Traumatic brain injury (TBI) has been referred to as the ?signature injury? of recent military combat operations in Iraq and Afghanistan. The form of TBI that is most prevalent among military service members and Veterans is repetitive, mild TBI, or rmTBI. Apart from the immediate effects of a head injury, rmTBI is also associated with a number of significant and chronic co-morbid conditions including cognitive dysfunction, sleep disorders, alterations in visual function, and psychiatric complications (e.g., depression, suicide, anxiety). rmTBI and its co-morbid conditions exact a steep toll on military personnel and Veterans and the cost to the nation of TBI is estimated to be $60 billion annually. The mechanisms by which rmTBI alters brain function are not well understood and all clinical trials of new therapies for TBI thus far have failed. Therefore, an effective treatment for TBI does not exist. Perhaps the most alarming aspect of rmTBI is the possibility that repeated mild impacts to the head do not cause clinically significant or recognizable symptoms but set in motion a cascade which has an endpoint of neurodegeneration and psychiatric illness. The primary goals of this application are to 1) refine and validate a humanized mouse model of rmTBI and 2) test two new mechanism-based therapies for the long-term consequences of rmTBI. These goals will be achieved by employing a new model of rmTBI that is very mild, even after as many as 20 head impacts, and which does not result in any behavioral or neuronal pathology at the end of the treatment period. We include preliminary data showing that rmTBI results in a delayed and progressive emergence of increased reactive gliosis and inflammation along white matter tracts, and increases in the pathologic form of tau, a microtubule stabilizing molecule. In addition, this model of rmTBI results in slowly developing cognitive deficits and psychiatric-like disorders (e.g., anxiety and depression), neither of which are evident immediately after the rmTBI course of treatment. These neuronal and behavioral outcomes are hallmark signs of chronic traumatic encephalopathy (CTE) and have been observed in postmortem brains of military service members exposed to rmTBI. Two new drugs will be tested as therapies for rmTBI and include an inhibitor of histone deacetylase 6 (HDAC6) and a colony-stimulating factor 1 receptor (CSFR1) inhibitor that ablates CNS microglia. The rationale behind the use of an HDAC6 inhibitor for treating rmTBI is compelling for several reasons. First, modification of tau by acetylation protects it from aggregation (i.e., its pathological form) by inhibiting its phosphorylation. Second, HDAC6 has been identified as the specific enzyme that deacetylates tau. Deacetylation of tau allows for modification of tau by phosphorylation. Third, inhibition of HDAC6 should shift the balance of acetylation/phosphorylation to favor acetylation and thereby protect tau against pathological aggregation in brain. The rationale behind the use of a CSF1R inhibitor is likewise compelling and strong because rmTBI results in significant increases in microglial activation which then causes a secondary activation of astrocytes. This increased glial reactivity results in neuronal damage. By ablating microglia, a CSF1R inhibitor should prevent activation of both microglia and astrocytes and reduce the CTE-like damage that occurs in CTE. The effects of rmTBI will be studied over a chronic time-frame in mice to simulate the slow-developing neuropathologies and behavioral disorders seen in humans after repeated head injuries. Treatment will not begin until after exposure of mice to repetitive head impacts in order to simulate a clinical situation more closely. It is hypothesized that inhibition of HDAC6 or CSF1R after rmTBI will prevent or reduce the development of CTE-like tau pathology. It is hypothesized further that prevention of the formation of tauopathies with these treatments will reduce the chronic co-morbid conditions that develop with high frequency after rmTBI to include cognitive dysfunction, alterations in vision and sleep, and depression- and anxiety-like behavioral disorders. This project has high translational relevance for the VA health care mission.
The research in this application will first characterize the delayed and progressive emergence of CTE- and psychiatric-like pathologies in a humanized mouse model of repetitive mild TBI. TBI is a major health problem among Veterans and its negative effects are amplified by numerous co-morbid conditions that are known to follow this injury to include cognitive dysfunction, alterations in vision and sleep and psychiatric conditions. An effective treatment for TBI is not available so we will also test new mechanistic-based therapies to protect against the chronic pathologies associated with TBI. Work in this application is aimed at BLRD and VA ORD research objectives to increase the understanding of chronic injury to the brain with emphasis on the long-term effects of co-occurring conditions, and to test new treatments for these conditions.
