Science 24 February 1995: Vol. 267. no. 5201, pp. 1161 - 1163 DOI: 10.1126/science.7855595

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Articles

Profile of Steve Kay.

B. Trivedi (2009)
PNAS 106, 18051-18053
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The significance of bolting and floral transitions as indicators of reproductive phase change in Arabidopsis.

S. Pouteau and C. Albertini (2009)
J. Exp. Bot. 60, 3367-3377
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A Role for Multiple Circadian Clock Genes in the Response to Signals That Break Seed Dormancy in Arabidopsis.

S. Penfield and A. Hall (2009)
PLANT CELL 21, 1722-1732
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Transcript Profiling of an Arabidopsis PSEUDO RESPONSE REGULATOR Arrhythmic Triple Mutant Reveals a Role for the Circadian Clock in Cold Stress Response.

N. Nakamichi, M. Kusano, A. Fukushima, M. Kita, S. Ito, T. Yamashino, K. Saito, H. Sakakibara, and T. Mizuno (2009)
Plant Cell Physiol. 50, 447-462
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Reconstruction of transcriptional dynamics from gene reporter data using differential equations.

B. Finkenstadt, E. A. Heron, M. Komorowski, K. Edwards, S. Tang, C. V. Harper, J. R. E. Davis, M. R. H. White, A. J. Millar, and D. A. Rand (2008)
Bioinformatics 24, 2901-2907
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Testing Time: Can Ethanol-Induced Pulses of Proposed Oscillator Components Phase Shift Rhythms in Arabidopsis?.

S. M. Knowles, S. X. Lu, and E. M. Tobin (2008)
J Biol Rhythms 23, 463-S 471
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Real-time luminescence monitoring of cell-cycle and respiratory oscillations in yeast.

J. B. Robertson, C. C. Stowers, E. Boczko, and C. Hirschie Johnson (2008)
PNAS 105, 17988-17993
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Two New Clock Proteins, LWD1 and LWD2, Regulate Arabidopsis Photoperiodic Flowering.

J.-F. Wu, Y. Wang, and S.-H. Wu (2008)
Plant Physiology 148, 948-959
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SENSITIVE TO FREEZING6 Integrates Cellular and Environmental Inputs to the Plant Circadian Clock.

H. Knight, A. J.W. Thomson, and H. G. McWatters (2008)
Plant Physiology 148, 293-303
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XAP5 CIRCADIAN TIMEKEEPER Coordinates Light Signals for Proper Timing of Photomorphogenesis and the Circadian Clock in Arabidopsis.

E. L. Martin-Tryon and S. L. Harmer (2008)
PLANT CELL 20, 1244-1259
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Disruption of the Arabidopsis Circadian Clock Is Responsible for Extensive Variation in the Cold-Responsive Transcriptome.

Z. Bieniawska, C. Espinoza, A. Schlereth, R. Sulpice, D. K. Hincha, and M. A. Hannah (2008)
Plant Physiology 147, 263-279
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FIONA1 Is Essential for Regulating Period Length in the Arabidopsis Circadian Clock.

J. Kim, Y. Kim, M. Yeom, J.-H. Kim, and H. G. Nam (2008)
PLANT CELL 20, 307-319
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PRR3 Is a Vascular Regulator of TOC1 Stability in the Arabidopsis Circadian Clock.

A. Para, E. M. Farre, T. Imaizumi, J. L. Pruneda-Paz, F. G. Harmon, and S. A. Kay (2007)
PLANT CELL 19, 3462-3473
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CIRCADIAN CLOCK ASSOCIATED1 Transcript Stability and the Entrainment of the Circadian Clock in Arabidopsis.

E. Yakir, D. Hilman, M. Hassidim, and R. M. Green (2007)
Plant Physiology 145, 925-932
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Move on up, it's time for change mobile signals controlling photoperiod-dependent flowering.

Y. Kobayashi and D. Weigel (2007)
Genes & Dev. 21, 2371-2384
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Bayesian inference for dynamic transcriptional regulation; the Hes1 system as a case study.

