Project description:Autophagy facilitates the degradation of cellular content via the lysosome and is involved in cellular homeostasis and stress response pathways. As such, malfunction of autophagy is linked to a variety of diseases ranging from organ specific illnesses like cardiomyopathy to systemic illnesses such as cancer or metabolic syndromes. Given the variety of autophagic functions within a cell and tissue, regulation of autophagy is complex and contains numerous positive and negative feedback loops. While our knowledge of mechanisms for cargo selectivity has significantly improved over the last decade, our understanding of signaling routes activating individual autophagy pathways remains rather sparce. In this resource study, we report on a well-characterized chemical library assembled within the IMI initiative EUbOPEN containing 77 GPCR-targeting ligands that was used to systematically analyze LC3B-based autophagy as well as ER-phagy flux upon compound treatment. The global impact of hit compounds TC-G 1004, BAY 60-6583, PSNCBAM-1, TC-G 1008, LPA2 Antagonist 1, ML154, JTC-801 and ML-290 targeting Adenosine receptor A2a (ADORA2A), Adenosine receptor A2b (ADORA2B), Cannabinoid receptor 1 (CNR1), G-protein coupled receptor 39 (GPR39), Lysophosphatidic acid receptor 2 (LPAR2), neuropeptide S receptor 1 (NPSR1), NOP (OPRL1), and Relaxin receptor 1 (RXFP1) were subsequently analyzed and compared by TMT-based mass spectrometry. Our results indicate the differential impact of targeted GPCRs on known autophagy-associated proteins.

Project description:While deleterious mutations are responsible for the vast majority of TBK1-linked ALS/FTD cases, the ALS/FTD causing missense mutation p.E696K leads to a selective loss of TBK1/optineurin binding. Knock-in of this specific missense mutation causes progressive autophagolysosomal dysfunction and an ALS/FTD-like phenotype in mice, while, as opposed to TBK1 deletion, RIPK/TNF-α-dependent necroptosis or overt inflammation are absent. Our results highlight the role of autophagolysosomal dysfunction as a therapeutic target in TBK1-ALS/FTD.

Project description:B6-CIITA-E cell line (C57Bl/6 fibroblasts expressing MHC-II molecules I-Ab and I-Ed) was infected with Influenza A virus (A/Puerto Rico/8/1934, PR8) or left uninfected (control), and the MHC-class II-associated peptidome analysed via immunopeptidomics.

Project description:Defining the repertoire of peptides presented by the major histocompatibility complex class I (MHC I) is a key step towards the identification of relevant antigens for cancer immunotherapy. However, the identification of the cancer-specific antigens is a significant analytical challenge in view of their low abundance and low mutational load found in primary cancer specimens. Here, we describe the application of isobaric peptide labeling with tandem mass tag (TMT) to improve the detection of the MHC I peptides. Isobaric peptide labeling was found to promote the formation of multiply-charged ions and to enhance the formation of b-type fragment ions, thus resulting in a 50% improvement of MHC I peptide identification. The gain in sensitivity obtained using TMT labeling enabled the detection of low abundance MHC I peptides including tumor-specific antigens (TSAs) and minor histocompatibility antigens (MiHAs). We further demonstrate the application of this approach to quantify MiHAs presented by B-cell lymphocytes and determined their expression levels by LC-MS/MS using both synchronous precursor selection (SPS) and high field asymmetric waveform ion mobility spectrometry (FAIMS).

Project description:Influenza A virus (IAV) infection can cause the lethal acute respiratory distress syndrome of the lung (ARDS). However, AKI is frequently noticed and correlated to an increased mortality. While the causality for influenza-related ARDS is well established, the pathogenesis of influenza-related AKI is incompletely understood. Yet, in post mortem studies of patients infected with H1N1- or H5N6-type IAV, viral antigen was detected in tubular and glomerular cells. Relevantly, receptors for human and avian IAV are present on human kidney cells, viremia was observed and IAV was repeatedly detected by infectivity- and PCR assays in human urine.

Project description:We propose a new pipeline for the refinement of spectrum-peptide assignment, designed specifically for MHC ligand identification. By modeling the peptidome as a collection of a limited number of specificities, corresponding to the MHC alleles of the cell line, our method achieves increased sequencing depth, while at the same time removing potential experimental outliers and contaminants.

Project description:RNA splicing and the ubiquitin system allow the functional proteome to adapt in response to changing cellular contexts. However, the regulatory mechanisms connecting these processes remain poorly understood. Here we show that the deregulation of the spliceosome B complex caused by USP39 deficiency leads to a novel splicing profile characterized by the use of cryptic 5′splice sites. Importantly, disruptive variants evade mRNA surveillance pathways and are translated into topologically incorrect proteins. These cryptic isoforms disrupt proteostasis and activate the unfolded protein response, causing ER stress-induced cell death. Human cells respond to this proteotoxicity by enhancing ubiquitin-mediated proteolysis and ER-phagy. Our findings show how cell death triggered by cryptic splicing can be mitigated, and provide insight into the molecular pathogenesis of diseases such as retinitis pigmentosa.

Project description:Macrophages from WT or G2A deficient mice were either control or 9-HODE treated and TMT10 multiplexed proteomics performed

Project description:Our extended analysis of the HLA-presented antigen landscape in cervical cancer cells using an integrative proteogenomics approach identifies, next to tumour-associated antigens and tumour-specific neoantigens, presentation of viral canonical, and alternative reading frame (ARF)-derived HLA-presented sequences, including peptides derived from HPV-E1.

Project description:Current mass spectrometry technologies allow for identification of MHC-associated peptide ligands. Studies have proven these data to be a rich source of information for learning the rules of MHC-mediated antigen presentation. Such immunopeptidomes are usually poly-specific, containing multiple sequence motifs matching the MHC molecules expressed in the system under investigation. Motif deconvolution -the process of associating each ligand to its presenting MHC molecule(s)- is a critical and challenging step in the analysis of MS-eluted MHC ligand data. Here, we describe NNAlign_MA, a computational method designed to address this challenge. NNAlign_MA simultaneously performs the tasks of i) clustering peptides into individual specificities; ii) automatic annotation of each cluster to an MHC molecule; and iii) training of a prediction model covering all MHCs present in the training set. NNAlign_MA was benchmarked on large and diverse datasets, covering class I and class II data. In all cases, the method was demonstrated to outperform state-of-the-art methods, effectively expanding the coverage of alleles for which accurate predictions can be made, resulting in improved identification of both eluted ligands and T cellepitopes. Given its high flexibility and ease of use, we expect NNAlign_MA to serve as an effective tool to increase our understanding of the rules of MHC antigen presentation and guide the development of novel T cell-based therapeutics.