Co-crystal structure and inhibition of factor Xa by PD0313052 identifies structurally stabilized active site residues of factor Xa and prothrombinase

The enzyme complex prothrombinase plays a pivotal role in fibrin clot development through the production of thrombin, making this enzyme complex an attractive target for therapeutic regulation. This study both functionally and structurally characterizes a potent, highly selective, active site directed inhibitor of human factor Xa and prothrombinase, PD0313052, and identifies structurally conserved residues in factor Xa and prothrombinase. Analyses of the association and dissociation of PD0313052 with human factor Xa identified a reversible, slow-onset mechanism of inhibition and a simple, single-step bimolecular association between factor Xa and PD0313052. This interaction was governed by association (k(on)) and dissociation (k(off)) rate constants of (1.0 +/- 0.1) x 10(7) M(-1) s(-1) and (1.9 +/- 0.5) x 10(-3) s(-1), respectively. The inhibition of human factor Xa by PD0313052 displayed significant tight-binding character described by a Ki* = 0.29 +/- 0.08 nM. Similar analyses of the inhibition of human prothrombinase by PD0313052 also identified a slow-onset mechanism with a Ki* = 0.17 +/- 0.03 nM and a k(on) and k(off) of (0.7 +/- 0.1) x 10(7) M(-1) s(-1) and (1.7 +/- 0.8) x 10(-3) s(-1), respectively. Crystals of factor Xa and PD0313052 demonstrated hydrogen bonding contacts within the S1-S4 pocket at residues Ser195, Asp189, Gly219, and Gly216, as well as interactions with aromatic residues within the S4 pocket. Overall, these data demonstrate that the inhibition of human factor Xa by PD0313052 occurs via a slow, tight-binding mechanism and indicate that active site residues of human factor Xa, including the catalytic Ser195, are effectively unaltered following assembly into prothrombinase.     

Reversible, slow, tight-binding inhibition of human leukocyte elastase

CBz-Ala-Ala-Pro-ambo-Val-CF3 (1) was synthesized. The compound inhibits human Leucocyte elastase with Ki = 1.0 x 10(-9) M. This inhibitor is reversible, slow, tight-binding inhibitor with k on = 2 x 10(4) M-1 s-1 k off = 1.9 x 10(-5) s-1. For the solubilization of elastin by HLE by 1 I.C. 50 = 110 nM. This inhibitor is the most effective aldehyde or ketone inhibitor of a serine proteinase yet described.     

Kinetics of factor Xa inhibition by recombinant tick anticoagulant peptide: both active site and exosite interactions are required for a slow- and tight-binding inhibition mechanism

Recombinant tick anticoagulant peptide (rTAP) is a competitive slow- and tight-binding inhibitor of factor Xa (FXa) with a reported equilibrium dissociation constant (K(I)) of approximately 0.2 nM. The inhibitory characteristics and the high selectivity of rTAP for FXa are believed to arise from the ability of the inhibitor to specifically interact with the residues of both the active site as well as those remote from the active site pocket of the protease. To localize the rTAP-interactive sites on FXa, the kinetics of inhibition of wild-type and 18 different mutants of recombinant FXa by the inhibitor were studied by either a discontinuous assay method employing the tight-binding quadratic equation or a continuous assay method employing the slow-binding kinetic approach. It was discovered that K(I) values for the interaction of rTAP with four FXa mutants (Tyr(99) --> Thr, Phe(174) --> Asn, Arg(143) --> Ala, and a Na(+)-binding loop mutant in which residues 220-225 of FXa were replaced with the corresponding residues of thrombin) were elevated by 2-3 orders of magnitude for each mutant. Further studies revealed that the characteristic slow type of inhibition by rTAP was also eliminated for the mutants. These findings suggest that the interaction of rTAP with the P2-binding pocket, the autolysis loop, and the Na(+)-binding loop is primarily responsible for its high specificity of FXa inhibition by a slow- and tight-binding mechanism.     