E. A. Heron, B. Finkenstadt, and D. A. Rand (2007)
Bioinformatics 23, 2596-2603
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A Functional Link between Rhythmic Changes in Chromatin Structure and the Arabidopsis Biological Clock.

M. Perales and P. Mas (2007)
PLANT CELL 19, 2111-2123
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Arabidopsis Clock-Associated Pseudo-Response Regulators PRR9, PRR7 and PRR5 Coordinately and Positively Regulate Flowering Time Through the Canonical CONSTANS-Dependent Photoperiodic Pathway.

N. Nakamichi, M. Kita, K. Niinuma, S. Ito, T. Yamashino, T. Mizoguchi, and T. Mizuno (2007)
Plant Cell Physiol. 48, 822-832
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ELF4 Is Required for Oscillatory Properties of the Circadian Clock.

H. G. McWatters, E. Kolmos, A. Hall, M. R. Doyle, R. M. Amasino, P. Gyula, F. Nagy, A. J. Millar, and S. J. Davis (2007)
Plant Physiology 144, 391-401
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Conservation, Convergence, and Divergence of Light-Responsive, Circadian-Regulated, and Tissue-Specific Expression Patterns during Evolution of the Arabidopsis GATA Gene Family.

I. W. Manfield, P. F. Devlin, C.-H. Jen, D. R. Westhead, and P. M. Gilmartin (2007)
Plant Physiology 143, 941-958
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GIGANTEA Acts in Blue Light Signaling and Has Biochemically Separable Roles in Circadian Clock and Flowering Time Regulation.

E. L. Martin-Tryon, J. A. Kreps, and S. L. Harmer (2007)
Plant Physiology 143, 473-486
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Plant circadian rhythms..

C. R. McClung (2006)
PLANT CELL 18, 792-803
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Analysis of Phase of LUCIFERASE Expression Reveals Novel Circadian Quantitative Trait Loci in Arabidopsis.

C. Darrah, B. L. Taylor, K. D. Edwards, P. E. Brown, A. Hall, and H. G. McWatters (2006)
Plant Physiology 140, 1464-1474
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Forward Genetic Analysis of the Circadian Clock Separates the Multiple Functions of ZEITLUPE.

E. Kevei, P. Gyula, A. Hall, L. Kozma-Bognar, W.-Y. Kim, M. E. Eriksson, R. Toth, S. Hanano, B. Feher, M. M. Southern, et al. (2006)
Plant Physiology 140, 933-945
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PHYTOCLOCK 1 encoding a novel GARP protein essential for the Arabidopsis circadian clock.

K. Onai and M. Ishiura (2005)
Genes Cells 10, 963-972
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Circadian Rhythm of Circumnutation in Inflorescence Stems of Arabidopsis.

K. Niinuma, N. Someya, M. Kimura, I. Yamaguchi, and H. Hamamoto (2005)
Plant Cell Physiol. 46, 1423-1427
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Circadian Control of Messenger RNA Stability. Association with a Sequence-Specific Messenger RNA Decay Pathway.

P. Lidder, R. A. Gutierrez, P. A. Salome, C. R. McClung, and P. J. Green (2005)
Plant Physiology 138, 2374-2385
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Plant Circadian Clocks Increase Photosynthesis, Growth, Survival, and Competitive Advantage.

A. N. Dodd, N. Salathia, A. Hall, E. Kevei, R. Toth, F. Nagy, J. M. Hibberd, A. J. Millar, and A. A. R. Webb (2005)
Science 309, 630-633
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LUX ARRHYTHMO encodes a Myb domain protein essential for circadian rhythms.

S. P. Hazen, T. F. Schultz, J. L. Pruneda-Paz, J. O. Borevitz, J. R. Ecker, and S. A. Kay (2005)
PNAS 102, 10387-10392
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Positive and Negative Factors Confer Phase-Specific Circadian Regulation of Transcription in Arabidopsis.

