Insight into the mechanism of serpin-proteinase inhibition from 2D [1H-15N] NMR studies of the 69 kDa alpha 1-proteinase inhibitor Pittsburgh-trypsin covalent complex

We have used [(1)H-(15)N]-HSQC NMR to investigate the structural changes that occur in both serpin and proteinase in forming the kinetically trapped covalent protein-protein complex that is the basis for serpin inhibition of serine proteinases. By alternately using (15)N-alanine specifically-labeled alpha(1)-proteinase inhibitor (alpha(1)PI) Pittsburgh (serpin) and bovine trypsin (proteinase), we were able to selectively monitor structural changes in each component of the 69 kDa complex. Residue-specific assignments of four alanines in the reactive center loop and seven other alanines aided interpretation of the spectral changes in the serpin. We found that the majority of the alanine resonances, including those from reactive center loop residues P12, P11, and P9, were at identical positions in covalent complex and in cleaved alpha(1)PI. Five alanines that are close to the contact region with proteinase showed some chemical shift perturbation compared with cleaved alpha(1)PI, indicating some degree of structural deformation. With (15)N label in the proteinase, an HSQC spectrum was obtained that more closely resembled that of a molten globule, suggesting that the structure of the proteinase had been significantly altered as a result of complex formation. Large increases in line width for all alpha(1)PI resonances in the covalent complex, with the sole exception of two residues in the flexible N-terminal tail, indicate that, unlike the noncovalent alpha(1)PI-anhydroproteinase complex, the covalent complex is a rigid body of effectively increased molecular weight. We conclude that the mutual perturbations of serpin and proteinase result from steric compression and distortion, rather than simple contact effects. This distortion provides a structural basis for the greatly reduced catalytic efficiency of the proteinase in the complex and hence kinetic trapping of the covalent reaction intermediate.     

alpha1-Proteinase inhibitor forms initial non-covalent and final covalent complexes with elastase analogously to other serpin-proteinase pairs, suggesting a common mechanism of inhibition

Despite several concordant structural studies on the initial non-covalent complex that serpins form with target proteinases, a recent study on the non-covalent complex between the serpin alpha(1)-proteinase inhibitor (alpha(1)PI) and anhydroelastase concluded that translocation of the proteinase precedes cleavage of the reactive center loop and formation of the acyl ester. Because this conclusion is diametrically opposite to those of the other structural studies on serpin-proteinase pairs, we proceeded to examine this specific serpin-proteinase complex by the same successful NMR approach used previously on the alpha(1)PI-Pittsburgh-S195A trypsin pair. Both non-covalent complex with anhydroelastase and covalent complex with active elastase were made with (15)N-alanine-labeled wild-type alpha(1)PI. The heteronuclear single quantum correlation spectroscopy (HSQC) NMR spectrum of the non-covalent complex showed that the entire reactive center loop remained exposed, and the serpin body maintained a conformation indistinguishable from that of native alpha(1)PI, indicating no movement of the proteinase and no insertion of the reactive center loop into beta-sheet A. In contrast, the HSQC NMR spectrum of the covalent complex showed that the reactive center loop had fully inserted into beta-sheet A, indicating that translocation of the proteinase had occurred. These results agree with previous NMR, fluorescence resonance energy transfer, and x-ray crystallographic studies and suggest that a common mechanism is employed in formation of serpin-proteinase complexes. We found that preparations of anhydroelastase that are not appropriately purified contain material that can regenerate active elastase over time. It is likely that the material used by Mellet and Bieth contained such active elastase, resulting in mistaken attribution of the behavior of covalent complex to that of the non-covalent complex.     

Resolution of Michaelis complex, acylation, and conformational change steps in the reactions of the serpin, plasminogen activator inhibitor-1, with tissue plasminogen activator and trypsin

