Project description:Poly(glycine-alanine) (polyGA) is one of the dipolypeptides expressed in Motor Neuron Disease caused by C9ORF72 mutations and accumulates as inclusion bodies in the brain of patients. Superficially these inclusions are similar to those formed by polyglutamine (polyQ) in Huntington’s disease and both have been reported to form an amyloid-like structure suggesting they might aggregate via similar mechanisms to confer cellular dysfunction similarly. Here we investigated which endogenous proteins were enriched in these inclusions and whether aggregation-prone lengths of polyQ (Q97), in context of Huntingtin exon 1, shared similar patterns to aggregation-prone lengths of polyGA (101GA). When co-expressed in the same cell, polyGA101 and HttQ97 inclusions adopted distinct phases with no overlap suggesting different endogenous proteins would be enriched. Proteomic analyses indeed yielded distinct sets of endogenous proteins recruited into the inclusion types. The proteosome, microtubules, Tric chaperones, and translational machinery were enriched in polyGA aggregates, whereas Dnaj chaperones, nuclear envelope and RNA splicing proteins were enriched in polyQ aggregates. Both structures revealed a synergy of degradation machinery including proteins in the polyQ aggregates that are risk factors for other neurodegenerative diseases involving protein aggregation when mutated, which suggests a convergence point in the pathomechanisms of these diseases.

Project description:Poly(glycine-alanine) (polyGA) is one of the dipolypeptides expressed in Motor Neuron Disease caused by C9ORF72 mutations and accumulates as inclusion bodies in the brain of patients. Superficially these inclusions are similar to those formed by polyglutamine (polyQ) in Huntington’s disease and both have been reported to form an amyloid-like structure suggesting they might aggregate via similar mechanisms to confer cellular dysfunction similarly. Here we investigated which endogenous proteins were enriched in these inclusions and whether aggregation-prone lengths of polyQ (Q97), in context of Huntingtin exon 1, shared similar patterns to aggregation-prone lengths of polyGA (101GA). When co-expressed in the same cell, polyGA101 and HttQ97 inclusions adopted distinct phases with no overlap suggesting different endogenous proteins would be enriched. Proteomic analyses indeed yielded distinct sets of endogenous proteins recruited into the inclusion types. The proteosome, microtubules, Tric chaperones, and translational machinery were enriched in polyGA aggregates, whereas Dnaj chaperones, nuclear envelope and RNA splicing proteins were enriched in polyQ aggregates. Both structures revealed a synergy of degradation machinery including proteins in the polyQ aggregates that are risk factors for other neurodegenerative diseases involving protein aggregation when mutated, which suggests a convergence point in the pathomechanisms of these diseases.

Project description:Huntington's disease is a fatal neurodegenerative disorder characterized by the aggregation of polyglutamine-expanded huntingtin into oligomers and fibrils. How protein aggregation leads to cellular dysfunction is not well understood. To address this question, we combined in-cell single molecule fluorescence spectroscopy with quantitative proteomics to define how huntingtin engages in aberrant protein interactions during its progressive aggregation. We find that huntingtin interacts preferentially with key components of distinct cellular processes as aggregation proceeds from soluble oligomers to end-stage inclusions. The aberrant interactions of soluble oligomers are highly enriched on RNA-binding proteins and with proteins functioning in ribosome biogenesis, translation, transcription, and vesicle transport. A significant characteristic of these interactors is the presence of extended low-complexity sequence regions. Compared to the soluble aggregates, the interactome of insoluble inclusions is significantly less complex and is enriched in protein quality control components. Our results suggest a 'multiple hit' model for polyglutamine interactions in pathogenesis, with detrimental effects on cell function occurring in an aggregation stage-dependent manner.

Project description:To determine the changes in the host proteome as result of virus infection. In particular we infected HeLa and HL-1 cells with Coxsackievirus B3.

Project description:The constant increase in the obese and overweight population creates opportunities for novel therapeutic innovations to allow people to eat without getting fat and getting sick. Here, fed a hyperlipidic diet (HD)C57BL6 thimet oligopeptidase null (THOP1-/-) male mice were shown to gain only 25% (females gained 60%) of the weight gained by control wild type (WT) mice. Distinct from WT mice,THOP1-/- fed HD exhibited normal blood glucose levels and no insulin resistance. THOP1-/-fed HD phenotype benefits also include regular blood cholesterol levels, reduced fat in adipose and liver tissues, increased adipose tissue adrenergic-stimulated lipolysis, and greater resistance and endurance on treadmill running tests at high intensity. THOP1-/-compared to WT have alterations on the expression levels of specific genes and microRNAs related to obesity. Intracellular peptides that had their relative levels altered in THOP1-/-were shown to modulate the expression levels of genes and mature microRNAs associated to obesity, in 3T3L1 adipocyte. The ubiquitous existence of intracellular peptides in different cells of different species suggests a broader biological significance of the present results, connecting proteasomal protein degradation to protein synthesis. These exciting results suggest THOP1 and intracellular peptides as novel therapeutic targets to control obesity and obesity-associated diseases.

