Project description:Mitochondria consist of hundreds of proteins, most of which are long-lived and inaccessible to the proteasomal quality control system of the cytosol. How cells stabilize the mitochondrial proteome during challenging conditions is poorly understood. Here we show that mitochondria form spatially defined protein aggregates as a stress-protecting mechanism. Thereby different types of intramitochondrial protein aggregates can be distinguished. The mitoribosomal protein Var1 (uS3m) undergoes a stress-induced transition from a soluble, chaperone-stabilized protein that is prevalent under benign conditions to an insoluble aggregated form upon acute stress. The formation of Var1 bodies stabilizes mitochondrial proteostasis presumably by sequestration of aggregation-prone proteins. The AAA chaperone Hsp78 associates with a different type of intramitochondrial aggregate. These Hsp78-bound aggregates sequester non-native matrix proteins to promote their subsequent folding or Pim1-mediated degradation. Our study shows that mitochondrial proteins actively control the formation of different types of intramitochondrial protein aggregates which actively cooperate to stabilize the mitochondrial proteome during proteotoxic stress conditions.

Project description:Mitochondria consist of hundreds of proteins, most of which are long-lived and inaccessible to the proteasomal quality control system of the cytosol. How cells stabilize the mitochondrial proteome during challenging conditions is poorly understood. Here we show that mitochondria form spatially defined protein aggregates as a stress-protecting mechanism. Thereby different types of intramitochondrial protein aggregates can be distinguished. The mitoribosomal protein Var1 (uS3m) undergoes a stress-induced transition from a soluble, chaperone-stabilized protein that is prevalent under benign conditions to an insoluble aggregated form upon acute stress. The formation of Var1 bodies stabilizes mitochondrial proteostasis presumably by sequestration of aggregation-prone proteins. The AAA chaperone Hsp78 associates with a different type of intramitochondrial aggregate. These Hsp78-bound aggregates sequester non-native matrix proteins to promote their subsequent folding or Pim1-mediated degradation. Our study shows that mitochondrial proteins actively control the formation of different types of intramitochondrial protein aggregates which actively cooperate to stabilize the mitochondrial proteome during proteotoxic stress conditions.

Project description:Mitochondria consist of hundreds of proteins, most of which are long-lived and inaccessible to the proteasomal quality control system of the cytosol. How cells stabilize the mitochondrial proteome during challenging conditions is poorly understood. Here we show that mitochondria form spatially defined protein aggregates as a stress-protecting mechanism. Thereby different types of intramitochondrial protein aggregates can be distinguished. The mitoribosomal protein Var1 (uS3m) undergoes a stress-induced transition from a soluble, chaperone-stabilized protein that is prevalent under benign conditions to an insoluble aggregated form upon acute stress. The formation of Var1 bodies stabilizes mitochondrial proteostasis presumably by sequestration of aggregation-prone proteins. The AAA chaperone Hsp78 associates with a different type of intramitochondrial aggregate. These Hsp78-bound aggregates sequester non-native matrix proteins to promote their subsequent folding or Pim1-mediated degradation. Our study shows that mitochondrial proteins actively control the formation of different types of intramitochondrial protein aggregates which actively cooperate to stabilize the mitochondrial proteome during proteotoxic stress conditions.

Project description:Mitochondria consist of hundreds of proteins, most of which are long-lived and inaccessible to the proteasomal quality control system of the cytosol. How cells stabilize the mitochondrial proteome during challenging conditions is poorly understood. Here we show that mitochondria form spatially defined protein aggregates as a stress-protecting mechanism. Thereby different types of intramitochondrial protein aggregates can be distinguished. The mitoribosomal protein Var1 (uS3m) undergoes a stress-induced transition from a soluble, chaperone-stabilized protein that is prevalent under benign conditions to an insoluble aggregated form upon acute stress. The formation of Var1 bodies stabilizes mitochondrial proteostasis presumably by sequestration of aggregation-prone proteins. The AAA chaperone Hsp78 associates with a different type of intramitochondrial aggregate. These Hsp78-bound aggregates sequester non-native matrix proteins to promote their subsequent folding or Pim1-mediated degradation. Our study shows that mitochondrial proteins actively control the formation of different types of intramitochondrial protein aggregates which actively cooperate to stabilize the mitochondrial proteome during proteotoxic stress conditions.

Project description:Mitochondria consist of hundreds of proteins, most of which are long-lived and inaccessible to the proteasomal quality control system of the cytosol. How cells stabilize the mitochondrial proteome during challenging conditions is poorly understood. Here we show that mitochondria form spatially defined protein aggregates as a stress-protecting mechanism. Thereby different types of intramitochondrial protein aggregates can be distinguished. The mitoribosomal protein Var1 (uS3m) undergoes a stress-induced transition from a soluble, chaperone-stabilized protein that is prevalent under benign conditions to an insoluble aggregated form upon acute stress. The formation of Var1 bodies stabilizes mitochondrial proteostasis presumably by sequestration of aggregation-prone proteins. The AAA chaperone Hsp78 associates with a different type of intramitochondrial aggregate. These Hsp78-bound aggregates sequester non-native matrix proteins to promote their subsequent folding or Pim1-mediated degradation. Our study shows that mitochondrial proteins actively control the formation of different types of intramitochondrial protein aggregates which actively cooperate to stabilize the mitochondrial proteome during proteotoxic stress conditions.