Michaelis complex, acylation, and conformational change steps were resolved in the reactions of the serpin, plasminogen activator inhibitor-1 (PAI-1), with tissue plasminogen activator (tPA) and trypsin by comparing the reactions of active and Ser 195-inactivated enzymes with site-specific fluorescent-labeled PAI-1 derivatives that report these events. Anhydrotrypsin or S195A tPA-induced fluorescence changes in P1'-Cys and P9-Cys PAI-1 variants labeled with the fluorophore, NBD, indicative of a substrate-like interaction of the serpin reactive loop with the proteinase active-site, with the P1' label but not the P9 label perturbing the interactions by 10-60-fold. Rapid kinetic analyses of the labeled PAI-1-inactive enzyme interactions were consistent with a single-step reversible binding process involving no conformational change. Blocking of PAI-1 reactive loop-beta-sheet A interactions through mutation of the P14 Thr --> Arg or annealing a reactive center loop peptide into sheet A did not weaken the binding of the inactive enzymes, suggesting that loop-sheet interactions were unlikely to be induced by the binding. Only active trypsin and tPA induced the characteristic fluorescence changes in the labeled PAI-1 variants previously shown to report acylation and reactive loop-sheet A interactions during the PAI-1-proteinase reaction. Rapid kinetic analyses showed saturation of the reaction rate constant and, in the case of the P1'-labeled PAI-1 reaction, biphasic changes in fluorescence indicative of an intermediate resembling the noncovalent complex on the path to the covalent complex. Indistinguishable K(M) and k(lim) values of approximately 20 microM and 80-90 s(-1) for reaction of the two labeled PAI-1s with trypsin suggested that a diffusion-limited association of PAI-1 and trypsin and rate-limiting acylation step, insensitive to the effects of labeling, controlled covalent complex formation. By contrast, differing values of K(M) of 1.7 and 0.1 microM and of k(lim) of 17 and 2.6 s(-1) for tPA reactions with P1' and P9-labeled PAI-1s, respectively, suggested that tPA-PAI-1 exosite interactions, sensitive to the effects of labeling, promoted a rapid association of PAI-1 and tPA and reversible formation of an acyl-enzyme complex but impeded a rate-limiting burial of the reactive loop leading to trapping of the acyl-enzyme complex. Together, the results suggest a kinetic pathway for formation of the covalent complex between PAI-1 and proteinases involving the initial formation of a Michaelis-type noncovalent complex without significant conformational change, followed by reversible acylation and irreversible reactive loop conformational change steps that trap the proteinase in a covalent complex.     

A concerted structural transition in the plasminogen activator inhibitor-1 mechanism of inhibition

The inhibition mechanism of serpins requires a change in structure to entrap the target proteinase as a stable acyl-enzyme complex. Although it has generally been assumed that reactive center loop insertion and associated conformational change proceeds in a concerted manner, this has not been demonstrated directly. Through the substitution of tryptophan with 7-azatryptophan and an analysis of transient reaction kinetics, we have described the formation of an inhibited serpin-proteinase complex as a single concerted transition of the serpin structure. Replacement of the four tryptophans of plasminogen activator inhibitor type-1 (PAI-1) with the spectrally unique analogue 7-azatryptophan permitted observations of conformational changes in the serpin but not those of the proteinase. Formation of covalent acyl-enzyme complexes, but not noncovalent Michaelis complexes, with tissue-type plasminogen activator (t-PA) or urokinase (u-PA) resulted in rapid decreases of fluorescence coinciding with insertion of the reactive center loop and expansion of beta-sheet A. Insertion of an octapeptide consisting of the P14-P7 residues of the reactive center loop into beta-sheet A produced the same conformational change in serpin structure measured by 7-azatryptophan fluorescence, suggesting that introduction of the proximal loop residues induces the structural rearrangement of the serpin molecule. The atom specific modification of the tryptophan indole rings through analogue substitution produced a proteinase specific effect on function. The reduced inhibitory activity of PAI-1 against t-PA but not u-PA suggested that the mechanism of loop insertion is sensitive to the intramolecular interactions of one or more tryptophan residues.     

Use of fluorescence resonance energy transfer to study serpin-proteinase interactions

One of the important questions in the serpin mechanism of inhibition of serine and cysteine proteinases of different specificities and structural classes is whether a common "crushing" mechanism of proteinase inactivation is used in all cases. This mechanism was seen in an X-ray structure of the complex between alpha(1)-proteinase inhibitor and trypsin and required the full insertion of the reactive center loop into beta-sheet A and translocation of the proteinase from one pole of the serpin to the other. However, it has yet to be shown to be general for serine proteinases of structural classes other than the trypsin-fold or for cysteine proteinases with the papain-fold or for the caspases. Fluorescence resonance energy transfer offers a potential means of obtaining an answer to this question for each of these classes, without the concern for the effect that increasing size has on the observed signal that applies to NMR spectroscopy. However, care must be taken to ensure that measurements made represent sufficient overdetermination that the answer obtained is unambiguous.     