S. L. Harmer and S. A. Kay (2005)
PLANT CELL 17, 1926-1940
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Rapid Array Mapping of Circadian Clock and Developmental Mutations in Arabidopsis.

S. P. Hazen, J. O. Borevitz, F. G. Harmon, J. L. Pruneda-Paz, T. F. Schultz, M. J. Yanovsky, S. J. Liljegren, J. R. Ecker, and S. A. Kay (2005)
Plant Physiology 138, 990-997
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PSEUDO-RESPONSE REGULATOR 7 and 9 Are Partially Redundant Genes Essential for the Temperature Responsiveness of the Arabidopsis Circadian Clock.

P. A. Salome and C. R. McClung (2005)
PLANT CELL 17, 791-803
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Generation of Active Pools of Abscisic Acid Revealed by In Vivo Imaging of Water-Stressed Arabidopsis.

A. Christmann, T. Hoffmann, I. Teplova, E. Grill, and A. Muller (2005)
Plant Physiology 137, 209-219
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Circadian Rhythms of Ethylene Emission in Arabidopsis.

S. C. Thain, F. Vandenbussche, L. J.J. Laarhoven, M. J. Dowson-Day, Z.-Y. Wang, E. M. Tobin, F. J.M. Harren, A. J. Millar, and D. Van Der Straeten (2004)
Plant Physiology 136, 3751-3761
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The Arabidopsis thaliana Clock.

P. A. Salome and C. R. McClung (2004)
J Biol Rhythms 19, 425-435
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Functional Specialization amongst the Arabidopsis Toc159 Family of Chloroplast Protein Import Receptors.

S. Kubis, R. Patel, J. Combe, J. Bedard, S. Kovacheva, K. Lilley, A. Biehl, D. Leister, G. Rios, C. Koncz, et al. (2004)
PLANT CELL 16, 2059-2077
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The Molecular Basis of Diversity in the Photoperiodic Flowering Responses of Arabidopsis and Rice.

R. Hayama and G. Coupland (2004)
Plant Physiology 135, 677-684
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SPINDLY and GIGANTEA Interact and Act in Arabidopsis thaliana Pathways Involved in Light Responses, Flowering, and Rhythms in Cotyledon Movements.

T.-S. Tseng, P. A. Salome, C. R. McClung, and N. E. Olszewski (2004)
PLANT CELL 16, 1550-1563
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Multiple Pathways in the Decision to Flower: Enabling, Promoting, and Resetting.

P. K. Boss, R. M. Bastow, J. S. Mylne, and C. Dean (2004)
PLANT CELL 16, S18-S31
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CK2 phosphorylation of CCA1 is necessary for its circadian oscillator function in Arabidopsis.

X. Daniel, S. Sugano, and E. M. Tobin (2004)
PNAS 101, 3292-3297
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The F-Box Protein ZEITLUPE Confers Dosage-Dependent Control on the Circadian Clock, Photomorphogenesis, and Flowering Time.

D. E. Somers, W.-Y. Kim, and R. Geng (2004)
PLANT CELL 16, 769-782
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Characterization of Plant Circadian Rhythms by Employing Arabidopsis Cultured Cells with Bioluminescence Reporters.

N. Nakamichi, S. Ito, T. Oyama, T. Yamashino, T. Kondo, and T. Mizuno (2004)
Plant Cell Physiol. 45, 57-67
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Circadian Expression of the PpLhcb2 Gene Encoding a Major Light-Harvesting Chlorophyll a/b-Binding Protein in the Moss Physcomitrella patens.

S. Aoki, S. Kato, K. Ichikawa, and M. Shimizu (2004)
Plant Cell Physiol. 45, 68-76
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Circadian gene expression in mammalian fibroblasts revealed by real-time luminescence reporting: Temperature compensation and damping.

