Project description:Haemophilia A is a chronic life-threatening condition caused by deficiency or dysfunction of plasma coagulation factor VIII (FVIII) and prophylaxis by regular infusion of FVIII protein is a common treatment. A major obstacle to FVIII replacement therapy is the generation of alloantibodies that diminish efficacy. Disulfide bonds link pairs of cysteine residues in proteins and in several proteins have been found to be only partially formed in the mature proteins. FVIII contains 8 disulfide bonds and their redox state in human blood and recombinant FVIII was determined using differential cysteine alkylation and mass spectrometry. All 8 disulphide bonds were found to be unformed in 1 in 10 to 2 in 3 molecules of FVIII populations, which suggested a conformational flexibility that could favour binding of certain ligands to subsets of FVIII with more or less formed disulfide bonds. To test this hypothesis, the binding of a panel of five patient-derived anti-FVIII antibodies to the population of FVIII disulfide-bonded states was evaluated. All five antibodies bound preferentially to FVIII states where 2 or 3 of the 8 disulphides are significantly more unformed; C1918-C1922 in the A3 domain, C2040-C2188 in the C1 domain and C2193-C2345 in the C2 domain. Disulfide bond mutagenesis experiments and molecular dynamics simulations indicate that this subset of FVIII states have long-range conformational dynamism that favours anti-drug antibody binding. These findings will assist efforts to engineer a FVIII molecule that diminishes the emergence of inhibitors and has general implications for autoimmune conditions and antibody drug efficacy.

Project description:Disulfide bonds link pairs of cysteine amino acids and their formation is assumed to be complete in the mature, functional protein. We tested this assumption by quantifying the redox state of disulfide bonds in the thrombosis protein, fibrinogen. There is an extraordinary disulfide lability in fibrinogen, with 13 bonds in the protein ranging from 10 to 50% reduced in human donors, indicating that fibrinogen exists in hundreds of different disulfide-bonded states. The significance of this finding for fibrinogen conversion to fibrin was investigated. Fibrin polymer formation triggers formation of disulfides in fibrin molecules, which is required for a robust fibrin matrix that withstands the mechanical forces of flowing blood and resists premature fibrinolysis. The covalent states of fibrinogen are changed by fluid shear forces ex vivo and in vivo, indicating that the different states are dynamic. These findings demonstrate that proteins can exist and function as a multitude of covalent forms.

Project description:von Willebrand factor (VWF) is the protective carrier of procoagulant factor VIII (FVIII) in the shear forces of the circulation, prolonging its half‐life and delivering it to the developing thrombus. VWF∙FVIII complex formation is characterized by catch‐bond behavior in which force first decelerates then accelerates bond dissociation. Patients with mutations in VWF at the FVIII binding site phenocopies hemophilia A and the most common mutations involve cysteine residues of multiple disulfides. Thirteen VWF disulfide bonds at the FVIII binding site exist in formed and unformed states, and binding of FVIII results in partial formation of 12 of the VWF bonds. The VWF∙FVIII bond stiffens in response to force and this property is ablated when VWF disulfide bonds are prevented from forming, resulting in slip‐bond behavior. These findings demonstrate that FVIII binding to VWF involves dynamic changes in the covalent states of several VWF disulfides that are required for productive interaction.

Project description:The αIIbβ3 integrin receptor coordinates platelet adhesion, activation and mechanosensing in thrombosis and haemostasis. Using differential cysteine alkylation and mass spectrometry, we have identified a disulfide bond in the αIIb subunit linking cysteines 490 and 545 that is missing in about one in three integrin molecules on the resting and activated human platelet surface. This alternate covalent form of αIIbβ3 is pre-determined as it is also produced by human megakaryoblasts and bovine hamster kidney cells transfected with recombinant human integrin. From co-immunoprecipitation experiments, the alternate form selectively partitions into focal adhesions on the activated platelet surface. Its function was evaluated in bovine hamster kidney cells expressing a mutant integrin with an ablated C490-C545 disulfide bond. The disulfide mutant integrin has extended residency time in focal adhesions due to reduced rate of clathrin-mediated integrin internalisation and recycling that is associated with enhanced affinity of the αIIb subunit for clathrin adaptor protein-2. The alternate covalent form also has different conformational dynamics measured by monoclonal antibody binding and molecular dynamic simulations, which is reflected in reduced fibrinogen binding and outside-in signalling. These findings indicate that the αIIbβ3 integrin receptor is produced in different covalent forms that have different functions. The C490, C545 cysteine pair is conserved across all 18 integrin α subunits and the disulfide bond in αV in a cancer cell line is similarly missing, suggesting that this alternate integrin form and function is also conserved.