High-level bacterial expression and 15N-alanine-labeling of bovine trypsin. Application to the study of trypsin-inhibitor complexes and trypsinogen activation by NMR spectroscopy

We describe here the high-level expression of bovine trypsinogen in E. coli, its refolding and activation to beta-trypsin, and the selective incorporation of (15)N-labeled alanine through supplementation of the growth medium. Using this procedure, we expressed (15)N-labeled S195A trypsinogens, both on a wild-type and on a D189S background, in amounts suitable for NMR spectroscopy. 2D [(1)H-(15)N]-HSQC NMR was used to follow conformational changes upon activation of trypsinogen and formation of noncovalent complexes between S195A or S195A/D189S trypsin and protein proteinase inhibitors of different structural families and different sizes, as well as to examine the effects of introduction of the D189S mutation. Spectra of good quality were obtained for both trypsins alone and in complexes of increasing size with the proteinase inhibitors BPTI (total molecular mass 31 kDa), SBTI (total molecular mass 44 kDa), and the serpin alpha(1)-proteinase inhibitor Pittsburgh (alpha(1)PI Pittsburgh) (total molecular mass 69 kDa). Assignments of alanines 55 and 56, close to the active site histidine, and of alanine 195, present in the S195A variant used for most of the studies, were made by mutagenesis. These three alanines, together with two others, probably close to the S1 specificity pocket, were very sensitive to complex formation. In contrast, the remaining 10 alanines were invariant in chemical shift in all 3 of the noncovalent complexes formed, reflecting the conservation of structure in complexes with BPTI and SBTI known from X-ray crystal structures, but also indicating that there is no change in backbone conformation for the noncovalent complex with alpha(1)PI, for which there is no crystal structure. This was true both for S195A and for S195A/D189S trypsins. This high-level expression and labeling approach will be of great use for solution NMR studies on trypsin-serpin complexes, as well as for structural and mechanistic studies on trypsin variants.     

Formation of the covalent chymotrypsin.antichymotrypsin complex involves no large-scale movement of the enzyme

alpha(1)-Antichymotrypsin is a member of the serine proteinase inhibitor, or serpin, family that typically forms very long-lived, enzymatically inactive 1:1 complexes (denoted E*I*) with its target proteinases. Serpins share a conserved tertiary structure, in which an exposed region of amino acid residues (called the reactive center loop or RCL) acts as bait for a target proteinase. Within E*I*, the two proteins are linked covalently as a result of nucleophilic attack by Ser(195) of the serine proteinase on the P1 residue within the RCL of the serpin. This species is formally similar to the acyl enzyme species normally seen as an intermediate in serpin proteinase catalysis. However, its subsequent hydrolysis is extremely slow as a result of structural changes within the enzyme leading to distortion of the active site. There is at present an ongoing debate concerning the structure of the E*I* complex; in particular, as to whether the enzyme, bound to P1, maintains its original position at the top of the serpin molecule or instead translocates across the entire length of the serpin, with concomitant insertion of RCL residues P1-P14 within beta-sheet A and a large separation of the enzyme and RCL residue P1'. We report time-resolved fluorescence energy transfer and rapid mixing/quench studies that support the former model. Our results indicate that the distance between residue P1' in alpha(1)-antichymotrypsin and the amino terminus of chymotrypsin actually decreases on conversion of the encounter complex E.I to E*I*. These results led us to formulate a comprehensive mechanism that accounted both for our results and for those of others supporting the two different E*I* structures. In this mechanism, partial insertion of the RCL, with no large perturbation of the P1' enzyme distance, is followed by covalent acyl enzyme formation. Full insertion can subsequently take place, in a reversible fashion, with the position of equilibrium between the partially and fully inserted complexes depending on the particular serpin-proteinase pair under consideration.     

