p62, Ref(2)P and ubiquitinated proteins are conserved markers of neuronal aging,aggregate formation and progressive autophagic defects

Suppression of macroautophagy, due to mutations or through processes linked to aging, results in the accumulation of cytoplasmic substrates that are normally eliminated by the pathway. This is a significant problem in long-lived cells like neurons, where pathway defects can result in the accumulation of aggregates containing ubiquitinated proteins. The p62/Ref(2)P family of proteins is involved in the autophagic clearance of cytoplasmic protein bodies or sequestosomes. These unique structures are closely associated with protein inclusions containing ubiquitin as well as key components of the autophagy pathway. In this study we show that detergent fractionation followed by western blot analysis of insoluble ubiquitinated proteins (IUP), mammalian p62 and its Drosophila homologue, Ref(2)P can be used to quantitatively assess the activity level of aggregate clearance (aggrephagy) in complex tissues. Using this technique we show that genetic or age-dependent changes that modify the long-term enhancement or suppression of aggrephagy can be identified. Moreover, using the Drosophila model system this method can be used to establish autophagy-dependent protein clearance profiles that are occurring under a wide range of physiological conditions including developmental, fasting and altered metabolic pathways. This technique can also be used to examine proteopathies that are associated with human disorders such as frontotemporal dementia, Huntington and Alzheimer disease. Our findings indicate that measuring IUP profiles together with an assessment of p62/Ref(2)P proteins can be used as a screening or diagnostic tool to characterize genetic and age-dependent factors that alter the long-term function of autophagy and the clearance of protein aggregates occurring within complex tissues and cells.     

Promoting basal levels of autophagy in the nervous system enhances longevity and oxidant resistance in adult Drosophila

Autophagy is involved with the turnover of intracellular components and the management of stress responses. Genetic studies in mice have shown that suppression of neuronal autophagy can lead to the accumulation of protein aggregates and neurodegeneration. However, no study has shown that increasing autophagic gene expression can be beneficial to an aging nervous system. Here we demonstrate that expression of several autophagy genes is reduced in Drosophila neural tissues as a normal part of aging. The age-dependent suppression of autophagy occurs concomitantly with the accumulation of insoluble ubiquitinated proteins (IUP), a marker of neuronal aging and degeneration. Mutations in the Atg8a gene (autophagy-related 8a) result in reduced lifespan, IUP accumulation and increased sensitivity to oxidative stress. In contrast, enhanced Atg8a expression in older fly brains extends the average adult lifespan by 56% and promotes resistance to oxidative stress and the accumulation of ubiquitinated and oxidized proteins. These data indicate that genetic or age-dependent suppression of autophagy is closely associated with the buildup of cellular damage in neurons and a reduced lifespan, while maintaining the expression of a rate-limiting autophagy gene prevents the age-dependent accumulation of damage in neurons and promotes longevity.     

Different effects of Atg2 and Atg18 mutations on Atg8a and Atg9 trafficking during starvation in Drosophila

The Atg2–Atg18 complex acts in parallel to Atg8 and regulates Atg9 recycling from phagophore assembly site (PAS) during autophagy in yeast. Here we show that in Drosophila, both Atg9 and Atg18 are required for Atg8a puncta formation, unlike Atg2. Selective autophagic degradation of ubiquitinated proteins is mediated by Ref(2)P/p62. The transmembrane protein Atg9 accumulates on refractory to Sigma P (Ref(2)P) aggregates in Atg7, Atg8a and Atg2 mutants. No accumulation of Atg9 is seen on Ref(2)P in cells lacking Atg18 or Vps34 lipid kinase function, while the Atg1 complex subunit FIP200 is recruited. The simultaneous interaction of Atg18 with both Atg9 and Ref(2)P raises the possibility that Atg18 may facilitate selective degradation of ubiquitinated protein aggregates by autophagy.     

