Investigating Dysfunction of Neuroimmune-Related Processes in Models of ALS/FTD TDP-43
Univ Of Massachusetts Med Sch Worcester, Worcester MA
Investigators
Abstract
ABSTRACT Amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) are neurodegenerative diseases with overlapping genetic and pathological features. While neuronal degeneration predicts the clinical and pathological manifestations of these disorders, non-neuronal cells significantly contribute to disease pathogenesis. Indeed, alterations in immune response and dysregulation of microglia are early features of ALS and FTD, and are believed to contribute to disease progression. A prominent, pathological feature of ALS, FTD and related neurodegenerative diseases is TAR DNA binding protein 43 (TDP-43) dysfunction. TDP-43 is an RNA/DNA-binding protein with many roles in RNA and DNA processing, yet the role of TDP-43 in these neurodegenerative diseases remains poorly defined. We have been investigating the link between traumatic brain injury (TBI) and neurodegeneration, as TBI is a known risk-factor for developing neurological disorders with TDP-43 pathology. Using a knock-in mouse model of mutant TDP-43 (i.e., ALS/FTD-TDP mice), we conducted neurological and omics analyses in ALS/FTD-TDP versus WT mice following a mild, concussive TBI. We found that ALS/FTD-TDP mice are more susceptible to neurological deficits following TBI compared to their WT counterparts, a phenotype that was accompanied by changes in innate immune pathways involved in nucleic acid sensing in ALS/FTD-TDP mice. Microglia are key modulators of innate immunity in the CNS, and are critical for recovery after injury. Therefore, Aim 1 in this proposal will probe innate immune pathways and characterize CNS cell types, including microglia subtypes, within ALS/FTD-TDP mice both at baseline and after TBI. To investigate the mechanistic impact of TDP-43 dysfunction on the properties of microglia, we will also employ a human induced pluripotent stem cell (iPSC) derived microglia (iMG) model in Aim 2. Complementary to our ALS/FTD-TDP mouse model, iMGs will allow us to determine the effects of TDP-43 mutation or TDP-43 knock-down on microglial function. We will further utilize this iMG model through xenotransplantation of iMGs into the mouse brain, allowing us to elucidate the impact of TDP-43 mutation specifically in microglia in vivo. The outcomes of this proposal have the potential to uncover mechanisms by which TDP-43 mis-expression alters the innate immune landscape in the CNS, including under conditions of CNS insult.
View original record on NIH RePORTER →