The contribution of the exosite residues of plasminogen activator inhibitor-1 to proteinase inhibition

The binding of plasminogen activator inhibitor-1 (PAI-1) to serine proteinases, such as tissue-type plasminogen activator (tPA) and urokinase-type plasminogen activator (uPA), is mediated by the exosite interactions between the surface-exposed variable region-1, or 37-loop, of the proteinase and the distal reactive center loop (RCL) of PAI-1. Although the contribution of such interactions to the inhibitory activity of PAI-1 has been established, the specific mechanistic steps affected by interactions at the distal RCL remain unknown. We have used protein engineering, stopped-flow fluorimetry, and rapid acid quenching techniques to elucidate the role of exosite interactions in the neutralization of tPA, uPA, and beta-trypsin by PAI-1. Alanine substitutions at the distal P4' (Glu-350) and P5' (Glu-351) residues of PAI-1 reduced the rates of Michaelis complex formation (k(a)) and overall inhibition (k(app)) with tPA by 13.4- and 4.7-fold, respectively, whereas the rate of loop insertion or final acyl-enzyme formation (k(lim)) increased by 3.3-fold. The effects of double mutations on k(a), k(lim), and k(app) were small with uPA and nonexistent with beta-trypsin. We provide the first kinetic evidence that the removal of exosite interactions significantly alters the formation of the noncovalent Michaelis complex, facilitating the release of the primed side of the distal loop from the active-site pocket of tPA and the subsequent insertion of the cleaved reactive center loop into beta-sheet A. Moreover, mutational analysis indicates that the P5' residue contributes more to the mechanism of tPA inhibition, notably by promoting the formation of a final Michaelis complex.     

Accelerated conversion of human plasminogen activator inhibitor-1 to its latent form by antibody binding.

The serpin plasminogen activator inhibitor-1 (PAI-1) slowly converts to an inactive latent form by inserting a major part of its reactive center loop (RCL) into its beta-sheet A. A murine monoclonal antibody (MA-33B8), raised against the human plasminogen activator (tPA).PAI-1 complex, rapidly inactivates PAI-1. Results presented here indicate that MA-33B8 induces acceleration of the active-to-latent conversion. The antibody-induced inactivation of PAI-1 labeled with the fluorescent probe N, N'-dimethyl-N-(acetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl) ethylene diamine (NBD) at P9 in the RCL caused a fluorescence enhancement and shift identical to those accompanying the spontaneous conversion of the P9.NBD PAI-1 to the latent form. Like latent PAI-1, antibody-inactivated PAI-1 was protected from cleavage by elastase. The rate constants for MA-33B8 binding, measured by NBD fluorescence or inactivation, were similar (1.3-1.8 x 10(4) M-1 s-1), resulting in a 4000-fold faster inactivation at 4.2 microM antibody binding sites. The apparent antibody binding rate constant, at least 1000 times slower than one limited by diffusion, indicates that exposure of its epitope depends on an unfavorable equilibrium of PAI-1. Our observations are consistent with this idea and suggest that the equilibrium involves partial insertion of the RCL into sheet A: latent, RCL-cleaved, and tPA-complexed PAI-1, which are inactive loop-inserted forms, bound much faster than active PAI-1 to MA-33B8, whereas two loop-extracted forms of PAI-1, modified to prevent loop insertion, did not bind or bound much more weakly to the antibody.     

A truncated plasminogen activator inhibitor-1 protein induces and inhibits angiostatin (kringles 1-3), a plasminogen cleavage product