Promoting basal levels of autophagy in the nervous system enhances longevity and oxidant resistance in adult Drosophila

Autophagy is involved with the turnover of intracellular components and the management of stress responses. Genetic studies in mice have shown that suppression of neuronal autophagy can lead to the accumulation of protein aggregates and neurodegeneration. However, no study has shown that increasing autophagic gene expression can be beneficial to an aging nervous system. Here we demonstrate that expression of several autophagy genes is reduced in Drosophila neural tissues as a normal part of aging. The age-dependent suppression of autophagy occurs concomitantly with the accumulation of insoluble ubiquitinated proteins (IUP), a marker of neuronal aging and degeneration. Mutations in the Atg8a gene (autophagy-related 8a) result in reduced lifespan, IUP accumulation and increased sensitivity to oxidative stress. In contrast, enhanced Atg8a expression in older fly brains extends the average adult lifespan by 56% and promotes resistance to oxidative stress and the accumulation of ubiquitinated and oxidized proteins. These data indicate that genetic or age-dependent suppression of autophagy is closely associated with the buildup of cellular damage in neurons and a reduced lifespan, while maintaining the expression of a rate-limiting autophagy gene prevents the age-dependent accumulation of damage in neurons and promotes longevity.     

The deubiquitinating enzyme USP36 controls selective autophagy activation by ubiquitinated proteins

Initially described as a nonspecific degradation process induced upon starvation, autophagy is now known also to be involved in the degradation of specific ubiquitinated substrates such as mitochondria, bacteria and aggregated proteins, ensuring crucial functions in cell physiology and immunity. We report here that the deubiquitinating enzyme USP36 controls selective autophagy activation in Drosophila and in human cells. We show that dUsp36 loss of function autonomously inhibits cell growth while activating autophagy. Despite the phenotypic similarity, dUSP36 is not part of the TOR signaling pathway. Autophagy induced by dUsp36 loss of function depends on p62/SQSTM1, an adaptor for delivering cargo marked by polyubiquitin to autophagosomes. Consistent with p62 requirement, dUsp36 mutant cells display nuclear aggregates of ubiquitinated proteins, including Histone H2B, and cytoplasmic ubiquitinated proteins; the latter are eliminated by autophagy. Importantly, USP36 function in p62-dependent selective autophagy is conserved in human cells. Our work identifies a novel, crucial role for a deubiquitinating enzyme in selective autophagy.     

The deubiquitinating enzyme USP36 controls selective autophagy activation by ubiquitinated proteins

Initially described as a nonspecific degradation process induced upon starvation, autophagy is now known also to be involved in the degradation of specific ubiquitinated substrates such as mitochondria, bacteria and aggregated proteins, ensuring crucial functions in cell physiology and immunity. We report here that the deubiquitinating enzyme USP36 controls selective autophagy activation in Drosophila and in human cells. We show that dUsp36 loss of function autonomously inhibits cell growth while activating autophagy. Despite the phenotypic similarity, dUSP36 is not part of the TOR signaling pathway. Autophagy induced by dUsp36 loss of function depends on p62/SQSTM1, an adaptor for delivering cargo marked by polyubiquitin to autophagosomes. Consistent with p62 requirement, dUsp36 mutant cells display nuclear aggregates of ubiquitinated proteins, including Histone H2B, and cytoplasmic ubiquitinated proteins; the latter are eliminated by autophagy. Importantly, USP36 function in p62-dependent selective autophagy is conserved in human cells. Our work identifies a novel, crucial role for a deubiquitinating enzyme in selective autophagy.     

Ref(2)P, the Drosophila melanogaster homologue of mammalian p62, is required for the formation of protein aggregates in adult brain

P62 has been proposed to mark ubiquitinated protein bodies for autophagic degradation. We report that the Drosophila melanogaster p62 orthologue, Ref(2)P, is a regulator of protein aggregation in the adult brain. We demonstrate that Ref(2)P localizes to age-induced protein aggregates as well as to aggregates caused by reduced autophagic or proteasomal activity. A similar localization to protein aggregates is also observed in D. melanogaster models of human neurodegenerative diseases. Although atg8a autophagy mutant flies show accumulation of ubiquitin- and Ref(2)P-positive protein aggregates, this is abrogated in atg8a/ref(2)P double mutants. Both the multimerization and ubiquitin binding domains of Ref(2)P are required for aggregate formation in vivo. Our findings reveal a major role for Ref(2)P in the formation of ubiquitin-positive protein aggregates both under physiological conditions and when normal protein turnover is inhibited.     

