| scholarly article | Q13442814 |
| P50 | author | Joseph Takahashi | Q6287342 |
| Zhijian Chen | Q8070836 | ||
| Prof Vivek Kumar | Q40668871 | ||
| P2093 | author name string | Hee-Kyung Hong | |
| Xinran Liu | |||
| Seung-Hee Yoo | |||
| Ming Xu | |||
| Carla B Green | |||
| Sandra M Siepka | |||
| Zheng Chen | |||
| Nobuya Koike | |||
| Yongli Shan | |||
| Jennifer A Mohawk | |||
| Seong Kwon Huh | |||
| Justin Nussbaum | |||
| Izabela Kornblum | |||
| P2860 | cites work | Post-translational modifications regulate the ticking of the circadian clock. | Q34605395 |
| Simultaneous visualization of multiple protein interactions in living cells using multicolor fluorescence complementation analysis | Q34648424 | ||
| Identification of a Novel Cryptochrome Differentiating Domain Required for Feedback Repression in Circadian Clock Function | Q36122122 | ||
| USP2a protein deubiquitinates and stabilizes the circadian protein CRY1 in response to inflammatory signals | Q36126977 | ||
| Visualization of molecular interactions by fluorescence complementation | Q36453786 | ||
| Genetics of Circadian Rhythms in Mammalian Model Organisms | Q37005459 | ||
| Forward genetic screens to identify circadian rhythm mutants in mice | Q37131758 | ||
| Methods to record circadian rhythm wheel running activity in mice | Q37164636 | ||
| A ubiquitin replacement strategy in human cells reveals distinct mechanisms of IKK activation by TNFalpha and IL-1beta. | Q37425442 | ||
| Kinetochore dynein generates a poleward pulling force to facilitate congression and full chromosome alignment | Q40097772 | ||
| PER-TIM interactions in living Drosophila cells: an interval timer for the circadian clock | Q40330425 | ||
| Ubiquitylation of the amino terminus of Myc by SCF(β-TrCP) antagonizes SCF(Fbw7)-mediated turnover | Q42820389 | ||
| Tuning the period of the mammalian circadian clock: additive and independent effects of CK1εTau and Fbxl3Afh mutations on mouse circadian behavior and molecular pacemaking. | Q48319530 | ||
| Cubism and the cell cycle: the many faces of the APC/C | Q48529643 | ||
| Proteolysis: anytime, any place, anywhere? | Q48550111 | ||
| Preferred in vivo ubiquitination sites | Q50771337 | ||
| Identification of a family of human F-box proteins | Q22010703 | ||
| Nucleocytoplasmic shuttling and mCRY-dependent inhibition of ubiquitylation of the mPER2 clock protein | Q24292430 | ||
| SCFFbxl3 controls the oscillation of the circadian clock by directing the degradation of cryptochrome proteins | Q24304073 | ||
| FBXL21 Regulates Oscillation of the Circadian Clock through Ubiquitination and Stabilization of Cryptochromes | Q24321496 | ||
| A noncanonical E-box enhancer drives mouse Period2 circadian oscillations in vivo | Q24556686 | ||
| Systematic analysis and nomenclature of mammalian F-box proteins | Q24561715 | ||
| PERIOD2::LUCIFERASE real-time reporting of circadian dynamics reveals persistent circadian oscillations in mouse peripheral tissues | Q24568134 | ||
| Setting clock speed in mammals: the CK1 epsilon tau mutation in mice accelerates circadian pacemakers by selectively destabilizing PERIOD proteins | Q24629727 | ||
| Differential regulation of mammalian period genes and circadian rhythmicity by cryptochromes 1 and 2 | Q24672297 | ||
| Feedback repression is required for mammalian circadian clock function | Q24680543 | ||
| Posttranslational Mechanisms Regulate the Mammalian Circadian Clock | Q27863710 | ||
| Role of the CLOCK protein in the mammalian circadian mechanism | Q27867710 | ||
| The orphan nuclear receptor REV-ERBalpha controls circadian transcription within the positive limb of the mammalian circadian oscillator | Q28216502 | ||
| Positional cloning of the mouse circadian clock gene | Q28238809 | ||
| Circadian mutant Overtime reveals F-box protein FBXL3 regulation of cryptochrome and period gene expression | Q28509189 | ||
| AMPK regulates the circadian clock by cryptochrome phosphorylation and degradation | Q28509385 | ||
| Delay in feedback repression by cryptochrome 1 is required for circadian clock function | Q28512076 | ||
