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Literature DB >> 30166454

Endolysosomal degradation of Tau and its role in glucocorticoid-driven hippocampal malfunction.

João Vaz-Silva^1,2,3, Patrícia Gomes^1,2, Qi Jin³, Mei Zhu³, Viktoriya Zhuravleva^3,4, Sebastian Quintremil³, Torcato Meira^1,2,5, Joana Silva^1,2, Chrysoula Dioli^1,2, Carina Soares-Cunha^1,2, Nikolaos P Daskalakis⁶, Nuno Sousa^1,2, Ioannis Sotiropoulos^1,2, Clarissa L Waites^7,5.

Abstract

Emerging studies implicate Tau as an essential mediator of neuronal atrophy and cognitive impairment in Alzheimer's disease (AD), yet the factors that precipitate Tau dysfunction in AD are poorly understood. Chronic environmental stress and elevated glucocorticoids (GC), the major stress hormones, are associated with increased risk of AD and have been shown to trigger intracellular Tau accumulation and downstream Tau-dependent neuronal dysfunction. However, the mechanisms through which stress and GC disrupt Tau clearance and degradation in neurons remain unclear. Here, we demonstrate that Tau undergoes degradation via endolysosomal sorting in a pathway requiring the small GTPase Rab35 and the endosomal sorting complex required for transport (ESCRT) machinery. Furthermore, we find that GC impair Tau degradation by decreasing Rab35 levels, and that AAV-mediated expression of Rab35 in the hippocampus rescues GC-induced Tau accumulation and related neurostructural deficits. These studies indicate that the Rab35/ESCRT pathway is essential for Tau clearance and part of the mechanism through which GC precipitate brain pathology.

Entities: Disease Gene

Keywords: zzm321990ESCRTzzm321990; Rab35; Tau; endolysosomal; glucocorticoid

Mesh：

Substances：

Year: 2018 PMID： 30166454 PMCID： PMC6187216 DOI： 10.15252/embj.201899084

Source DB: PubMed Journal: EMBO J ISSN： 0261-4189 Impact factor: 11.598

56 in total

1. Microtubule-associated protein tau is a substrate of ATP/Mg(2+)-dependent proteasome protease system.

Authors: J Y Zhang; S J Liu; H L Li; J-Z Wang
Journal: J Neural Transm (Vienna) Date: 2004-09-14 Impact factor: 3.575

Review 2. The ESCRT machinery in endosomal sorting of ubiquitylated membrane proteins.

Authors: Camilla Raiborg; Harald Stenmark
Journal: Nature Date: 2009-03-26 Impact factor: 49.962

3. Alterations in late endocytic trafficking related to the pathobiology of LRRK2-linked Parkinson's disease.

Authors: Pilar Rivero-Ríos; Patricia Gómez-Suaga; Belén Fernández; Jesús Madero-Pérez; Andrew J Schwab; Allison D Ebert; Sabine Hilfiker
Journal: Biochem Soc Trans Date: 2015-06 Impact factor: 5.407

4. Interaction of endogenous tau protein with synaptic proteins is regulated by N-methyl-D-aspartate receptor-dependent tau phosphorylation.

Authors: Siddhartha Mondragón-Rodríguez; Emilie Trillaud-Doppia; Anthony Dudilot; Catherine Bourgeois; Michel Lauzon; Nicole Leclerc; Jannic Boehm
Journal: J Biol Chem Date: 2012-07-25 Impact factor: 5.157

5. Tau binds to lipid membrane surfaces via short amphipathic helices located in its microtubule-binding repeats.

Authors: Elka R Georgieva; Shifeng Xiao; Peter P Borbat; Jack H Freed; David Eliezer
Journal: Biophys J Date: 2014-09-16 Impact factor: 4.033

6. ESCRT proteins restrict constitutive NF-κB signaling by trafficking cytokine receptors.

Authors: Agnieszka Mamińska; Anna Bartosik; Magdalena Banach-Orłowska; Iwona Pilecka; Kamil Jastrzębski; Daria Zdżalik-Bielecka; Irinka Castanon; Morgane Poulain; Claudine Neyen; Lidia Wolińska-Nizioł; Anna Toruń; Ewelina Szymańska; Agata Kowalczyk; Katarzyna Piwocka; Anne Simonsen; Harald Stenmark; Maximilian Fürthauer; Marcos González-Gaitán; Marta Miaczynska
Journal: Sci Signal Date: 2016-01-19 Impact factor: 8.192

