scholarly journals Structural and Mutational Analyses of the Molecular Interactions between the Catalytic Domain of Factor XIa and the Kunitz Protease Inhibitor Domain of Protease Nexin 2

2005 ◽  
Vol 280 (43) ◽  
pp. 36165-36175 ◽  
Author(s):  
Duraiswamy Navaneetham ◽  
Lei Jin ◽  
Pramod Pandey ◽  
James E. Strickler ◽  
Robert E. Babine ◽  
...  
Keyword(s):  
Protease Inhibitor ◽  
Catalytic Domain ◽  
Point Mutations ◽  
Protein Data Bank Code ◽  
Mutant Form ◽  
Wild Type ◽  
Site Mutation ◽  
Kunitz Protease Inhibitor ◽  
Factor Xia ◽  
Protease Nexin

Factor XIa (FXIa) is a serine protease important for initiating the intrinsic pathway of blood coagulation. Protease nexin 2 (PN2) is a Kunitz-type protease inhibitor secreted by activated platelets and a physiologically important inhibitor of FXIa. Inhibition of FXIa by PN2 requires interactions between the two proteins that are confined to the catalytic domain of the enzyme and the Kunitz protease inhibitor (KPI) domain of PN2. Recombinant PN2KPI and a mutant form of the FXI catalytic domain (FXIac) were expressed in yeast, purified to homogeneity, co-crystallized, and the structure of the complex was solved at 2.6 Å (Protein Data Bank code 1ZJD). In this complex, PN2KPI has a characteristic, disulfide-stabilized double loop structure that fits into the FXIac active site. To determine the contributions of residues within PN2KPI to its inhibitory activity, selected point mutations in PN2KPI loop 1 11TGPCRAMISR20 and loop 2 34FYGGC38 were tested for their ability to inhibit FXIa. The P1 site mutation R15A completely abolished its ability to inhibit FXIa. IC50 values for the wild type protein and the remaining mutants were as follows: PN2KPI WT, 1.28 nm; P13A, 5.92 nm; M17A, 1.62 nm; S19A, 1.86 nm; R20A, 5.67 nm; F34A, 9.85 nm. The IC50 values for the M17A and S19A mutants were not significantly different from those obtained with wild type PN2KPI. These functional studies and activated partial thromboplastin time analysis validate predictions made from the PN2KPI-FXIac co-crystal structure and implicate PN2KPI residues, in descending order of importance, Arg15, Phe34, Pro13, and Arg20 in FXIa inhibition by PN2KPI.

scholarly journals The Role of Factor XIa (FXIa) Catalytic Domain Exosite Residues in Substrate Catalysis and Inhibition by the Kunitz Protease Inhibitor Domain of Protease Nexin 2

2011 ◽  
Vol 286 (36) ◽  
pp. 31904-31914 ◽  
Author(s):  
Ya-Chi Su ◽  
Tara N. Miller ◽  
Duraiswamy Navaneetham ◽  
Robert T. Schoonmaker ◽  
Dipali Sinha ◽  
...  
Keyword(s):  
Protease Inhibitor ◽  
Catalytic Domain ◽  
Kunitz Protease Inhibitor ◽  
Factor Xia ◽  
Protease Nexin ◽  
Kunitz Protease Inhibitor Domain

A genetically engineered human Kunitz protease inhibitor with increased kallikrein inhibition in an ovine model of cardiopulmonary bypass

Perfusion ◽  
2001 ◽  
Vol 16 (3) ◽  
pp. 199-206 ◽  
Author(s):  
Sunil K Ohri ◽  
Rachel Parratt ◽  
Tyler White ◽  
Jenny Becket ◽  
John J Brannan ◽  
...  
Keyword(s):  
Cardiopulmonary Bypass ◽  
Protease Inhibitor ◽  
Randomized Study ◽  
Genetically Engineered ◽  
Wild Type ◽  
Ovine Model ◽  
Double Blind ◽  
Perioperative Bleeding ◽  
Kunitz Inhibitor ◽  
Kunitz Protease Inhibitor

A recombinant human serine protease inhibitor known as Kunitz protease inhibitor (KPI) wild type has functional similarities to the bovine Kunitz inhibitor, aprotinin, and had shown a potential to reduce bleeding in an ovine model of cardiopulmonary bypass (CPB). The aim of this study was to assess KPI-185, a modification of KPI-wild type that differs from KPI-wild type in two amino acid residues and which enhances anti-kallikrein activity in a further double-blind, randomized study in an ovine model of CPB, and to compare with our previous study of KPI-wild type and aprotinin in the same ovine model. Post-operative drain losses and subjective assessment of wound ‘dryness’ showed no significant differences between KPI-185 and KPI-wild type, despite the significant enhancement of kallikrein inhibition using KPI-185 seen in serial kallikrein inhibition assays. These preliminary findings support the hypothesis that kallikrein inhibition is not the major mechanism by which Kunitz inhibitors such as aprotinin reduce perioperative bleeding.