| BMAL1-dependent circadian oscillation of nuclear CLOCK: posttranslational events induced by dimerization of transcriptional activators of the mammalian clock system | Q28584828 | ||
| Mammalian Cry1 and Cry2 are essential for maintenance of circadian rhythms | Q28584936 | ||
| The after-hours mutant reveals a role for Fbxl3 in determining mammalian circadian period | Q28594339 | ||
| Visualization of interactions among bZIP and Rel family proteins in living cells using bimolecular fluorescence complementation | Q29616037 | ||
| Central and peripheral circadian clocks in mammals | Q29616556 | ||
| Circadian integration of metabolism and energetics | Q29619638 | ||
| Intercellular coupling confers robustness against mutations in the SCN circadian clock network | Q30543329 | ||
| Inducible and reversible Clock gene expression in brain using the tTA system for the study of circadian behavior | Q33275305 | ||
| Implication of the F-Box Protein FBXL21 in circadian pacemaker function in mammals | Q33379609 | ||
| Regulation of circadian behaviour and metabolism by REV-ERB-α and REV-ERB-β | Q34264573 | ||
| Ratchets and clocks: the cell cycle, ubiquitylation and protein turnover | Q34277719 | ||
| Speed control: cogs and gears that drive the circadian clock | Q34285136 | ||
| p53 post-translational modification: deregulated in tumorigenesis | Q34300569 | ||
| Utilization of a whole genome SNP panel for efficient genetic mapping in the mouse | Q34483116 | ||
| P433 | issue | 5 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | cytoplasm | Q79899 |
| circadian rhythm | Q208353 | ||
| Cryptochrome 1 (photolyase-like) | Q14866013 | ||
| Period circadian clock 2 | Q15323263 | ||
| F-box and leucine-rich repeat protein 3 | Q15323488 | ||
| F-box and leucine-rich repeat protein 21 | Q21498159 | ||
| Cryptochrome 2 (photolyase-like) | Q21499186 | ||
| P304 | page(s) | 1091-1105 | |
| P577 | publication date | 2013-02-01 | |
| P1433 | published in | Cell | Q655814 |
| P1476 | title | Competing E3 ubiquitin ligases govern circadian periodicity by degradation of CRY in nucleus and cytoplasm | |
| P478 | volume | 152 |
| Q33585833 | A Cryptochrome 2 mutation yields advanced sleep phase in humans |
| Q35783557 | A Novel Bmal1 Mutant Mouse Reveals Essential Roles of the C-Terminal Domain on Circadian Rhythms |
| Q38242190 | A central role for ubiquitination within a circadian clock protein modification code |
| Q58725605 | A novel photic entrainment mechanism for the circadian clock in an insect: involvement of and s |
| Q42200145 | Ammonia-lowering activities and carbamoyl phosphate synthetase 1 (Cps1) induction mechanism of a natural flavonoid |
| Q53078281 | An evolutionary hotspot defines functional differences between CRYPTOCHROMES. |
| Q39021800 | Animal Cryptochromes: Divergent Roles in Light Perception, Circadian Timekeeping and Beyond |
| Q89224112 | Autophagy Regulates the Liver Clock and Glucose Metabolism by Degrading CRY1 |
| Q93340232 | Biallelic variants in FBXL3 cause intellectual disability, delayed motor development and short stature |
| Q34544579 | CRY2 and FBXL3 Cooperatively Degrade c-MYC. |
| Q30370484 | CUL4-DDB1-CDT2 E3 Ligase Regulates the Molecular Clock Activity by Promoting Ubiquitination-Dependent Degradation of the Mammalian CRY1 |
| Q36893551 | Calorie restriction regulates circadian clock gene expression through BMAL1 dependent and independent mechanisms. |
| Q28541855 | Cell type-specific functions of period genes revealed by novel adipocyte and hepatocyte circadian clock models |
| Q27687867 | Chemical chronobiology: Toward drugs manipulating time |
| Q39338008 | Chromatin Dynamics of Circadian Transcription |
| Q35699594 | Chromatin landscape and circadian dynamics: Spatial and temporal organization of clock transcription |
| Q37017288 | Circadian Amplitude Regulation via FBXW7-Targeted REV-ERBα Degradation |
| Q35691235 | Circadian Clock Gene CRY2 Degradation Is Involved in Chemoresistance of Colorectal Cancer. |
| Q37083936 | Circadian Profiling of the Arabidopsis Proteome Using 2D-DIGE |
| Q90310156 | Circadian clock genes and the transcriptional architecture of the clock mechanism |