Insight into the molecular basis of coagulation proteinase specificity by mutagenesis of the serpin antithrombin

Specific cleavage of factor V at several P1Arg sites is critical for maintenance of hemostasis. While cleavage by procoagulant proteinases fXa and thrombin activates the cofactor, its cleavage by the anticoagulant proteinase activated protein C (APC) inactivates it. Antithrombin (AT), a specific serpin inhibitor of both thrombin and factor Xa, but not APC, was used as a model system to investigate molecular determinants of APC specificity in the inactivation reaction. Two mutants were prepared in which the P2 or the P3-P3' residues of the reactive site loop of the serpin were replaced with the corresponding residues of the APC cleavage site in factor V spanning residues 504-509 (Asp(504)-Arg-Arg-Gly-Ile-Gln(509)). Kinetic analysis showed that the reactivities of mutants were impaired by approximately 2-3 orders of magnitude with both factor Xa and thrombin, but improved by approximately 2 orders of magnitude with APC. The saturable dependence of the observed first-order rate constants on the concentrations of AT in complex with approximately 70-saccharide high-affinity heparin revealed that changes in the reactivity of the 504-509 mutant with proteinases are primarily due to an effect in the second reaction step in which a noncovalent serpin-proteinase encounter complex is converted to a stable, covalent complex. These results suggest that the P3-P3' residues of the APC cleavage site in factor Va, particularly P2Arg, confer specificity for the anticoagulant proteinase by improving the reactivity of the catalytic pocket with the transition state of the substrate in the second step of the reaction.     

Evidence for a tetrahedral intermediate complex during serpin-proteinase interactions

Proteinase inhibitors in the serpin family form complexes with serine proteinases by interactions between the gamma-OH group at serine 195 of the enzyme and a specific peptide bond within the reactive site loop of the inhibitor. However, the type of complex formed (i.e. Michaelis, acyl, or tetrahedral) is unknown. Until now, 13C NMR spectroscopy studies have only been useful in examining complexes formed with either peptide-related or small protein inhibitors, where 13C-labeled amino acids can be inserted semi-synthetically. Recombinant DNA technology has, however, made it possible to specifically enrich larger proteins with 13C. In the case of serpins we have examined the structure of the complex formed between human alpha 1-proteinase inhibitor uniformally labeled with [13C]methionine and porcine pancreatic elastase. 13C NMR spectroscopic studies revealed a large upfield chemical shift of the carbonyl signal of Met-358 upon complex formation suggesting for the first time that a tetrahedral adduct is formed between a serpin inhibitor and a serine proteinase.     

Mutation of the highly conserved tryptophan in the serpin breach region alters the inhibitory mechanism of plasminogen activator inhibitor-1

We have demonstrated that interactions within the conserved serpin breach region play a direct role in the critical step of the serpin reaction in which the acyl-enzyme intermediate must first be exposed to hydrolyzing water and aqueous deacylation. Substitution of the breach tryptophan in PAI-1 (Trp175), a residue found in virtually all known serpins, with phenylalanine altered the kinetics of the reaction mechanism and impeded the ability of PAI-1 to spontaneously become latent without compromising the inherent rate of cleaved loop insertion or partitioning between the final inhibited serpin-proteinase complex and hydrolyzed serpin. Kinetic dissection of the PAI-1 inhibitory mechanism using multiple target proteinases made possible the identification of a single rate-limiting intermediate step coupled to the molecular interactions within the breach region. This step involves the initial insertion of the proximal reactive center loop hinge residue(s) into beta-sheet A and facilitates translocation of the distal P'-side of the cleaved reactive center loop from the substrate cleft of the proteinase. Substitution of the tryptophan residue raised the kinetic barrier restricting the initial loop insertion event, significantly retarding the rate-limiting step in tPA reactions in which strong exosite interactions must be overcome for the reaction to proceed.     

Active site distortion is sufficient for proteinase inhibition by serpins: structure of the covalent complex of alpha1-proteinase inhibitor with porcine pancreatic elastase

We report here the x-ray structure of a covalent serpin-proteinase complex, alpha1-proteinase inhibitor (alpha1PI) with porcine pancreatic elastase (PPE), which differs from the only other x-ray structure of such a complex, that of alpha1PI with trypsin, in showing nearly complete definition of the proteinase. alpha1PI complexes with trypsin, PPE, and human neutrophil elastase (HNE) showed similar rates of deacylation and enhanced susceptibility to proteolysis by exogenous proteinases in solution. The differences between the two x-ray structures therefore cannot arise from intrinsic differences in the inhibition mechanism. However, self-proteolysis of purified complex resulted in rapid cleavage of the trypsin complex, slower cleavage of the PPE complex, and only minimal cleavage of the HNE complex. This suggests that the earlier alpha1 PI-trypsin complex may have been proteolyzed and that the present structure is more likely to be representative of serpin-proteinase complexes. The present structure shows that active site distortion alone is sufficient for inhibition and suggests that enhanced proteolysis is not necessarily exploited in vivo.     

