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Search results 3801 to 3900 out of 8814 for Clock

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Type Details Score
Protein
F7DEN0
Organism: Mus musculus/domesticus
Length: 112  
Fragment?: true
Publication
11152681 | -
First Author: Rho J
Year: 2001
Journal: J Biol Chem
Title: Prmt5, which forms distinct homo-oligomers, is a member of the protein-arginine methyltransferase family.
Volume: 276
Issue: 14
Pages: 11393-401
Publication
11278267 | -
First Author: Bao S
Year: 2001
Journal: J Biol Chem
Title: The highly conserved protein methyltransferase, Skb1, is a mediator of hyperosmotic stress response in the fission yeast Schizosaccharomyces pombe.
Volume: 276
Issue: 18
Pages: 14549-52
Publication
10903903 | -
First Author: Lee JH
Year: 2000
Journal: Biochem Biophys Res Commun
Title: Hsl7p, the yeast homologue of human JBP1, is a protein methyltransferase.
Volume: 274
Issue: 1
Pages: 105-11
Publication
17363895 | -
First Author: Wang X
Year: 2007
Journal: EMBO J
Title: SKB1-mediated symmetric dimethylation of histone H4R3 controls flowering time in Arabidopsis.
Volume: 26
Issue: 7
Pages: 1934-41
Publication
22269951 | -
First Author: Bandyopadhyay S
Year: 2012
Journal: Mol Cell Biol
Title: HOXA9 methylation by PRMT5 is essential for endothelial cell expression of leukocyte adhesion molecules.
Volume: 32
Issue: 7
Pages: 1202-13
Publication
8499615 | -
First Author: Reimmann C
Year: 1993
Journal: Plant Mol Biol
Title: Circadian rhythmicity in the expression of a novel light-regulated rice gene.
Volume: 22
Issue: 1
Pages: 165-70
Publication
26941088 | -
First Author: Yang C
Year: 2016
Journal: Plant Cell
Title: LIGHT-INDUCED RICE1 Regulates Light-Dependent Attachment of LEAF-TYPE FERREDOXIN-NADP+ OXIDOREDUCTASE to the Thylakoid Membrane in Rice and Arabidopsis.
Volume: 28
Issue: 3
Pages: 712-28
Publication
16703358 | -
First Author: Canamero RC
Year: 2006
Journal: Planta
Title: Cryptochrome photoreceptors cry1 and cry2 antagonistically regulate primary root elongation in Arabidopsis thaliana.
Volume: 224
Issue: 5
Pages: 995-1003
Publication
20133010 | -
First Author: Zeng J
Year: 2010
Journal: J Plant Physiol
Title: Arabidopsis cryptochrome-1 restrains lateral roots growth by inhibiting auxin transport.
Volume: 167
Issue: 8
Pages: 670-3
Publication
18988809 | -
First Author: Liu H
Year: 2008
Journal: Science
Title: Photoexcited CRY2 interacts with CIB1 to regulate transcription and floral initiation in Arabidopsis.
Volume: 322
Issue: 5907
Pages: 1535-9
Publication
26839287 | -
 
First Author: Huang H
Year: 2016
Journal: Elife
Title: PCH1 integrates circadian and light-signaling pathways to control photoperiod-responsive growth in Arabidopsis.
Volume: 5
Pages: e13292
Protein Domain
IPR014133 | Cry_DASH
Type: Family
Description: The cryptochrome and photolyase families consist of structurally related flavin adenine dinucleotide (FAD) proteins that use the absorption of blue light to accomplish different tasks. The photolyasess use the blue light for light-driven electron transfer to repair UV-damaged DNA, while the cryptochromes are blue-light photoreceptors involved in the circadian clock for plants and animals [, ].This entry represents a branch of the photolyase/cryptochrome family that is known as the cryptochrome-DASH family (Cry-DASH). The Cry-DASH family members have been shown to act as photolyases with high degree of specificity for cyclobutane pyrimidine dimers in ssDNA [].