Structural and Mutational Analysis of Canonical Loop Residues In Protease Nexin 2 Involved In Factor XIa and Trypsin Inhibition.

Blood ◽  
2010 ◽  
Vol 116 (21) ◽  
pp. 1147-1147
Author(s):  
Duraiswamy Navaneetham ◽  
Dipali Sinha ◽  
Peter N. Walsh
Keyword(s):  
Inhibitory Activity ◽  
Significant Contribution ◽  
Catalytic Domain ◽  
Hydrophobic Interactions ◽  
Conflicts Of Interest ◽  
Side Chain ◽  
Trypsin Inhibition ◽  
Factor Xia ◽  
Protease Nexin ◽  
Loop 2

Abstract Abstract 1147 Factor XIa (FXIa) activates FIX and is regulated by platelet-secreted protease nexin 2 (PN2) that contains a Kunitz-type protease inhibitor (KPI) domain. Trypsin is regulated by basic pancreatic trypsin inhibitor (BPTI). The primary and tertiary structures of trypsin and the catalytic domain of FXIa are highly homologous, and KPI and BPTI are nearly identical structurally. We have previously identified two loop structures (loops 1 and 2) in the KPI domain of PN2 that interact with residues in the FXIa catalytic domain. Based on the structure of the FXIa/KPI complex crystal structure, residues within loops 1 and 2 were mutated for experiments examining the inhibition of FXIa and trypsin. Results show that the loop-1-region P1 site residue Arg15 of PN2KPI plays a major role in FXIa inhibition by protruding into the S1 specificity pocket of FXIa. Ala mutation at this site renders PN2KPI non-inhibitory for both FXIa and trypsin. BPTI has Lys15 at the P1 site. BPTI inhibits both FXIa and trypsin significantly less effectively than PN2KPI. PN2KPI-R15K lost FXIa inhibitory activity, whereas BPTI-K15R substantially gained affinity for FXIa. Like FXIa, trypsin preferred BPTI-K15R showing a significant enhancement in affinity. Thus, a major determinant of the inhibitory activity of PN2KPI and BPTI against FXIa and trypsin is the P1 residue, with Arg being preferred over Lys for both inhibitors and both proteases. In addition, loop 1 residues Pro13 and Arg20 make important contributions to both FXIa and trypsin inhibition as demonstrated by significantly elevated Ki values for Ala mutations (P13A, and R20A) at these sites. In contrast, Ser19 makes no significant contribution to inhibition of either FXIa or trypsin whereas Met17 makes a significant contribution to the inhibition of trypsin, but not FXIa. In loop 2, only Phe34 is identified as a residue making significant contributions to the inhibition of both FXIa and trypsin, since the PN2KPI-F34A mutant displayed reduced inhibitory activity for both FXIa (6-fold) and for trypsin (3-fold). To rationalize these findings, we examined the crystal structures of the FXIa(catalytic domain)/PN2KPI complex, and the trypsin/BPTI complex. Structurally, the PN2KPI loop-1, P1-site residue Arg15 makes a complex primary interaction with Asp189 of both FXIa and trypsin. Disruption of this site by R15A mutation renders PN2KPI non-inhibitory because it preempts salt bridge interactions from two nitrogen atoms of the guanidinium group of Arg15 with Asp189 and Gly218 in FXIa. In addition, the Arg15 carbonyl oxygen forms hydrogen bonds with main-chain nitrogen atoms of one of the catalytic triad residues, Ser195, and with Gly193. The other important interaction in FXIa/PN2KPI or trypsin/BPTI is hydrophobic, between PN2KPI-Phe34 and FXIa-Tyr143 and between BPTI-Val34 and trypsin-Tyr151. This intermolecular interaction is further strengthened by an intramolecular interaction in which the side chain of Phe34 packs closely with the side chain of Met17 within PN2KPI, altogether forming a strong hydrophobic patch in FXIa-PN2KPI and trypsin-PN2KPI. PN2KPI-F34A disrupts both inter- and intramolecular hydrophobic interactions, leading to discernable reductions in affinity for both FXIa and trypsin. Despite occupying extreme positions in the autolysis loops, (143YRKLRDKI151 in FXIa and 143NTKSSGTSY151 in trypsin), Tyr143/151 residues still orient themselves in close proximity to Phe34. Thus, loop-1 residues of PN2KPI establish complex ionic interactions that play a major role, which is supplemented by the loop-2 residue, Phe34 (in PN2KPI) or Val34 (in BPTI), which establish hydrophobic interactions with residues in FXIa and trypsin leading to very high-affinity enzyme-inhibitor complexes. Disclosures: No relevant conflicts of interest to declare.

