Abstract

The mammalian suprachiasmatic nucleus (SCN) is required for daily cycles in behavior and physiology. Some other brain regions, including the main olfactory bulb (OB), also express intrinsic circadian rhythms. It is not known how or which cells within these regions synchronize and sustain these rhythms or what role they play in behavior. The neuropeptide vasoactive intestinal polypeptide (VIP) is required for circadian synchrony in the SCN and is found in neurons of other circadian tissues. Little is known about how VIP mediates synchrony within the SCN or if it coordinates rhythms in other brain regions. The proposed studies directly address these issues by taking advantage of long-duration recording technologies--multielectrode arrays and bioluminescent reporters of gene activity--and the unique properties of mice with mutations in genes involved in circadian timekeeping or transgenes that allow conditional manipulation of gene expression and cell viability in specific cell types.
Aim 1 tests the hypotheses that VIP entrains daily rhythms in variety of brain regions and cell types. The strategy is to compare VIP-induced changes in acute and circadian firing rate and gene expression patterns in real time of neurons and glia within 3 brain regions. In addition, the role of VIP in the OB and in olfaction will be assayed in vivo.
Aim 2 tests the hypotheses that VIP neurons in the SCN are required to entrain and sustain circadian locomotor rhythms and that VIP neurons in the OB are required for rhythms in the OB and in olfactory behavior.
This Aim also tests whether clock genes in VIP neurons are essential for their rhythmicity and for these rhythms in behavior.
Aim 3 uses correlated firing and gene expression patterns and pharmacology to map functional connectivity and the relative roles of glutamate, nitric oxide and VIP in circadian synchrony within the SCN. The recent discoveries of putative circadian oscillators in many mammalian tissues have led to the hypothesis that the circadian system is hierarchically organized and that disruption of this coordination could underlie various neurological disorders including depression. These experiments will, for the first time, identify the mechanisms that coordinate ensemble daily rhythms in the brain and the distinct roles they play in behavior. Daily rhythms in behavior and mood are driven by circadian clocks in the brain. This project examines the role of specific neurons and signaling molecules in the circadian regulation of neural activity and gene expression in and between brain areas and in locomotor and sensory function.

Public Health Relevance

Daily rhythms in behavior and mood are driven by circadian clocks in the brain. This project examines the role of specific neurons and signaling molecules in the circadian regulation of neural activity and gene expression in and between brain areas and in locomotor and sensory function.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
5R01MH063104-13
Application #
8235061
Study Section
Special Emphasis Panel (ZRG1-IFCN-L (02))
Program Officer
Desmond, Nancy L
Project Start
2000-07-15
Project End
2014-01-31
Budget Start
2012-02-01
Budget End
2013-01-31
Support Year
13
Fiscal Year
2012
Total Cost
$376,670
Indirect Cost
$122,593

  Institution

Name
Washington University
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
068552207
City
Saint Louis
State
MO
Country
United States
Zip Code
63130

  Publications

Herzog, Erik D; Hermanstyne, Tracey; Smyllie, Nicola J et al. (2017) Regulating the Suprachiasmatic Nucleus (SCN) Circadian Clockwork: Interplay between Cell-Autonomous and Circuit-Level Mechanisms. Cold Spring Harb Perspect Biol 9:
Bedont, Joseph L; LeGates, Tara A; Slat, Emily A et al. (2014) Lhx1 controls terminal differentiation and circadian function of the suprachiasmatic nucleus. Cell Rep 7:609-22
Freeman Jr, G Mark; Krock, Rebecca M; Aton, Sara J et al. (2013) GABA networks destabilize genetic oscillations in the circadian pacemaker. Neuron 78:799-806
Freeman Jr, G Mark; Nakajima, Masato; Ueda, Hiroki R et al. (2013) Picrotoxin dramatically speeds the mammalian circadian clock independent of Cys-loop receptors. J Neurophysiol 110:103-8
Satoh, Akiko; Brace, Cynthia S; Rensing, Nick et al. (2013) Sirt1 extends life span and delays aging in mice through the regulation of Nk2 homeobox 1 in the DMH and LH. Cell Metab 18:416-30
Granados-Fuentes, Daniel; Herzog, Erik D (2013) The clock shop: coupled circadian oscillators. Exp Neurol 243:21-7
An, Sungwon; Tsai, Connie; Ronecker, Julie et al. (2012) Spatiotemporal distribution of vasoactive intestinal polypeptide receptor 2 in mouse suprachiasmatic nucleus. J Comp Neurol 520:2730-41
Granados-Fuentes, Daniel; Norris, Aaron J; Carrasquillo, Yarimar et al. (2012) I(A) channels encoded by Kv1.4 and Kv4.2 regulate neuronal firing in the suprachiasmatic nucleus and circadian rhythms in locomotor activity. J Neurosci 32:10045-52
Hogenesch, John B; Herzog, Erik D (2011) Intracellular and intercellular processes determine robustness of the circadian clock. FEBS Lett 585:1427-34
Marpegan, Luciano; Swanstrom, Adrienne E; Chung, Kevin et al. (2011) Circadian regulation of ATP release in astrocytes. J Neurosci 31:8342-50

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