Protein Domain
IPR014134 | Cryptochrome_pln
Type: Family
Description: The cryptochrome and photolyase families consist of structurally related flavin adenine dinucleotide (FAD) proteins that use the absorption of blue light to accomplish different tasks. The photolyasess use the blue light for light-driven electron transfer to repair UV-damaged DNA, while the cryptochromes are blue-light photoreceptors involved in the circadian clock for plants and animals [, ].Members of this subfamily are from plants; they appear mostly to be regulatory proteins that respond to blue light. For instance, Arabidopsis cryptochromes Cry1 and Cry2 antagonistically regulate primary root elongation [, ]. Cry2 is also reported to interact with CIB1 and regulate transcription and floral initiation [].
Protein Domain
IPR038528 | TEL2_C_sf
Type: Homologous_superfamily
Description: This entry represents a conserved domain found in a group of proteins called telomere-length regulation TEL2, or clock abnormal protein-2, which are conserved from plants to humans. These proteins regulate telomere length and contribute to silencing of sub-telomeric regions []. In vitro the protein binds to telomeric DNA repeats. Tel2 acts at an early step of the TEL1/ATM pathway of DNA damage signaling []. The structure of Tel2 consists of HEAT-like helical repeats that assemble into two separate α-solenoids []. This entry represents the C-terminal solenoid which consists of eleven helices.
Protein Domain
IPR010624 | KaiC_dom
Type: Domain
Description: This entry represents a domain within bacterial and archaeal proteins, most of which are hypothetical. More than one copy is sometimes found in each protein in this entry. These include KaiC, which is one of the Kai proteins among which direct protein-protein association may be a critical process in the generation of circadian rhythms in cyanobacteria [].The circadian clock protein KaiC, is encoded in the kaiABC operon that controls circadian rhythms and may be universal inCyanobacteria. Each member contains two copies of this domain, which is alsofound in other proteins. KaiC performs autophosphorylation and acts as its own transcriptional repressor.
Protein Domain
IPR012942 | SRR1-like
Type: Domain
Description: This domain is found in SRR1-like proteins.SRR1 are signalling proteins thought to be involved in regulating the circadian clock input pathway, which is required for normal oscillator function. In Arabidopsis thaliana it regulates the expression of clock-regulated genes such as CCA1 and TOC1. It is also involved in both the phytochrome B (PHYB) and PHYB-independent signaling pathways []. The mouse homologue of the plant circadian-regulating protein SRR1 plays roles in heme-regulated circadian rhythms and cell proliferation [].The yeast SRR1-like protein Ber1 is involved in microtubule stability [].
Protein Domain
IPR009523 | Prokineticin
Type: Family
Description: The prokineticin family includes prokinectin itself and related proteins such as BM8 and the AVIToxins. The suprachiasmatic nucleus (SCN) controls the circadian rhythm of physiological and behavioural processes in mammals. It has been shown that prokineticin 2 (PK2), a cysteine-rich secreted protein, functions as an output molecule from the SCN circadian clock. PK2 messenger RNA is rhythmically expressed in the SCN, and the phase of PK2 rhythm is responsive to light entrainment. Molecular and genetic studies have revealed that PK2 is a gene that is controlled by a circadian clock [].
Protein Domain
IPR009856 | Lir1
Type: Family
Description: This family consists of several plant specific light regulated Lir1 proteins. Lir1 mRNA accumulates in the light, reaching maximum and minimum steady-state levels at the end of the light and dark period, respectively. Plants germinated in the dark have very low levels of lir1 mRNA, whereas plants germinated in continuous light express lir1 at an intermediate but constant level. It is thought that lir1 expression is controlled by light and a circadian clock []. Lir1 interacts with LEAF-TYPE Ferredoxin-NADP(+) oxidoreductase (LFNR), an essential chloroplast enzyme functioning in the last step of photosynthetic linear electron transfer, and forms a thylakoid protein complex with LFNR, TIC62 and TROL [].
