Project description:Plasma Factor XIII is a zymogen (plasma protransglutaminase) with the tetrametric structure A2B2, whereas the cellular protransglutaminase, i.e. Factor XIII in the platelet and monocyte/macrophage, consists exclusively of A subunits (A2). It is generally accepted that at Ca2+ concentrations comparable with that in plasma the proteolytic removal of an N-terminal activation peptide is the prerequisite for the Ca2(+)-induced formation of a catalytically active configuration of subunit A. In this study it was demonstrated that at high concentrations NaCl or KCl induced a non-proteolytic activation of cellular (placental macrophage) but not plasma protransglutaminase. The activation depended on time and salt concentration, and Ca2+, in the range 0-20 mM, greatly enhanced the activation process. At 1.25 M-NaCl maximal activation occurred within 60 min in the presence of 2 mM-CaCl2, and even at physiological NaCl concentration a slow progressive activation could be observed in the presence of Ca2+. The specific activity of salt-activated Factor XIII was 1.5-2.0-fold higher than that obtained after thrombin activation. The non-proteolytic activation of cellular protransglutaminase was abolished by the addition of subunit B of plasma Factor XIII in stoichiometric amount, which suggests that (one of) the physiological function(s) of the B subunit in plasma Factor XIII is to prevent the slow spontaneous activation of A subunit that would occur in a plasmatic environment.

Project description:The dimeric FXIII-A2, a pro-transglutaminase is the catalytic part of the heterotetrameric coagulation FXIII-A2B2 complex that upon activation by calcium binding/thrombin cleavage covalently cross-links preformed fibrin clots protecting them from premature fibrinolysis. Our study characterizes the recently disclosed three calcium binding sites of FXIII-A concerning evolution, mutual crosstalk, thermodynamic activation profile, substrate binding, and interaction with other similarly charged ions. We demonstrate unique structural aspects within FXIII-A calcium binding sites that give rise to functional differences making FXIII unique from other transglutaminases. The first calcium binding site showed an antagonistic relationship towards the other two. The thermodynamic profile of calcium/thrombin-induced FXIII-A activation explains the role of bulk solvent in transitioning its zymogenic dimeric form to an activated monomeric form. We also explain the indirect effect of solvent ion concentration on FXIII-A activation. Our study suggests FXIII-A calcium binding sites could be putative pharmacologically targetable regions.

Project description:Factor XIII catalyzes formation of ?-glutamyl-?-lysyl crosslinks within fibrin clots. FXIII A(2) can be activated proteolytically with thrombin and low mM Ca(2+) or nonproteolytically with high monovalent/divalent cations along with low mM Ca(2+). Physiologically, FXIII A(2) is poised to respond to transient influxes of Ca(2+) in a Na(+) containing environment. A successful strategy to monitor FXIII conformational events is hydrogen-deuterium exchange (HDX) coupled with mass spectrometry. FXIII A(2) was examined in the presence of different cations (Ca(2+), Mg(2+), Ba(2+), Cu(2+), Na(+), TMAC(+), and EDA(2+)) ranging from 1 to 2mM, physiological Ca(2+) concentration, to 50-500mM for nonproteolytic activation. Increases in FXIII solvent exposure could already be observed at 1mM Ca(2+) for the dimer interface, the catalytic site, and glutamine substrate regions. By contrast, solvent protection was observed at the secondary cleavage site. These events occurred even though 1mM Ca(2+) is insufficient for FXIII activation. The metals 1mM Mg(2+), 1mM Ba(2+), and 1mM Cu(2+) each led to conformational changes, many in the same FXIII regions as Ca(2+). FXIII could also be activated nonproteolytically with 500mM tetramethylammonium chloride (TMAC(+)) and 500mM ethylenediamine (EDA(2+)), both with 2mM Ca(2+). These different HDX studies help reveal the first FXIII segments that respond to physiological Ca(2+) levels.

Project description:1. A continuous fluorimetric assay for blood-clotting Factor XIII based on the incorporation of dansylcadaverine into casein was investigated. 2. Hammarsten casein was fractionated to yield the beta-casein, which was dephosphorylated and acetylated to give a substrate which itself did not bind calcium and which was not cross-linked by the activated Factor. 3. The modified beta-casein was used as substrate for a continuous fluorimetric assay and as substrate for the incorporation of radioactive glycine ethylester. 4. A linked fluorimetric assay for the zymogen is described. 5. The K(m) for calcium was redetermined and at 0.2mm was in the physiological range and much lower than the values reported by others using substrates which interact with calcium. 6. The K(m) for casein is about 14mum.