Purification and characterization of the beta-trefoil fold protein barley alpha-amylase/subtilisin inhibitor overexpressed in Escherichia coli

Barley alpha-amylase/subtilisin inhibitor (BASI) is a beta-trefoil fold protein related to soybean trypsin inhibitor (Kunitz) and inhibits barley alpha-amylase isozyme 2 (AMY2), which is de novo synthesized in the seed during germination. Recombinant BASI was produced in Escherichia coli in an untagged form (untagged rBASI), in two His(6)-tag forms (His(6)-rBASI and His(6)-Xa-rBASI), and in an intein-CBD-tagged form (rBASI (intein)). The yields per liter culture after purification were (i) 25 mgl(-1) His(6)-rBASI; (ii) 6 mgl(-1) rBASI purified after cleavage of His(6)-Xa-rBASI by Factor Xa; (iii) 3 mgl(-1) untagged rBASI; and (iv) 0.2 mgl(-1) rBASI after a chitin-column and autohydrolysis of the rBASI-intein-CBD. In Pichia pastoris, rBASI was secreted at 0.1 mgl(-1). The recombinant BASI forms and natural seed BASI (sBASI) all had an identical isoelectric point of 7.2 and a mass of 19,879 Da, as determined by mass spectrometry. The fold of rBASI from the different preparations was confirmed by circular dichroism spectroscopy and rBASI (intein), His(6)-rBASI, and sBASI inhibited AMY2 catalyzed starch hydrolysis with K(i) of 0.10, 0.06, and 0.09 nM, respectively. Surface plasmon resonance analysis of the formation of AMY2/rBASI (intein) gave k(on)=1.3x10(5)M(-1)s(-1), k(off)=1.4x10(-4)s(-1), and K(D)=1.1 nM, and of the savinase-His(6)-rBASI complex k(on)=21.0x10(4)M(-1)s(-1), k(off)=53.0x10(-4)s(-1), and K(D)=25.0 nM, in agreement with sBASI values. K(i) was 77 and 65 nM for inhibition of savinase activity by His(6)-rBASI and sBASI, respectively.     

Binding sites for blood coagulation factor Xa and protein S involving residues 493-506 in factor Va.

Inactivation due to cleavage of Factor Va (FVa) at Arg 506 by activated protein C (APC) helps to downregulate blood coagulation. To identify potential functional roles of amino acids near Arg 506, synthetic overlapping pentadecapeptides comprising FVa heavy chain residues 481-525 were tested for their ability to inhibit prothrombin activation by prothrombinase complexes [Factor Xa (FXa):FVa:phospholipids:Ca2+]. The most potent inhibition was observed for peptide VP493 (residues 493-506), with 50% inhibition at 2.5 microM. VP493 also inhibited FXa in plasma in FXa-1-stage clotting assays by 50% at 3 microM. When the C-terminal carboxamide group of VP493 was replaced by a carboxyl group, most prothrombinase inhibitory activity was lost. VP493 preincubated with FXa inhibited prothrombinase with a pattern of mixed inhibition. Homologous peptides from Factor VIII sequences did not inhibit prothrombinase. Affinity-purified antibodies to VP493 inhibited prothrombinase activity and prolonged FXa-1-stage clotting times. VP493 also blocked the ability of protein S to inhibit prothrombinase independently of APC. Immobilized VP493 bound specifically with similar affinity to both FXa and protein S (Kd approximately 40 nM), but did not measurably bind prothrombin or APC. These studies suggest that FVa residues 493-506 contribute to binding sites for both FXa and protein S, providing a rationale for the ability of protein S to negate the protective effect of FXa toward APC cleavage of FVa. Possible loss of this FVa binding site for FXa due to cleavage at Arg 506 by APC may help explain why this cleavage causes 40% decrease in FVa activity and facilitates inactivation of FVa.     