Protein Domain
IPR007857 | Arg_MeTrfase_PRMT5
Type: Family
Description: This entry represents a group of arginine N-methyltransferases, including Skb1 from S. pombe [], Hsl7 from S. cerevisiae []and their homologues PRMT5 from animals [, , ]and plants []. Skb1 is a mediator of hyperosmotic stress response in Schizosaccharomyces pombe []. Plant PMRT15 is involved in the post-transcriptional regulation of the circadian clock []. Human PRMT5 is a component of multiple protein complexes and contributes to essential cellular processes, such as RNA transport and splicing, cell cycle regulation, tumour growth, and chromatin remodelling, leading to either gene silencing or activation [].
Protein Domain
IPR040044 | SRR1L
Type: Family
Description: This entry includes the plant Sensitivity To Red Light Reduced proteins (SRR1), yeast SRR1-like protein Ber1 and mammalian homologue SRR1 domain containing (SRRD) protein.SRR1 are signalling proteins thought to be involved in regulating the circadian clock input pathway, which is required for normal oscillator function. In Arabidopsis thaliana it regulates the expression of clock-regulated genes such as CCA1 and TOC1. It is also involved in both the phytochrome B (PHYB) and PHYB-independent signaling pathways []. The mouse homologue of the plant circadian-regulating protein SRR1 plays roles in heme-regulated circadian rhythms and cell proliferation [].The yeast SRR1-like protein Ber1 is involved in microtubule stability [].
Protein Domain
IPR037476 | PCH1
Type: Family
Description: In plants, a photoreceptor called phytochrome B (phyB) responds to red light and regulates the ability of plants to grow. PCH1 (At2g16365) regulates photoperiod-responsive growth by integrating the plant clock with light perception pathways. PCH1 stabilizes the structure of phyB so that it remains active, even in the dark. This prolonged activity acts as a molecular memory of prior exposure to light and helps to prevent plants from growing too much in the winter, when there are fewer hours of daylight. PCH1 is also found in other species of plants [].
Protein Domain
IPR035075 | PRMT5
Type: Domain
Description: This entry represents a domain found in arginine-N-methyltransferase PRMT5. Proteins containing this domain include Skb1 from S. pombe [], Hsl7 from S. cerevisiae []and their homologues PRMT5 from animals [, , ]and plants [].Skb1 is a mediator of hyperosmotic stress response in Schizosaccharomyces pombe []. Plant PMRT15 is involved in the post-transcriptional regulation of the circadian clock []. Human PRMT5 is a component of multiple protein complexes and contributes to essential cellular processes, such as RNA transport and splicing, cell cycle regulation, tumour growth, and chromatin remodelling, leading to either gene silencing or activation [].
Protein Domain
IPR035247 | PRMT5_TIM
Type: Domain
Description: This entry represents the N-terminal TIM barrel domain of PRMT5.Proteins containing this domain includes Skb1 from S. pombe [], Hsl7 from S. cerevisiae []and their homologues PRMT5 from animals [, , ]and plants []. Skb1 is a mediator of hyperosmotic stress response in Schizosaccharomyces pombe []. Plant PMRT15 is involved in the post-transcriptional regulation of the circadian clock []. Human PRMT5 is a component of multiple protein complexes and contributes to essential cellular processes, such as RNA transport and splicing, cell cycle regulation, tumour growth, and chromatin remodelling, leading to either gene silencing or activation [].
Protein Domain
IPR035248 | PRMT5_C
Type: Domain
Description: This entry represents the C-terminal oligomerisation domain of PRMT5.Proteins containing this domain includes Skb1 from S. pombe [], Hsl7 from S. cerevisiae []and their homologues PRMT5 from animals [, , ]and plants []. Skb1 is a mediator of hyperosmotic stress response in Schizosaccharomyces pombe []. Plant PMRT15 is involved in the post-transcriptional regulation of the circadian clock []. Human PRMT5 is a component of multiple protein complexes and contributes to essential cellular processes, such as RNA transport and splicing, cell cycle regulation, tumour growth, and chromatin remodelling, leading to either gene silencing or activation [].
Publication
10508694 | J:58310
First Author: Pourquié O
Year: 1999
Journal: Curr Opin Genet Dev
Title: Notch around the clock.
Volume: 9
Issue: 5
Pages: 559-65
Publication
9169144 | J:40153
First Author: Jackson FR
Year: 1997
Journal: Genomics
Title: A novel zinc finger-containing RNA-binding protein conserved from fruitflies to humans.