Partitioning of serpin-proteinase reactions between stable inhibition and substrate cleavage is regulated by the rate of serpin reactive center loop insertion into beta-sheet A

The serpin family of serine proteinase inhibitors is a mechanistically unique class of naturally occurring proteinase inhibitors that trap target enzymes as stable covalent acyl-enzyme complexes. This mechanism appears to require both cleavage of the serpin reactive center loop (RCL) by the proteinase and a significant conformational change in the serpin structure involving rapid insertion of the RCL into the center of an existing beta-sheet, serpin beta-sheet A. The present study demonstrates that partitioning between inhibitor and substrate modes of reaction can be altered by varying either the rates of RCL insertion or deacylation using a library of serpin RCL mutants substituted in the critical P(14) hinge residue and three different proteinases. We further correlate the changes in partitioning with the actual rates of RCL insertion for several of the variants upon reaction with the different proteinases as determined by fluorescence spectroscopy of specific RCL-labeled inhibitor mutants. These data demonstrate that the serpin mechanism follows a branched pathway, and that the formation of a stable inhibited complex is dependent upon both the rate of the RCL conformational change and the rate of enzyme deacylation.     

Canonical inhibitor-like interactions explain reactivity of alpha1-proteinase inhibitor Pittsburgh and antithrombin with proteinases

The serpin antithrombin is a slow thrombin inhibitor that requires heparin to enhance its reaction rate. In contrast, alpha1-proteinase inhibitor (alpha1PI) Pittsburgh (P1 Met --> Arg natural variant) inhibits thrombin 17 times faster than pentasaccharide heparin-activated antithrombin. We present here x-ray structures of free and S195A trypsin-bound alpha1PI Pittsburgh, which show that the reactive center loop (RCL) possesses a canonical conformation in the free serpin that does not change upon binding to S195A trypsin and that contacts the proteinase only between P2 and P2'. By inference from the structure of heparin cofactor II bound to S195A thrombin, this RCL conformation is also appropriate for binding to thrombin. Reaction rates of trypsin and thrombin with alpha1PI Pittsburgh and antithrombin and their P2 variants show that the low antithrombin-thrombin reaction rate results from the antithrombin RCL sequence at P2 and implies that, in solution, the antithrombin RCL must be in a similar canonical conformation to that found here for alpha1PI Pittsburgh, even in the nonheparin-activated state. This suggests a general, limited, canonical-like interaction between serpins and proteinases in their Michaelis complexes.     

Identification of plasma proteinase complexes with serpin-3 in Manduca sexta

Extracellular serine proteinase cascades stimulate prophenoloxidase (proPO) activation and antimicrobial peptide production in insect innate immune responses. Serpins in plasma regulate such cascades by selective inhibition of proteinases, in reactions which result in the formation of covalent serpin-proteinase complexes. We carried out experiments to identify plasma proteinases that are inhibited by Manduca sexta serpin-3, an immune-inducible serpin known to regulate proPO activation. Immunoaffinity chromatography, using antiserum to serpin-3, yielded serpin-3 complexes with proteinases identified by immunoblot analysis as prophenoloxidase-activating proteinase (PAP)-1, PAP-2, PAP-3, and hemolymph proteinase 8 (HP8). HP8 can cleave and activate the Toll ligand, Spätzle, leading to synthesis of antimicrobial peptides. Analysis by mass spectrometry of tryptic peptides derived from the serpin-3 complexes confirmed the presence of PAP-1, PAP-3, and HP8. Purified recombinant serpin-3 and active HP8 formed an SDS-stable complex in vitro. Identification of serpin-3-proteinase complexes in plasma provides insight into proteinase targets of serpin-3 and extends the understanding of serpin/proteinase function in the immune response of M. sexta.     