Dynamics of the degradation of ubiquitinated proteins by proteasomes and autophagy: association with sequestosome 1/p62

Proteotoxicity resulting from accumulation of damaged/unwanted proteins contributes prominently to cellular aging and neurodegeneration. Proteasomal removal of these proteins upon covalent polyubiquitination is highly regulated. Recent reports proposed a role for autophagy in clearance of diffuse ubiquitinated proteins delivered by p62/SQSTM1. Here, we compared the turnover dynamics of endogenous ubiquitinated proteins by proteasomes and autophagy by assessing the effect of their inhibitors. Autophagy inhibitors bafilomycin A1, ammonium chloride, and 3-methyladenine failed to increase ubiquitinated protein levels. The proteasome inhibitor epoxomicin raised ubiquitinated protein levels at least 3-fold higher than the lysosomotropic agent chloroquine. These trends were observed in SK-N-SH cells under serum or serum-free conditions and in WT or Atg5(-/-) mouse embryonic fibroblasts (MEFs). Notably, chloroquine considerably inhibited proteasomes in SK-N-SH cells and MEFs. In these cells, elevation of p62/SQSTM1 was greater upon proteasome inhibition than with all autophagy inhibitors tested and was reduced in Atg5(-/-) MEFs. With epoxomicin, soluble p62/SQSTM1 associated with proteasomes and p62/SQSTM1 aggregates contained inactive proteasomes, ubiquitinated proteins, and autophagosomes. Prolonged autophagy inhibition (96 h) failed to elevate ubiquitinated proteins in rat cortical neurons, although epoxomicin did. Moreover, prolonged autophagy inhibition in cortical neurons markedly increased p62/SQSTM1, supporting its degradation mainly by autophagy and not by proteasomes. In conclusion, we clearly demonstrate that pharmacologic or genetic inhibition of autophagy fails to elevate ubiquitinated proteins unless the proteasome is affected. We also provide strong evidence that p62/SQSTM1 associates with proteasomes and that autophagy degrades p62/SQSTM1. Overall, the function of p62/SQSTM1 in the proteasomal pathway and autophagy requires further elucidation.     

The PI 3-kinase regulator Vps15 is required for autophagic clearance of protein aggregates

Autophagy is involved in cellular clearance of aggregate-prone proteins, thereby having a cytoprotective function. Studies in yeast have shown that the PI 3-kinase Vps34 and its regulatory protein kinase Vps15 are important for autophagy, but the possible involvement of these proteins in autophagy in a multicellular animal has not been addressed genetically. Here, we have created a Drosophila deletion mutant of vps15 and studied its role in autophagy and aggregate clearance. Homozygous Deltavps15 Drosophila died at the early L3 larval stage. Using GFP-Atg8a as an autophagic marker, we employed fluorescence microscopy to demonstrate that fat bodies of wild type Drosophila larvae accumulated autophagic structures upon starvation whereas vps15 fat bodies showed no such response. Likewise, electron microscopy revealed starvation-induced autophagy in gut cells from wild type but not Deltavps15 larvae. Fluorescence microscopy showed that Deltavps15 mutant tissues accumulated profiles that were positive for ubiquitin and Ref(2)P, the Drosophila homolog of the sequestosome marker SQSTM1/p62. Biochemical fractionation and Western blotting showed that these structures were partially detergent insoluble, and immuno-electron microscopy further demonstrated the presence of Ref(2)P positive membrane free protein aggregates. These results provide the first genetic evidence for a function of Vps15 in autophagy in multicellular organisms and suggest that the Vps15-containing PI 3-kinase complex may play an important role in clearance of protein aggregates.     

Phasing out the bad—How SQSTM1/p62 sequesters ubiquitinated proteins for degradation by autophagy

The degradation of misfolded, ubiquitinated proteins is essential for cellular homeostasis. These proteins are primarily degraded by the ubiquitin-proteasome system (UPS) and macroautophagy/autophagy serves as a backup mechanism when the UPS is overloaded. How autophagy and the UPS are coordinated is not fully understood. During the autophagy of misfolded, ubiquitinated proteins, referred to as aggrephagy, substrate proteins are clustered into larger structures in a SQSTM1/p62-dependent manner before they are sequestered by phagophores, the precursors to autophagosomes. We have recently shown that SQSTM1/p62 and ubiquitinated proteins spontaneously phase separate into micrometer-sized clusters in vitro. This enabled us to characterize the properties of the ubiquitin-positive substrates that are necessary for the SQSTM1/p62-mediated cluster formation. Our results suggest that aggrephagy is triggered by the accumulation of substrates with multiple ubiquitin chains and that the process can be inhibited by active proteasomes.     