Plasminogen activator inhibitor-1 (PAI-1) is a serpin protease inhibitor that binds plasminogen activators (uPA and tPA) at a reactive center loop located at the carboxyl-terminal amino acid residues 320-351. The loop is stretched across the top of the active PAI-1 protein maintaining the molecule in a rigid conformation. In the latent PAI-1 conformation, the reactive center loop is inserted into one of the beta sheets, thus making the reactive center loop unavailable for interaction with the plasminogen activators. We truncated porcine PAI-1 at the amino and carboxyl termini to eliminate the reactive center loop, part of a heparin binding site, and a vitronectin binding site. The region we maintained corresponds to amino acids 80-265 of mature human PAI-1 containing binding sites for vitronectin, heparin (partial), uPA, tPA, fibrin, thrombin, and the helix F region. The interaction of "inactive" PAI-1, rPAI-1(23), with plasminogen and uPA induces the formation of a proteolytic protein with angiostatin properties. Increasing amounts of rPAI-1(23) inhibit the proteolytic angiostatin fragment. Endothelial cells exposed to exogenous rPAI-1(23) exhibit reduced proliferation, reduced tube formation, and 47% apoptotic cells within 48 h. Transfected endothelial cells secreting rPAI-1(23) have a 30% reduction in proliferation, vastly reduced tube formation, and a 50% reduction in cell migration in the presence of VEGF. These two studies show that rPAI-1(23) interactions with uPA and plasminogen can inhibit plasmin by two mechanisms. In one mechanism, rPAI-1(23) cleaves plasmin to form a proteolytic angiostatin-like protein. In a second mechanism, rPAI-1(23) can bind uPA and/or plasminogen to reduce the number of uPA and plasminogen interactions, hence reducing the amount of plasmin that is produced.     

The reactive-center loop of active PAI-1 is folded close to the protein core and can be partially inserted

Plasminogen activator inhibitor 1 (PAI-1) is the main inhibitor of plasminogen activators and plays an important role in many pathophysiological processes. Like other members of the serpin family, PAI-1 has a reactive center consisting of a mobile loop (RCL) with P1 and P1' residues acting as a "bait" for cognate protease. In contrast to the other serpins, PAI-1 loses activity by spontaneous conversion to an inactive latent form. This involves full insertion of the RCL into beta-sheet A. To search for molecular determinants that could be responsible for conversion of PAI-1 to the latent form, we studied the conformation of the RCL in active PAI-1 in solution. Intramolecular distance measurements by donor-donor energy migration and probe quenching methods reveal that the RCL is located much closer to the core of PAI-1 than has been suggested by the recently resolved X-ray structures of stable PAI-1 mutants. Disulfide bonds can be formed in double-cysteine mutants with substitutions at positions P11 or P13 of the RCL and neighboring residues in beta-sheet A. This suggests that the RCL may be preinserted up to residue P13 in active PAI-1, and possibly even to residue P11. We propose that the close proximity of the RCL to the protein core, and the ability of the loop to preinsert into beta-sheet A is a possible reason for PAI-1 being able to convert spontaneously to its latent form.     

Structural basis for recognition of urokinase-type plasminogen activator by plasminogen activator inhibitor-1

Plasminogen activator inhibitor-1 (PAI-1), together with its physiological target urokinase-type plasminogen activator (uPA), plays a pivotal role in fibrinolysis, cell migration, and tissue remodeling and is currently recognized as being among the most extensively validated biological prognostic factors in several cancer types. PAI-1 specifically and rapidly inhibits uPA and tissue-type PA (tPA). Despite extensive structural/functional studies on these two reactions, the underlying structural mechanism has remained unknown due to the technical difficulties of obtaining the relevant structures. Here, we report a strategy to generate a PAI-1·uPA(S195A) Michaelis complex and present its crystal structure at 2.3-Å resolution. In this structure, the PAI-1 reactive center loop serves as a bait to attract uPA onto the top of the PAI-1 molecule. The P4–P3′ residues of the reactive center loop interact extensively with the uPA catalytic site, accounting for about two-thirds of the total contact area. Besides the active site, almost all uPA exosite loops, including the 37-, 60-, 97-, 147-, and 217-loops, are involved in the interaction with PAI-1. The uPA 37-loop makes an extensive interaction with PAI-1 β-sheet B, and the 147-loop directly contacts PAI-1 β-sheet C. Both loops are important for initial Michaelis complex formation. This study lays down a foundation for understanding the specificity of PAI-1 for uPA and tPA and provides a structural basis for further functional studies.     

