Project description:Infective endocarditis results in the growth of a vegetative mass on native or bio prosthetic valves hindering function and increasing risk of thromboses. This study set out to determine the proteomic composition of these vegetations including the influence of different micro-organisms and the proteases known to be present. Our data has allowed us to describe for first time the influence different infectious organisms have on vegetation growth. Including the contribution of the immune response and circulatory proteins/cells make in composing a vegetation. Furthermore, we describe the protease activity and both known and novel cleavage sites in a plethora of targets. This data provides a deep insight into the homogeneity and heterogeneity of vegetation composition.

Project description:Proteases, and specifically metalloproteinases, have been linked to the loss of platelet function during storage before transfusion, albeit the mechanism remains unknown. We used a dedicated N-terminomics technique, multiplex iTRAQ-TAILS (Terminal Amine Isotope Labeling of Substrates), to characterize the human platelet proteome, N-terminome, and their post-translational modifications throughout platelet storage under blood banking conditions. From the identified 2,938 proteins and 7,503unique peptides we characterized N-terminal methionine excision, co- and post-translational N-acetylation, maturation and proteolytic processing of proteins in human platelets. We also identified for the first time in platelets 10 proteins previously classified as “missing” in the human proteome. Most of identified N-termini (77%) were internal, of which 105 were novel potential alternative translation start sites, with 2,180 representing stable proteolytic products, thus highlighting a prominent previously uncharacterized role of proteolytic processing during platelet storage. Protease inhibitor studies revealed metalloproteinases as being primarily responsible for proteolytic processing (as opposed to degradation) during storage. System-wide identification of metallo- and other proteinase substrates and their respective cleavage sites offers novel potential mechanisms of their effect on protein activity and platelet function during storage.

Project description:Positional proteomics methodologies have transformed protease research and have brought mass spectrometry (MS)-based degradomics studies to the forefront of protease characterization and system-wide interrogation of protease signaling. Considerable advancements in sensitivity and throughput of liquid chromatography (LC)-MS/MS instrumentation enable generation of enormous positional proteomics datasets of protein termini and neo-termini of cleaved protease substrates. However, such progress has not been observed to the same extent in data analysis and post-processing steps, which arguably constitute the largest bottleneck in positional proteomics workflows. Here, we present a computational tool, CLIPPER 2.0, that builds on prior algorithms developed for MS-based protein termini analysis, facilitating peptide level annotation and data analysis. CLIPPER 2.0 can be used with several sample preparation workflows and proteomics search algorithms, and enables fast and automated database information retrieval, statistical and network analysis, as well as visualization of terminomic datasets. We demonstrate our tool by analyzing GluC and MMP9 cleavages in HeLa lysates. CLIPPER 2.0 is available at https://github.com/UadKLab/CLIPPER-2.0.

Project description:Disintegrin and metalloproteinases ADAM10 and ADAM17 can release the extracellular region of a variety of membrane-bound proteins including cytokines, adhesion molecules, growth factors and receptors, important for many biological functions (ectodomain shedding).. So far, substrate identification for ADAM10 and ADAM17 focused exclusively on their membrane-anchored forms and their function as sheddases. With ADAM8 we now describe the first protease capable of releasing the ADAM17 ectodomain. Based on these findings, we investigated whether the soluble ectodomains of ADAM10 and ADAM17 still exhibit shedding activity and to determine their soluble protein substrate pool . To address this, a mass spectrometry-based N-terminomics approach (TAILS) was used to identify potential targets of soluble ADAM10 and ADAM17 (sADAM10/17) within the secretome of the murine cardiomyocyte cell line HL-1. We identified almost 140 protein cleavage events in total and 45 common substrates for both sADAM10 and sADAM17. Further in-vitro studies confirmed fibronectin, cystatin C, sN-cadherin, PCPE-1 as well as sAPP as direct substrates of soluble ADAM10 and/or ADAM17. Overall, we present the first degradome study for sADAM10 and sADAM17, thereby introducing a new regulation mode of the proteolytic activity of these essential proteases within the protease web.

