Abstract
Nuclear factor TDP-43 has been shown to play a key role in Amyotrophic Lateral Sclerosis and Frontotemporal Dementia, where TDP-43 aggregates accumulate in patient's affected neurons and this event can cause neuronal dysfunction. A major focus of today's research is to discover the critical factors that lead to TDP-43 aggregation and the consequences for neuronal metabolism. From a structural point of view, several lines of evidence point toward TDP-43 C-terminus as a key domain able to mediate this process. Regarding this region, we have recently described a novel cellular TDP-43 aggregation model based on 12 tandem repetitions of its 339-366 Q/N rich prion-like domain. In addition, we have shown and confirmed that a minimal TDP-43 construct constituted by the N and C-terminal regions, but lacking both RRM domains, induce aggregation of endogenous TDP-43 and leads to its total loss of function as seen by changes in the alternative splicing of endogenous genes. In this work, we further characterize this model and show the importance of the N-terminus structure in the loss of function process. In addition, from a biochemical point of view we report that, as shown in a previous version of this model (GFP 12 × Q/N), the endogenous TDP-43 trapped in the aggregates undergoes the 2 most important post-translational modifications seen in pathological TDP-43 inclusions: ubiquitination and hyperphosphorylation.