The length of the reactive center loop modulates the latency transition of plasminogen activator inhibitor-1

Plasminogen activator inhibitor-1 (PAI-1) belongs to the serine protease inhibitor (serpin) protein family, which has a common tertiary structure consisting of three beta-sheets and several alpha-helices. Despite the similarity of its structure with those of other serpins, PAI-1 is unique in its conformational lability, which allows the conversion of the metastable active form to a more stable latent conformation under physiological conditions. For the conformational conversion to occur, the reactive center loop (RCL) of PAI-1 must be mobilized and inserted into the major beta-sheet, A sheet. In an effort to understand how the structural conversion is regulated in this conformationally labile serpin, we modulated the length of the RCL of PAI-1. We show that releasing the constraint on the RCL by extension of the loop facilitates a conformational transition of PAI-1 to a stable state. Biochemical data strongly suggest that the stabilization of the transformed conformation is owing to the insertion of the RCL into A beta-sheet, as in the known latent form. In contrast, reducing the loop length drastically retards the conformational change. The results clearly show that the constraint on the RCL is a factor that regulates the conformational transition of PAI-1.     

Saturation mutagenesis of the plasminogen activator inhibitor-1 reactive center.

Plasminogen activator inhibitor-1 (PAI-1) is a specific inhibitor of the serine proteases tissue-type plasminogen activator (tPA) and urokinase-type plasminogen activator (uPA). To systematically investigate the roles of the reactive center P1 and P1' residues in PAI-1 function, saturation mutagenesis was utilized to construct a library of PAI-1 variants. Examination of 177 unique recombinant proteins indicated that a basic residue was required at P1 for significant inhibitory activity toward uPA, whereas all substitutions except proline were tolerated at P1'. P1Lys variants exhibited lower inhibition rate constants and greater sensitivity to P1' substitutions than P1Arg variants. Alterations at either P1 or P1' generally had a larger effect on the inhibition of tPA. A number of variants that were relatively specific for either uPA or tPA were identified. P1Lys-P1'Ala reacted 40-fold more rapidly with uPA than tPA, whereas P1Lys-P1'Trp showed a 6.5-fold preference for tPA. P1-P1' variants containing additional mutations near the reactive center demonstrated only minor changes in activity, suggesting that specific amino acids in this region do not contribute significantly to PAI-1 function. These findings have important implications for the role of reactive center residues in determining serine protease inhibitor (serpin) function and target specificity.     

Interaction between the P14 residue and strand 2 of beta-sheet B is critical for reactive center loop insertion in plasminogen activator inhibitor-2

The molecular interactions driving reactive center loop (RCL) insertion are of considerable interest in gaining a better understanding of the serpin inhibitory mechanism. Previous studies have suggested that interactions in the proximal hinge/breach region may be critical determinants of RCL insertion in serpins. In this study, conformational and functional changes in plasminogen activator inhibitor-2 (PAI-2) following incubation with a panel of synthetic RCL peptides indicated that the P14 residue is critical for RCL insertion, and hence inhibitory activity, in PAI-2. Only RCL peptides with a P14 threonine were able to induce the stressed to relaxed transition and abolish inhibitory activity in PAI-2, indicating that RCL insertion into beta-sheet A of PAI-2 is dependent upon this residue. The recently solved crystal structure of relaxed PAI-2 (PAI-2.RCL peptide complex) allowed detailed analysis of molecular interactions involving P14 related to RCL insertion. Of most interest is the rearrangement of hydrogen bonding around the breach region that accompanies the stressed to relaxed transition, in particular the formation of a side chain hydrogen bond between the threonine at P14 and an adjacent tyrosine on strand 2 of beta-sheet B in relaxed PAI-2. Structural alignment of known serpin sequences showed that this pairing (or the equivalent serine/threonine pairing) is highly conserved ( approximately 87%) in inhibitory serpins and may represent a general structural basis for serpin inhibitory activity.     

Structure-function studies of the SERPIN plasminogen activator inhibitor type 1. Analysis of chimeric strained loop mutants.