M. Izumo, C. H. Johnson, and S. Yamazaki (2003)
PNAS 100, 16089-16094
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Comparative Genetic Studies on the APRR5 and APRR7 Genes Belonging to the APRR1/TOC1 Quintet Implicated in Circadian Rhythm, Control of Flowering Time, and Early Photomorphogenesis.

Y. Yamamoto, E. Sato, T. Shimizu, N. Nakamich, S. Sato, T. Kato, S. Tabata, A. Nagatani, T. Yamashino, and T. Mizuno (2003)
Plant Cell Physiol. 44, 1119-1130
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Enhanced Fitness Conferred by Naturally Occurring Variation in the Circadian Clock.

T. P. Michael, P. A. Salome, H. J. Yu, T. R. Spencer, E. L. Sharp, M. A. McPeek, J. M. Alonso, J. R. Ecker, and C. R. McClung (2003)
Science 302, 1049-1053
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The TIME FOR COFFEE Gene Maintains the Amplitude and Timing of Arabidopsis Circadian Clocks.

A. Hall, R. M. Bastow, S. J. Davis, S. Hanano, H. G. McWatters, V. Hibberd, M. R. Doyle, S. Sung, K. J. Halliday, R. M. Amasino, et al. (2003)
PLANT CELL 15, 2719-2729
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Arabidopsis PSEUDO-RESPONSE REGULATOR7 Is a Signaling Intermediate in Phytochrome-Regulated Seedling Deetiolation and Phasing of the Circadian Clock.

K. A. Kaczorowski and P. H. Quail (2003)
PLANT CELL 15, 2654-2665
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The Novel MYB Protein EARLY-PHYTOCHROME-RESPONSIVE1 Is a Component of a Slave Circadian Oscillator in Arabidopsis.

N. Kuno, S. G. Moller, T. Shinomura, X. Xu, N.-H. Chua, and M. Furuya (2003)
PLANT CELL 15, 2476-2488
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Two Arabidopsis circadian oscillators can be distinguished by differential temperature sensitivity.

T. P. Michael, P. A. Salome, and C. R. McClung (2003)
PNAS 100, 6878-6883
 |  Abstract »  |  Full Text »  |  PDF »

Circadian phase-specific degradation of the F-box protein ZTL is mediated by the proteasome.

W.-Y. Kim, R. Geng, and D. E. Somers (2003)
PNAS 100, 4933-4938
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Cell Autonomous Circadian Waves of the APRR1/TOC1 Quintet in an Established Cell Line of Arabidopsis thaliana.

N. Nakamichi, A. Matsushika, T. Yamashino, and T. Mizuno (2003)
Plant Cell Physiol. 44, 360-365
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Dual Role of TOC1 in the Control of Circadian and Photomorphogenic Responses in Arabidopsis.

P. Mas, D. Alabadi, M. J. Yanovsky, T. Oyama, and S. A. Kay (2003)
PLANT CELL 15, 223-236
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Aberrant Expression of the Arabidopsis Circadian-Regulated APRR5 Gene Belonging to the APRR1/TOC1 Quintet Results in Early Flowering and Hypersensitiveness to Light in Early Photomorphogenesis.

E. Sato, N. Nakamichi, T. Yamashino, and T. Mizuno (2002)
Plant Cell Physiol. 43, 1374-1385
 |  Abstract »  |  Full Text »  |  PDF »

Phase-Specific Circadian Clock Regulatory Elements in Arabidopsis.

T. P. Michael and C. R. McClung (2002)
Plant Physiology 130, 627-638
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The Circadian Clock That Controls Gene Expression in Arabidopsis Is Tissue Specific.

S. C. Thain, G. Murtas, J. R. Lynn, Robert. B. McGrath, and A. J. Millar (2002)
Plant Physiology 130, 102-110
 |  Abstract »  |  Full Text »  |  PDF »

Aberrant Expression of the Light-Inducible and Circadian-Regulated APRR9 Gene Belonging to the Circadian-Associated APRR1/TOC1 Quintet Results in the Phenotype of Early Flowering in Arabidopsis thaliana.

