Unique ion channels activated by both glutamate and voltage, NMDA receptors (NMDARs) play crucial roles in synapse formation, synaptic plasticity, learning, and memory. NMDARs have been associated with either the pathogenesis or the damage caused by several neurological disorders including schizophrenia, epilepsy, Parkinson's disease, drug addiction, and ischemia/stroke. The modulation of NMDARs by intracellular signaling pathways is an active area of investigation. Growing evidence now suggests that activity can dynamically regulate NMDARs, though much remains unexplored. We are currently aware of activity-dependent NMDAR regulation at only a few synapses, although its underlying molecular mechanisms and functional consequences remain unknown. We propose experiments to identify the mechanisms and specific functional contributions of activity-dependent NMDAR modulation, beginning with a novel form recently discovered in our laboratory. Recently we found that brief tetanic activity can induce long-term potentiation of NMDAR-mediated transmission at the hippocampal mossy fiber-CA3 pyramidal cell synapse (NMDAR-mfLTP). Preliminary data suggests that NMDAR-mfLTP is induced and expressed postsynaptically in a Ca2+-dependent process and is restricted to NMDARs. We propose to investigate the molecular mechanisms and functional consequences of NMDAR-mfLTP using electrophysiological recording and functional analysis, pharmacological manipulation, and Ca2+ imaging in acute hippocampal slices. In studies of the induction mechanism, we will use inhibitors and activators of signal transduction pathways including those known to regulate NMDARs in expression systems and cultured neurons. We will investigate whether this potentiation is expressed as an increase in NMDAR number and/or function. In terms of function consequences, we will determine whether NMDAR-mfLTP is associated with long-term enhancement of Ca2+ signaling at mf-CA3 synapses, and we will test the hypothesis that NMDAR-mfLTP will substantially modify the input/output function of this synapse. In addition, we will test whether NMDAR-mfLTP, once established, might modify the subsequent modifiability of excitatory and inhibitory CA3 synapses, a phenomenon known as metaplasticity. Finally, we will look for other forms of NMDAR plasticity at this synapse, including long-term depression, de-potentiation, and de-depression. Dynamic long-term modification of NMDARs may have important consequences for both normal and pathological physiology. For this reason, understanding the role of these forms of plasticity at the cellular and network level is critical to a more realistic representation of brain function, and may contribute to the development of therapeutic strategies to reverse or prevent NMDAR-mediated dysregulation or damage.

Public Health Relevance

NMDA receptors are a subtype of receptors in the brain that participate in excitatory neurotransmission and are crucial for synapse formation, synaptic plasticity and learning and memory. Dynamic long-term modification of NMDA receptors by neuronal activity may have important consequences for both normal and pathological physiology with potential involvement in ischemia/stroke, epilepsy, schizophrenia, drug addiction, chronic pain, and Parkinson's disease. Understanding how these receptors are regulated is critical to a more realistic representation of brain function, and may contribute to the development of therapeutic strategies to reverse or prevent NMDAR-mediated dysregulation or brain damage. ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
1R01MH081935-01A1
Application #
7528173
Study Section
Neurotransporters, Receptors, and Calcium Signaling Study Section (NTRC)
Program Officer
Asanuma, Chiiko
Project Start
2008-07-01
Project End
2013-01-31
Budget Start
2008-07-01
Budget End
2009-01-31
Support Year
1
Fiscal Year
2008
Total Cost
$364,590
Indirect Cost
Name
Albert Einstein College of Medicine
Department
Neurosciences
Type
Schools of Medicine
DUNS #
110521739
City
Bronx
State
NY
Country
United States
Zip Code
10461
Weng, Feng-Ju; Garcia, Rodrigo I; Lutzu, Stefano et al. (2018) Npas4 Is a Critical Regulator of Learning-Induced Plasticity at Mossy Fiber-CA3 Synapses during Contextual Memory Formation. Neuron 97:1137-1152.e5
Monday, Hannah R; Younts, Thomas J; Castillo, Pablo E (2018) Long-Term Plasticity of Neurotransmitter Release: Emerging Mechanisms and Contributions to Brain Function and Disease. Annu Rev Neurosci 41:299-322
Nandi, Sayan; Alviña, Karina; Lituma, Pablo J et al. (2018) Neurotrophin and FGF Signaling Adapter Proteins, FRS2 and FRS3, Regulate Dentate Granule Cell Maturation and Excitatory Synaptogenesis. Neuroscience 369:192-201
Monday, Hannah R; Castillo, Pablo E (2017) Closing the gap: long-term presynaptic plasticity in brain function and disease. Curr Opin Neurobiol 45:106-112
Hashimotodani, Yuki; Nasrallah, Kaoutsar; Jensen, Kyle R et al. (2017) LTP at Hilar Mossy Cell-Dentate Granule Cell Synapses Modulates Dentate Gyrus Output by Increasing Excitation/Inhibition Balance. Neuron 95:928-943.e3
Dore, Kim; Stein, Ivar S; Brock, Jennifer A et al. (2017) Unconventional NMDA Receptor Signaling. J Neurosci 37:10800-10807
Araque, Alfonso; Castillo, Pablo E; Manzoni, Olivier J et al. (2017) Synaptic functions of endocannabinoid signaling in health and disease. Neuropharmacology 124:13-24
Harony-Nicolas, Hala; Kay, Maya; Hoffmann, Johann du et al. (2017) Oxytocin improves behavioral and electrophysiological deficits in a novel Shank3-deficient rat. Elife 6:
Jones, Brian W; Deem, Jennifer; Younts, Thomas J et al. (2016) Targeted deletion of AKAP7 in dentate granule cells impairs spatial discrimination. Elife 5:
Younts, Thomas J; Monday, Hannah R; Dudok, Barna et al. (2016) Presynaptic Protein Synthesis Is Required for Long-Term Plasticity of GABA Release. Neuron 92:479-492

Showing the most recent 10 out of 34 publications