Lineage-specific biology revealed by a finished genome assembly of the mouse.Church D.M., Goodstadt L., Hillier L.W., Zody M.C., Goldstein S., She X., Bult C.J., Agarwala R., Cherry J.L.[...], Ponting C.P.View abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]StrainC57BL/6JCategoriesSequencesSourceUniProtKB unreviewed (TrEMBL)PubMedEurope PMCPLoS Biol. 7:E1000112-E1000112 (2009)Cited in99+99+
Modernizing reference genome assemblies.Church D.M., Schneider V.A., Graves T., Auger K., Cunningham F., Bouk N., Chen H.C., Agarwala R., McLaren W.M.[...], Hubbard T.Cited forNUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]StrainC57BL/6JCategoriesSequencesSourceUniProtKB unreviewed (TrEMBL)PubMedEurope PMCPLoS Biol 9:e1001091-e1001091 (2011)Cited in99+
No title available.EnsemblCited forIDENTIFICATIONStrainC57BL/6JSourceUniProtKB unreviewed (TrEMBL)Submission Submitted to UniProtKB (JUN-2024)Cited in99+
Role of mouse cryptochrome blue-light photoreceptor in circadian photoresponses.Thresher R.J., Vitaterna M.H., Miyamoto Y., Kazantsev A., Hsu D.S., Petit C., Selby C.P., Dawut L., Smithies O.[...], Sancar A.View abstractCategoriesFunctionSourceMGI: 1270841PubMedEurope PMCScience 282:1490-1494 (1998)Mapped to4
Characterization of photolyase/blue-light receptor homologs in mouse and human cells.Kobayashi K., Kanno S., Smit B., van der Horst G.T.J., Takao M., Yasui A.View abstractCategoriesSequences, Subcellular LocationSourceMGI: 1270841PubMedEurope PMCNucleic Acids Res. 26:5086-5092 (1998)Cited in3Mapped to6
Vitamin B2-based blue-light photoreceptors in the retinohypothalamic tract as the photoactive pigments for setting the circadian clock in mammals.Miyamoto Y., Sancar A.View abstractCategoriesExpressionSourceMGI: 1270841PubMedEurope PMCProc. Natl. Acad. Sci. U.S.A. 95:6097-6102 (1998)Cited in1Mapped to8
Cloning, tissue expression, and mapping of a human photolyase homolog with similarity to plant blue-light receptors.van der Spek P.J., Kobayashi K., Bootsma D., Takao M., Eker A.P.M., Yasui A.View abstractCategoriesSequencesSourceMGI: 1270841PubMedEurope PMCGenomics 37:177-182 (1996)Cited in1Mapped to5
Bmal1 integrates circadian function and temperature sensing in the suprachiasmatic nucleus.Hoekstra M.M.B., Ness N., Badia-Soteras A., Brancaccio M.View abstractSourceMGI: 1270841PubMedEurope PMCProc Natl Acad Sci U S A 121:e2316646121-e2316646121 (2024)Mapped to9
Genetic determinants of micronucleus formation in vivo.Adams D.J., Barlas B., McIntyre R.E., Salguero I., van der Weyden L., Barros A., Vicente J.R., Karimpour N., Haider A.[...], White J.K.View abstractSourceMGI: 1270841PubMedEurope PMCNature 627:130-136 (2024)Mapped to99+
The circadian clock time tunes axonal regeneration.De Virgiliis F., Mueller F., Palmisano I., Chadwick J.S., Luengo-Gutierrez L., Giarrizzo A., Yan Y., Danzi M.C., Picon-Munoz C.[...], Di Giovanni S.View abstractCategoriesFunctionSourceMGI: 1270841PubMedEurope PMCCell Metab 35:2153-2164.e4 (2023)Mapped to9
<i>Cry1</i> expression during postnatal development is critical for the establishment of normal circadian period.Schirmer A.E., Kumar V., Schook A., Song E.J., Marshall M.S., Takahashi J.S.View abstractCategoriesFunctionSourceMGI: 1270841PubMedEurope PMCFront Neurosci 17:1166137-1166137 (2023)Mapped to4
Circadian rhythm of PERIOD2::LUCIFERASE expression in the trigeminal ganglion of mice.Shirakawa Y., Ohno S.N., Yamagata K.A., Kuramoto E., Oda Y., Nakamura T.J., Nakamura W., Sugimura M.View abstractSourceMGI: 1270841PubMedEurope PMCFront Neurosci 17:1142785-1142785 (2023)Mapped to5
Timed exercise stabilizes behavioral rhythms but not molecular programs in the brain's suprachiasmatic clock.Hitrec T., Petit C., Cryer E., Muir C., Tal N., Fustin J.M., Hughes A.T.L., Piggins H.D.View abstractCategoriesFunction, ExpressionSourceMGI: 1270841PubMedEurope PMCiScience 26:106002-106002 (2023)Mapped to8
