; Atlas SA; Owens IS; Nebert DW. 1978. 2,3,7,8-tetrachlorodibenzo-p-dioxin as cocarcinogen causing 3-methylcholanthrene-initiated subcutaneous tumors in mice genetically 'nonresponsive' at Ah locus. Cancer Res 38(9):2777-83. [PubMed: 679184]  [MGI Ref ID J:84318]

Moriguchi T; Motohashi H; Hosoya T; Nakajima O; Takahashi S; Ohsako S; Aoki Y; Nishimura N; Tohyama C; Fujii-Kuriyama Y; Yamamoto M. 2003. Distinct response to dioxin in an arylhydrocarbon receptor (AHR)-humanized mouse. Proc Natl Acad Sci U S A 100(10):5652-7. [PubMed: 12730383]  [MGI Ref ID J:132380]

Nebert DW; Atlas SA; Guenthner TM; Kouri RE. 1978. The Ah locus: genetic regulation of the enzymes which metabolize polycyclic hydrocarbons and the risk of cancer. In: Polycyclic Hydrocarbons and Cancer: Chemistry, Molecular Biology and Environment. Academic Press, New York.  [MGI Ref ID J:30693]

Nebert DW; Considine N; Owens IS. 1973. Genetic expression of aryl hydrocarbon hydroxylase induction. VI. Control of other aromatic hydrocarbon-inducible mono-oxygenase activities at or near the same genetic locus. Arch Biochem Biophys 157(1):148-59. [PubMed: 4716952]  [MGI Ref ID J:84313]

Nebert DW; Gelboin HV. 1969. The in vivo and in vitro induction of aryl hydrocarbon hydroxylase in mammalian cells of different species, tissues, strains, and developmental and hormonal states. Arch Biochem Biophys 134(1):76-89. [PubMed: 4981257]  [MGI Ref ID J:84248]

Nebert DW; Gielen JE. 1972. Genetic regulation of aryl hydrocarbon hydroxylase induction in the mouse. Fed Proc 31(4):1315-25. [PubMed: 4114109]  [MGI Ref ID J:5282]

Nebert DW; Gielen JE; Goujon FM. 1972. Genetic expression of aryl hydrocarbon hydroxylase induction. 3. Changes in the binding of n-octylamine to cytochrome P-450. Mol Pharmacol 8(6):651-66. [PubMed: 4118364]  [MGI Ref ID J:84251]

Nebert DW; Goujon FM; Gielen JE. 1972. Aryl hydrocarbon hydroxylase induction by polycyclic hydrocarbons: simple autosomal dominant trait in the mouse. Nat New Biol 236(65):107-10. [PubMed: 4502804]  [MGI Ref ID J:84249]

Nebert DW; Robinson JR; Niwa A; Kumaki K; Poland AP. 1975. Genetic expression of aryl hydrocarbon hydroxylase activity in the mouse. J Cell Physiol 85(2 Pt 2 Suppl 1):393-414. [PubMed: 1091656]  [MGI Ref ID J:84317]

Niwa A; Kumaki K; Nebert DW; Poland AP. 1975. Genetic expression of aryl hydrocarbon hydroxylase activity in the mouse. Distinction between the 'responsive' homozygote and heterozygote at the Ah locus. Arch Biochem Biophys 166(2):559-64. [PubMed: 1119809]  [MGI Ref ID J:84316]

Okey AB; Vella LM; Harper PA. 1989. Detection and characterization of a low affinity form of cytosolic Ah receptor in livers of mice nonresponsive to induction of cytochrome P1-450 by 3-methylcholanthrene. Mol Pharmacol 35(6):823-30. [PubMed: 2543914]  [MGI Ref ID J:27899]

Poel WE; Stanton D; Peters E; Wade HO. 1958. Comparative susceptibilities of seven inbred strains of mice to qualified applications of 3, 4-benzpyrene Proc Am Assoc Cancer Res 2:335.  [MGI Ref ID J:84245]

Poland A; Bradfield C. 1992. A brief review of the Ah locus. Tohoku J Exp Med 168(2):83-7. [PubMed: 1339107]  [MGI Ref ID J:12546]

Poland A; Glover E. 1990. Characterization and strain distribution pattern of the murine Ah receptor specified by the Ahd and Ahb-3 alleles. Mol Pharmacol 38(3):306-12. [PubMed: 2169579]  [MGI Ref ID J:34840]

Poland A; Glover E; Kende AS. 1976. Stereospecific, high affinity binding of 2,3,7,8-tetrachlorodibenzo-p-dioxin by hepatic cytosol. Evidence that the binding species is receptor for induction of aryl hydrocarbon hydroxylase. J Biol Chem 251(16):4936-46. [PubMed: 956169]  [MGI Ref ID J:84247]

Poland A; Glover E; Taylor BA. 1987. The murine Ah locus: a new allele and mapping to chromosome 12. Mol Pharmacol 32(4):471-8. [PubMed: 2823093]  [MGI Ref ID J:8895]

Poland A; Palen D; Glover E. 1994. Analysis of the four alleles of the murine aryl hydrocarbon receptor. Mol Pharmacol 46(5):915-21. [PubMed: 7969080]  [MGI Ref ID J:22144]

