Voltage-dependent Ca2+ channels are ubiquitous regulators of electrically excitable cells, initiating events as diverse as exocytosis, membrane excitability, cell motility, enzyme activation, and gene induction. Ca2+ influx through such channels is not simply a binary """"""""switch"""""""" that turns these responses on and off; rather, the rate, amplitude, and time course of intracellular Ca2+ signals strongly influence the degree and specificity of coupling between Ca2+ channels and downstream effector responses. Membrane voltage and G protein signaling pathways act together to fine-tune the gating of Ca2+ channels and, as a result, modulate the spatial and temporal properties of cytoplasmic Ca2+ signals. It is now well accepted that such coordinate regulation of Ca2+ channels in nerve terminals is an essential component of processing in the nervous system, providing a rapid and reversible means of altering synaptic strength. Surprisingly, no detailed studies have yet investigated the effects of Ca2+ channel modulation on other Ca2+ dependent cellular responses. Experiments in this application will rectify this deficit by evaluating the impact of G protein-dependent Ca2+ channel modulation on two somatic effector responses in dorsal root ganglion neurons--membrane excitability and gene transcription. Both responses are subject to activity-dependent regulation in sensory neurons, and both are strongly affected by somatic Ca2+ influx through voltage-gated channels. Given the dynamic control of Ca2+ channels that is provided by G protein signaling pathways in these cells, we hypothesize that G protein-dependent modulation will have significant impact on both acute and chronic responses to environmental stimuli. Experiments proposed here will define a set of molecular tools that alter G protein signaling and produce unique intracellular Ca2+ profiles in response to patterned, physiologically-appropriate stimuli. These stimuli (modeled after action potential waveforms and firing patterns characteristic of sensory neuron types in vivo) will then be employed to study short-term alterations in membrane excitability (mediated by Ca2+- activated Cl- channels) and long-term changes in gene transcription (mediated by the Ca2+-activated transcription factor, CREB). As sensory neuron plasticity underlies not only the normal adaptive responses of these cells to a changing environment but also their pathological responses to pain -- e.g., allodynia and hypersensitivity- identifying mechanisms that control Ca2+ influx in sensory neurons may allow development of new therapeutic strategies to treat chronic pain.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS016483-24
Application #
7154099
Study Section
Special Emphasis Panel (ZRG1-MDCN-1 (02))
Program Officer
Stewart, Randall R
Project Start
1980-07-01
Project End
2008-11-30
Budget Start
2006-12-01
Budget End
2008-11-30
Support Year
24
Fiscal Year
2007
Total Cost
$312,784
Indirect Cost
Name
Tufts University
Department
Neurosciences
Type
Schools of Medicine
DUNS #
039318308
City
Boston
State
MA
Country
United States
Zip Code
02111
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