This peripheral nerve injury research program aims to provide mechanistic insights and targeted therapeutic strategies for neuronal damage. In the course of our VA Merit Award program we discovered matrix metalloproteinases (MMPs), a family of exracellular proteases, as key modulators of neuroimmune activation, demyelination, neuronal death and neuropathic pain after sciatic nerve injury, used as a successful mammalian model of neuronal regeneration. Individual MMP family members display differential functions during nerve damage, suggesting the importance of selective MMP inhibitor (MMPi) therapy for targeted intervention. For example, MMP-9 is an early-gene family member, that is expressed in nerve exclusively after injury by up to a 300-fold and only hours after insult. MMP-9 stimulates Schwann cell (SC) trophic (e.g. ErbB and IGF-1) signaling leading to sustained activation of extracellular signal-regulated kinase (ERK) and regulation of SC mitosis and myelin protein synthesis. MMP-9 gene deletion demonstrate remarkable neuroprotection, reduced immune cell infiltration into the injured nerve and notable changes to myelin protein turnover. Therapy with specific, broad- spectrum MMPi was highly effective in reducing painful tactile allodynia (i.e., pain from normally innocous stimuli), in protecting myelin from degradation and improving neuronal and glial survival. Our pilot data also demonstrates its promise in promoting the rate of nerve regrowth after rat sciatic nerve crush. The goal of this program is to establish the roles of individual MMPs in the processes of initiation and development of neurodegenerative cascades in peripheral nerve, utilizing a series of in vitro, ex vivo and in vivo approaches. It offers to develop therapeutic strategies for neurodegenerative diseases and sensory loss in VA patients. The most common causes of neurodegeneration and neuropathic pain are on the list of the VA patients most common health concerns, including diabetes, alcoholism, stroke and spinal cord injury. This porgram is designed to expedite the development and implementation of novel therapies to neurodegenerative diseases.
The current demographic profile of the VA patients shows that almost one-third of the nation's population (over 60 million people) are veterans, dependents or survivors of deceased veterans who have privileges of the VA Healthcare System. The epidemiology of neurodegenerative diseases suggests that the VA patient population is at special risk of neuronal damage, loss of sensory function and debilitating neuropathic pain. The causes are on the list of the VA patients'most common health concerns, including trauma, spinal cord injury, diabetes and alcoholism and may be amenable to the molecular intervention by inhibition on matrix metalloproteainses (MMPs). Understanding the mechanisms of neuronal damage through preclinical studies is critical to expediteing the development and implementation of novel therapies to neurodegenerative diseases.