7. Tau-dependent suppression of adult neurogenesis in the stressed hippocampus.

Authors: C Dioli; P Patrício; R Trindade; L G Pinto; J M Silva; M Morais; E Ferreiro; S Borges; A Mateus-Pinheiro; A J Rodrigues; N Sousa; J M Bessa; L Pinto; I Sotiropoulos
Journal: Mol Psychiatry Date: 2017-05-30 Impact factor: 15.992

8. GTRD: a database of transcription factor binding sites identified by ChIP-seq experiments.

Authors: Ivan Yevshin; Ruslan Sharipov; Tagir Valeev; Alexander Kel; Fedor Kolpakov
Journal: Nucleic Acids Res Date: 2016-10-24 Impact factor: 16.971

9. Patient iPSC-Derived Neurons for Disease Modeling of Frontotemporal Dementia with Mutation in CHMP2B.

Authors: Yu Zhang; Benjamin Schmid; Nanett K Nikolaisen; Mikkel A Rasmussen; Blanca I Aldana; Mikkel Agger; Kirstine Calloe; Tina C Stummann; Hjalte M Larsen; Troels T Nielsen; Jinrong Huang; Fengping Xu; Xin Liu; Lars Bolund; Morten Meyer; Lasse K Bak; Helle S Waagepetersen; Yonglun Luo; Jørgen E Nielsen; Bjørn Holst; Christian Clausen; Poul Hyttel; Kristine K Freude
Journal: Stem Cell Reports Date: 2017-02-16 Impact factor: 7.765

10. Novel function of Tau in regulating the effects of external stimuli on adult hippocampal neurogenesis.

Authors: Noemí Pallas-Bazarra; Jerónimo Jurado-Arjona; Marta Navarrete; Jose A Esteban; Félix Hernández; Jesús Ávila; María Llorens-Martín
Journal: EMBO J Date: 2016-05-19 Impact factor: 11.598

25 in total

Review 1. Endosomal recycling reconciles the Alzheimer's disease paradox.

Authors: Scott A Small; Gregory A Petsko
Journal: Sci Transl Med Date: 2020-12-02 Impact factor: 17.956

2. Targeted Quantitative Proteomic Approach for High-Throughput Quantitative Profiling of Small GTPases in Brain Tissues of Alzheimer's Disease Patients.

Authors: Ming Huang; Martin Darvas; C Dirk Keene; Yinsheng Wang
Journal: Anal Chem Date: 2019-09-10 Impact factor: 6.986

3. Clearance of intracellular tau protein from neuronal cells via VAMP8-induced secretion.

Authors: Julie Pilliod; Alexandre Desjardins; Camille Pernègre; Hélène Jamann; Catherine Larochelle; Edward A Fon; Nicole Leclerc
Journal: J Biol Chem Date: 2020-10-22 Impact factor: 5.157

4. Rab35 controls cilium length, function and membrane composition.

Authors: Stefanie Kuhns; Cecília Seixas; Sara Pestana; Bárbara Tavares; Renata Nogueira; Raquel Jacinto; José S Ramalho; Jeremy C Simpson; Jens S Andersen; Arnaud Echard; Susana S Lopes; Duarte C Barral; Oliver E Blacque
Journal: EMBO Rep Date: 2019-08-21 Impact factor: 8.807

5. Ferroptosis promotes microtubule-associated protein tau aggregation via GSK-3β activation and proteasome inhibition.

Authors: Shaohui Wang; Yao Jiang; Yabo Liu; Qianhui Liu; Hongwei Sun; Mengjie Mei; Xiaomei Liao
Journal: Mol Neurobiol Date: 2022-01-07 Impact factor: 5.590

Review 6. It's all about tau.

Authors: Cheril Tapia-Rojas; Fabian Cabezas-Opazo; Carol A Deaton; Erick H Vergara; Gail V W Johnson; Rodrigo A Quintanilla
Journal: Prog Neurobiol Date: 2018-12-31 Impact factor: 11.685

7. Tau and other proteins found in Alzheimer's disease spinal fluid are linked to retromer-mediated endosomal traffic in mice and humans.

Authors: Sabrina Simoes; Jessica L Neufeld; Gallen Triana-Baltzer; Setareh Moughadam; Emily I Chen; Milankumar Kothiya; Yasir H Qureshi; Vivek Patel; Lawrence S Honig; Hartmuth Kolb; Scott A Small
Journal: Sci Transl Med Date: 2020-11-25 Impact factor: 17.956