Literature DB >> 17362839

Autophagy and neurodegeneration: when the cleaning crew goes on strike.

Marta Martinez-Vicente1, Ana Maria Cuervo.   

Abstract

Intracellular accumulation of altered and misfolded proteins is the basis of most neurodegenerative disorders. Altered proteins are usually organised in the form of toxic multimeric complexes that eventually promote neuronal death. Cells rely on surveillance mechanisms that take care of the removal of these toxic products. What then goes wrong in these pathologies? Recent studies have shown that a primary failure in autophagy, a mechanism for clearance of intracellular components in lysosomes, could be responsible for the accumulation of these altered proteins inside the affected neurons. In this Review we summarise our current knowledge on the contribution of autophagy to the maintenance of normal cellular homoeostasis, its changes in neurodegenerative disorders, and the role of aggravating factors such as oxidative stress and ageing on autophagic failure in these pathologies.

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Year:  2007        PMID: 17362839     DOI: 10.1016/S1474-4422(07)70076-5

Source DB:  PubMed          Journal:  Lancet Neurol        ISSN: 1474-4422            Impact factor:   44.182


  179 in total

1.  The LRRK2 G2019S mutant exacerbates basal autophagy through activation of the MEK/ERK pathway.

Authors:  José M Bravo-San Pedro; Mireia Niso-Santano; Rubén Gómez-Sánchez; Elisa Pizarro-Estrella; Ana Aiastui-Pujana; Ana Gorostidi; Vicente Climent; Rakel López de Maturana; Rosario Sanchez-Pernaute; Adolfo López de Munain; José M Fuentes; Rosa A González-Polo
Journal:  Cell Mol Life Sci       Date:  2012-07-08       Impact factor: 9.261

2.  Defective autophagy is associated with neuronal injury in a mouse model of multiple sclerosis.

Authors:  Xuedan Feng; Huiqing Hou; Yueli Zou; Li Guo
Journal:  Bosn J Basic Med Sci       Date:  2017-05-20       Impact factor: 3.363

3.  Redox proteomics analyses of the influence of co-expression of wild-type or mutated LRRK2 and Tau on C. elegans protein expression and oxidative modification: relevance to Parkinson disease.

Authors:  Fabio Di Domenico; Rukhsana Sultana; Andrew Ferree; Katelyn Smith; Eugenio Barone; Marzia Perluigi; Raffaella Coccia; William Pierce; Jian Cai; Cesare Mancuso; Rachel Squillace; Manfred Wiengele; Isabella Dalle-Donne; Benjamin Wolozin; D Allan Butterfield
Journal:  Antioxid Redox Signal       Date:  2012-03-20       Impact factor: 8.401

4.  Constitutive activation of chaperone-mediated autophagy in cells with impaired macroautophagy.

Authors:  Susmita Kaushik; Ashish C Massey; Noboru Mizushima; Ana Maria Cuervo
Journal:  Mol Biol Cell       Date:  2008-03-12       Impact factor: 4.138

5.  MIR181A regulates starvation- and rapamycin-induced autophagy through targeting of ATG5.

Authors:  Kumsal Ayse Tekirdag; Gozde Korkmaz; Deniz Gulfem Ozturk; Reuven Agami; Devrim Gozuacik
Journal:  Autophagy       Date:  2013-01-15       Impact factor: 16.016

6.  Tau deletion exacerbates the phenotype of Niemann-Pick type C mice and implicates autophagy in pathogenesis.

Authors:  Chris D Pacheco; Matthew J Elrick; Andrew P Lieberman
Journal:  Hum Mol Genet       Date:  2008-12-12       Impact factor: 6.150

Review 7.  Cellular Metabolism in Lung Health and Disease.

Authors:  Gang Liu; Ross Summer
Journal:  Annu Rev Physiol       Date:  2018-11-28       Impact factor: 19.318

Review 8.  The ubiquitin-proteasome pathway in Huntington's disease.

Authors:  Steven Finkbeiner; Siddhartha Mitra
Journal:  ScientificWorldJournal       Date:  2008-04-20

Review 9.  An emerging role for Ubiquilin 1 in regulating protein quality control system and in disease pathogenesis.

Authors:  Can Zhang; Aleister J Saunders
Journal:  Discov Med       Date:  2009-06       Impact factor: 2.970

Review 10.  Autophagy and aging: keeping that old broom working.

Authors:  Ana Maria Cuervo
Journal:  Trends Genet       Date:  2008-11-05       Impact factor: 11.639
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