A. Matsushika, A. Imamura, T. Yamashino, and T. Mizuno (2002)
Plant Cell Physiol. 43, 833-843
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The out of phase 1 Mutant Defines a Role for PHYB in Circadian Phase Control in Arabidopsis.

P. A. Salome, T. P. Michael, E. V. Kearns, A. G. Fett-Neto, R. A. Sharrock, and C. R. McClung (2002)
Plant Physiology 129, 1674-1685
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Signs of the time: environmental input to the circadian clock.

P. F. Devlin (2002)
J. Exp. Bot. 53, 1535-1550
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MYB transcription factors in the Arabidopsis circadian clock.

I. A. Carre and J.-Y. Kim (2002)
J. Exp. Bot. 53, 1551-1557
 |  Abstract »  |  Full Text »  |  PDF »

Control of Flowering Time: Interacting Pathways as a Basis for Diversity.

A. Mouradov, F. Cremer, and G. Coupland (2002)
PLANT CELL 14, S111-130
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The APRR1/TOC1 Quintet Implicated in Circadian Rhythms of Arabidopsis thaliana: I. Characterization with APRR1-Overexpressing Plants.

S. Makino, A. Matsushika, M. Kojima, T. Yamashino, and T. Mizuno (2002)
Plant Cell Physiol. 43, 58-69
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A Role for LKP2 in the Circadian Clock of Arabidopsis.

T. F. Schultz, T. Kiyosue, M. Yanovsky, M. Wada, and S. A. Kay (2001)
PLANT CELL 13, 2659-2670
 |  Abstract »  |  Full Text »  |  PDF »

Reciprocal Regulation Between TOC1 and LHY/CCA1 Within the Arabidopsis Circadian Clock.

D. Alabadi, T. Oyama, M. J. Yanovsky, F. G. Harmon, P. Mas, and S. A. Kay (2001)
Science 293, 880-883
 |  Abstract »  |  Full Text »  |  PDF »

shygrl1 Is a Mutant Affected in Multiple Aspects of Photomorphogenesis.

M. Santiago-Ong, R. M. Green, S. Tingay, J. A. Brusslan, and E. M. Tobin (2001)
Plant Physiology 126, 587-600
 |  Abstract »  |  Full Text »  |  PDF »

Evidence for Non-Circadian Light/Dark-Regulated Expression of Hsp70s in Spinach Leaves.

Q.-B. Li and C. L. Guy (2001)
Plant Physiology 125, 1633-1642
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Flower development pathways.

M. A. Blazquez (2001)
J. Cell Sci. 113, 3547-3548
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Light Response of the Circadian Waves of the APRR1/TOC1 Quintet: When Does the Quintet Start Singing Rhythmically in Arabidopsis?.

S. Makino, A. Matsushika, M. Kojima, Y. Oda, and T. Mizuno (2001)
Plant Cell Physiol. 42, 334-339
 |  Abstract »  |  Full Text »  |  PDF »

Fifty Years of Fun.

J. W. Hastings (2001)
J Biol Rhythms 16, 5-18
 |  PDF »

Microarray Analysis of Diurnal and Circadian-Regulated Genes in Arabidopsis.

R. Schaffer, J. Landgraf, M. Accerbi, V. Simon, M. Larson, and E. Wisman (2001)
PLANT CELL 13, 113-123
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Time for Plants. Progress in Plant Chronobiology.

S. S. Golden and C. Strayer (2001)
Plant Physiology 125, 98-101
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Circadian Waves of Expression of the APRR1/TOC1 Family of Pseudo-Response Regulators in Arabidopsis thaliana: Insight into the Plant Circadian Clock.

A. Matsushika, S. Makino, M. Kojima, and T. Mizuno (2000)
Plant Cell Physiol. 41, 1002-1012
 |  Abstract »  |  Full Text »  |  PDF »

Cloning of the Arabidopsis Clock Gene TOC1, an Autoregulatory Response Regulator Homolog.