Volume: 41
Issue: 3
Pages: 444-52
Publication
12451142 | J:80431
First Author: Wee R
Year: 2002
Journal: J Neurosci
Title: Loss of photic entrainment and altered free-running circadian rhythms in math5-/- mice.
Volume: 22
Issue: 23
Pages: 10427-33
Publication
20604961 | J:280079
 
First Author: Ruggiero L
Year: 2010
Journal: Behav Brain Funct
Title: Mice with early retinal degeneration show differences in neuropeptide expression in the suprachiasmatic nucleus.
Volume: 6
Pages: 36
Publication
25820768 | J:322990
First Author: Savalli G
Year: 2015
Journal: Amino Acids
Title: Anhedonic behavior in cryptochrome 2-deficient mice is paralleled by altered diurnal patterns of amygdala gene expression.
Volume: 47
Issue: 7
Pages: 1367-77
Publication
34954114 | J:319806
 
First Author: Oda Y
Year: 2022
Journal: Neurosci Lett
Title: Role of heterozygous and homozygous alleles in cryptochrome-deficient mice.
Volume: 772
Pages: 136415
Publication
30655559 | J:284022
First Author: Correia SP
Year: 2019
Journal: Sci Rep
Title: The circadian E3 ligase complex SCFFBXL3+CRY targets TLK2.
Volume: 9
Issue: 1
Pages: 198
Protein
Q14A28
Organism: Mus musculus/domesticus
Length: 105  
Fragment?: false
Protein
Q9QXU7
Organism: Mus musculus/domesticus
Length: 128  
Fragment?: false
Protein
Q8K2M3
Organism: Mus musculus/domesticus
Length: 249  
Fragment?: false
Protein
A0A0A6YY01
Organism: Mus musculus/domesticus
Length: 117  
Fragment?: true
Protein
G3X8R6
Organism: Mus musculus/domesticus
Length: 65  
Fragment?: false
Protein
Q14AB2
Organism: Mus musculus/domesticus
Length: 128  
Fragment?: false
Protein
F6Q7H5
Organism: Mus musculus/domesticus
Length: 349  
Fragment?: true
Publication
17062752 | -
First Author: Selby CP
Year: 2006
Journal: Proc Natl Acad Sci U S A
Title: A cryptochrome/photolyase class of enzymes with single-stranded DNA-specific photolyase activity.
Volume: 103
Issue: 47
Pages: 17696-700
Publication
11747464 | -
First Author: Okamoto OK
Year: 2001
Journal: Biochemistry
Title: Members of a dinoflagellate luciferase gene family differ in synonymous substitution rates.
Volume: 40
Issue: 51
Pages: 15862-8
Publication
15313603 | -
First Author: Vakonakis I
Year: 2004
Journal: J Mol Biol
Title: Structure of the N-terminal domain of the circadian clock-associated histidine kinase SasA.
Volume: 342
Issue: 1
Pages: 9-17
Publication
15014139 | -
First Author: Dvornyk V
Year: 2004
Journal: Mol Biol Evol
Title: Structure and molecular phylogeny of sasA genes in cyanobacteria: insights into evolution of the prokaryotic circadian system.
Volume: 21
Issue: 8
Pages: 1468-76
Publication
12449424 | -
First Author: Klewer DA
Year: 2002
Journal: J Biomol NMR
Title: Sequence-specific resonance assignments of the N-terminal, 105-residue KaiC-interacting domain of SasA, a protein necessary for a robust circadian rhythm in Synechococcus elongatus.
Volume: 24
Issue: 1
Pages: 77-8
Publication
18064466 | -
First Author: Fiechter V
Year: 2008
Journal: Curr Genet
Title: The evolutionary conserved BER1 gene is involved in microtubule stability in yeast.