Project description:1. The reaction of iodoacetate, 2-chloromercuri-4-nitrophenol and 5,5'-dithiobis-(2-nitrobenzoate) with thrombin-cleaved Factor XIII (i.e. Factor XIII(a)) was accompanied by enzyme inhibition. 2. The reaction with iodoacetate and 5,5'-dithiobis-(2-nitrobenzoate) was absolutely dependent on Ca(2+), and the rate of reaction increased with the Ca(2+) concentration up to very high, non-physiological concentrations. 3. 2-Chloromercuri-4-nitrophenol reacted with Factor XIII(a) in the absence of Ca(2+), but at a much slower rate. 4. Stopped-flow methods were used to quantify the reaction with 5,5'-dithiobis-(2-nitro-benzoate) because of the Ca(2+)-dependent dissociation of Factor XIII(a) (a'(2)b(2)) and subsequent aggregation of the a' chains into turbid precipitates. 5. The 3-carboxy-4-nitrothio-phenolate released was consistent with the reaction of 2 thiol groups/molecule of Factor XIII(a). The isolated b chains of Factor XIII did not react with either of the chromophoric reagents. This indicated that the a' chains of Factor XIII(a) were responsible for the thiol reactivity of the enzyme. 6. The Ca(2+) dependence of the enzyme inhibition by these thiol reagents was very dependent on protein concentration. This is discussed in relation to the Ca(2+)-induced dissociation of Factor XIII(a). 7. The acceptor substrate, casein, decreased the Ca(2+) concentration required for enzyme inhibition by both the mercurial and the aromatic disulphide compounds. Dansylcadaverine did not affect Ca(2+) dependence of inhibition.

Project description:1. Large quantities of human Factor XIII were prepared from ethanol precipitates of outdated human plasma. 2. Material homogeneous after chromatography on DEAE-cellulose was further resolved into two proteins, A and B, after filtration on Sepharose 6B. 3. Protein A has a molecular weight of 350000 and a subunit structure a(2)b(2) and is activated by thrombin and calcium. Protein B is inactive and probably has a subunit structure b(2). 4. Calcium causes protein A, after thrombin cleavage, to fragment to give protein B and a protein, containing only a' subunits, which is catalytically active. The latter protein slowly forms a misty precipitate which is still active and not cross-linked covalently. This confirms the suggestion of Schwartz et al. (1971) that catalytic activity is only associated with a' subunits. 5. Iodoacetate, which inhibits the enzyme, does not inhibit dissociation and aggregation of protein A. 6. The existence of two proteins and the fragmentation are possible explanations for the wide range of molecular weights given for Factor XIII in the literature.

Project description:Factor XIII A (FXIIIA) is a member of the transglutaminase enzyme family that cross-links both intra- and extracellular protein substrates. To prevent undesired cross-linking, FXIIIA is expressed as an inactive zymogen and exists intracellularly as an A2 homodimer. In plasma, FXIII A2 is complexed with two protective factor XIII B subunits (A2 B2 ) that dissociate upon activation of the zymogen. Based on limited experimental data, activated FXIII was considered a dimer of two catalytically active A subunits. However, accumulating but indirect evidence has suggested activation may lead to a monomeric state instead. In the present study, we employed analytical ultracentrifugation (AUC) to directly explore the oligomerization state of zymogen as well as active FXIIIA in solution. We first confirmed that the zymogen was a FXIIIA2 dimer. When we activated FXIIIA nonproteolytically (by high mm Ca2+ ), the protein dissociated to monomers. More importantly, FXIIIA incubation with its physiological partner, the protease thrombin, led to a monomeric state as well. AUC studies of partially cleaved FXIIIA further suggested that thrombin cleavage of a single activation peptide in a zymogen dimer is sufficient to weaken intersubunit interactions, initiating the transition to monomer. The enzymatic activity of the thrombin-cleaved species was higher than nonproteolytically activated enzyme, suggesting that displacement of the activation peptide renders the FXIIIA more accessible to substrates. Thus, results provide evidence that FXIII undergoes a change in oligomerization state as part of the activation process, and emphasize the role of the activation peptide in preventing FXIIIA catalytic activity. ENZYMES:Factor XIIIA (EC2.3.2.13).