Selective removal of dishevelled by autophagy: A role of p62

Autophagy has long been viewed as a process to remove long-lived or misfolded protein aggregates and aging and damaged organelles. Our study identified a previously unknown function of autophagy in suppression of Wnt signaling. A signaling protein, Dishevelled (Dvl), can be degraded via the autophagy pathway upon starvation. In this selective degradation, p62/sequestosome-1 binds to ubiquitinated Dvl proteins and promotes Dvl aggregation. Intriguingly, LC3 can also directly interact with Dvl. The studies on the mechanism for autophagic clearance of Dishevelled led to several interesting findings.     

The PI 3-kinase regulator Vps15 is required for autophagic clearance of protein aggregates

Autophagy is involved in cellular clearance of aggregate-prone proteins, thereby having a cytoprotective function. Studies in yeast have shown that the PI 3-kinase Vps34 and its regulatory protein kinase Vps15 are important for autophagy, but the possible involvement of these proteins in autophagy in a multicellular animal has not been addressed genetically. Here, we have created a Drosophila deletion mutant of vps15 and studied its role in autophagy and aggregate clearance. Homozygous Δvps15 Drosophila died at the early L3 larval stage. Using GFP-Atg8a as an autophagic marker, we employed fluorescence microscopy to demonstrate that fat bodies of wild type Drosophila larvae accumulated autophagic structures upon starvation whereas vps15 fat bodies showed no such response. Likewise, electron microscopy revealed starvation-induced autophagy in gut cells from wild type but not Δvps15 larvae. Fluorescence microscopy showed that Δvps15 mutant tissues accumulated profiles that were positive for ubiquitin and Ref(2)P, the Drosophila homolog of the sequestosome marker SQSTM1/p62. Biochemical fractionation and Western blotting showed that these structures were partially detergent insoluble, and immuno-electron microscopy further demonstrated the presence of Ref(2)P positive membrane free protein aggregates.. These results provide the first genetic evidence for a function of Vps15 in autophagy in multicellular organisms and suggest that the Vps15-containing PI 3-kinase complex may play an important role in clearance of protein aggregates.     

Neurodegenerative diseases: model organisms,pathology and autophagy

A proteostasis view of neurodegeneration (ND) identifies protein aggregation as a leading causative reason for damage seen at the cellular and organ levels. While investigative therapies that aim at dissolving aggregates have failed, and the promises of silencing expression of ND associated pathogenic proteins or the deployment of engineered induced pluripotent stem cells (iPSCs) are still in the horizon, emerging literature suggests degrading aggregates through autophagy-related mechanisms hold the current potential for a possible cure. Macroautophagy (hereafter autophagy) is an intracellular degradative pathway where superfluous or unwanted cellular cargoes (such as peroxisomes, mitochondria, ribosomes, intracellular bacteria and misfolded protein aggregates) are wrapped in double membrane vesicles called autophagosomes that eventually fuses with lysosomes for their degradation. The selective branch of autophagy that deals with identification, capture and degradation of protein aggregates is called aggrephagy. Here, we cover the workings of aggrephagy detailing its selectivity towards aggregates. The diverse cellular adaptors that bridge the aggregates with the core autophagy machinery in terms of autophagosome formation are discussed. In ND, essential protein quality control mechanisms fail as the constituent components also find themselves trapped in the aggregates. Thus, although cellular aggrephagy has the potential to be upregulated, its dysfunction further aggravates the pathogenesis. This phenomenon when combined with the fact that neurons can neither dilute out the aggregates by cell division nor the dead neurons can be replaced due to low neurogenesis, makes a compelling case for aggrephagy pathway as a potential therapeutic option.     