A slow-tight binding inhibitor of dopamine beta-monooxygenase: a transition state analogue for the product release step

The steady-state kinetic data show that 3-hydroxy-4-phenylthiazole-2(3H)-thione (3H4PTT) is a potent tight-binding inhibitor for dopamine beta-monooxygenase (DbetaM) with a dissociation constant of 0.9 nM. Ackermann-Potter plots of the enzyme dependence of the inhibition revealed that the stoichiometry of the enzyme inhibition by 3H4PTT is 1:1. Pre-steady-state progress curves at varying inhibitor with fixed reductant and enzyme concentrations clearly show the slow binding behavior of the inhibitor. The observed kinetic behavior is consistent with the apparent direct formation of the tightly bound E x I* complex. The k(on) and k(off) for 3H4PTT which were determined under pre-steady-state conditions at variable inhibitor concentrations were found to be (1.85 +/- 0.07) x 10(6) M(-1) s(-1) and (1.9 +/- 0.6) x 10(-3) s(-1), respectively. The dissociation constant calculated from these rates was similar to that determined under steady-state conditions, confirming that 3H4PTT is a kinetically well-behaved inhibitor. The steady-state as well as pre-steady-state kinetic studies at variable DMPD concentrations show that the inhibition is competitive with respect to the reductant, demonstrating the exclusive interaction of 3H4PTT with the oxidized form of the enzyme. The kinetic behavior and the structural properties of 3H4PTT are consistent with the proposal that the E x 3H4PTT complex may mimic the transition state for the product (protonated) release step of the enzyme. Therefore, 3H4PTT could be used as a convenient probe to examine the properties of the E x P complex of the DbetaM reaction and also as an active site titrant for the oxidized enzyme.     

Kinetics and energetics of the binding between barley alpha-amylase/subtilisin inhibitor and barley alpha-amylase 2 analyzed by surface plasmon resonance and isothermal titration calorimetry

The kinetics and energetics of the binding between barley alpha-amylase/subtilisin inhibitor (BASI) or BASI mutants and barley alpha-amylase 2 (AMY2) were determined using surface plasmon resonance and isothermal titration calorimetry (ITC). Binding kinetics were in accordance with a 1:1 binding model. At pH 5.5, [Ca(2+)] = 5 mM, and 25 degrees C, the k(on) and k(off) values were 8.3 x 10(+4) M(-1) s(-1) and 26.0 x 10(-4) s(-1), respectively, corresponding to a K(D) of 31 nM. K(D) was dependent on pH, and while k(off) decreased 16-fold upon increasing pH from 5.5 to 8.0, k(on) was barely affected. The crystal structure of AMY2-BASI shows a fully hydrated Ca(2+) at the protein interface, and at pH 6.5 increase of [Ca(2+)] in the 2 microM to 5 mM range raised the affinity 30-fold mainly due to reduced k(off). The K(D) was weakly temperature-dependent in the interval from 5 to 35 degrees C as k(on) and k(off) were only increasing 4- and 12-fold, respectively. A small salt dependence of k(on) and k(off) suggested a minor role for global electrostatic forces in the binding and dissociation steps. Substitution of a positively charged side chain in the mutant K140L within the AMY2 inhibitory site of BASI accordingly did not change k(on), whereas k(off) increased 13-fold. ITC showed that the formation of the AMY2-BASI complex is characterized by a large exothermic heat (Delta H = -69 +/- 7 kJ mol(-1)), a K(D) of 25 nM (27 degrees C, pH 5.5), and an unfavorable change in entropy (-T Delta S = 26 +/- 7 kJ mol(-1)). Calculations based on the thermodynamic data indicated minimal structural changes during complex formation.     

Enantiopure five-membered cyclicdiamine derivatives as potent and selective inhibitors of factor Xa. Improving in vitro metabolic stability via core modifications

We previously reported a series of enantiopure cis-(1R,2S)-cyclopentyldiamine derivatives as potent and selective inhibitors of Factor Xa (FXa). Herein, we describe our approach to improve the metabolic stability of this series via core modifications. Multiple resulting series of compounds demonstrated similarly high FXa potency and improved metabolic stability in human liver microsomes compared with the cyclopentyldiamide 1. (3R,4S)-Pyrrolidinyldiamide 31 was the best overall compound with human FXa K(i) of 0.50 nM, PT EC(2x) of 2.1 microM in human plasma, bioavailability of 25% and t(1/2)of 2.7h in dogs. Further biochemical characterization of compound 31 is also presented.     

Role of factor VIII C2 domain in factor VIII binding to factor Xa.