Three chimeric mutants of plasminogen activator inhibitor 1 (PAI-1) have been constructed where the strained loop of wild type PAI-1 (wtPAI-1) has been replaced with a 19-amino acid region from either plasminogen activator inhibitor 2 (PAI-2), antithrombin III, or with an artificial serine protease inhibitor superfamily consensus strained loop. The inhibitors were expressed in Escherichia coli, and the purified proteins had specific activities toward urokinase-type plasminogen activator (uPA) or the single- and two-chain forms of tissue type plasminogen activator (tPA) that were similar to wtPAI-1. Experiments suggest that the strained loop of PAI-1 is not responsible for the transition between the latent and the active conformations or for binding to vitronectin. Second-order rate constants for the interactions with uPA and single- or two-chain tPA were similar to those of wtPAI-1. Values range from a low of 1.8 x 10(5) M-1 s-1 for the interaction of the PAI-2 chimera with single-chain tPA to a high value of 1.6 x 10(7) M-1 s-1 for the consensus mutant with two-chain tPA. This former value is 200 times higher than the reported rate constant for the interaction between PAI-2 and single-chain tPA, suggesting that structures outside of the strained loop are responsible for the major differences in specificity between PAI-1 and PAI-2.     

Protonation state of a single histidine residue contributes significantly to the kinetics of the reaction of plasminogen activator inhibitor-1 with tissue-type plasminogen activator

Stopped-flow fluorometry was used to study the kinetics of the reactive center loop insertion occurring during the reaction of N-((2-(iodoacetoxy)ethyl)-N-methyl)amino-7-nitrobenz-2-oxa-3-diazole (NBD) P9 plasminogen activator inhibitor-1 (PAI-1) with tissue-(tPA) and urokinase (uPA)-type plasminogen activators and human pancreatic elastase at pH 5.5-8.5. The limiting rate constants of reactive center loop insertion (k(lim)) and concentrations of proteinase at half-saturation (K(0.5)) for tPA and uPA and the specificity constants (k(lim)/K(0.5)) for elastase were determined. The pH dependences of k(lim)/K(0.5) reflected inactivation of each enzyme due to protonation of His57 of the catalytic triad. However, the specificity of the inhibitory reaction with tPA and uPA was notably higher than that for the substrate reaction catalyzed by elastase. pH dependences of k(lim) and K(0.5) obtained for tPA revealed an additional ionizable group (pKa, 6.0-6.2) affecting the reaction. Protonation of this group resulted in a significant increase in both k(lim) and K(0.5) and a 4.6-fold decrease in the specificity of the reaction of tPA with NBD P9 PAI-1. Binding of monoclonal antibody MA-55F4C12 to PAI-1 induced a decrease in k(lim) and K(0.5) at any pH but did not affect either the pKa of the group or an observed decrease in k(lim)/K(0.5) due to protonation of the group. In contrast to tPA, the k(lim) and K(0.5) for the reactions of uPA with NBD P9 PAI-1 or its complex with the monoclonal antibody were independent of pH in the 6.5-8.5 range. Since slightly acidic pH is a feature of a number of malignant tumors, alterations in PAI-1/tPA kinetics could play a role in the cancerogenesis. Changes in the protonation state of His(188), which is placed closely to the S1 site and is unique for tPA, has been proposed to contribute to the observed pH dependences of k(lim) and K(0.5).     

The plasminogen activator inhibitor-1 binding site in the kringle-2 domain of tissue-type plasminogen activator

We have shown that synthetic peptides containing the amino acid sequence Asn-Arg-Arg-Leu, derived from the amino acid sequence of the inner loop of the kringle-2 domain of tissue-type plasminogen activator (tPA), inhibited complex formation between two chain tPA and plasminogen activator inhibitor-1 (PAI-1) by binding to PAI-1. This binding was reversible and was inhibited by not only tPA but also by enzymatically inactive tPA. Quantitative analyses of the interaction of PAI-1 with the peptide containing the Asn-Arg-Arg-Leu sequence indicated that the PAI-1 binding site residues in the inner loop of the kringle-2 domain and is preferentially expressed in two chain tPA.     

