Science 17 September 1982: Vol. 217. no. 4565, pp. 1104 - 1111 DOI: 10.1126/science.6287576

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Articles

cAMP-Dependent Signaling as a Core Component of the Mammalian Circadian Pacemaker.

J. S. O'Neill, E. S. Maywood, J. E. Chesham, J. S. Takahashi, and M. H. Hastings (2008)
Science 320, 949-953
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The first fifty microarray studies in filamentous fungi.

A. Breakspear and M. Momany (2007)
Microbiology 153, 7-15
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A review of pediatric nonrespiratory sleep disorders..

M. Moore, D. Allison, and C. L. Rosen (2006)
Chest 130, 1252-1262
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Negative energy balance and leptin regulate neuromedin-U expression in the rat pars tuberalis..

R. Nogueiras, S. Tovar, S. E Mitchell, P. Barrett, D V. Rayner, C. Dieguez, and L. M Williams (2006)
J. Endocrinol. 190, 545-553
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A Ba2+-Sensitive K+ Current Contributes to the Resting Membrane Potential of Neurons in Rat Suprachiasmatic Nucleus.

M. de Jeu, A. Geurtsen, and C. Pennartz (2002)
J Neurophysiol 88, 869-878
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Light-Dependent Induction of cFos during Subjective Day and Night in PACAP-Containing Ganglion Cells of the Retinohypothalamic Tract.

J. Hannibal, N. Vrang, J. P. Card, and J. Fahrenkrug (2001)
J Biol Rhythms 16, 457-470
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Glutamate Blocks Serotonergic Phase Advances of the Mammalian Circadian Pacemaker through AMPA and NMDA Receptors.

R. A. Prosser (2001)
J. Neurosci. 21, 7815-7822
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Low temperature limits photoperiod control of smolting in Atlantic salmon through endocrine mechanisms.

S. D. McCormick, S. Moriyama, and B. T. Bjornsson (2000)
Am J Physiol Regulatory Integrative Comp Physiol 278, R1352-R1361
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Day/Night Differences in the Stimulation of Adenylate Cyclase Activity by Calcium/Calmodulin in Chick Pineal Cell Cultures: Evidence for Circadian Regulation of Cyclic AMP.

S. S. Nikaido and J. S. Takahashi (1998)
J Biol Rhythms 13, 479-493
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Cellular Mechanisms of Melatonin Action.

J. VANECEK (1998)
Physiol Rev 78, 687-721
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Resetting the Biological Clock: Mediation of Nocturnal CREB Phosphorylation via Light, Glutamate, and Nitric Oxide.

J. M. Ding, L. E. Faiman, W. J. Hurst, L. R. Kuriashkina, and M. U. Gillette (1997)
J. Neurosci. 17, 667-675
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Quantitative Two-Dimensional Gel Electrophoretic Analysis of Clock-Controlled Proteins in Cultured Chick Pineal Cells: Circadian Regulation of Tryptophan Hydroxylase.

J. C. Florez and J. S. Takahashi (1996)
J Biol Rhythms 11, 241-257
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Pinealectomized Rats Entrain and Phase-Shift to Melatonin Injections in a Dose-Dependent Manner.

W. S. Warren, D. B. Hodges, and V. M. Cassone (1993)
J Biol Rhythms 8, 233-245
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Does the Circadian Pacemaker Act through Cyclic AMP to Drive the Melatonin Rhythm in Chick Pineal Cells?.

M. Zatz (1992)
J Biol Rhythms 7, 301-311
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The Pineal Gland Influences Rat Circadian Activity Rhythms in Constant Light.

V. M. Cassone (1992)
J Biol Rhythms 7, 27-40
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Combined Effects on the Circadian Clock of Agents with Different Phase Response Curves: Phase-Shifting Effects of Triazolam and Light.

J. E. Joy (1992)
J Biol Rhythms 7, 51-63
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Feedback in the Rabbit's Central Circadian System, Revealed by the Changes in Its Free-Running Food Intake Pattern Induced by Blinding, Cervical Sympathectomy, Pinealectomy, and Melatonin Administration.

A.C. Bobbert and J.J. Riethoven (1991)
J Biol Rhythms 6, 263-278
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Light and Norepinephrine Similarly Prevent Damping of the Melatonin Rhythm in Cultured Chick Pineal Cells: Regulation of Coupling between the Pacemaker and Overt Rhythms?.

M. Zatz (1991)
J Biol Rhythms 6, 137-147
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Light pulses that shift rhythms induce gene expression in the suprachiasmatic nucleus.

B Rusak, H. Robertson, W Wisden, and S. Hunt (1990)
Science 248, 1237-1240
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Bright light induction of strong (type 0) resetting of the human circadian pacemaker.

C. Czeisler, R. Kronauer, J. Allan, J. Duffy, M. Jewett, E. Brown, and J. Ronda (1989)
Science 244, 1328-1333
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Effects of Stimulated Physical Activity on the Circadian Pacemaker of Vertebrates 1.

F. W. Turek (1989)
J Biol Rhythms 4, 23-35
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Different Responses of the Circadian System to GABA-Active Drugs in Two Strains of Mice.

S. Ebihara, M. Goto, and I. Oshima (1988)
J Biol Rhythms 3, 357-364
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Circadian Photoentrainment: Parameters of Phase Delaying.

P. J. DeCoursey (1986)
J Biol Rhythms 1, 171-186
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Clinical Applications of Corticotropin-Releasing Factor.

G. P. CHROUSOS, T. H. SCHUERMEYER, J. DOPPMAN, E. H. OLDFIELD, H. M. SCHULTE, P. W. GOLD, and D. L. LORIAUX (1985)
Ann Intern Med 102, 344-358
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A Biological Clock in Drosophila.

M.W. Young, F.R. Jackson, H.-S. Shin, and T.A. Bargiello (1985)
Cold Spring Harb Symp Quant Biol 50, 865-875
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Avian pancreatic polypeptide phase shifts hamster circadian rhythms when microinjected into the suprachiasmatic region.

H. Albers, C. Ferris, S. Leeman, and B. Goldman (1984)
Science 223, 833-835
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Chronobiologic Considerations in Pharmacologic and Toxicologic Studies: Fact or Fancy.

V. Nair and A. Chedid (1983)
International Journal of Toxicology 2, 337-345
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Adenylate cyclase activation shifts the phase of a circadian pacemaker.

A Eskin and J. Takahashi (1983)
Science 220, 82-84
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