Qun-Yong Zhou - US grants

DESCRIPTION (Adapted from applicant's abstract): The long-term objective of this project is to further our understanding of the physiological role of dopamine D1 and D2 receptors in normal CNS function and in the functional pathologies associated with schizophrenia and other mental health disorders. Evidence put forth by a number of investigators suggests that the overactivation of dopaminergic synaptic transmission may be important in the pathophysiology of schizophrenia. The precise relation of dopamine overactivation to schizophrenia, however, remaines vague. The present series of studies seeks to bridge this gap by investigating the consequences of overactivated dopamine systems on brain development and function by genetic manipulation of dopamine receptors, and by identifying the consequences of expression of mutant dopamine receptors in transgenic animals. In brief, these studies seek (a) to create constitutively active mutants of dopamine D1 and D2 receptors and to identify their pharmacological and biochemical characteristics, (b) to introduce selected constitutively active D1 and D2 receptor mutants into transgenic mice, (c) to characterize developmental abnormalities in animals with overactivated dopamine systems, and (d) to identify behavioral abnormalities in mice with constitutively active dopamine receptors. The studies will enhance our understanding of D1 and D2 receptors at the molecular level, lead to a better understanding of the action mechanisms for dopamine receptors, and may lead to the development of improved pharmacotherapies for dopamine system malfunctions. These studies will also lead to a better understanding of the developmental and functional consequences of dopamine overactivation and should provide us with some fundamental information pertaining to the relation of dopamine neurotransmission malfunctions with the development of the behavioral malfunctions underlying complex mental health disorders.

[unreadable] DESCRIPTION (provided by applicant): Organization of physiology and behavior with recurring daily environmental conditions is an adaptation that occurs in essentially all living organisms. Circadian rhythms are regulated by three components: the circadian pacemaker, an input mechanism and an output mechanism. In mammals, the master pacemaker driving circadian rhythms resides in the suprachiasmatic nuclei (SCN) of the anterior hypothalamus. Environmental light-dark cycles entrain the SCN clock to the 24-hr day. Synchronization of SCN neurons leads to coordinated circadian outputs that regulate expressed rhythms. A clear view of molecular clock mechanisms within the SCN has emerged. The molecular clockwork of the SCN circadian clock consists of auto-regulatory transcriptional and translational feedback loops that have both positive and negative elements. Similarly, the signal pathway of how light input resets SCN clock to synchronize with the environmental light/dark cycle is also emerging. In contrast to molecular mechanisms of SCN pacemaker clockwork and input pathway, relatively little is known about the output mechanism by which the SCN circadian pacemaker sends timing information to control physiological and behavioral rhythms. Prokineticin 2 (PK2), a cysteine-rich protein, has recently been shown as a SCN output molecule that transmits the circadian locomotor rhythm. PK2 fulfill the criteria expected for a bona fide output molecule from SCN circadian clock: 1) PK2 is a secreted molecule; 2) The transcription of PK2 is regulated by core clock genes, and PK2 mRNA oscillates in the SCN with high magnitude; 3) The production of PK2 is responsive to light entrainment; 4) Receptor for PK2 is expressed in primary SCN output target areas; and 5) Intracerebroventricular (ICV) administration of PK2 at subjective night, when endogenous PK2 levels are low, suppressed high nocturnal wheel-running activity. We propose to further investigate the role of PK2 signaling in the output mechanism of the SCN circadian clock. Specifically, the rhythms of PK2 protein in the cell bodies, terminal areas of SCN neurons and cerebral spinal fluid will be investigated by quantitative immunocytochemistry and/or radioimmunoassay. Whether PK2 is the common signal that mediates the output of SCN circadian clock and light masking will be investigated. How the PK2 rhythmic output from the SCN responds to abrupt shifts of light/dark cycle will also be investigated. Moreover, the effects of PK2 on SCN circadian clock-controlled locomotor and sleep/wake rhythms will be investigated by acute and chronic infusion of PK2 and PK2 antagonist in rats. Furthermore, the PK2 gene will be disrupted in mice and its effect on SCN-controlled circadian behavioral rhythms as well as core SCN circadian loops will be examined. Finally, the SCN PK2 output pathway will be investigated by a genetic approach. These proposed studies should help us gain further insight into the mechanism of PK2 signaling in mediating the output of timing information from the SCN circadian crock, and could have a major impact on the future treatment of a number of circadian disorders such as jet-lag, shift work syndrome, and chronic insomnia [unreadable] [unreadable]