Volume: 53
Issue: 2
Pages: 107-15
Protein Domain
IPR017944 | KaiA/RbsU_helical_domain_sf
Type: Homologous_superfamily
Description: This superfamily represents a structural domain consisting of four helices in a bundle with a right-handed superhelix. Homologous structural domains can be found in:The C-terminal domain of the circadian clock protein KaiAThe N-terminal domain of the phosphoserine phosphatase protein RsbUThe cyanobacterial clock proteins KaiA, KaiB and KaiC are proposed as regulators of the circadian rhythm in cyanobacteria. KaiA activates the expression of the kaiBC locus, while KaiC represses it. KaiA is composed of three functional domains: the N-terminal amplitude-amplifier domain, the central period-adjuster domain and the C-terminal clock-oscillator domain. The C-terminal domain is responsible for dimer formation, binding to KaiC, enhancing KaiC phosphorylation and generating the circadian oscillations []. The KaiA protein from Anabaena sp. (strain PCC 7120) lacks the N-terminal CheY-like domain.The phosphoserine phosphatase RsbU acts as a positive regulator of the general stress-response factor of Gram-positive organisms, sigma-B. RsbU dephosphorylates rsbV in response to environmental stress conveyed from the rsbXST module. The phosphatase activity of RsbU is stimulated during the stress response by associating with the RsbT kinase. This association leads to the induction of sigmaB activity. The N-terminal domain forms a helix-swapped dimer that is otherwise similar to the KaiA domain dimer. Deletions in the N-terminal domain are deleterious to the activity of RsbU. The C-terminal domain of RsbU is similar to the catalytic domains of PP2C-type phosphatases [].
Protein Domain
IPR011649 | KaiB_domain
Type: Domain
Description: The cyanobacterial clock proteins KaiA, KaiB and SasA are proposed as regulators of the circadian rhythm in cyanobacteria [, ]. Mutations in both proteins have been reported to alter or abolish circadian rhythmicity. KaiB adopts an α-β meander motif and is found to be a dimer []. KaiB was originally discovered from the cyanobacterium Synechococcus as part of the circadian clock gene cluster, kaiABC. KaiB attenuates KaiA-enhanced KaiC autokinase activity by interacting with KaiA-KaiC complexes in a circadian fashion [, ]. KaiB is membrane-associated as well as cytosolic. The amount of membrane-associated protein peaks in the evening (at circadian time (CT) 12-16) while the cytosolic form peaks later (at CT 20). The rhythmic localization of KaiB may function in regulating the formation of Kai complexes. SasA is a sensory histidine kinase which associates with KaiC []. Although it is not an essential oscillator component, it is important in enhancing kaiABC expression and is important in metabolic growth control under day/night cycle conditions. SasA contains an N-terminal sensory domain with a TRX fold which is involved in the SasA-KaiC interaction []. This domain shows high sequence similarity with KaiB []. However, the KaiB structure does not show a classical TRX fold. The N-terminal half of KaiB shares the same beta-α-β topology as TRX, but the topology of its C-terminal half diverges.
Publication
19036988 | J:142498
First Author: Sutton GM
Year: 2008
Journal: J Neurosci
Title: The melanocortin-3 receptor is required for entrainment to meal intake.
Volume: 28
Issue: 48
Pages: 12946-55
Publication
19188586 | J:146641
First Author: Ozturk N
Year: 2009
Journal: Proc Natl Acad Sci U S A
Title: Loss of cryptochrome reduces cancer risk in p53 mutant mice.
Volume: 106
Issue: 8
Pages: 2841-6
Publication
36866044 | J:336425
First Author: Hitrec T
Year: 2023
Journal: iScience
Title: Timed exercise stabilizes behavioral rhythms but not molecular programs in the brain's suprachiasmatic clock.
Volume: 26
Issue: 2
Pages: 106002
Publication
20023637 | J:157667
First Author: Doi M
Year: 2010
Journal: Nat Med
Title: Salt-sensitive hypertension in circadian clock-deficient Cry-null mice involves dysregulated adrenal Hsd3b6.
Volume: 16
Issue: 1
Pages: 67-74
Publication
28813682 | J:269829
First Author: Mauvoisin D
Year: 2017
Journal: Cell Rep
Title: Circadian and Feeding Rhythms Orchestrate the Diurnal Liver Acetylome.