Factor VIII (FVIII) is activated by proteolytic cleavages with thrombin and factor Xa (FXa) in the intrinsic blood coagulation pathway. The anti-C2 monoclonal antibody ESH8, which recognizes residues 2248-2285 and does not inhibit FVIII binding to von Willebrand factor or phospholipid, inhibited FVIII activation by FXa in a clotting assay. Furthermore, analysis by SDS-polyacrylamide gel electrophoresis showed that ESH8 inhibited FXa cleavage in the presence or absence of phospholipid. The light chain (LCh) fragments (both 80 and 72 kDa) and the recombinant C2 domain dose-dependently bound to immobilized anhydro-FXa, a catalytically inactive derivative of FXa in which dehydroalanine replaces the active-site serine. The affinity (K(d)) values for the 80- and 72-kDa LCh fragments and the C2 domain were 55, 51, and 560 nM, respectively. The heavy chain of FVIII did not bind to anhydro-FXa. Similarly, competitive assays using overlapping synthetic peptides corresponding to ESH8 epitopes (residues 2248-2285) demonstrated that a peptide designated EP-2 (residues 2253-2270; TSMYVKEFLISSSQDGHQ) inhibited the binding of the C2 domain or the 72-kDa LCh to anhydro-FXa by more than 95 and 84%, respectively. Our results provide the first evidence for a direct role of the C2 domain in the association between FVIII and FXa.     

Kinetics of slow, tight-binding inhibitors of angiotensin converting enzyme

Five phosphorus-containing inhibitors of angiotensin converting enzyme were found to exhibit slow, tight-binding kinetics by using furanacryloyl-L-phenylalanylglycylglycine as substrate at pH 7.50 and T = 25 degrees C. Two of the inhibitors, (O-ethylphospho)-Ala-Pro (2) and (O-isopropylphospho)-Ala-Pro (3), are found to follow at minimum a two-step mechanism of binding (mechanism B) to the enzyme. This mechanism consists of an initial fast formation of a weaker enzyme-inhibitor complex (Ki = 130 nM for 2 and 180 nM for 3) followed by a slow reversible isomerization to a tighter complex with measurable forward (K3) and reverse (k4) rate constants (k3 = 4.5 X 10(-2) s-1 for 2 and 5.4 X 10(-2) s-1 for 3; k4 = 9.2 X 10(-3) s-1 for 2 and 3.5 X 10(-3) s-1 for 3). For the remaining three inhibitors, phospho-Ala-Pro (1), (O-benzyl-phospho)-Ala-Pro (4), and (P-phenethylphosphono)-Ala-Pro (5), a one-step binding mechanism (mechanism A) is observed under the conditions of the experiment. The second-order rate constants k1 (M-1 s-1) for the binding of these inhibitors to converting enzyme are found to have values more than 3 orders of magnitude lower than the diffusion-controlled limit for a bimolecular reaction involving the enzyme, viz., 3.9 X 10(5) for 1, 2.2 X 10(5) for 4, and 4.8 X 10(5) for 5.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transferrin, is a mixed chelate-protein ternary complex involved in the mechanism of iron uptake by serum-transferrin in vitro?

Iron uptake by transferrin from triacetohydroxamatoFe(III) (Fe(AHA)3) in the presence of bicarbonate has been investigated between pH 7 and 8.2. The protein transits from the opened apo- to the closed holoform by several steps with the accumulation of at least three kinetic intermediates. All these steps are accompanied by proton losses, probably occurring from the protein ligands and the side-chains involved in the interdomain H-bonding nets. The minor bihydroxamatoFe(III) species Fe(AHA)2 exchanges its iron with the C-site of apotransferrin in interaction with bicarbonate without detectable formation of any intermediate protein-iron-ligand mixed complex; direct second-order rate constant k1=4.15(+/-0.05)x10(7) M(-1) s(-1). The kinetic product loses a single proton and undergoes a modification in its conformation followed by the loss of two or three protons; first-order rate constant k2=3.25(+/-0.15) s(-1). This induces a new modification in the conformation; first-order rate constant k3=5.90(+/-0.30)x10(-2) s(-1). This new modification in conformation rate controls iron uptake by the N-site of the protein and is followed by a single proton loss; K3a=6.80 nM. Finally, the holoprotein or the monoferric transferrin in its thermodynamic equilibrated state is produced by a last modification in the conformation occurring in about 4000 seconds. But for the Fe(AHA)3 dissociation and the involvement of Fe(AHA)2 in the first step of iron uptake, this mechanism is identical to that reported for iron uptake from FeNAc3. This implies that the exchange of iron between a chelate and serum-transferrin occurs by a single general mechanism. The nature of the iron-providing chelate is only important for the first kinetic step of the exchange, which can be slowed to such an extent that it rate limits the exchange of iron.     