Poland AP; Glover E; Robinson JR; Nebert DW. 1974. Genetic expression of aryl hydrocarbon hydroxylase activity. Induction of monooxygenase activities and cytochrome P1-450 formation by 2,3,7,8-tetrachlorodibenzo-p-dioxin in mice genetically 'nonresponsive' to other aromatic hydrocarbons. J Biol Chem 249(17):5599-606. [PubMed: 4370044]  [MGI Ref ID J:84314]

Robinson JR; Considine N; Nebert DW. 1974. Genetic expression of aryl hydrocarbon hydroxylase induction. Evidence for the involvement of other genetic loci. J Biol Chem 249(18):5851-9. [PubMed: 4413562]  [MGI Ref ID J:84315]

Schmid FA; Demetriades MS; Schabel FM rd; Tarnowski GS. 1967. Toxicity of several cancerigenic polycyclic hydrocarbons and other agents in AKR and C57BL-6 mice. Cancer Res 27(3):563-7. [PubMed: 6021514]  [MGI Ref ID J:84246]

Schmid FA; Elmer I; Tarnowski GS. 1969. Genetic determination of differential inflammatory reactivity and subcutaneous tumor susceptibility of AKR-J and C57BL-6J mice to 7,12-dimethylbenz- [a]anthracene. Cancer Res 29(8):1585-9. [PubMed: 5807232]  [MGI Ref ID J:34134]

Schmid FA; Pena RC; Robinson W; Tarnowski GS. 1967. Toxicity of intraperitoneal injections of 7, 12-dimethylbenz[a]anthracene in inbred mice. Cancer Res 27(3):558-62. [PubMed: 6021513]  [MGI Ref ID J:26440]

Schmidt JV; Carver LA; Bradfield CA. 1993. Molecular characterization of the murine Ahr gene. Organization, promoter analysis, and chromosomal assignment. J Biol Chem 268(29):22203-9. [PubMed: 8408082]  [MGI Ref ID J:15153]

Taylor BA. 1971. Strain distribution and linkage tests of 7,12-dimethylbenzanthracene (DMBA) inflammatory response in mice. Life Sci I 10(19):1127-34. [PubMed: 5132702]  [MGI Ref ID J:5244]

Thomas PE; Hutton JJ; Taylor BA. 1973. Genetic relationship between aryl hydrocarbon hydroxylase inducibility and chemical carcinogen induced skin ulceration in mice. Genetics 74(4):655-9. [PubMed: 4750810]  [MGI Ref ID J:5387]

Thomas PE; Kouri RE; Hutton JJ. 1972. The genetics of aryl hydrocarbon hydroxylase induction in mice: a single gene difference between C57BL-6J and DBA-2J. Biochem Genet 6(2):157-68. [PubMed: 4666754]  [MGI Ref ID J:31977]

Yu Z; Mahadevan B; Lohr CV; Fischer KA; Louderback MA; Krueger SK; Pereira CB; Albershardt DJ; Baird WM; Bailey GS; Williams DE. 2006. Indole-3-carbinol in the maternal diet provides chemoprotection for the fetus against transplacental carcinogenesis by the polycyclic aromatic hydrocarbon dibenzo[a,l]pyrene. Carcinogenesis 27(10):2116-23. [PubMed: 16704990]  [MGI Ref ID J:113356]

Health & husbandry

Health & Colony Maintenance Information

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

Purchasing information

Pricing, Supply Level & Notes, Controls, General Terms & Conditions

Pricing

Supply Details

Standard Supply

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

Supply Notes

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). This strain is included in the Mouse Mutant Resource collection. Genomic DNA is available for this strain from the Mouse DNA Resource.

Control Information

	Control
	000671 DBA/2J
Considerations for Choosing Controls
USA, Canada and Mexico - Control Pricing Information for Genetically Engineered Mutant Strains.
International - Control Pricing Information for Genetically Engineered Mutant Strains.

Payment Terms and Conditions

Terms are granted by individual review and stated on the customer invoice(s) and account statement. These transactions are payable in U.S. currency within the granted terms. Payment for services, products, shipping containers, and shipping costs that are rendered are expected within the payment terms indicated on the invoice or stated by contract. Invoices and account balances in arrears of stated terms may result in The Jackson Laboratory pursuing collection activities including but not limited to outside agencies and court filings.

See Terms of Use tab for General Terms and Conditions

The Jackson Laboratory's Genotype Promise

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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Ordering and Purchasing Information

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Tel: 1-800-422-6423 or 1-207-288-5845
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Terms of Use

Terms of Use

General Terms and Conditions

Contact information

General inquiries

Contracts Administration

phone:	207-288-6470
fax:	207-288-6655

JAX^® Mice, Products & Services Conditions of Use

"MICE" means mouse strains, their progeny derived by inbreeding or crossbreeding, unmodified derivatives from mouse strains or their progeny supplied by The Jackson Laboratory ("JACKSON"). "PRODUCTS" means biological materials supplied by JACKSON, and their derivatives. "RECIPIENT" means each recipient of MICE, PRODUCTS, or services provided by JACKSON including each institution, its employees and other researchers under its control. MICE or PRODUCTS shall not be: (i) used for any purpose other than the internal research, (ii) sold or otherwise provided to any third party for any use, or (iii) provided to any agent or other third party to provide breeding or other services. Acceptance of MICE or PRODUCTS from JACKSON shall be deemed as agreement by RECIPIENT to these conditions, and departure from these conditions requires JACKSON's prior written authorization.

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