Volume: 20
Issue: 7
Pages: 1729-1743
Publication
11114194 | J:66580
First Author: Selby CP
Year: 2000
Journal: Proc Natl Acad Sci U S A
Title: Functional redundancy of cryptochromes and classical photoreceptors for nonvisual ocular photoreception in mice.
Volume: 97
Issue: 26
Pages: 14697-702
HT Experiment
GSE79087 | REV-ERBalpha influences stability and nuclear localization of the glucocorticoid receptor
 
Experiment Type: RNA-Seq
Study Type: WT vs. Mutant
Source: GEO
Publication
24003036 | J:201649
First Author: Li Y
Year: 2013
Journal: Physiol Genomics
Title: Genome-wide analysis of the p53 gene regulatory network in the developing mouse kidney.
Volume: 45
Issue: 20
Pages: 948-64
Publication
23531614 | J:198214
First Author: Barclay JL
Year: 2013
Journal: Am J Physiol Endocrinol Metab
Title: High-fat diet-induced hyperinsulinemia and tissue-specific insulin resistance in Cry-deficient mice.
Volume: 304
Issue: 10
Pages: E1053-63
Publication
18545654 | J:137151
First Author: Hatori M
Year: 2008
Journal: PLoS One
Title: Inducible ablation of melanopsin-expressing retinal ganglion cells reveals their central role in non-image forming visual responses.
Volume: 3
Issue: 6
Pages: e2451
Publication
18648504 | J:138240
First Author: Rossner MJ
Year: 2008
Journal: PLoS One
Title: Disturbed clockwork resetting in Sharp-1 and Sharp-2 single and double mutant mice.
Volume: 3
Issue: 7
Pages: e2762
Publication
25340473 | J:222446
First Author: Baier PC
Year: 2014
Journal: PLoS One
Title: Mice lacking the circadian modulators SHARP1 and SHARP2 display altered sleep and mixed state endophenotypes of psychiatric disorders.
Volume: 9
Issue: 10
Pages: e110310
Publication
15893577 | J:101906
First Author: Iijima M
Year: 2005
Journal: Neurosci Res
Title: Altered food-anticipatory activity rhythm in Cryptochrome-deficient mice.
Volume: 52
Issue: 2
Pages: 166-73
Publication
21858120 | J:176363
First Author: Chaves I
Year: 2011
Journal: PLoS One
Title: The Potorous CPD photolyase rescues a cryptochrome-deficient mammalian circadian clock.
Volume: 6
Issue: 8
Pages: e23447
Publication
24344304 | J:206288
First Author: Mauvoisin D
Year: 2014
Journal: Proc Natl Acad Sci U S A
Title: Circadian clock-dependent and -independent rhythmic proteomes implement distinct diurnal functions in mouse liver.
Volume: 111
Issue: 1
Pages: 167-72
Publication
15331384 | J:95766
First Author: Nagashima K
Year: 2005
Journal: Am J Physiol Regul Integr Comp Physiol
Title: The involvement of Cry1 and Cry2 genes in the regulation of the circadian body temperature rhythm in mice.
Volume: 288
Issue: 1
Pages: R329-35
Publication
12121621 | J:77822
First Author: Albus H
Year: 2002
Journal: Curr Biol
Title: Cryptochrome-deficient mice lack circadian electrical activity in the suprachiasmatic nuclei.
Volume: 12
Issue: 13
Pages: 1130-3
Publication
24386234 | J:209844
First Author: Destici E
Year: 2013
Journal: PLoS One
Title: Altered phase-relationship between peripheral oscillators and environmental time in Cry1 or Cry2 deficient mouse models for early and late chronotypes.
Volume: 8
Issue: 12
Pages: e83602
Publication
18514517 | J:137722
First Author: Van der Zee EA
Year: 2008
Journal: Curr Biol
Title: Circadian time-place learning in mice depends on Cry genes.
Volume: 18
Issue: 11
Pages: 844-8
Publication
39880968 | J:361516
First Author: Tir S
Year: 2025
Journal: Sci Rep
Title: Evaluation of the Digital Ventilated Cage® system for circadian phenotyping.