The conversion of active to latent plasminogen activator inhibitor-1 is an energetically silent event

PAI-1 is a proteinase inhibitor, which plays a key role in the regulation of fibrinolysis. It belongs to the serpins, a family of proteins that behave either as proteinase inhibitors or proteinase substrates, both reactions involving limited proteolysis of the reactive center loop and insertion of part of this loop into beta-sheet A. Titration calorimetry shows that the inhibition of tissue-type plasminogen and pancreatic trypsin are exothermic reactions with DeltaH = -20.3, and -22.5 kcal.mol(-1), respectively. The Pseudomonas aeruginosa elastase-catalyzed reactive center loop cleavage and inactivation of the inhibitor is also exothermic (DeltaH = -38.9 kcal.mol(-1)). The bacterial elastase also hydrolyses peptide-bound PAI-1 in which acetyl-TVASSSTA, the octapeptide corresponding to the P(14)-P(7) sequence of the reactive center loop is inserted into beta-sheet A of the serpin with DeltaH = -4.0 kcal.mol(-1). In contrast, DeltaH = 0 for the spontaneous conversion of the metastable active PAI-1 molecule into its thermodynamically stable inactive (latent) conformer although this conversion also involves loop/sheet insertion. We conclude that the active to latent transition of PAI-1 is an entirely entropy-driven phenomenon.     

Modulation of serpin reaction through stabilization of transient intermediate by ligands bound to alpha-helix F

Mechanism-based inhibition of proteinases by serpins involves enzyme acylation and fast insertion of the reactive center loop (RCL) into the central beta-sheet of the serpin, resulting in mechanical inactivation of the proteinase. We examined the effects of ligands specific to alpha-helix F (alphaHF) of plasminogen activator inhibitor-1 (PAI-1) on the stoichiometry of inhibition (SI) and limiting rate constant (k(lim)) of RCL insertion for reactions with beta-trypsin, tissue-type plasminogen activator (tPA), and urokinase. The somatomedin B domain of vitronectin (SMBD) did not affect SI for any proteinase or k(lim) for tPA but decreased the k(lim) for beta-trypsin. In contrast to SMBD, monoclonal antibodies MA-55F4C12 and MA-33H1F7, the epitopes of which are located at the opposite side of alphaHF, decreased k(lim) and increased SI for every enzyme. These effects were enhanced in the presence of SMBD. RCL insertion for beta-trypsin and tPA is limited by different subsequent steps of PAI-1 mechanism as follows: enzyme acylation and formation of a loop-displaced acyl complex (LDA), respectively. Stabilization of LDA through the disruption of the exosite interactions between PAI-1 and tPA induced an increase in the k(lim) but did not affect the SI. Thus it is unlikely that LDA contributes significantly to the outcome of the serpin reaction. These results demonstrate that the rate of RCL insertion is not necessarily correlated with SI and indicate that an intermediate, different from LDA, which forms during the late steps of PAI-1 mechanism, and could be stabilized by ligands specific to alphaHF, controls bifurcation between the inhibitory and the substrate pathways.     

Plasminogen activator inhibitor type-1-deficient mice have an enhanced IFN-gamma response to lipopolysaccharide and staphylococcal enterotoxin B

Plasminogen activator inhibitor type-1 (PAI-1) is a major inhibitor of fibrinolysis by virtue of its capacity to inhibit urokinase-type plasminogen activator (uPA) and tissue-type plasminogen activator (tPA). Systemic inflammation is invariably associated with elevated circulating levels of PAI-1, and during human sepsis plasma PAI-1 concentrations predict an unfavorable outcome. Knowledge about the functional role of PAI-1 in a systemic inflammatory response syndrome is highly limited. In this study, we determined the role of endogenous PAI-1 in cytokine release induced by administration of LPS or staphylococcal enterotoxin B (SEB). Both LPS and SEB elicited secretion of PAI-1 into the circulation of normal wild-type (Wt) mice. Relative to Wt mice, PAI-1 gene-deficient (PAI-1(-/-)) mice demonstrated strongly elevated plasma IFN-gamma concentrations after injection of either LPS or SEB. In addition, PAI-1(-/-) splenocytes released more IFN-gamma after incubation with LPS or SEB than Wt splenocytes. Both PAI-1(-/-) CD4+ and CD8+ T cells produced more IFN-gamma upon stimulation with SEB. LPS-induced IFN-gamma release in mice deficient for uPA, the uPA receptor, or tPA was not different from IFN-gamma release in LPS-treated Wt mice. These results identify a novel function of PAI-1 during systemic inflammation, where endogenous PAI-1 serves to inhibit IFN-gamma release by a mechanism that does not depend on its interaction with uPA/uPA receptor or tPA.     