A potential role of <i>p75NTR</i> in the regulation of circadian rhythm and incremental growth lines during tooth development.Yuan H., Xie B., Yu X., Lin C., Li M., Zhang Y., Zou X., Lu M., Zhao M., Wen X.View abstractCategoriesExpressionSourceMGI: 1270841PubMedEurope PMCFront Physiol 13:981311-981311 (2022)Mapped to62
Distinct phosphorylation states of mammalian CaMKIIbeta control the induction and maintenance of sleep.Tone D., Ode K.L., Zhang Q., Fujishima H., Yamada R.G., Nagashima Y., Matsumoto K., Wen Z., Yoshida S.Y.[...], Ueda H.R.View abstractCategoriesFunctionSourceMGI: 1270841PubMedEurope PMCPLoS Biol 20:e3001813-e3001813 (2022)Mapped to17
Neuronal Bmal1 regulates retinal angiogenesis and neovascularization in mice.Jidigam V.K., Sawant O.B., Fuller R.D., Wilcots K., Singh R., Lang R.A., Rao S.View abstractCategoriesFunction, ExpressionSourceMGI: 1270841PubMedEurope PMCCommun Biol 5:792-792 (2022)Mapped to35
Circadian protection against bacterial skin infection by epidermal CXCL14- mediated innate immunity.Tsujihana K., Tanegashima K., Santo Y., Yamada H., Akazawa S., Nakao R., Tominaga K., Saito R., Nishito Y.[...], Okamura H.View abstractSourceMGI: 1270841PubMedEurope PMCProc Natl Acad Sci U S A 119:e2116027119-e2116027119 (2022)Mapped to7
Hepatic GSK3beta-Dependent CRY1 Degradation Contributes to Diabetic Hyperglycemia.Kim Y.Y., Jang H., Lee G., Jeon Y.G., Sohn J.H., Han J.S., Lee W.T., Park J., Huh J.Y.[...], Kim J.B.View abstractCategoriesFunction, PTM / ProcessingSourceMGI: 1270841PubMedEurope PMCDiabetes 71:1373-1387 (2022)Mapped to8
P2Y1 purinergic receptor identified as a diabetes target in a small- molecule screen to reverse circadian beta-cell failure.Marcheva B., Weidemann B.J., Taguchi A., Perelis M., Ramsey K.M., Newman M.V., Kobayashi Y., Omura C., Manning Fox J.E.[...], Bass J.View abstractSourceMGI: 1270841PubMedEurope PMCElife 11:e75132-e75132 (2022)Mapped to15
Heart neurons use clock genes to control myocyte proliferation.Tampakakis E., Gangrade H., Glavaris S., Htet M., Murphy S., Lin B.L., Liu T., Saberi A., Miyamoto M.[...], Kwon C.View abstractCategoriesFunctionSourceMGI: 1270841PubMedEurope PMCSci Adv 7:eabh4181-eabh4181 (2021)Mapped to99+
CHRONO and DEC1/DEC2 compensate for lack of CRY1/CRY2 in expression of coherent circadian rhythm but not in generation of circadian oscillation in the neonatal mouse SCN.Ono D., Honma K.I., Schmal C., Takumi T., Kawamoto T., Fujimoto K., Kato Y., Honma S.View abstractCategoriesFunction, Phenotypes & VariantsSourceMGI: 1270841PubMedEurope PMCSci Rep 11:19240-19240 (2021)Mapped to19
Single-cell transcriptomics of suprachiasmatic nuclei reveal a Prokineticin-driven circadian network.Morris E.L., Patton A.P., Chesham J.E., Crisp A., Adamson A., Hastings M.H.View abstractSourceMGI: 1270841PubMedEurope PMCEMBO J 40:e108614-e108614 (2021)Mapped to13
Restoring the Molecular Clockwork within the Suprachiasmatic Hypothalamus of an Otherwise Clockless Mouse Enables Circadian Phasing and Stabilization of Sleep-Wake Cycles and Reverses Memory Deficits.Maywood E.S., Chesham J.E., Winsky-Sommerer R., Hastings M.H.View abstractCategoriesFunction, Expression, Phenotypes & VariantsSourceMGI: 1270841PubMedEurope PMCJ Neurosci 41:8562-8576 (2021)Mapped to4
A circadian clock regulates efflux by the blood-brain barrier in mice and human cells.Zhang S.L., Lahens N.F., Yue Z., Arnold D.M., Pakstis P.P., Schwarz J.E., Sehgal A.View abstractCategoriesFunction, ExpressionSourceMGI: 1270841PubMedEurope PMCNat Commun 12:617-617 (2021)Mapped to8
CRYPTOCHROMES confer robustness, not rhythmicity, to circadian timekeeping.Putker M., Wong D.C.S., Seinkmane E., Rzechorzek N.M., Zeng A., Hoyle N.P., Chesham J.E., Edwards M.D., Feeney K.A.[...], O'Neill J.S.View abstractCategoriesFunctionSourceMGI: 1270841PubMedEurope PMCEMBO J 40:e106745-e106745 (2021)Mapped to10