Thermodynamic linkage between the S1 site, the Na+ site, and the Ca2+ site in the protease domain of human coagulation factor xa. Studies on catalytic efficiency and inhibitor binding

The serine protease domain of factor Xa (FXa) contains a sodium as well as a calcium-binding site. Here, we investigated the functional significance of these two cation-binding sites and their thermodynamic links to the S1 site. Kinetic data reveal that Na(+) binds to the substrate bound FXa with K(d) approximately 39 mm in the absence and approximately 9.5 mm in the presence of Ca(2+). Sodium-bound FXa (sodium-Xa) has approximately 18-fold increased catalytic efficiency ( approximately 4.5-fold decrease in K(m) and approximately 4-fold increase in k(cat)) in hydrolyzing S-2222 (benzoyl-Ile-Glu-Gly-Arg-p-nitroanilide), and Ca(2+) further increases this k(cat) approximately 1.4-fold. Ca(2+) binds to the protease domain of substrate bound FXa with K(d) approximately 705 microm in the absence and approximately 175 microm in the presence of Na(+). Ca(2+) binding to the protease domain of FXa (Xa-calcium) has no effect on the K(m) but increases the k(cat) approximately 4-fold in hydrolyzing S-2222, and Na(+) further increases this k(cat) approximately 1.4-fold. In agreement with the K(m) data, sodium-Xa has approximately 5-fold increased affinity in its interaction with p-aminobenzamidine (S1 site probe) and approximately 4-fold increased rate in binding to the two-domain tissue factor pathway inhibitor; Ca(2+) (+/-Na(+)) has no effect on these interactions. Antithrombin binds to Xa-calcium with a approximately 4-fold faster rate, to sodium-Xa with a approximately 24-fold faster rate and to sodium-Xa-calcium with a approximately 28-fold faster rate. Thus, Ca(2+) and Na(+) together increase the catalytic efficiency of FXa approximately 28-fold. Na(+) enhances Ca(2+) binding, and Ca(2+) enhances Na(+) binding. Further, Na(+) enhances S1 site occupancy, and S1 site occupancy enhances Na(+) binding. Therefore, Na(+) site is thermodynamically linked to the S1 site as well as to the protease domain Ca(2+) site, whereas Ca(2+) site is only linked to the Na(+) site. The significance of these findings is that during physiologic coagulation, most of the FXa formed will exist as sodium-Xa-calcium, which has maximum biologic activity.     

Platelet receptor occupancy with factor IXa promotes factor X activation

To investigate the activated platelet surface as a locus for factor X activation, the functional consequences of factor IXa binding to platelets were studied. The concentration of factor IXa required for half-maximal rates of factor X activation in the presence of factor VIIIa and thrombin-activated platelets was 0.53 nM, which is close to the Kd (0.56 nM) for factor IXa binding to platelets under identical conditions, determined from equilibrium binding studies. In direct comparative experiments, there was a close correspondence between equilibrium binding of factor IXa to thrombin-activated platelets in the presence of factor VIIIa and kinetic determinations of factor X activation rates. Analysis by polyacrylamide gel electrophoresis revealed that 125I-labeled factor IXa bound to platelets was structurally intact and did not form covalent complexes with platelet proteins. Factor IXa active site-inhibited by 5-dimethylaminonaphthalene-1-sulfonyl glutamyl-glycylarginyl chloromethyl ketone was shown to be a competitive inhibitor of factor IXa binding in the absence (Ki = 2.3 nM) and presence (Ki = 0.43 nM) of factor VIIIa and factor X and of factor X activation (Ki = 0.4 nM) by factor IXa in the presence of factor VIIIa, indicating that the generation of factor Xa is not required for factor IXa binding and that factor IXa bound to activated platelets in the presence of factor VIIIa is closely coupled with rates of factor X activation. We conclude that factor IXa bound tightly to a platelet receptor in the presence of factor VIIIa is the enzyme active in factor X activation.     

