Abstract

Circadian rhythms show considerable plasticity: they synchronize to environmental light cycles, shift phase in response to single light pulses, and alter their free-running periods and their sensitivity to fight as a function of their light exposure history. The mechanisms underlying much of this plasticity are incompletely understood. We propose to investigate two instances of plasticity at the cellular level: one in the pineal and the other in the suprachiasmatic nucleus (SCN). We have discovered that mammalian pineal gland, although not normally photosensitive, may become photosensitive when cultured.
Our first aim i s to describe the changes produced by culturing the gland, define the optimal culture conditions for producing them and to test the hypothesis that these changes do not occur in vivo because they are suppressed by endogenous norepinephrine from sympathetic input to the developing pineal. We have recently observed dramatic changes in the distribution of cell bodies visualized with antisera to serotonin (5HT) as a consequence of light exposure history. Such cell bodies, which are normally found only in the raphe nuclei, appear in large numbers in the SCN of hamsters that have been held for 16-20 weeks in constant darkness.
Our second aim i s to explore this observation further by testing two hypotheses: 1) that the effect is caused either by the complete absence of light or by the absence of a daily environmental entraining signal; 2) that the 5HT in SCN cells is a consequence of changes in the uptake mechanism. If we are able to block 5HT uptake and eliminate the 5HT cell bodies in the SCN we will assess the effects of such blocking treatments on circadian physiology and behavior. Because the pineal and the SCN are both centrally important components of the mammalian circadian axis, changes in their morphology (and physiology) produced by the environment may well be involved in circadian behavioral plasticity. Light 5HT and circadian rhythmicity have all been shown to be important mediators of mental state. Our findings are most likely to relate to the biological basis of mood disorders. The collaborative work described in this proposal will extend and deepen the ties that already exist between the Neuroscience Institute at Morehouse School of Medicine and the neuroscience community at University of Virginia and will provide the principal investigator with opportunities for continued training and development.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Minority Biomedical Research Support Thematic Project Grants (S11)
Project #
5S11NS038483-05
Application #
6639562
Study Section
Special Emphasis Panel (ZNS1-SRB-W (01))
Project Start
1999-04-15
Project End
2005-03-31
Budget Start
2003-04-01
Budget End
2005-03-31
Support Year
5
Fiscal Year
2003
Total Cost
$328,271
Indirect Cost

  Institution

Name
Morehouse School of Medicine
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
102005451
City
Atlanta
State
GA
Country
United States
Zip Code
30310

  Publications

Tosini, Gianluca; Owino, Sharon; Guillaume, Jean-Luc et al. (2014) Understanding melatonin receptor pharmacology: latest insights from mouse models, and their relevance to human disease. Bioessays 36:778-87
Davidson, Alec J; Aujard, Fabienne; London, Brian et al. (2003) Thermochron ibuttons: an inexpensive method for long-term recording of core body temperature in untethered animals. J Biol Rhythms 18:430-2
Fukuhara, Chiaki; Tosini, Gianluca (2003) Induction of photosensitivity in cultured rat pineal affects Aa-nat regulation. Brain Res Dev Brain Res 142:219-21
Fukuhara, Chiaki; Dirden, James C; Tosini, Gianluca (2003) Analysis of gene expression following norepinephrine stimulation in the rat pineal gland using DNA microarray technique. J Pineal Res 35:196-203
Tosini, G; Fukuhara, C (2003) Photic and circadian regulation of retinal melatonin in mammals. J Neuroendocrinol 15:364-9
Tosini, Gianluca; Fukuhara, Chiaki (2002) The mammalian retina as a clock. Cell Tissue Res 309:119-26
Fukuhara, Chiaki; Dirden, James C; Tosini, Gianluca (2002) Regulation of period 1 expression in cultured rat pineal. Neurosignals 11:103-14
Fukuhara, C; Dirden, J C; Tosini, G (2001) Photic regulation of melatonin in rat retina and the role of proteasomal proteolysis. Neuroreport 12:3833-7
Herzog, E D; Tosini, G (2001) The mammalian circadian clock shop. Semin Cell Dev Biol 12:295-303
Tosini, G; Dirden, J C (2000) Dopamine inhibits melatonin release in the mammalian retina: in vitro evidence. Neurosci Lett 286:119-22

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