Mariella Vicinanza scite author profile

Autophagy is a conserved pathway that delivers cytoplasmic contents to the lysosome for degradation. Here we consider its roles in neuronal health and disease. We review evidence from mouse knockout studies demonstrating the normal functions of autophagy as a protective factor against neurodegeneration associated with intracytoplasmic aggregate-prone protein accumulation as well as other roles, including in neuronal stem cell differentiation. We then describe how autophagy may be affected in a range of neurodegenerative diseases. Finally, we describe how autophagy upregulation may be a therapeutic strategy in a wide range of neurodegenerative conditions and consider possible pathways and druggable targets that may be suitable for this objective.

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Mammalian Autophagy: How Does It Work?

Bento

Renna²,

Ghislat³

et al. 2016

Annu. Rev. Biochem.

601

576

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Autophagy is a conserved intracellular pathway that delivers cytoplasmic contents to lysosomes for degradation via double-membrane autophagosomes. Autophagy substrates include organelles such as mitochondria, aggregate-prone proteins that cause neurodegeneration and various pathogens. Thus, this pathway appears to be relevant to the pathogenesis of diverse diseases, and its modulation may have therapeutic value. Here, we focus on the cell and molecular biology of mammalian autophagy and review the key proteins that regulate the process by discussing their roles and how these may be modulated by posttranslational modifications. We consider the membrane-trafficking events that impact autophagy and the questions relating to the sources of autophagosome membrane(s). Finally, we discuss data from structural studies and some of the insights these have provided.

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OCRL controls trafficking through early endosomes via PtdIns4,5P₂-dependent regulation of endosomal actin

et al. 2011

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Mutations in the phosphatidylinositol 4,5-bisphosphate (PtdIns4,5P(2)) 5-phosphatase OCRL cause Lowe syndrome, which is characterised by congenital cataracts, central hypotonia, and renal proximal tubular dysfunction. Previous studies have shown that OCRL interacts with components of the endosomal machinery; however, its role in endocytosis, and thus the pathogenic mechanisms of Lowe syndrome, have remained elusive. Here, we show that via its 5-phosphatase activity, OCRL controls early endosome (EE) function. OCRL depletion impairs the recycling of multiple classes of receptors, including megalin (which mediates protein reabsorption in the kidney) that are retained in engorged EEs. These trafficking defects are caused by ectopic accumulation of PtdIns4,5P(2) in EEs, which in turn induces an N-WASP-dependent increase in endosomal F-actin. Our data provide a molecular explanation for renal proximal tubular dysfunction in Lowe syndrome and highlight that tight control of PtdIns4,5P(2) and F-actin at the EEs is essential for exporting cargoes that transit this compartment.

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Polyglutamine tracts regulate beclin 1-dependent autophagy

Ashkenazi

Bento

Ricketts

et al. 2017

Nature

308

245

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Nine neurodegenerative diseases are caused by expanded polyglutamine (polyQ) tracts in different proteins, like huntingtin in Huntington’s disease (HD) and ataxin-3 in spinocerebellar ataxia type 3 (SCA3)1, 2. Age-at-onset decreases with increasing polyglutamine length in these proteins and the normal length is also polymorphic3. PolyQ expansions drive pathogenesis in these diseases, as isolated polyQ tracts are toxic, and an N-terminal huntingtin fragment comprising exon 1, which occurs in vivo due to alternative splicing4, causes toxicity. While such mutant proteins are aggregate-prone5, toxicity is also associated with soluble forms of the proteins6. The function of the polyQ tracts in many normal/wild-type cytoplasmic proteins is unclear. One such protein is the deubiquitinating enzyme ataxin 37, 8, which is widely expressed in the brain9, 10. Here we show that the polyQ domain in wild-type ataxin-3 enables its interaction with beclin 1, a key autophagy initiator11. This interaction allows the deubiquitinase activity of ataxin-3 to protect beclin 1 from proteasome-mediated degradation and thus enables autophagy. Starvation-induced autophagy, which is regulated by beclin 1, was particularly inhibited in ataxin-3-depleted human cell-lines, primary neurons and in-vivo. This activity of ataxin-3 and its interaction with beclin 1 mediated by its polyQ domain was competed by other soluble proteins with polyQ tracts in a length-dependent fashion. This resulted in impaired starvation-induced autophagy in cells expressing mutant huntingtin exon 1, which was also recapitulated in the brain of HD mouse model and in patient cells. A similar phenomenon was also seen with other polyQ disease proteins, including mutant ataxin-3 itself. Our data thus describe a specific function for a wild-type polyQ tract which is abrogated by a competing longer polyQ mutation in a disease protein. This also reveals a deleterious function of such mutations distinct from their aggregation propensity.

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PI(5)P Regulates Autophagosome Biogenesis

Vicinanza¹,

Korolchuk²,

Ashkenazi³

et al. 2015

Molecular Cell

214

206

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SummaryPhosphatidylinositol 3-phosphate (PI(3)P), the product of class III PI3K VPS34, recruits specific autophagic effectors, like WIPI2, during the initial steps of autophagosome biogenesis and thereby regulates canonical autophagy. However, mammalian cells can produce autophagosomes through enigmatic noncanonical VPS34-independent pathways. Here we show that PI(5)P can regulate autophagy via PI(3)P effectors and thereby identify a mechanistic explanation for forms of noncanonical autophagy. PI(5)P synthesis by the phosphatidylinositol 5-kinase PIKfyve was required for autophagosome biogenesis, and it increased levels of PI(5)P, stimulated autophagy, and reduced the levels of autophagic substrates. Inactivation of VPS34 impaired recruitment of WIPI2 and DFCP1 to autophagic precursors, reduced ATG5-ATG12 conjugation, and compromised autophagosome formation. However, these phenotypes were rescued by PI(5)P in VPS34-inactivated cells. These findings provide a mechanistic framework for alternative VPS34-independent autophagy-initiating pathways, like glucose starvation, and unravel a cytoplasmic function for PI(5)P, which previously has been linked predominantly to nuclear roles.

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