scholarly journals Mouse Hepatitis Virus Stem-Loop 2 Adopts a uYNMG(U)a-Like Tetraloop Structure That Is Highly Functionally Tolerant of Base Substitutions

2009 ◽  
Vol 83 (23) ◽  
pp. 12084-12093 ◽  
Author(s):  
Pinghua Liu ◽  
Lichun Li ◽  
Sarah C. Keane ◽  
Dong Yang ◽  
Julian L. Leibowitz ◽  
...  
Keyword(s):  
Hepatitis Virus ◽  
Mouse Hepatitis Virus ◽  
Point Mutations ◽  
Wild Type Virus ◽  
Wild Type ◽  
Site Mutation ◽  
Structural Element ◽  
Nucleotide Substitutions ◽  
Stem Loop ◽  
Loop 2

ABSTRACT Stem-loop 2 (SL2) of the 5′-untranslated region of the mouse hepatitis virus (MHV) contains a highly conserved pentaloop (C47-U48-U49-G50-U51) stacked on a 5-bp stem. Solution nuclear magnetic resonance experiments are consistent with a 5′-uYNMG(U)a or uCUYG(U)a tetraloop conformation characterized by an anti-C47-syn-G50 base-pairing interaction, with U51 flipped out into solution and G50 stacked on A52. Previous studies showed that U48C and U48A substitutions in MHV SL2 were lethal, while a U48G substitution was viable. Here, we characterize viruses harboring all remaining single-nucleotide substitutions in the pentaloop of MHV SL2 and also investigate the degree to which the sequence context of key pentaloop point mutations influences the MHV replication phenotype. U49 or U51 substitution mutants all are viable; C47 substitution mutants also are viable but produce slightly smaller plaques than wild-type virus. In contrast, G50A and G50C viruses are severely crippled and form much smaller plaques. Virus could not be recovered from G50U-containing mutants; rather, only true wild-type revertants or a virus, G50U/C47A, containing a second site mutation were recovered. These functional data suggest that the Watson-Crick edges of C47 and G50 (or A47 and U50 in the G50U/C47A mutant) are in close enough proximity to a hydrogen bond with U51 flipped out of the hairpin. Remarkably, increasing the helical stem stability rescues the previously lethal mutants U48C and G50U. These studies suggest that SL2 functions as an important, but rather plastic, structural element in stimulating subgenomic RNA synthesis in coronaviruses.

The Role of the P1 Residue of Protease Nexin 2 and Basic Pancreatic Trypsin Inhibitor in the Mechanism of Factor XIa Inhibition.

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 2015-2015
Author(s):  
Duraiswamy Navaneetham ◽  
Dipali Sinha ◽  
Peter N. Walsh
Keyword(s):  
Steady State ◽  
Protease Inhibitor ◽  
Trypsin Inhibitor ◽  
Tight Binding ◽  
Basic Pancreatic Trypsin Inhibitor ◽  
Factor Xia ◽  
Pancreatic Trypsin Inhibitor ◽  
Kunitz Type ◽  
Protease Nexin ◽  
Kunitz Type Protease Inhibitor