Type 2 transglutaminase is involved in the autophagy-dependent clearance of ubiquitinated proteins

Eukaryotic cells are equipped with an efficient quality control system to selectively eliminate misfolded and damaged proteins, and organelles. Abnormal polypeptides that escape from proteasome-dependent degradation and aggregate in the cytosol can be transported via microtubules to inclusion bodies called 'aggresomes', where misfolded proteins are confined and degraded by autophagy. Here, we show that Type 2 transglutaminase (TG2) knockout mice display impaired autophagy and accumulate ubiquitinated protein aggregates upon starvation. Furthermore, p62-dependent peroxisome degradation is also impaired in the absence of TG2. We also demonstrate that, under cellular stressful conditions, TG2 physically interacts with p62 and they are localized in cytosolic protein aggregates, which are then recruited into autophagosomes, where TG2 is degraded. Interestingly, the enzyme's crosslinking activity is activated during autophagy and its inhibition leads to the accumulation of ubiquitinated proteins. Taken together, these data indicate that the TG2 transamidating activity has an important role in the assembly of protein aggregates, as well as in the clearance of damaged organelles by macroautophagy.     

Proteotoxic Stress Induces Phosphorylation of p62/SQSTM1 by ULK1 to Regulate Selective Autophagic Clearance of Protein Aggregates

Disruption of proteostasis, or protein homeostasis, is often associated with aberrant accumulation of misfolded proteins or protein aggregates. Autophagy offers protection to cells by removing toxic protein aggregates and injured organelles in response to proteotoxic stress. However, the exact mechanism whereby autophagy recognizes and degrades misfolded or aggregated proteins has yet to be elucidated. Mounting evidence demonstrates the selectivity of autophagy, which is mediated through autophagy receptor proteins (e.g. p62/SQSTM1) linking autophagy cargos and autophagosomes. Here we report that proteotoxic stress imposed by the proteasome inhibition or expression of polyglutamine expanded huntingtin (polyQ-Htt) induces p62 phosphorylation at its ubiquitin-association (UBA) domain that regulates its binding to ubiquitinated proteins. We find that autophagy-related kinase ULK1 phosphorylates p62 at a novel phosphorylation site S409 in UBA domain. Interestingly, phosphorylation of p62 by ULK1 does not occur upon nutrient starvation, in spite of its role in canonical autophagy signaling. ULK1 also phosphorylates S405, while S409 phosphorylation critically regulates S405 phosphorylation. We find that S409 phosphorylation destabilizes the UBA dimer interface, and increases binding affinity of p62 to ubiquitin. Furthermore, lack of S409 phosphorylation causes accumulation of p62, aberrant localization of autophagy proteins and inhibition of the clearance of ubiquitinated proteins or polyQ-Htt. Therefore, our data provide mechanistic insights into the regulation of selective autophagy by ULK1 and p62 upon proteotoxic stress. Our study suggests a potential novel drug target in developing autophagy-based therapeutics for the treatment of proteinopathies including Huntington’s disease.     

A new class of ubiquitin-Atg8 receptors involved in selective autophagy and polyQ protein clearance

Selective ubiquitin-dependent autophagy mediates the disposal of superfluous cellular structures and clears cells of protein aggregates such as polyQ proteins linked to Huntington disease. Crucial selectivity factors of this pathway are ubiquitin-Atg8 receptors such as human SQSTM1/p62, which recognize ubiquitinated cargoes and deliver them to phagophores for degradation. Contrasting previous beliefs, we recently showed that ubiquitin-dependent autophagy is not restricted to higher eukaryotes but also exists in yeast with Cue5, harboring a ubiquitin-binding CUE domain, being a ubiquitin-Atg8 receptor. Notably, the human CUE domain protein TOLLIP is functionally similar to yeast Cue5, indicating that Cue5/TOLLIP (CUET) proteins represent a new and conserved class of autophagy receptors. Remarkably, both Cue5 in yeast and TOLLIP in human cells mediate efficient clearance of aggregation-prone polyQ proteins derived from human HTT/huntingtin. Indeed, TOLLIP is potentially more potent in polyQ clearance than SQSTM1/p62 in HeLa cells, suggesting that TOLLIP, also implicated in innate immunity, may be significant for human health and disease.     