Volume: 15
Issue: 1
Pages: 3674
Publication
17442820 | J:121103
First Author: Bando H
Year: 2007
Journal: J Neurosci
Title: Vagal regulation of respiratory clocks in mice.
Volume: 27
Issue: 16
Pages: 4359-65
Publication
24187535 | J:271349
 
First Author: De Bundel D
Year: 2013
Journal: Front Behav Neurosci
Title: Cognitive dysfunction, elevated anxiety, and reduced cocaine response in circadian clock-deficient cryptochrome knockout mice.
Volume: 7
Pages: 152
Publication
39278902 | J:354309
First Author: Steel LCE
Year: 2024
Journal: BMC Biol
Title: Light sampling behaviour regulates circadian entrainment in mice.
Volume: 22
Issue: 1
Pages: 208
Publication
10518585 | J:58114
First Author: Vitaterna MH
Year: 1999
Journal: Proc Natl Acad Sci U S A
Title: Differential regulation of mammalian period genes and circadian rhythmicity by cryptochromes 1 and 2.
Volume: 96
Issue: 21
Pages: 12114-9
Publication
17175102 | J:119093
First Author: Tanida M
Year: 2007
Journal: Neurosci Lett
Title: Autonomic and cardiovascular responses to scent stimulation are altered in cry KO mice.
Volume: 413
Issue: 2
Pages: 177-82
Publication
24782829 | J:288951
 
First Author: Griebel G
Year: 2014
Journal: Front Endocrinol (Lausanne)
Title: Mice deficient in cryptochrome 1 (cry1 (-/-)) exhibit resistance to obesity induced by a high-fat diet.
Volume: 5
Pages: 49
Publication
12696673 | J:81357
First Author: Van Gelder RN
Year: 2002
Journal: J Neurogenet
Title: Pleiotropic effects of cryptochromes 1 and 2 on free-running and light-entrained murine circadian rhythms.
Volume: 16
Issue: 3
Pages: 181-203
Publication
16061665 | J:100767
First Author: Gauger MA
Year: 2005
Journal: Cancer Res
Title: Cryptochrome, circadian cycle, cell cycle checkpoints, and cancer.
Volume: 65
Issue: 15
Pages: 6828-34
Publication
11818067 | J:73916
First Author: Froy O
Year: 2002
Journal: Curr Biol
Title: Redox potential: differential roles in dCRY and mCRY1 functions.
Volume: 12
Issue: 2
Pages: 147-52
Publication
19278294 | J:149749
First Author: Baggs JE
Year: 2009
Journal: PLoS Biol
Title: Network features of the mammalian circadian clock.
Volume: 7
Issue: 3
Pages: e52
Publication
24449901 | J:206573
First Author: St John PC
Year: 2014
Journal: Proc Natl Acad Sci U S A
Title: Spatiotemporal separation of PER and CRY posttranslational regulation in the mammalian circadian clock.
Volume: 111
Issue: 5
Pages: 2040-5
Publication
33473114 | J:301232
First Author: Butterfield NC
Year: 2021
Journal: Nat Commun
Title: Accelerating functional gene discovery in osteoarthritis.
Volume: 12
Issue: 1
Pages: 467
Publication
25910181 | -
First Author: Gindt YM
Year: 2015
Journal: Biochemistry
Title: Binding of Substrate Locks the Electrochemistry of CRY-DASH into DNA Repair.
Volume: 54
Issue: 18
Pages: 2802-5
Publication
26352435 | -
First Author: Mei Q
Year: 2015
Journal: PLoS One
Title: Evolutionary History of the Photolyase/Cryptochrome Superfamily in Eukaryotes.
Volume: 10
Issue: 9
Pages: e0135940
Publication
30523327 | J:279696
First Author: Masri S
Year: 2018
Journal: Nat Med
Title: The emerging link between cancer, metabolism, and circadian rhythms.