Abstract Factor XIa (FXIa), a plasma serine protease that activates FIX, is regulated by protease nexin 2 (PN2), a Kunitz-type protease inhibitor (KPI) secreted on platelet activation. The Kunitz protease inhibitor domain of protease nexin 2 (PN2KPI) is highly homologous (45% primary sequence identity) to basic pancreatic trypsin inhibitor (BPTI, another Kunitz-type protease inhibitor) and their backbone tertiary structures are nearly identical (J Biol Chem280: 36165, 2005; J Mol Biol230: 919, 2005). However, PN2KPI (Ki 1 nM) is 600-fold more potent as a FXIa inhibitor than bovine basic pancreatic trypsin inhibitor (BPTI; Ki 630 nM). The present study is aimed at examining why these two structurally similar inhibitors are so different in their affinities and specificities in FXIa inhibition and analyzing the mechanisms of FXIa inhibition by these two inhibitors. Reasoning that the P1 residue (Arg15 in PN2KPI and Lys15 in BPTI) might play a crucial role in determining the affinity and specificity for FXIa we expressed BPTI-K15R (mimicking PN2KPI at the P1 site) and PN2KPI-R15K (mimicking BPTI at the P1 site) and examined their inhibitory properties. BPTI-K15R was found to inhibit FXIa with a Ki (10 nM) ~60-fold tighter than BPTI (Ki 630 nM), whereas PN2KPI-R15K inhibited FXIa with a Ki (32 nM) that was 32- fold impaired compared with PN2KPI (Ki 1 nM). Progress curves of peptidyl fluorogenic substrate (Boc-Glu-Ala-Arg-AMC) hydrolysis by FXIa in the presence of all the inhibitors except BPTI clearly demonstrated higher initial rates that continuously decreased until reaching a steady state, typical of slow inhibition. Progress curves obtained using BPTI, on the other hand, were found to be linear at all concentrations of the inhibitor. Analysis using steady state kinetics clearly demonstrated that BPTI is a competitive inhibitor in FXIa hydrolysis of the peptidyl chromogenic substrate, pyro-Glu-Pro-Arg-pNA. Analysis of progress curves using kinetic equations for slow, tight-binding inhibitors confirmed that the formation of the FXIa:PN2KPI complex occurs in a single step that is slow, whereas formation of FXIa:PN2KPI-R15K, FXIa:BPTI and FXIa:BPTI-K15R complexes do not conform to the same kinetic mechanism. Thus PN2KPI and BPTI inhibit FXIa by distinctly different mechanisms and the Arg at the P1 site of PN2KPI confers specificity and high affinity for FXIa inhibition and in part determines the mechanism of PN2KPI as a slow, tight binding inhibitor.

scholarly journals Factor VII Deficiency due to Compound Heterozygosity for Leu-48Pro Mutation and a Novel Pro260Leu Mutation

2011 ◽  
Vol 17 (6) ◽  
pp. E205-E210 ◽  
Author(s):  
N. Kogiso ◽  
M. Taki ◽  
O. Takamiya
Keyword(s):  
Japanese Patient ◽  
Catalytic Domain ◽  
Novel Mutation ◽  
Point Mutations ◽  
Factor Vii ◽  
Compound Heterozygous ◽  
Wild Type ◽  
Bhk Cells ◽  
Er Targeting ◽  
Normal Controls

We investigated the mechanisms responsible for factor VII (FVII) deficiency in a compound heterozygous Japanese patient with mutations both in the signal peptide and in the catalytic domain. FVII activity (FVII:C) and antigen (FVII:Ag) levels of the patient were 14.5% and 12.5% of those of the normal controls, respectively. In all, 2 heterozygous point mutations were identified in the patient: one was the mutation substituting Pro for Leu-48 in the prepeptide domain of FVII; the other one was a novel mutation substituting Leu for Pro260 in the catalytic domain. FVII activity and FVII:Ag levels in the condition medium that transiently coexpressed the 2 different FVII mutants in baby hamster kidney (BHK) cells were 4.81% and 5.18% of the wild-type FVII. Factor VII defect of the patient may be combined with both impairing endoplasmic reticulum (ER) targeting and altering FVII folding/biosynthesis, but cotransfection of 2 different FVII mutants may interfere with their expression in BHK cells.

scholarly journals The kunitz protease inhibitor domain of protease nexin-2 inhibits factor XIa and murine carotid artery and middle cerebral artery thrombosis

Blood ◽  
2012 ◽  
Vol 120 (3) ◽  
pp. 671-677 ◽  
Author(s):  
Wenman Wu ◽  
Hongbo Li ◽  
Duraiswamy Navaneetham ◽  
Zachary W. Reichenbach ◽  
Ronald F. Tuma ◽  
...  
Keyword(s):  
Carotid Artery ◽  
Protease Inhibitor ◽  
Middle Cerebral Artery ◽  
Cerebral Artery ◽  
Intravenous Administration ◽  
Antithrombotic Therapy ◽  
Thrombus Formation ◽  
Specific Inhibitor ◽  
Kunitz Protease Inhibitor ◽  
Protease Nexin