Project description:Protein aggregates are a hallmark of neurodegenerative disease proposed to promote neurotoxicity through a diverse and growing set of mechanisms. Aggregation of polyglycine is specifically implicated in the pathogenesis of an emerging group of neurodegenerative GGC repeat expansion diseases. Here, we find that polyglycine aggregates incorporate endogenous proteins harboring glycine-rich sequences, including FAM98B, a conserved component of the vertebrate tRNA ligase complex. Through sequestration and accelerated proteosome-dependent turnover mediated by the FAM98B glycine-rich intrinsically disordered region (IDR), polyglycine depletes the ligase complex and disrupts tRNA processing. Accordingly, brains of affected patients reveal aggregate-associated sequestration and depletion of the tRNA-LC as well as accumulation of aberrant tRNA species.

Project description:A loss of the checkpoint kinase ATM leads to impairments in the DNA damage response, and in humans causes cerebellar neurodegeneration, and a high risk to cancer. A loss of ATM is also associated with increased protein aggregation. The relevance and characteristics of this aggregation are still incompletely understood. Moreover, it is unclear to what extent other genotoxic conditions can trigger protein aggregation as well. Here, we show that targeting ATM, but also ATR or DNA topoisomerases result in a similar, widespread aggregation of a metastable, disease-associated subfraction of the proteome. Aggregation-prone model substrates, including expanded polyglutamine repeats, aggregate faster under these conditions. This increased aggregation results from an overload of chaperone systems, which lowers the cell-intrinsic threshold for proteins to aggregate. In line with this, we find that inhibition of the HSP70 chaperone system further exacerbates the increased protein aggregation. Moreover, we identify the molecular chaperone HSPB5 as a potent suppressor of it. Our findings reveal that various genotoxic conditions trigger protein aggregation, in a manner that is highly reminiscent of the widespread aggregation occurring in situations of proteotoxic stress and in proteinopathies.

Project description:The goal of the study is the analysis of the transcriptional adaptation of cultured cells to the exposure and uptake of peptide aggregates of different sizes. Synthetic aggregating peptides with low and high aggregation propensities that form small (<500 nm, Peptide PepS) versus large (>1 µm, PepL) aggregate size distributions were designed. We found that soluble peptides and small aggregates (less than 500 nm diameter) were taken up by non-specific endocytosis as part of the fluid phase and travelled through the endosomal compartment to lysosomes. By contrast, aggregates bigger than 1 µm in diameter, which could not be internalized along with the fluid phase, were taken up through a mechanism dependent of cytoskeletal reorganization and membrane remodelling with the morphological hallmarks of phagocytosis. The microarray analysis aims to determine what's the impact of these different mechanisms of aggregate endocytosis on the transcriptional activity of the cell.

Project description:In this study the generic impact of protein aggregation (aggregation of proteins not associated with neurodegenerative disease) on gene expression in cultured cells was investigated by DNA microarray technology. The survey of gene expression showed that the Hsp40, Hsp70 and Hsp105 genes, all of which have documented aggregation suppression activity, were up-regulated. Unexpectedly, the survey also showed increased expression of the MEK5 gene with concomitant silencing of the MEK3 gene. The expression pattern of MEK5 at the mRNA and protein levels aligns with the kinetics of aggregate formation and dissolution. Cell viability was unaffected by protein aggregates. These findings are of particular importance for chronic neurodegenerative diseases where the intraneuronal accumulation of aggregate-prone proteins are a major characteristic of the diseases. The identification of changes in MEK5 gene expression have been observed in Alzheimer-related diseases which provides new diagnostic and therapeutic avenues in these diseases. The molecular neuropathological findings would not have occurred without the generic microarray analyses.

Project description:Protein aggregation is a hallmark of numerous degenerative diseases, yet its underlying mechanisms remain poorly understood due to the challenges in identifying the composition and interaction networks of these aggregates. To address this issue, we developed TAggiXL, a novel method that combines fluorescence-traceable aggregate isolation with cross-linking proteomics, significantly enhancing the efficiency and precision of isolating protein aggregates. This method facilitates unbiased profiling of aggregated proteomes and their interactomes in live cells. The TAggiXL approach leverages advanced cross-linking proteomics, density gradient centrifugation, and fluorescence tracking to provide detailed characterization of protein aggregation under various stress conditions, including HSP90 and proteasome inhibition. Using TAggiXL, we identified key components and interactions within the aggregates, particularly highlighting the E3 ubiquitin ligase TRIM26, which plays a crucial role in aggregate formation and autophagic clearance under stress and pathogenic conditions. Moreover, TAggiXL revealed that HSPA1B functions as a central interaction hub within the aggregated proteome. It preferentially interacts with intrinsically disordered regions (IDRs) of aggregate components and demonstrates dynamic behavior within the aggregate. In summary, TAggiXL offers a powerful tool for dissecting the complex composition and interaction networks of protein aggregates, with significant potential to advance our understanding of protein aggregation in degenerative diseases. It also holds promise for informing the development of future therapeutic interventions.