Volume: 24
Issue: 12
Pages: 1795-1803
Protein
O35710
Organism: Mus musculus/domesticus
Length: 429  
Fragment?: false
Protein
Q3UEU2
Organism: Mus musculus/domesticus
Length: 429  
Fragment?: false
Protein
B2RTJ8
Organism: Mus musculus/domesticus
Length: 429  
Fragment?: false
Protein Coding Gene
MGI:96397 | Id2
Type: protein_coding_gene
Organism: mouse, laboratory
Publication
25035422 | J:228603
 
First Author: Hatori M
Year: 2014
Journal: Elife
Title: Lhx1 maintains synchrony among circadian oscillator neurons of the SCN.
Volume: 3
Pages: e03357
Publication
27626074 | J:259079
First Author: Ono D
Year: 2016
Journal: Sci Adv
Title: Differential roles of AVP and VIP signaling in the postnatal changes of neural networks for coherent circadian rhythms in the SCN.
Volume: 2
Issue: 9
Pages: e1600960
Publication
17041588 | -
First Author: Higa LA
Year: 2006
Journal: Nat Cell Biol
Title: CUL4-DDB1 ubiquitin ligase interacts with multiple WD40-repeat proteins and regulates histone methylation.
Volume: 8
Issue: 11
Pages: 1277-83
Protein
H7BX89
Organism: Mus musculus/domesticus
Length: 534  
Fragment?: true
Protein
E9Q302
Organism: Mus musculus/domesticus
Length: 122  
Fragment?: true
Protein
Q812D7
Organism: Mus musculus/domesticus
Length: 264  
Fragment?: true
Publication
17709427 | -
First Author: Gonsalvez GB
Year: 2007
Journal: J Cell Biol
Title: Two distinct arginine methyltransferases are required for biogenesis of Sm-class ribonucleoproteins.
Volume: 178
Issue: 5
Pages: 733-40
Publication
7945373 | -
First Author: Veenstra JA
Year: 1994
Journal: Biochem Biophys Res Commun
Title: Isolation and structure of the Drosophila corazonin gene.
Volume: 204
Issue: 1
Pages: 292-6
Publication
15669053 | -
First Author: Choi YJ
Year: 2005
Journal: J Comp Neurol
Title: Comparative analysis of Corazonin-encoding genes (Crz's) in Drosophila species and functional insights into Crz-expressing neurons.
Volume: 482
Issue: 4
Pages: 372-85
Publication
17140699 | -
First Author: Predel R
Year: 2007
Journal: Peptides
Title: Corazonin in insects.
Volume: 28
Issue: 1
Pages: 3-10
Publication
16024659 | -
First Author: Horn PJ
Year: 2005
Journal: Genes Dev
Title: A Rik1-associated, cullin-dependent E3 ubiquitin ligase is essential for heterochromatin formation.
Volume: 19
Issue: 14
Pages: 1705-14
Publication
21959250 | -
First Author: Iovine B
Year: 2011
Journal: Int J Biochem Cell Biol
Title: Damage-specific DNA binding protein 1 (DDB1): a protein with a wide range of functions.
Volume: 43
Issue: 12
Pages: 1664-7
Publication
18551167 | -
First Author: Molinier J
Year: 2008
Journal: PLoS Genet
Title: Regulation and role of Arabidopsis CUL4-DDB1A-DDB2 in maintaining genome integrity upon UV stress.
Volume: 4
Issue: 6
Pages: e1000093
Publication
31998554 | -
 
First Author: Paffendorf BAM
Year: 2020
Journal: PeerJ
Title: TRANSPARENT TESTA GLABRA 1 participates in flowering time regulation in Arabidopsis thaliana.
Volume: 8
Pages: e8303




MouseMine is a collaboration between MGI at The Jackson Laboratory and the InterMine project at the Cambridge Systems Biology Centre. MouseMine is funded through a grant from the NIH/NHGRI.The Jackson Laboratory makes no representation about the suitability or accuracy of this software or data for any purpose, and makes no warranties, either express or implied, including merchantability and fitness for a particular purpose or that the use of this software or data will not infringe any third party patents, copyrights, trademarks, or other rights. the software and data are provided "as is". This software and data are provided to enhance knowledge and encourage progress in the scientific community and are to be used only for research and educational purposes. Any reproduction or use for commercial purpose is prohibited without the prior express written permission of the Jackson Laboratory.

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