Reactive site mutants of recombinant protein C inhibitor

Protein C inhibitor (PCI) is a heparin-binding serine proteinase inhibitor (serpin) which is thought to be a physiological regulator of activated protein C (APC). The residues F353-R354-S355 (P2-P1-P1′) constitute part of the reactive site loop of PCI with the R-S peptide bond being cleaved by the proteinase. Changing the reactive site P1 and P2 residues to those of either proteinase nexin-1, α₁-proteinase inhibitor or heparin cofactor II resulted in a decrease in inhibitory activity towards thrombin and APC. Changing the P2 residue F353 → P generated a rPCI which was a better thrombin inhibitor, but was 10-fold less active with APC. While these results support the concept that the P1 and P2 residues are important in the specificity of PCI, they suggest that the reactive site residues are not the only determinant of serpin specificity. Kinetic analysis of the rPCI variants was consistent with PCI operating by a mechanism similar to that proposed for other serpins. In this model an intermediary complex forms between inhibitor and proteinase that can proceed to either cleavage of the inhibitor as substrate or formation of an inactive complex.     

The pH dependence of serpin-proteinase complex dissociation reveals a mechanism of complex stabilization involving inactive and active conformational states of the proteinase which are perturbable by calcium

Serpin family protein proteinase inhibitors trap proteinases at the acyl-intermediate stage of cleavage of the serpin as a proteinase substrate by undergoing a dramatic conformational change, which is thought to distort the proteinase active site and slow deacylation. To investigate the extent to which proteinase catalytic function is defective in the serpin-proteinase complex, we compared the pH dependence of dissociation of several serpin-proteinase acyl-complexes with that of normal guanidinobenzoyl-proteinase acyl-intermediate complexes. Whereas the apparent rate constant for dissociation of guanidinobenzoyl-proteinase complexes (k(diss, app)) showed a pH dependence characteristic of His-57 catalysis of complex deacylation, the pH dependence of k(diss, app) for the serpin-proteinase complexes showed no evidence for His-57 involvement in complex deacylation and was instead characteristic of a hydroxide-mediated deacylation similar to that observed for the hydrolysis of tosylarginine methyl ester. Hydroxylamine enhanced the rate of serpin-proteinase complex dissociation but with a rate constant for nucleophilic attack on the acyl bond several orders of magnitude slower than that of hydroxide, implying limited accessibility of the acyl bond in the complex. The addition of 10-100 mm Ca(2+) ions stimulated up to 80-fold the dissociation rate constant of several serpin-trypsin complexes in a saturable manner at neutral pH and altered the pH dependence to a pattern characteristic of His-57-catalyzed complex deacylation. These results support a mechanism of kinetic stabilization of serpin-proteinase complexes wherein the complex is trapped as an acyl-intermediate by a serpin conformational change-induced inactivation of the proteinase catalytic function, but suggest that the inactive proteinase conformation in the complex is in equilibrium with an active proteinase conformation that can be stabilized by the preferential binding of an allosteric ligand such as Ca(2+).     

Conformational distributions of protease-serpin complexes: a partially translocated complex

Serpins regulate serine proteases by forming metastable covalent complexes with their targets. The protease docks with the serpin and cleaves the serpin's reactive center loop (RCL) forming an acylenzyme intermediate. Cleavage triggers insertion of the RCL into beta sheet A, translocating the attached protease approximately 70 A and disrupting the protease active site, trapping the acylenzyme intermediate. Using single-pair F?rster resonance energy transfer (spFRET), we have measured the conformational distributions of trypsin and alpha(1)-proteinase inhibitor (alpha(1)PI) covalent complexes. Bovine trypsin (BTryp) complexes display a single set of conformations consistent with the full translocation of BTryp (E(full)I*). However, the range of spFRET efficiencies is large, suggesting that the region around the trypsin label is mobile. Most complexes between alpha(1)PI variants and the more stable rat trypsin (RTryp) also show a single set of conformations, but the conformational distribution is narrower, indicating less disruption of RTryp. Surprisingly, RTryp complexes containing alpha(1)PI labeled at Cys232 with a cationic fluorophore display two equally populated conformations, E(full)I* and a conformation in which RTryp is only partially translocated (E(part)I*). Destabilizing the RTryp active site, by substituting Ala for Ile16, increases the E(full)I* population. Thus, interactions between anionic RTryp and cationic dyes likely exert a restraining force on alpha(1)PI, increasing the energy needed to translocate trypsin, and this force can be counteracted by active site destabilization. These results highlight the role of protease stability in determining the conformational distributions of protease-serpin covalent complexes and show that full translocation is not required for the formation of metastable complexes.     

