Project description:Basic mathematical model of the formation of coagulation factor Xa involving TF:VIIa and its inhibition by TFPI.

Project description:Reused mathematical model (Hockin et al., 2002) of blood coagulation simulating the effects of coagulation factor inhibitors, fondaparinux (synthetic heparin) and Rivaroxaban. Fondaparinux (Fpx) simulated to reversibly bind with ATIII before irreversibly binding to Xa, IXa, mIIa, TF:VIIa, Xa:Va and IIa. Rivaroxaban simulated to bind reversibly to Xa and Xa:Va.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way. Here, we designed two octapeptides, GIPRAAGD (α Thrombin) and GIGRRIAE (Factor Xa), and evaluated their cleavage with the target proteases.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way. Here, we designed two octapeptides, GIPRAAGD (α Thrombin) and GIGRRIAE (Factor Xa), and evaluated their cleavage with the target proteases.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way. Here, we designed two octapeptides, GIPRAAGD (α Thrombin) and GIGRRIAE (Factor Xa), and evaluated their cleavage with the target proteases.

Project description:Proteases are crucial physiologic regulators of protein structure and function. While proteomic methods contributed extensively to protease characterization efforts, technical challenges remain in terms of throughput, scalability and large datasets of protease cleavages remain scarce. Here, we describe a high-throughput protease screen (HTPS) which allows simultaneous characterization of multiple proteases under various conditions on a microscale 96FASP format. After benchmarking the performance with Trypsin, LysC, GluC, AspN, Chymotrypsin, MMP-2 and MMP-3, we applied it to profile proteases of the blood coagulation cascade (Factors VIIa, IXa, Xa, XIa, Thrombin α, β and γ, Plasmin and Protein C). The large dataset enabled us to map activity, specificity, cleave entropy, allosteric changes of blood cascade proteases induced by Na+ and to predict potential substrates in a data-driven way.

Project description:Mathematical model of blood coagulation. Extended model of Mitrophanov2011 (which is an extension of Hockin2002). Additional reactions added involving thrombin. Modelling the effects of dilution and addition of recombinant factor VIIa, II, VII, IX, X, AT.

Project description:Blood coagulation model investigating effects of Xa-inhibitors (Rivaroxaban and Apixaban). Model is an extension of Pohl1994 and reduced from Wajima2009. Encoding the model from the supplementary files results in 43 species, 82 reactions and 111 parameters. Including the drug (Xa-inhibitor) and drug-Xa complexes results in 46 species, 84 reactions and 115 parameters (+1 dummy variable to change inhibitory kinetic parameters depending on which drug is simulated). The publication lists there being 45 species, 84 reactions and 116 parameters. Publication figure 2 has 45 species present however the complex VIIa:Xa (reaction 51 involving Xa and VIIa) is not shown. This figure also has numerous small errors such as listing IXa:ATIII complex twice (instead of one being XIa:ATIII), not showing XIa:ATIII, typo ('Va' -> Va), typo (IXa + VIIIa -> IXA:'VIIa'). Rate laws for Xa-drug interactions were assumed to be mass action.

Project description:Mathematical model of blood coagulation investigating effects of varied factor VIIa on thrombin generation. Model derived from Hockin2002/Butenas2004. Butenas added two new reactions (R28 and R29) and two new parameters (k43 and k44). Here, changes to parameters k32 and k38 and TF initial conc. changed to 5e-12

Project description:Jones1994_BloodCoagulation This model is built based on the experimental findings described in Lawson et al., 1994 (PMID:8083241) This model is described in the article: A model for the tissue factor pathway to thrombin. II. A mathematical simulation. Jones KC, Mann KG. J. Biol. Chem. 1994 Sep; 269(37): 23367-23373 Abstract: A mathematical simulation of the tissue factor pathway to the generation of thrombin has been developed using a combination of empirical, estimated, and deduced rate constants for reactions involving the activation of factor IX, X, V, and VIII, in the formation of thrombin, as well as rate constants for the assembly of the coagulation enzyme complexes which involve factor VIIIa-factor IXa (intrinsic tenase) and factor Va-Xa (prothrombinase) assembled on phospholipid membrane. Differential equations describing the fate of each species in the reaction were developed and solved using an interactive procedure based upon the Runge-Kutta technique. In addition to the theoretical considerations involving the reactions of the tissue factor pathway, a physical constraint associated with the stability of the factor VIIIa-factor IXa complex has been incorporated into the model based upon the empirical observations associated with the stability of this complex. The model system provides a realistic accounting of the fates of each of the proteins in the coagulation reaction through a range of initiator (factor VIIa-tissue factor) concentrations ranging from 5 pM to 5 nM. The model is responsive to alterations in the concentrations of factor VIII, factor V, and their respective activated species, factor VIIIa and factor Va, and overall provides a reasonable approximation of empirical data. The computer model permits the assessment of the reaction over a broad range of conditions and provides a useful tool for the development and management of reaction studies. This model is hosted on BioModels Database and identified by: BIOMD0000000336. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.