Tau in MAPK Activation

Chad J Leugers,Gloria Lee,Willis Hong,Ju Yong Koh

doi:10.3389/fneur.2013.00161

Abstract

The nature of “toxic” tau in Alzheimer’s disease (AD) has been unclear. During pathogenesis, the importance of tau oligomerization vs. tau phosphorylation is controversial and the investigation of both remains critical toward defining the “toxicity” of tau. The phosphorylation of tau on serines and/or threonines occurs early in the disease course and altering phosphorylation has been shown to disrupt neuropathogenesis. We have recently reported that in PC12-derived cells, tau had a role in signal transduction processes activated by NGF. By depleting tau, NGF-induced MAPK activation was attenuated and by restoring tau, MAPK activation was restored. Furthermore, the phosphorylation of tau on Thr231 was required for tau to potentiate MAPK activation. Here we report the effects of additional disease-related tau phosphorylation sites and tau isoform on the ability of tau to potentiate MAPK activation. Our findings, which tested three other sites of phosphorylation, showed that phosphorylation at these other sites mainly lessened MAPK activation; none potentiated MAPK activation. In comparing 0N3R tau to the other five brain tau isoforms, most showed a trend toward less MAPK activation, with only 2N4R tau showing significantly less activation. Since MAPK activation has been reported in AD brain and is characteristic of cell proliferation mechanisms, tau phosphorylation that promotes MAPK activation could promote cell cycle activation mechanisms. In neurons, the activation of the cell cycle leads to cell death, suggesting that abnormally phosphorylated tau can be a toxic species. The relationship between tau oligomerization and its ability to potentiate MAPK activation needs to be determined.

Highlights

The existence of tau pathology occurs in many age-related neurodegenerative diseases that are termed“tauopathies.”Among these diseases, Alzheimer’s disease (AD) is the most prevalent and it has been suggested that the presence of tau is critical for disease progression [1, 2]
A phospho-mimicking mutation at Thr231 brought further increases to MAPK activation while a Thr to ala mutation at Thr231 showed a dominant negative effect on MAPK activation [19]. This led us to conclude that tau phosphorylation at Thr231 was required for the effect of tau on MAPK signaling
The fact that tau can undergo phosphorylation at a number of sites during early brain development [26] or during neurodegeneration [27], we further investigated the effects of tau phosphorylation on MAPK activation

Summary

INTRODUCTION

The existence of tau pathology occurs in many age-related neurodegenerative diseases that are termed“tauopathies.”Among these diseases, Alzheimer’s disease (AD) is the most prevalent and it has been suggested that the presence of tau is critical for disease progression [1, 2]. The investigation of tau oligomers has suggested that they may have an early role in neurodegeneration. The molecular mechanism by which tau oligomers cause toxicity has not been clearly demonstrated In these studies, the tau oligomers were composed of phosphorylated tau, making it difficult to isolate the effects of oligomerization from those of phosphorylation. We found that tau has the ability to potentiate NGF-induced MAPK activation and that phosphorylation on Thr231 was critical for the activity [19]. Since this activity was seen within 3 h after NGF addition, our data identified a new role for tau in signal transduction processes that take place during neuronal differentiation. We investigate the effects of alternative splicing on the ability of tau to affect MAPK activation

MATERIALS AND METHODS

RESULTS AND DISCUSSION

27. Morishima-Kawashima