Inhibition of tissue factor-factor VIIa-catalyzed factor X activation by factor Xa-tissue factor pathway inhibitor. A rotating disc study on the effect of phospholipid membrane composition.

The physiological inhibitor of tissue factor (TF).factor VIIa (FVIIa), full-length tissue factor pathway inhibitor (TFPI(FL)) in complex with factor Xa (FXa), has a high affinity for anionic phospholipid membranes. The role of anionic phospholipids in the inhibition of TF.FVIIa-catalyzed FX activation was investigated. FXa generation at a rotating disc coated with TF embedded in a membrane composed of pure phosphatidylcholine (TF.PC) or 25% phosphatidylserine and 75% phosphatidylcholine (TF.PSPC) was measured in the presence of preformed complexes of FXa.TFPI(FL) or FXa.TFPI(1-161) (TFPI lacking the third Kunitz domain and C terminus). At TF.PC, FXa.TFPI(FL) and FXa.TFPI(1-161) showed similar rate constants of inhibition (0.07 x 10(8) M(-1) s(-1) and 0.1 x 10(8) M(-1) s(-1), respectively). With phosphatidylserine present, the rate constant of inhibition for FXa.TFPI(FL) increased 3-fold compared with a 9-fold increase in the rate constant for FXa. TFPI(1-161). Incubation of TF.PSPC with FXa.TFPI(FL) in the absence of FVIIa followed by depletion of solution FXa.TFPI(FL) showed that FXa.TFPI(FL) remained bound at the membrane and pursued its inhibitory activity. This was not observed with FXa.TFPI(1-161) or at TF.PC membranes. These data suggest that the membrane-bound pool of FXa.TFPI(FL) may be of physiological importance in an on-site regulation of TF.FVIIa activity.     

Anophelin: kinetics and mechanism of thrombin inhibition

Anophelin is a 6.5-kDa peptide isolated from the salivary gland of Anopheles albimanus that behaves as an alpha-thrombin inhibitor. In this paper, kinetic analyses and the study of mechanism of alpha-thrombin inhibition by anophelin were performed. Anophelin was determined to be a reversible, slow, tight-binding inhibitor of alpha-thrombin, displaying a competitive type of inhibition. The binding of anophelin to alpha-thrombin is stoichiometric with a dissociation constant (K(i)) of 5.87 +/- 1.46 pM, a calculated association rate constant (k(1)) of 2.11 +/- 0.06 x 10(8) M(-1) s(-1), and a dissociation rate constant (k(-1)) of 4.05 +/- 0.97 x 10(-4) s(-1). In the presence of 0.15 and 0.4 M NaCl, a 17.6- and 207-fold increase in the K(i) of anophelin-alpha-thrombin complex was observed, respectively, indicating that ionic interactions are important in anophelin-alpha-thrombin complex formation. Incubation of alpha-thrombin with C-terminal hirudin fragment 54-65 that binds to alpha-thrombin anion binding exosite 1 (TABE1) attenuates alpha-thrombin inhibition by anophelin; anophelin also blocks TABE1-dependent trypsin-mediated proteolysis of alpha-thrombin. Using gamma-thrombin, an alpha-thrombin derivative where the anion binding exosite has been disrupted, anophelin behaves as a fast and classical competitive inhibitor of gamma-thrombin hydrolysis of small chromogenic substrate (K(i) = 0. 694 +/- 0.063 nM). In addition, anophelin-gamma-thrombin complex formation is prevented by treatment of the enzyme with D-Phe-Pro-Arg-chloromethyl ketone (PPACK), a reagent that irreversibly blocks the catalytic site of thrombin. It is concluded that anophelin is a potent dual inhibitor of alpha-thrombin because it binds both to TABE1 and to the catalytic site, optimal binding being dependent on the availability of both domains. Finally, anophelin inhibits clot-bound alpha-thrombin with an IC(50) of 45 nM and increases the lag phase that precedes explosive in vitro alpha-thrombin generation after activation of intrinsic pathway of blood coagulation. Because of its unique primary sequence, anophelin may be used as a novel reagent to study the structure and function of alpha-thrombin.     