Project description:C9ORF72-associated Motor Neuron Disease patients feature abnormal expression of 5 dipeptide repeat (DPR) polymers. Here we used quantitative proteomics in a mouse neuronal-like cell line (Neuro2a) to demonstrate that the valency of Arg in the most toxic DPRS, PR and GR, drives promiscuous binding to the proteome, compared to a relative sparse binding of the more inert AP and GA. Notable targets included ribosomal proteins, translation initiation factors and translation elongation factors. PR and GR comprising more than 10 repeats robustly stalled the ribosome suggesting high-valency Arg electrostatically jams the ribosome exit tunnel during synthesis. Poly-GR also bound to arginine methylases and induced hypomethylation of endogenous proteins, with a profound destabilization of the actin cytoskeleton. Our findings point to arginine in GR and PR polymers as multivalent toxins to translation as well as arginine methylation with concomitant downstream effects on widespread biological processes including ribosome biogenesis, mRNA splicing and cytoskeleton assembly.

Project description:The accumulation of aberrant protein aggregates in neurodegenerative diseases is associated with a widespread failure of the protein homeostasis system. To investigate whether there is a subproteome that consistently aggregates under stress and define the broader determinants for protein aggregation at the proteome level we measured the changes in proteome solubility of a mouse neuroblastoma cell line (Neuro2a) under 6 different protein homeostasis stresses, including a Huntington’s disease model, Hsp70, Hsp90, proteasome and ER-mediated folding inhibition, and oxidative stress. By partitioning cell lysates into supernatants and pellets by centrifugation, we found that just over a one-quarter of the proteome extensively changed in solubility upon one or more stresses. Surprisingly, almost all the increases in insolubility were counteracted by increases on solubility of other proteins. Each stress directed a highly specific pattern of change, which reflected the remodelling of protein complexes involved in adaptation to perturbation, most notably stress granule proteins, which were highly enriched but responded differently across the different 2 stresses. The solubility patterns clustered into molecular functions anticipated from stress responses and metabolic pathway hotspots, and indicate a robust rewiring of protein-ligand interactions.

Project description:The accumulation of aberrant protein aggregates in neurodegenerative diseases is associated with a widespread failure of the protein homeostasis system. To investigate whether there is a subproteome that consistently aggregates under stress and define the broader determinants for protein aggregation at the proteome level we measured the changes in proteome solubility of a mouse neuroblastoma cell line (Neuro2a) under 6 different protein homeostasis stresses, including a Huntington’s disease model, Hsp70, Hsp90, proteasome and ER-mediated folding inhibition, and oxidative stress. By partitioning cell lysates into supernatants and pellets by centrifugation, we found that just over a one-quarter of the proteome extensively changed in solubility upon one or more stresses. Surprisingly, almost all the increases in insolubility were counteracted by increases on solubility of other proteins. Each stress directed a highly specific pattern of change, which reflected the remodelling of protein complexes involved in adaptation to perturbation, most notably stress granule proteins, which were highly enriched but responded differently across the different 2 stresses. The solubility patterns clustered into molecular functions anticipated from stress responses and metabolic pathway hotspots, and indicate a robust rewiring of protein-ligand interactions.

Project description:We study the global gene expression profiles of BKV viremia and nephropathy patients using microarrays in order to better understand the immunologic response to polyomavirus BK (BKV). BKV has become increasingly prevalent since the introduction of more potent immunosuppressive agents. It has been shown that as many as 30% of renal transplant recipients develop asymptomatic viral shedding in the urine shortly after transplant, 10-20% have viremia, and as many as 1-10% can go on to develop overt nephropathy (BKVN) that might lead to graft loss. To date, the genomics of BKV viremia and BKVN have not been investigated thoroughly by microarray. Patients who were enrolled in the IRB-approved Immune Monitoring Study had blood PAXGene samples taken at post-transplant visits and had clinically indicated biopsy samples were used for analysis. A total of 17 biopsy samples were used for gene expression profiling microarrays, three with histopathologic diagnosis of BKVN, 3 patients with evidence of BK viral replication in peripheral blood, but normal biopsy and 11 patients with normal biopsies or mild IFTA, and stable graft function. Blood PAXGene samples from 40 patients were used for gene expression profiling by microarrays, 14 patients with stable graft function and without BK viremia, 19 patients' blood samples at the time of BKV viremia, and 7 patients blood samples taken 1-2 months prior to development of BK viremia.

Project description:Halophilic microorganisms have long been known to survive within the brine inclusions of salt crystals, as evidenced by their pigmentation. However, the molecular mechanisms allowing this survival has remained an open question for decades. While protocols for the surface sterilization of halite (NaCl) have enabled isolation of cells and DNA from within halite brine inclusions, “-omics” based approaches have faced two main technical challenges: (1) removal of all contaminating organic biomolecules (including proteins) from halite surfaces, and (2) performing selective biomolecule extractions directly from cells contained within halite brine inclusions with sufficient speed to avoid modifications in gene expression during extraction. In this study, we present methods to resolve these two technical challenges. In addition, we apply these methods to perform the first examination of the early acclimation of a model haloarchaeon (Halobacterium salinarum NRC-1) to halite brine inclusions. Examinations of the proteome of Halobacterium cells two months post-evaporation revealed a high degree of similarity with stationary phase liquid cultures, but with a sharp down-regulation of ribosomal proteins. Low quantities of RNA from halite brine inclusions corroborate the hypothesis of low transcriptional and translational activities. While proteins for central metabolism were part of the shared proteome between liquid cultures and halite brine inclusions, proteins involved in cell mobility (archaellum, gas vesicles) were either absent or less abundant in halite samples. Proteins unique to cells within brine inclusions included transporters, suggesting modified interactions between cells and the surrounding brine inclusions microenvironment. The methods and hypotheses presented here enable future studies of the survival of halophiles in both culture model and natural halite systems.