Abstract Coagulation factor XI (FXI) plays an important part in both venous and arterial thrombosis, rendering FXIa a potential target for the development of antithrombotic therapy. The kunitz protease inhibitor (KPI) domain of protease nexin-2 (PN2) is a potent, highly specific inhibitor of FXIa, suggesting its possible role in the inhibition of FXI-dependent thrombosis in vivo. Therefore, we examined the effect of PN2KPI on thrombosis in the murine carotid artery and the middle cerebral artery. Intravenous administration of PN2KPI prolonged the clotting time of both human and murine plasma, and PN2KPI inhibited FXIa activity in both human and murine plasma in vitro. The intravenous administration of PN2KPI into WT mice dramatically decreased the progress of FeCl3-induced thrombus formation in the carotid artery. After a similar initial rate of thrombus formation with and without PN2KPI treatment, the propagation of thrombus formation after 10 minutes and the amount of thrombus formed were significantly decreased in mice treated with PN2KPI injection compared with untreated mice. In the middle cerebral artery occlusion model, the volume and fraction of ischemic brain tissue were significantly decreased in PN2KPI-treated compared with untreated mice. Thus, inhibition of FXIa by PN2KPI is a promising approach to antithrombotic therapy.

Characterization of Heparin Binding Site Residues on the Catalytic Domain of Factor XIa

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 1018-1018 ◽  
Author(s):  
Likui Yang ◽  
Mao-fu Sun ◽  
Chandrashekhara Manithody ◽  
David Gailani ◽  
Alireza R. Rezaie
Keyword(s):  
Binding Site ◽  
Rate Constants ◽  
Serine Proteases ◽  
Catalytic Domain ◽  
Inhibitory Effect ◽  
Heparin Binding ◽  
Wild Type ◽  
Single Chain ◽  
Factor Xia ◽  
Mutant Forms

Abstract The basic residues of the 170-helix (chymotrypsinogen numbering) in the catalytic domain of the procoagulant serine proteases are known to interact with heparin and facilitate their rapid inhibition by specific plasma serpins. The homologous loop of factor XIa possesses three basic residues (Lys-170, Arg-171 and Arg-173). To investigate the role of these residues in the heparin-mediated inhibition of fXIa by C1-inhibitor (C1-INH) and antithrombin (AT), we expressed the monomeric light chain fragment of fXIa containing only the catalytic domain of the protease in wild-type and mutant forms in which the three basic residues of the 170-helix have been substituted individually, or in combinations, with Ala. The catalytic properties of fXIa derivatives were compared to wild-type fXIa (fXIa-WT) with respect to their ability to hydrolyze the chromogenic substrate S2366 and to undergo inhibition by C1-INH and AT in the absence and presence of heparin. All mutants exhibited normal amidolytic activity, hydrolyzing S2366 with catalytic efficiencies similar to fXIa-WT. All mutants were also inhibited by both C1-INH and AT with normal rate constants in the absence of heparin. However, the heparincatalyzed inhibition of mutants by both serpins differed to varying degrees relative to fXIa-WT, with the Arg-171 to Ala substitution mutant exhibiting ~3-fold lower rate of inhibition by C1-INH and requiring ~3-fold higher concentration of heparin for observing optimal inhibitory effect. In reactions with AT, all three basic residues appeared to make similar contributions to the heparin-catalyzed inhibition of fXIa by the serpin as evidenced by all three mutants exhibiting dramatically lower inhibition rate constants in the presence of heparin. A bell-shaped heparin concentration dependence for the fXIa inhibition by both serpins suggested that the template effect of heparin primarily accounts for the acceleration mechanism. However, a comparison of the heparin bell-shaped dependence inhibition of the dimeric plasma-derived wild-type fXIa with that of the isolated single chain catalytic domain suggested that the optimal concentration of heparin for the acceleration of the protease has been increased from ~50 nM for the dimeric protease to ~250 nM for the isolated catalytic domain, possibly suggesting further contribution to affinity of the fXIaheparin interaction from the Apple-3 domain of the non-catalytic domain on which a binding-site for heparin has been reported.

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