Project description:Quantification of the redox state of disulfide bonds in the beta 2 subunit of human recombinant Mac-1 integrin.

Project description:Mapping of disulfide bonds and quantification of their redox state in the human histidine rich glycoprotein

Project description:The Simple Light Isotope Metabolic labeling (SLIM-labeling) is an inovative method to quantify proteome variations based on an original in vivo labeling strategy. Heterotrophic cells grown on a U-[12C] sole source of carbon synthesize U-[12C]-amino acids which are incorporated into proteins giving rise ultimately to U-[12C]-proteins. This results in a large increase of the intensity of the monoisotope ion of peptides and proteins, and therefore allows higher identification scores and protein sequence coverage in mass spectrometry experiments. The method initially developed for signal processing and quantification of the rate of incorporation of 12C into peptides was based on a multistep process that was found difficult to implement by many laboratories. To overcome these limitations, we developed a new theoretical background to analyze the bottom-up proteomics data using SLIM-labeling (bSLIM) and set simple procedures based on open source software, using dedicated OpenMS modules, and embedded R scripts to process the bSLIM experimental data. These new tools allow both the computation of the 12C abundance in peptides to follow kinetics of protein labeling, and of the molar fraction of unlabeled and 12C-labeled peptides in multiplexing experiments to determine the relative abun-dance of proteins extracted from different biological conditions. The tools also allow us to take into account incomplete 12C labeling as observed in cells with nutritional requirements for non-labeled amino acids. These tools were validated on experimental dataset produced using various yeast strains of Saccharomyces cerevisiae and growth conditions. The workflows are built on the implemen-tation of appropriate calculus modules in a KNIME working environment. These new integrated tools provide a convenient frame-work for a wider use of the SLIM-labeling strategy.

Project description:Platelet-derived growth factors (PDGF) are disulfide-bonded dimers that act on PDGF receptors (PDGFR) to stimulate cell proliferation, differentiation, migration, and/or function. There are multiple isoforms of both the ligand and receptor, which combined with the potential for heterodimerization, gives the system great complexity. Different ligands may be promiscuous or specific for receptor partners. To better understand how ligand sequence relates to receptor recognition, the mutational landscape of PDGF-B for binding to the high affinity receptor PDGFRbeta was experimentally determined by deep mutational scanning. A PDGF-B library containing all possible single amino acid substitutions was displayed on the surface of yeast and sorted for binding to the PDGFRbeta ectodomain. Following deep sequencing, the enrichment or depletion of all mutations was calculated as a proxy for relative activity. All PDGF-B cysteines forming three intra- and two interchain disulfides are highly conserved, indicating that PDGF-B is correctly folding into disulfide-linked dimers on the yeast surface. Indeed, several mutations at the ligand dimer interface are enriched and may enhance dimerization through increased hydrophobic packing or reduced electrostatic repulsion. Residues from the protruding PDGF-B subunit in contact with the receptor are tightly conserved, whereas interfacial residues from the receding subunit are mutationally tolerant. There are multiple enriched mutations at the receptor interface that the scan predicts increase PDGF-BB–PDGFRbeta affinity. The data may prove insightful for engineering PDGF ligands biased towards forming homodimers with increased receptor affinity.

Project description:DAP12 is a transmembrane protein, expressed as a disulfide-bonded homodimer and bears an immunoreceptor tyrosine-based activation motif (ITAM). DAP12 is broadly expressed in hematopoietic cells and associates with a variety of cell surface receptors in lymphoid and myeloid cells. Macrophages express several DAP12-associated receptors including triggering receptors expressed by myeloid cells (TREM)-1,2 and 3, myeloid DAP12-associating lectin (MDL)-1, CD200R like proteins CD200R3/R4 and CD300C/D/E . Experiment Overall Design: The current experiment was designed to evaluate the effect of DAP12 knockdown on macrophage gene expression, both in basal conditions and in the response to IL-4.

Project description:Identification of targets of the protein disulfide reductase thioredoxin using liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) and thiol specific differential labeling with isotope-coded affinity tags (ICAT). Reduction of specific target disulfides is quantified by measuring ratios of cysteine residues labeled with the “heavy” (13C) and “light” (12C) ICAT reagents in peptides derived from tryptic digests of Trx-treated and non-treated samples. Keywords: protein, LC-MS/MS, ICAT