As much as 20% of the population will suffer from chronic pain lasting for more than 6 months. Chronic pain and its underlying pathophysiology, can result in depression and other debilitating neurological effects and although there are effective treatments for acute pain chronic pain is resistant to most current treatments requiring the development of novel therapeutics that target molecular events underlying these pain states. Neuropathic and persistent post-surgical pain occurs, at least in part, due to long lasting changes in the function of excitatory synaptic transmission in the spinal dorsal horn resulting in enhanced pain signaling (hyperalgesia) and innocuous stimuli evoking pain (allodynia). These synaptic events share many features of neuronal plasticity that has been studied in higher CNS areas. Many of these changes are NMDAR dependent resulting in increased synaptic strength. One mechanism that has emerged underlying these changes in synaptic function is the potentiation of NMDAR function by a direct molecular interaction with the EphB receptor tyrosine kinase. Building on our published work, we will test the hypothesis that an EphB-NMDAR interaction is responsible for the development of a chronic pain state by directing NMDARs to synapses by expressing wild type or mutant EphB2 receptors in vitro and in mice. To test this hypothesis, we will determine the mechanism mediating the EphB-NDMAR interaction, characterize molecules and other tools to disrupt this interaction, and determine whether preventing the EphB-NMDAR interaction will alleviate chronic pain. To address these questions we will undertake three specific aims: 1. Determine the domain on the NMDAR responsible for the EphB-NMDAR interaction. 2. Test the hypothesis that VLK directs phosphorylation of Y504 on EphB2. 3. Determine the functional significance of VLK in pain plasticity. Collectively these aims will create a new knowledge that will provide a deeper understanding of the role of EphB-NMDAR interaction in pain and enable progress toward understanding the basic mechanisms behind chronic pain states.
The NMDAR is key to pain plasticity, yet we lack effective therapies. The project will test the hypothesis that extracellular phosphorylation of EphBs controls NMDAR clustering and function at synapses, examines the molecular mechanisms that govern these events, and determine the impact of these events in models of pain. Answering these questions will create new knowledge defining a novel mechanism for synaptic plasticity, and enable progress toward development of completely new therapeutic interventions for neurological disorders and understanding of neuronal development.