Fighting disease by selective autophagy of aggregate-prone proteins

Ubiquitinated protein aggregates are hallmarks of a range of human diseases, including neurodegenerative, liver and muscle disorders. These protein aggregates are typically positive for the autophagy receptor p62. Whereas the ubiquitin-proteasome system (UPS) degrades shortlived and misfolded ubiquitinated proteins that are small enough to enter the narrow pore of the barrel-shaped proteasome, the lysosomal pathway of autophagy can degrade larger structures including entire organelles or protein aggregates. This degradation requires autophagy receptors that link the cargo with the molecular machinery of autophagy and is enhanced by certain posttranslational modifications of the cargo. In this review we focus on how autophagy clears aggregate-prone proteins and the relevance of this process to protein aggregate associated diseases.     

A new class of ubiquitin-Atg8 receptors involved in selective autophagy and polyQ protein clearance

Selective ubiquitin-dependent autophagy mediates the disposal of superfluous cellular structures and clears cells of protein aggregates such as polyQ proteins linked to Huntington disease. Crucial selectivity factors of this pathway are ubiquitin-Atg8 receptors such as human SQSTM1/p62, which recognize ubiquitinated cargoes and deliver them to phagophores for degradation. Contrasting previous beliefs, we recently showed that ubiquitin-dependent autophagy is not restricted to higher eukaryotes but also exists in yeast with Cue5, harboring a ubiquitin-binding CUE domain, being a ubiquitin-Atg8 receptor. Notably, the human CUE domain protein TOLLIP is functionally similar to yeast Cue5, indicating that Cue5/TOLLIP (CUET) proteins represent a new and conserved class of autophagy receptors. Remarkably, both Cue5 in yeast and TOLLIP in human cells mediate efficient clearance of aggregation-prone polyQ proteins derived from human HTT/huntingtin. Indeed, TOLLIP is potentially more potent in polyQ clearance than SQSTM1/p62 in HeLa cells, suggesting that TOLLIP, also implicated in innate immunity, may be significant for human health and disease.     

Serine 403 phosphorylation of p62/SQSTM1 regulates selective autophagic clearance of ubiquitinated proteins

Selective macroautophagy (autophagy) of ubiquitinated protein is implicated as a compensatory mechanism of the ubiquitin-proteasome system. p62/SQSTM1 is a key molecule managing autophagic clearance of polyubiquitinated proteins. However, little is known about mechanisms controlling autophagic degradation of polyubiquitinated proteins. Here, we show that the specific phosphorylation of p62 at serine 403 (S403) in its ubiquitin-associated (UBA) domain increases the affinity between UBA and polyubiquitin chain, resulting in efficiently targeting polyubiquitinated proteins in "sequestosomes" and stabilizing sequestosome structure as a cargo of ubiquitinated proteins for autophagosome entry. Casein kinase 2 (CK2) phosphorylates S403 of p62 directly. Furthermore, CK2 overexpression or phosphatase inhibition reduces the formation of inclusion bodies of the polyglutamine-expanded huntingtin exon1 fragment in a p62-dependent manner. We propose that phosphorylation of p62 at S403 regulates autophagic clearance of ubiquitinated proteins and protein aggregates that are poorly degraded by proteasomes.     

NBR1 and p62 as cargo receptors for selective autophagy of ubiquitinated targets

Autophagy is an evolutionary conserved cell survival process for degradation of long-lived proteins, damaged organelles and protein aggregates. The mammalian proteins p62 and NBR1 are selectively degraded by autophagy and can act as cargo receptors or adaptors for the autophagic degradation of ubiquitinated substrates. Despite differing in size and primary sequence, both proteins share a similar domain architecture containing an N-terminal PB1 domain, a LIR motif interacting with ATG8 family proteins, and a C-terminal UBA domain interacting with ubiquitin. The LIR motif is essential for their autophagic degradation, indicating that ATG8 family proteins are responsible for the docking of p62 and NBR1 to nucleating autophagosomes. p62 and NBR1 co-operate in the sequestration of misfolded and ubiquitinated proteins in p62 bodies and are both required for their degradation by autophagy. Here we discuss the role of p62 and NBR1 in degradation of ubiquitinated cargoes and the putative role of LIR as a general motif for docking of proteins to ATG8 family proteins.