Project description:Kallikrein-related peptidase 7 (KLK7) is a serine peptidase that is over-produced in the most lethal form of ovarian cancer, called high grade serous ovarian cancer (HGSOC). To determine its underlying molecular mechanism of action, a comprehensive analysis of KLK7 degradome in the OVMZ-6 cell-secreted proteins was performed using two complementary proteomic approaches, quantitative PROtein Topography and Migration Analysis Platform (qPROTOMAP) and Terminal Amine Isotopic Labelling of Substrates (TAILS).

Project description:Kallikrein-related peptidase 7 (KLK7) is a serine peptidase that is over-produced in the most lethal form of ovarian cancer, called high grade serous ovarian cancer (HGSOC). To determine its underlying molecular mechanism of action, a comprehensive analysis of KLK7 degradome in the SKOV-3 cell-secreted proteins was performed using two complementary proteomic approaches, quantitative PROtein Topography and Migration Analysis Platform (qPROTOMAP) and Terminal Amine Isotopic Labelling of Substrates (TAILS).

Project description:Mito-TAILS N-terminomics analysis of proteolytic events during EPEC infection of human epithelial cells, on whole-cell level and mitochondria.

Project description:Differential proteolytic processing in control and mitochondrial clpp protease-deficient mice were compared.

Project description:The micronemes and rhoptries are specialized organelles that secrete their contents at the apical tip of apicomplexan parasites in a sequential and regulated manner. Microneme and rhoptry proteins crucially participate in motility, invasion, and egress from infected cells. They first traffic through an endosomal-like compartment (ELC) and are subjected to proteolytic maturation prior to organellar storage and discharge. Here we establish that Toxoplasma gondii aspartyl protease 3 (ASP3) resides in the ELC and plays a crucial role associated to rhoptry discharge during invasion and to host cell plasma membrane lysis during egress. A comparison of the N-terminome, by terminal amine isotopic labelling of substrates (TAILS) between wild type and ASP3 depleted parasites identified microneme and rhoptry proteins as putative ASP3 substrates. The role of ASP3 as maturase for known as well as newly identified organellar proteins is confirmed in vivo and in vitro. A derivative from a series of antimalarial compounds based on a hydroxyethylamine scaffold interrupts the lytic cycle of T. gondii at submicromolar concentration by selectively targeting ASP3.

Project description:Protein N-termini are prone to post translational modification and are major determinants of protein stability in bacteria, eukaryotes, and perhaps also in chloroplasts. Most chloroplast proteins undergo N-terminal maturation, but this is poorly understood due to insufficient experimental information and the N-termini of mature chloroplast proteins cannot be accurately predicted. This motivated an extensive characterization of chloroplast protein N-termini using terminal amine isotopic labeling of substrates (TAILS). Many nuclear-encoded plastid proteins accumulated with two or three different N-termini; we evaluated the significance of these different proteoforms. Ala, Val, Thr (often in N-α acetylated form) and Ser were the most frequently observed N-terminal residues, even after normalization for their frequency in the plastid proteome, while other residues were absent or highly under-represented. Plastid-encoded proteins showed a similar distribution of N-terminal residues, but with a higher frequency of Met. Infrequent residues such as Ile, Arg, Cys, Pro, Asp and Glu were observed for several abundant proteins likely reflecting functional regulation through their N-termini. In contrast, the thylakoid lumenal proteome showed a wide diversity of N-terminal residues, including those typically associated with instability (Asp, Glu, Leu, Phe). We propose that after cleavage of the chloroplast transit peptide by stromal processing peptidase, additional processing by unidentified peptidases occurs to avoid unstable or otherwise unfavorable N-terminal residues. The possibility of a chloroplast N-end rule is discussed. This work provides a baseline for understanding N-terminal processing and maturation of chloroplast proteins.