Though intrinsic plasticity is an important mechanism by which the brain may encode and store information, it has been largely understudied in the learning and memory field. Our lab recently described a novel form of intrinisic plasticity in the excitability of pyramidal neurons in subiculum, the primary output pathway of the hippocampus. Plasticity of burst firing followed theta-patterned synaptic stimulation and did not depend on AMPA or NMDA receptors, but rather on synergistic activation of metabotropic muscarinic and glutamate receptors (mAChRs and mGluRs). By activating different sub-types of metabotropic receptors during dendritic stimulation, a long lasting enhancement or suppression of burst firing was induced (Moore et al., Neuron 2009). While this mechanism may exert profound influence of the fidelity of information transfer from the hippocampus, the mechanisms underlying burst plasticity expression remain unknown. We are now studying whether burst plasticity occurs in CA1 neurons. Using whole-cell current-clamp and cell-attached voltage- clamp recordings, we found that while burst plasticity can be induced in these neurons, the pharmacology of burst plasticity differed between CA1 and subiculum. In burst-firing subicular neurons, synergistic activation of mGluR1 and mAChRs was required to induce a long lasting increase in burst firing, whereas mGluR5 mediated a suppression of burst firing. In regular-spiking CA1 neurons, however, preliminary data suggest that mGluR5 mediated enhanced burst firing and antagonism of mGluR1 and mAChRs did not block the induction of increased burst firing. In addition to elucidating the pharmacological processes contributing to burst plasticity induction, I will also explore how plasticity is expressed in CA1. Is increased burst firing achieved by upregulating a depolarizing conductance, such as a voltage-gated sodium or calcium channel, by downregulating a potassium channel, or a combination of both? Using selective blockers for numerous voltage- gated and calcium-activated channels, I will record specific ionic currents following burst plasticity induction to determine the molecular identity of plasticity expression. Further scrutiny of the mechanisms underlying burst plasticity will yield valuable insight regarding the role of intrinsic plasticity in modulating hippocampal integration and output, and may further suggest novel mechanisms for information storage.

Public Health Relevance

This project studies the cellular underpinnings of a novel form of information storage in the hippocampus, a crucial brain area involved in memory formation. Presently, very little is known regarding the molecular mechanisms linking changes in neuronal signaling to memory. Elucidating these mechanisms will increase our understanding of the complex processes behind memory and may yield valuable insights into pathological conditions associated with memory deficits, such as Alzheimer's and dementia.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Predoctoral Individual National Research Service Award (F31)
Project #
1F31NS067758-01A1
Application #
7914034
Study Section
Special Emphasis Panel (ZRG1-F03B-H (20))
Program Officer
Talley, Edmund M
Project Start
2010-05-01
Project End
2013-04-30
Budget Start
2010-05-01
Budget End
2011-04-30
Support Year
1
Fiscal Year
2010
Total Cost
$33,577
Indirect Cost
Name
Northwestern University at Chicago
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
160079455
City
Evanston
State
IL
Country
United States
Zip Code
60201
Graves, Austin R; Moore, Shannon J; Bloss, Erik B et al. (2012) Hippocampal pyramidal neurons comprise two distinct cell types that are countermodulated by metabotropic receptors. Neuron 76:776-89