C. Strayer, T. Oyama, T. F. Schultz, R. Raman, D. E. Somers, P. Más, S. Panda, J. A. Kreps, and S. A. Kay (2000)
Science 289, 768-771
 |  Abstract »  |  Full Text »

The protein kinase CK2 is involved in regulation of circadian rhythms in Arabidopsis.

S. Sugano, C. Andronis, M. S. Ong, R. M. Green, and E. M. Tobin (1999)
PNAS 96, 12362-12366
 |  Abstract »  |  Full Text »  |  PDF »

The Physiology and Molecular Bases of the Plant Circadian Clock.

D. E. Somers (1999)
Plant Physiology 121, 9-20
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Loss of the circadian clock-associated protein 1 in Arabidopsis results in altered clock-regulated gene expression.

R. M. Green and E. M. Tobin (1999)
PNAS 96, 4176-4179
 |  Abstract »  |  Full Text »  |  PDF »

How Temperature Changes Reset a Circadian Oscillator.

Y. Liu, M. Merrow, J. J. Loros, and J. C. Dunlap (1998)
Science 281, 825-829
 |  Abstract »  |  Full Text »

An Arabidopsis Mutant Hypersensitive to Red and Far-Red Light Signals.

T. Genoud, A. J. Millar, N. Nishizawa, S. A. Kay, E. Schäfer, A. Nagatani, and N.-H. Chua (1998)
PLANT CELL 10, 889-904
 |  Abstract »  |  Full Text »

The Suprachiasmatic Nucleus: A 25-Year Retrospective.

D. R. Weaver (1998)
J Biol Rhythms 13, 100-112
 |  Abstract »  |  PDF »

Conserved Regions of the timeless (tim) Clock Gene in Drosophila Analyzed Through Phylogenetic and Functional Studies.

A. Ousley, K. Zafarullah, Y. Chen, M. Emerson, L. Hickman, and A. Sehgal (1998)
Genetics 148, 815-826
 |  Abstract »  |  Full Text »  |  PDF »

The short-period mutant, toc1-1, alters circadian clock regulation of multiple outputs throughout development in Arabidopsis thaliana.

D. Somers, A. Webb, M Pearson, and S. Kay (1998)
Development 125, 485-494
 |  Abstract »  |  PDF »

AtGRP7, a nuclear RNA-binding protein as a component of a circadian-regulated negative feedback loop in Arabidopsis thaliana.

C. Heintzen, M. Nater, K. Apel, and D. Staiger (1997)
PNAS 94, 8515-8520
 |  Abstract »  |  Full Text »  |  PDF »

Quantitative Analysis of Drosophila period Gene Transcription in Living Animals.

J. D. Plautz, M. Straume, R. Stanewsky, C. F. Jamison, C. Brandes, H. B. Dowse, J. C. Hall, and S. A. Kay (1997)
J Biol Rhythms 12, 204-217
 |  Abstract »  |  PDF »

Isolation of timeless by PER Protein Interaction: Defective Interaction Between timeless Protein and Long-Period Mutant PER^L.

N. Gekakis, L. Saez, A.-M. Delahaye-Brown, M. P. Myers, A. Sehgal, M. W. Young, and C. J. Weitz (1995)
Science 270, 811-815
 |  Abstract »  |  PDF »

Plant genetics. Shedding light on the ticking of internal timekeepers.

M Barinaga (1995)
Science 267, 1091-1092
 |  PDF »

Blue Light Sensing in Higher Plants.

J. M. Christie and W. R. Briggs (2001)
J. Biol. Chem. 276, 11457-11460
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Photic and circadian expression of luciferase in mPeriod1-luc transgenic mice invivo.

L. D. Wilsbacher, S. Yamazaki, E. D. Herzog, E.-J. Song, L. A. Radcliffe, M. Abe, G. Block, E. Spitznagel, M. Menaker, and J. S. Takahashi (2002)
PNAS 99, 489-494
 |  Abstract »  |  Full Text »  |  PDF »

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