| Q37475253 | Circadian clock-dependent and -independent rhythmic proteomes implement distinct diurnal functions in mouse liver. |
| Q26863154 | Circadian genomics reveal a role for post-transcriptional regulation in mammals |
| Q35657123 | Circadian metabolism in the light of evolution |
| Q30581156 | Circadian pacemaking in cells and circuits of the suprachiasmatic nucleus. |
| Q98471395 | Circadian regulation of chemotherapy-induced peripheral neuropathic pain and the underlying transcriptomic landscape |
| Q38844421 | Circadian regulation of lipid metabolism |
| Q28390852 | Circadian regulation of metabolism |
| Q38126764 | Circadian rhythms, skeletal muscle molecular clocks, and exercise |
| Q34454032 | Circadian rhythms, the molecular clock, and skeletal muscle |
| Q34460462 | Circadian rhythms. Decoupling circadian clock protein turnover from circadian period determination |
| Q37699510 | Clock-Enhancing Small Molecules and Potential Applications in Chronic Diseases and Aging |
| Q28080676 | Coupling circadian rhythms of metabolism and chromatin remodelling |
| Q41059627 | Criticality and Adaptivity in Enzymatic Networks. |
| Q35156678 | DNA damage shifts circadian clock time via Hausp-dependent Cry1 stabilization |
| Q41438450 | Delayed Cryptochrome Degradation Asymmetrically Alters the Daily Rhythm in Suprachiasmatic Clock Neuron Excitability |
| Q47644252 | Design Principles of Phosphorylation-Dependent Timekeeping in Eukaryotic Circadian Clocks |
| Q51793703 | Development and Therapeutic Potential of Small-Molecule Modulators of Circadian Systems |
| Q35905811 | Dual attenuation of proteasomal and autophagic BMAL1 degradation in Clock Δ19/+ mice contributes to improved glucose homeostasis |
| Q28248138 | Dual modes of CLOCK:BMAL1 inhibition mediated by Cryptochrome and Period proteins in the mammalian circadian clock |
| Q28249506 | Emerging models for the molecular basis of mammalian circadian timing |
| Q89402889 | Emerging relevance of circadian rhythms in headaches and neuropathic pain |
| Q27010130 | Evolving roles of circadian rhythms in liver homeostasis and pathology |
| Q26785368 | F-box protein interactions with the hallmark pathways in cancer |
| Q33652788 | FAD Regulates CRYPTOCHROME Protein Stability and Circadian Clock in Mice |
| Q24321496 | FBXL21 Regulates Oscillation of the Circadian Clock through Ubiquitination and Stabilization of Cryptochromes |
| Q92609296 | Forward genetic approach for behavioral neuroscience using animal models |
| Q98465762 | Genome-Wide Identification of Apple Ubiquitin SINA E3 Ligase and Functional Characterization of MdSINA2 |
| Q38846253 | Highly Efficient Genome Editing via CRISPR/Cas9 to Create Clock Gene Knockout Cells |
| Q36071773 | HnRNP Q Has a Suppressive Role in the Translation of Mouse Cryptochrome1. |
| Q43044922 | In vivo role of phosphorylation of cryptochrome 2 in the mouse circadian clock |
| Q38218231 | Interactive features of proteins composing eukaryotic circadian clocks |
| Q26765492 | Interdependence of nutrient metabolism and the circadian clock system: Importance for metabolic health |
| Q50608185 | Investigation of genetic variants in ubiquitin enzyme genes involved in the modulation of neurodevelopmental processes: a role in schizophrenia susceptibility? |
| Q41269902 | Involvement of posttranscriptional regulation of Clock in the emergence of circadian clock oscillation during mouse development. |
| Q60310158 | JMJD5 links CRY1 function and proteasomal degradation |
| Q36134420 | KPNB1 mediates PER/CRY nuclear translocation and circadian clock function |
| Q36472428 | Label-free quantitative analysis of the casein kinase 2-responsive phosphoproteome of the marine minimal model species Ostreococcus tauri |
| Q37346900 | Mammalian Period represses and de-represses transcription by displacing CLOCK-BMAL1 from promoters in a Cryptochrome-dependent manner |
| Q28080813 | Manipulating the circadian and sleep cycles to protect against metabolic disease |
| Q37307464 | Mechanisms and function of substrate recruitment by F-box proteins. |