Project description:The formation of a blood clot involves the interplay of thrombin, fibrinogen, and Factor XIII. Thrombin cleaves fibrinopeptides A and B from the N-termini of the fibrinogen Aalpha and Bbeta chains. Fibrin monomers are generated that then polymerize into a noncovalently associated network. By hydrolyzing the Factor XIII activation peptide segment at the R37-G38 peptide bond, thrombin assists in activating the transglutaminase FXIIIa that incorporates cross-links into the fibrin clot. In this work, the kinetic effects of introducing fibrinogen Aalpha character into the FXIII AP segment were examined. Approximately 25% of fibrinogen Aalpha is phosphorylated at Ser3, producing a segment with improved binding to thrombin. FXIII AP ((22)AEDDL(26)) has sequence properties in common with Fbg Aalpha ((1)ADSpGE(5)). Kinetic benefits to FXIII AP cleavage were explored by extending FXIII AP (28-41) to FXIII AP (22-41) and examining peptides with D24, D24S, D24Sp, and D24Sp P27G. These modifications did not provide the same kinetic advantages that were observed with Fbg Aalpha (1-20) S3p. Such results further emphasize that FXIII AP derives most of its substrate specificity from the P(9)-P(1) segment. To enhance the kinetic properties of FXIII AP (28-41), we introduced substitutions at the P(9), P(4), and P(3) positions. Studies reveal that FXIII AP (28-41) V29F, V34G, V35G exhibits kinetic improvements that are comparable to those of FXIII AP V29F, V34L and approach those of Fbg Aalpha (7-20). Selective changes to the FXIII AP segment sequence may be used to design FXIII species that can be activated more or less readily.

Project description:The activation peptide of blood coagulation factor XIII (AP-FXIII) has important functions in stabilizing the FXIII-A2 dimer and regulating FXIII activation. Contributions of many of its 37 amino acids to these functions have been described. However, the role of proline 36, which is adjacent to the thrombin cleavage site at Arg37, has not yet been studied in detail. We approached this question when we came across a patient with congenital FXIII deficiency in whom we detected a novel Pro36Ser mutation. We expressed the mutant FXIII-A Pro36Ser protein in Chinese hamster ovary cells and found that this mutation does not influence FXIII-A expression but significantly inhibits proteolytic activation by thrombin. The enzymatic transglutaminase activity is not affected as it can be induced in the presence of high Ca2+ concentrations. We performed nuclear magnetic resonance analysis to investigate AP-FXIII-thrombin interactions, which showed that the mutant Ser36 peptide binds less well to the thrombin surface than the native Pro36 peptide. The Arg37 at the P1 position still makes strong interactions with the active site cleft but the P4-P2 residues (34VVS36) appear to be less well positioned to contact the neighbouring thrombin active site region. In conclusion, we have characterized a novel mutation in AP-FXIII representing only the fourth case of the rare FXIII-A type II deficiency. This case served as a perfect in vivo model to shed light on the crucial role of Pro36 in the proteolytic activation of FXIII-A. Our results contribute to the understanding of structure-function relationship in FXIII.

Project description:Thrombin helps to activate Factor XIII (FXIII) by hydrolyzing the R37-G38 peptide bond. The resultant transglutaminase introduces cross-links into the fibrin clot. With the development of therapeutic coagulation factors, there is a need to better understand interactions involving FXIII. Such knowledge will help predict ability to activate FXIII and thus ability to promote/hinder the generation of transglutaminase activity. Kinetic parameters have been determined for a series of thrombin species hydrolyzing the FXIII (28-41) V34X activation peptides (V34, V34L, V34F, and V34P). The V34P substitution introduces PAR4 character into the FXIII, and the V34F exhibits important similarities to the cardioprotective V34L. FXIII activation peptides containing V34, V34L, or V34P could each be accommodated by alanine mutants of thrombin lacking either the W60d or Y60a residue in the 60-insertion loop. By contrast, FXIII V34F AP could be cleaved by thrombin W60dA but not by Y60aA. FXIII V34P is highly reliant on the thrombin W215 platform for its strong substrate properties whereas FXIII V34F AP becomes the first segment that can maintain its K(m) upon loss of the critical thrombin W215 residue. Interestingly, FXIII V34F AP could also be readily accommodated by thrombin L99A and E217A. Hydrolysis of FXIII V34F AP by thrombin W217A/E217A (WE) was similar to that of FXIII V34L AP whereas WE could not effectively cleave FXIII V34P AP. FXIII V34F and V34P AP show promise for designing FXIII activation systems that are either tolerant of or greatly hindered by the presence of anticoagulant thrombins.