The influence of acetaldehyde and glycosaminoglycans upon factor Xa- and factor X-deficient plasma

The comparative effects of glycosaminoglycans and acetaldehyde (AcH)--glycosaminoglycan (GAG) mixtures upon Factor Xa- (FXa) and Factor X-deficient plasma (FXDP) have been studied by activated partial thromboplastin time (APTT) studies. Heparin at 0.025, 0.030, 0.04, and 0.05 U statistically prolonged the APTT when pre-incubated with FXa at 37 degrees C for 3 min prior to addition to FXDP and subsequent addition of Ca2+. Upon addition of 0.25, 0.375, and 0.5 microg heparin-6000 (H6k) to FXa, significant increases in APTT were observed. Similarly, profound increases in APTT were observed when 0.5, 0.75, and 1.0 microg heparin-3000 (H3k) was added to FXa. The chondroitin sulfates (CSA, CSB, CSC) had far less impact upon APTT with the FXa-FXDP system. In examining the effects of AcH-GAG mixtures upon the clotting factor, it was observed that 44.3 and 443 mM AcH synergistically prolonged the APTT in a statistically significant manner regardless of the order of premixing the three components. Hence, AcH may play a role in prolonging APTT in alcoholics. It synergistically prolonged APTT in concert with GAGs and FXa at the AcH levels used in this study. The effect of the GAGs upon FXDP is far less than its effect upon FXa.     

Interaction of factor XII, high-molecular-weight (HMW) kininogen and prekallikrein with sulfatide: analysis by fluorescence polarization

The interaction of high-molecular-weight (HMW) kininogen, Factor XII and prekallikrein with sulfatide was studied by fluorescence polarization. Fluorescein-conjugated derivatives of HMW kininogen, Factor XII and prekallikrein were prepared by reacting the purified bovine factors with fluorescein isothiocyanate (FITC). The apparent dissociation constant (Kd) for the binding of FITC-labeled HMW kininogen (F-HMW kininogen) with sulfatide was calculated to be 3.2 (+/- 0.3) X 10(-8) M. This binding was partially inhibited by three kininogen derivatives, fragment 1 X 2, kinin-free protein and fragment 1 X 2-light chain, but not by kinin and fragment 1 X 2-free protein. In the presence of Factor XII, the binding of F-HMW kininogen with sulfatide was strongly inhibited, suggesting that the zymogen and the protein cofactor compete for the same or a closely related binding site on the sulfatide surface. In contrast, the binding of FITC-labeled Factor XII (F-Factor XII) with sulfatide was weakly inhibited by HMW kininogen but not by prekallikrein. The Kd value for binding of F-Factor XII with sulfatide was calculated to be 2.0 (+/- 0.3) X 10(-8) M. F-Prekallikrein did not interact with sulfatide. Moreover, the fluorescence polarization value of F-HMW kininogen decreased in the presence of prekallikrein, leveling off at a one-to-one molar ratio of prekallikrein to F-HMW kininogen. The Kd value for binding of F-HMW kininogen-light chain (F-light chain) with prekallikrein was calculated to be 3.8 (+/- 0.6) X 10(-8) M and the stoichiometry was estimated as 1 to 1.2 on a molar basis from the Scatchard plot.     