Structure of a serpin-enzyme complex probed by cysteine substitutions and fluorescence spectroscopy

The x-ray crystal structure of the serpin-proteinase complex is yet to be determined. In this study we have investigated the conformational changes that take place within antitrypsin during complex formation with catalytically inactive (thrombin(S195A)) and active thrombin. Three variants of antitrypsin Pittsburgh (an effective thrombin inhibitor), each containing a unique cysteine residue (Cys(232), Cys(P3'), and Cys(313)) were covalently modified with the fluorescence probe N,N'-dimethyl-N-(iodoacetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)ethylenediamine. The presence of the fluorescent label did not affect the structure or inhibitory activity of the serpin. We monitored the changes in the fluorescence emission spectra of each labeled serpin in the native and cleaved state, and in complex with active and inactive thrombin. These data show that the serpin undergoes conformational change upon forming a complex with either active or inactive proteinase. Steady-state fluorescence quenching measurements using potassium iodide were used to further probe the nature and extent of this conformational change. A pronounced conformational change is observed upon locking with an active proteinase; however, our data reveal that docking with the inactive proteinase thrombin(S195A) is also able to induce a conformational change in the serpin.     

Inhibitory plant serpins with a sequence of three glutamine residues in the reactive center

Serpins appear to be ubiquitous in eukaryotes, except fungi, and are also present in some bacteria, archaea and viruses. Inhibitory serpins with a glutamine as the reactive-center P1 residue have been identified exclusively in a few plant species. Unique serpins with a reactive center sequence of three Gln residues at P3-P1 or P2-P1' were isolated from barley and wheat grain, respectively. Barley BSZ3 was an irreversible inhibitor of chymotrypsin, with a second-order association rate constant for complex formation k(a)' of the order of 10(4) M(-1) s(-1); however, only a minor fraction of the serpin molecules reacted with chymotrypsin, with the majority insensitive to cleavage in the reactive center loop. Wheat WSZ3 was cleaved specifically at P8 Thr and was not an inhibitor of chymotrypsin. These reactive-center loops may have evolved conformations that are optimal as inhibitory baits for proeinases that specifically degrade storage prolamins containing Gln-rich repetitive sequences, most likely for digestive proteinases of insect pests or fungal pathogens that infect cereals. An assembled full-length amino acid sequence of a serpin expressed in cotton boll fiber (GaZ1) included conserved regions essential for serpin-proteinase interaction, suggesting inhibitory capacity at a putative reactive center P2-P2' with a sequence of four Gln residues.     

Kinetic Intermediates en Route to the Final Serpin-Protease Complex: STUDIES OF COMPLEXES OF α1-PROTEASE INHIBITOR WITH TRYPSIN*

Serpin protein protease inhibitors inactivate their target proteases through a unique mechanism in which a major serpin conformational change, resulting in a 70-Å translocation of the protease from its initial reactive center loop docking site to the opposite pole of the serpin, kinetically traps the acyl-intermediate complex. Although the initial Michaelis and final trapped acyl-intermediate complexes have been well characterized structurally, the intermediate stages involved in this remarkable transformation are not well understood. To better characterize such intermediate steps, we undertook rapid kinetic studies of the FRET and fluorescence perturbation changes of site-specific fluorophore-labeled derivatives of the serpin, α₁-protease inhibitor (α₁PI), which report the serpin and protease conformational changes involved in transforming the Michaelis complex to the trapped acyl-intermediate complex in reactions with trypsin. Two kinetically resolvable conformational changes were observed in the reactions, ascribable to (i) serpin reactive center loop insertion into sheet A with full protease translocation but incomplete protease distortion followed by, (ii) full conformational distortion and movement of the protease and coupled serpin conformational changes involving the F helix-sheet A interface. Kinetic studies of calcium effects on the labeled α₁PI-trypsin reactions demonstrated both inactive and low activity states of the distorted protease in the final complex that were distinct from the intermediate distorted state. These studies provide new insights into the nature of the serpin and protease conformational changes involved in trapping the acyl-intermediate complex in serpin-protease reactions and support a previously proposed role for helix F in the trapping mechanism.