Differential regulation of mammalian period genes and circadian rhythmicity by cryptochromes 1 and 2
Martha Vitaterna
1999
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An evolutionary hotspot defines functional differences between CRYPTOCHROMES
Carla Green
Nature communications, 2018
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Phosphorylation of the Cryptochrome 1 C-terminal Tail Regulates Circadian Period Length
Joseph S Takahashi
Journal of Biological Chemistry, 2013
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Circadian Amplitude of Cryptochrome 1 Is Modulated by mRNA Stability Regulation via Cytoplasmic hnRNP D Oscillation
Dae-cheong Ha (하대청)
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Cryptochromes and the Circadian Clock: The Story of a Very Complex Relationship in a Spinning World
Carlo Fasano
Genes
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Author response: Molecular assembly of the period-cryptochrome circadian transcriptional repressor complex
Joseph S Takahashi
2014
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Post-translational regulation of circadian transcriptional CLOCK (NPAS2)/BMAL1 complex by CRYPTOCHROMES
Roman Kondratov
Cell Cycle, 2006
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Conserved amino acid residues in C-terminus of PERIOD 2 are involved in interaction with CRYPTOCHROME 1
Norio Ishida
Biochimica et Biophysica Acta (BBA) - Molecular Cell Research, 2010
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Nuclear Localization and Transcriptional Repression Are Confined to Separable Domains in the Circadian Protein CRYPTOCHROME
Carla Green
Current Biology, 2003
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Structure Function Analysis of Mammalian Cryptochromes
Inês Chaves
Cold Spring Harbor Symposia on Quantitative Biology, 2007
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Molecular assembly of the period-cryptochrome circadian transcriptional repressor complex
Carla Green, Joseph S Takahashi
eLife, 2014
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Structure and Function of Animal Cryptochromes
Dongping Zhong
Cold Spring Harbor Symposia on Quantitative Biology, 2007
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The mammalian circadian clock protein period counteracts cryptochrome in phosphorylation dynamics of circadian locomotor output cycles kaput (CLOCK)
Isao Tokuda
The Journal of biological chemistry, 2014
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Functional and Structural Analyses of Cryptochrome
Takeshi Todo
Journal of Biological Chemistry, 2003
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Structure/Function Analysis of Xenopus Cryptochromes 1 and 2 Reveals Differential Nuclear Localization Mechanisms and Functional Domains Important for Interaction with and Repression of CLOCK-BMAL1
Carla Green
Molecular and Cellular Biology, 2007
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The Cryptochrome1 (cry1) Gene has Oscillating Expression Under Short and Long Photoperiods inSesamia nonagrioides
Anna Kourti
International Journal of Molecular and Theoretical Physics
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Identification of a New Cryptochrome Class
Takeshi Todo
Molecular Cell, 2003
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Identification of a New Cryptochrome ClassStructure, Function, and Evolution
John Tainer
Molecular Cell, 2003
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Cryptochromes and biological clocks.
V. R. Bhagwat
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In vivo role of phosphorylation of cryptochrome 2 in the mouse circadian clock
Takeshi Todo
Molecular and cellular biology, 2014
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Drosophila CRYPTOCHROME Is a Circadian Transcriptional Repressor
Ralf Stanewsky
Current Biology, 2006
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Interacting molecular loops in the mammalian circadian clock
Inês Chaves
Science, 2000
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Cryptochrome-Deficient Mice Lack Circadian Electrical Activity in the Suprachiasmatic Nuclei
Gijsbertus Van Der Horst, Inês Chaves
Current Biology, 2002
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Functional and Structural Analyses of Cryptochrome: VERTEBRATE CRY REGIONS RESPONSIBLE FOR INTERACTION WITH THE CLOCK:BMAL1 HETERODIMER AND ITS NUCLEAR LOCALIZATION
Jun Hirayama
Journal of Biological Chemistry, 2003
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Delayed Cryptochrome Degradation Asymmetrically Alters the Daily Rhythm in Suprachiasmatic Clock Neuron Excitability
Mino Belle
The Journal of Neuroscience, 2017
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Structures of Drosophila Cryptochrome and Mouse Cryptochrome1 Provide Insight into Circadian Function
Anna Czarna
Cell, 2013
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Circadian Mutant Overtime Reveals F-box Protein FBXL3 Regulation of Cryptochrome and Period Gene Expression
vivek kumar
Cell, 2007
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cryptochrome genes form an oscillatory loop independent of the per/tim loop in the circadian clockwork of the cricket Gryllus bimaculatus
Kenji Tomioka
Zoological letters, 2017
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Advanced analysis of a cryptochrome mutation's effects on the robustness and phase of molecular cycles in isolated peripheral tissues of Drosophila
Pablo Funes
BMC neuroscience, 2002
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