| Q38654326 | Memory Takes Time |
| Q47663049 | Meta-analysis of transcriptomic datasets identifies genes enriched in the mammalian circadian pacemaker. |
| Q34408902 | Metabolic and nontranscriptional circadian clocks: eukaryotes |
| Q28587594 | Metastasis-associated protein 1 is an integral component of the circadian molecular machinery |
| Q54977501 | Metformin and AMP Kinase Activation Increase Expression of the Sterol Transporters ABCG5/8 (ATP-Binding Cassette Transporter G5/G8) With Potential Antiatherogenic Consequences. |
| Q28082125 | Molecular components of the circadian clock in mammals |
| Q91452385 | Molecular mechanisms and physiological importance of circadian rhythms |
| Q38968773 | Molecular modulators of the circadian clock: lessons from flies and mice |
| Q37145166 | Muscle-specific loss of Bmal1 leads to disrupted tissue glucose metabolism and systemic glucose homeostasis |
| Q93085962 | Neurogenetic basis for circadian regulation of metabolism by the hypothalamus |
| Q41066859 | Oligomerization of SCFTIR1 Is Essential for Aux/IAA Degradation and Auxin Signaling in Arabidopsis |
| Q42608943 | Period2 3'-UTR and microRNA-24 regulate circadian rhythms by repressing PERIOD2 protein accumulation. |
| Q58606720 | Periodicity, repression, and the molecular architecture of the mammalian circadian clock |
| Q41161152 | Phosphorylation Regulating the Ratio of Intracellular CRY1 Protein Determines the Circadian Period |
| Q28590815 | Phosphorylation of the cryptochrome 1 C-terminal tail regulates circadian period length |
| Q26750780 | Post-transcriptional control of the mammalian circadian clock: implications for health and disease |
| Q39066281 | Regulating the Suprachiasmatic Nucleus (SCN) Circadian Clockwork: Interplay between Cell-Autonomous and Circuit-Level Mechanisms. |
| Q37168364 | Regulation of circadian clocks by redox homeostasis |
| Q37664744 | Regulation of histone modifying enzymes by the ubiquitin-proteasome system |
| Q36069161 | Reprogramming of the circadian clock by nutritional challenge. |
| Q38920788 | Rhythmic control of mRNA stability modulates circadian amplitude of mouse Period3 mRNA. |
| Q35012352 | Roles of F-box proteins in cancer |
| Q39743125 | SCFFbl12 Increases p21Waf1/Cip1 Expression Level through Atypical Ubiquitin Chain Synthesis |
| Q97643945 | SIRT7 couples light-driven body temperature cues to hepatic circadian phase coherence and gluconeogenesis |
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| Q38133856 | Solving the mystery of human sleep schedules one mutation at a time |
| Q37571135 | Spatiotemporal separation of PER and CRY posttranslational regulation in the mammalian circadian clock |
| Q47440454 | Stability of Wake-Sleep Cycles Requires Robust Degradation of the PERIOD Protein. |
| Q37289330 | Substrate binding promotes formation of the Skp1-Cul1-Fbxl3 (SCF(Fbxl3)) protein complex |
| Q37348759 | Synchronized human skeletal myotubes of lean, obese and type 2 diabetic patients maintain circadian oscillation of clock genes |
| Q33573675 | Systems Chronotherapeutics |
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| Q46198633 | The Blue Light-Dependent Polyubiquitination and Degradation of Arabidopsis Cryptochrome2 Requires Multiple E3 Ubiquitin Ligases |
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| Q92647937 | The NRON complex controls circadian clock function through regulated PER and CRY nuclear translocation |
| Q33720405 | The Role of the Molecular Clock in Skeletal Muscle and What It Is Teaching Us About Muscle-Bone Crosstalk. |
| Q40204797 | The Small Molecule Nobiletin Targets the Molecular Oscillator to Enhance Circadian Rhythms and Protect against Metabolic Syndrome. |
| Q41720395 | The genomic landscape of human cellular circadian variation points to a novel role for the signalosome. |
| Q39030572 | The intricate dance of post-translational modifications in the rhythm of life |
| Q49827006 | The mammalian circadian system: a hierarchical multi-oscillator structure for generating circadian rhythm. |
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