Kinetics and mechanism for the conformational transition in p-guanidinobenzoate bovine trypsinogen induced by the isoleucine-valine dipeptide

The interaction between p-guanidinobenzoate-trypsinogen and the isoleucine-valine dipeptide has been investigated by temperature-jump relaxation spectrometry. Using the absorbance at 281 nm the concentration dependence of the relaxation parameters is consistent with the conventional induced-fit model: rapid ligand binding coupled to a slower intramolecular change; some alternative mechanisms can be excluded. At 296 K, 0.1 M Tris HCl, pH = 7.4, the dissociation equilibrium constant for the overall process is K = 5.1(+/- 0.2) X 10(-5) M; for the binding step K1 = 2.3(+/- 0.3) X 10(-3) M and the rate constants for the structural change are k2 = 26(+/-6)s-1 and k-2 = 0.61(+/- 0.04)s-1; the overall dissociation reaction enthalpy is delta H0 = 26(+/-6)KJmol-1 and the reactiom entropy is delta S0 = 4(+/- 20) kJ-1 mol-1. In combination with CD and X-ray crystallographic data, the results of this study suggest that the binding of the dipeptide to a trypsinogen-like, partially disordered conformation induces a transition to a trypsin-like highly ordered structure.     

Design and synthesis of highly constrained factor Xa inhibitors: amidine-substituted bis(benzoyl)--diazepan-2-ones and bis(benzylidene)-bis(gem-dimethyl)cycloketones

Two conformationally constrained templates have been designed to provide selective inhibitors of the coagulation cascade serine protease, Factor Xa (FXa). The most active inhibitor, 2,7-bis[(Z)-p-amidinobenzylidene)]-3,3,6,6-tetramethylcycloheptanone, exhibits a K(i) of 42 nM against FXa, with strong selectivity against thrombin (1000-fold), trypsin (300-fold) and plasmin (900-fold). With only two freely rotatable bonds, molecular modeling suggests that one amidine group is positioned into the S1 pocket, forming hydrogen bonds with the side chain of Asp189, similar to other amidine-based inhibitors, with the second benzamidine positioned into the S4 pocket in a position to form strong cation-pi bonding with the S4 aryl cage. We suggest that this interaction plays an important role in the specificity of these inhibitors against other serine proteases.     

NVP-DPP728 (1-[[[2-[(5-cyanopyridin-2-yl)amino]ethyl]amino]acetyl]-2-cyano-(S)- pyrrolidine), a slow-binding inhibitor of dipeptidyl peptidase IV.

Inhibition of dipeptidyl peptidase IV (DPP-IV) has been proposed recently as a therapeutic approach to the treatment of type 2 diabetes. N-Substituted-glycyl-2-cyanopyrrolidide compounds, typified by NVP-DPP728 (1-[[[2-[(5-cyanopyridin-2-yl)amino]ethyl]amino]acetyl]-2-cyano-(S )-p yrrolidine), inhibit degradation of glucagon-like peptide-1 (GLP-1) and thereby potentiate insulin release in response to glucose-containing meals. In the present study NVP-DPP728 was found to inhibit human DPP-IV amidolytic activity with a K(i) of 11 nM, a k(on) value of 1.3 x 10(5) M(-)(1) s(-)(1), and a k(off) of 1.3 x 10(-)(3) s(-)(1). Purified bovine kidney DPP-IV bound 1 mol/mol [(14)C]-NVP-DPP728 with high affinity (12 nM K(d)). The dissociation constant, k(off), was 1.0 x 10(-)(3) and 1.6 x 10(-)(3) s(-)(1) in the presence of 0 and 200 microM H-Gly-Pro-AMC, respectively (dissociation t(1/2) approximately 10 min). Through kinetic evaluation of DPP-IV inhibition by the D-antipode, des-cyano, and amide analogues of NVP-DPP728, it was determined that the nitrile functionality at the 2-pyrrolidine position is required, in the L-configuration, for maximal activity (K(i) of 11 nM vs K(i) values of 5.6 to >300 microM for the other analogues tested). Surprisingly, it was found that the D-antipode, despite being approximately 500-fold less potent than NVP-DPP728, displayed identical dissociation kinetics (k(off) of 1.5 x 10(-)(3) s(-)(1)). NVP-DPP728 inhibited DPP-IV in a manner consistent with a two-step inhibition mechanism. Taken together, these data suggest that NVP-DPP728 inhibits DPP-IV through formation of a novel, reversible, nitrile-dependent complex with transition state characteristics.