Role of the Tau N-terminal Region in Microtubule Stabilization Revealed by New Endogenous Truncated Forms

Overview

Journal Sci Rep

Specialty Science

Date 2015 May 15

PMID 25974414

Citations 66

Authors

Maxime Derisbourg

Coline Leghay

Giovanni Chiappetta

Francisco-Jose Fernandez-Gomez

Cyril Laurent

Dominique Demeyer

Sebastien Carrier

Valerie Buee-Scherrer

David Blum

Joelle Vinh

Nicolas Sergeant

Yann Verdier

Luc Buee

Malika Hamdane

Affiliations

Soon will be listed here.

Abstract

Tau is a central player in Alzheimer's disease (AD) and related Tauopathies, where it is found as aggregates in degenerating neurons. Abnormal post-translational modifications, such as truncation, are likely involved in the pathological process. A major step forward in understanding the role of Tau truncation would be to identify the precise cleavage sites of the several truncated Tau fragments that are observed until now in AD brains, especially those truncated at the N-terminus, which are less characterized than those truncated at the C-terminus. Here, we optimized a proteomics approach and succeeded in identifying a number of new N-terminally truncated Tau species from the human brain. We initiated cell-based functional studies by analyzing the biochemical characteristics of two N-terminally truncated Tau species starting at residues Met11 and Gln124 respectively. Our results show, interestingly, that the Gln124-Tau fragment displays a stronger ability to bind and stabilize microtubules, suggesting that the Tau N-terminal domain could play a direct role in the regulation of microtubule stabilization. Future studies based on our new N-terminally truncated-Tau species should improve our knowledge of the role of truncation in Tau biology as well as in the AD pathological process.

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