Distinct encounter complexes of PAI‐1 with plasminogen activators and vitronectin revealed by changes in the conformation and dynamics of the reactive center loop

Plasminogen activator inhibitor‐1 (PAI‐1) is a biologically important serine protease inhibitor (serpin) that, when overexpressed, is associated with a high risk for cardiovascular disease and cancer metastasis. Several of its ligands, including vitronectin, tissue‐type and urokinase‐type plasminogen activator (tPA, uPA), affect the fate of PAI‐1. Here, we measured changes in the solvent accessibility and dynamics of an important unresolved functional region, the reactive center loop (RCL), upon binding of these ligands. Binding of the catalytically inactive S195A variant of tPA to the RCL causes an increase in fluorescence, indicating greater solvent protection, at its C‐terminus, while mobility along the loop remains relatively unchanged. In contrast, a fluorescence increase and large decrease in mobility at the N‐terminal RCL is observed upon binding of S195A‐uPA to PAI‐1. At a site distant from the RCL, binding of vitronectin results in a modest decrease in fluorescence at its proximal end without restricting overall loop dynamics. These results provide the new evidence for ligand effects on RCL conformation and dynamics and differences in the Michaelis complex with plasminogen activators that can be used for the development of more specific inhibitors to PAI‐1. This study is also the first to use electron paramagnetic resonance (EPR) spectroscopy to investigate PAI‐1 dynamics. Significance : Balanced blood homeostasis and controlled cell migration requires coordination between serine proteases, serpins, and cofactors. These ligands form noncovalent complexes, which influence the outcome of protease inhibition and associated physiological processes. This study reveals differences in binding via changes in solvent accessibility and dynamics within these complexes that can be exploited to develop more specific drugs in the treatment of diseases associated with unbalanced serpin activity.     

促性腺激素诱导猕猴排卵周期中卵巢纤溶酶...

Changes of plasminogen activator (PA) and its inhibitor (PAI-1) activity and antigen have been investigated during PMSG/hCG induced ovulation in rhesus monkeys. It has been demonstrated that the ovarian tissue type PA (tPA) activity, which reaches maximum prior to ovulation and declines thereafter, is closely related to follicular rupture; significant increases in urokinase type PA (uPA) only occurs in granulosa cells after ovulation. Since the secretory activity of ovarian PAI-1 reaches its peak level 12-24 h earlier than tPA the rapid decrease in PAI-1 activity in the approach of ovulation is correlated with the elevation of tPA activity. It is, therefore, suggested that a counterbalance of tPA and PAI-1 activity within the ovary may play an important role in the ovulation mechanism, whereas uPA may be involved in the regulation of corpus luteum formation.     

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 Model of the Reactive Form of Plasminogen Activator Inhibitor-1

A model of the reactive form of plasminogen activator inhibitor-1 (PAI-1) has been constructed using molecular graphics and starting from the known crystal structure of latent PAI-1. The residues P16 to P10′, of which P16-P4 form strand 4 of the β-sheet A (s4A) and P3-P10′ form an extended loop in the latent form, have been removed and remodeled into this structure, based on the structures of ovalbumin and cleaved α1-proteinase inhibitor. Residues P4′-P10′ were remodeled as a β-strand s1C, located on the surface of the molecule and the N-terminal end (P16-P14) of the eliminated loop was rebuilt using appropriate backbone dihedrals. Subsequently, a secondary structure prediction program was applied and further optimization of the model was performed by several molecular dynamics runs. Apparently the β-strand was stabilized by only two hydrogen bonds. Further analysis revealed that, although s4A was removed, s3A and s5A did not approach each other. In this current model it was also found that the large gap between the loop connecting s4C-s3C and the loop connecting s3B-hG remained 11 Å in contrast to the small gap (4Å) at a similar position in other serpins. These observations may explain the ease of a conformational change of the reactive site loop of PAI-1 during transition to the latent and the preinserted form. In addition the current model can be used for the design of stable, functional, PAI-1 mutants. Detailed structural analysis of the latter may facilitate studies on the structure-function relationship in PAI-1 in particular and in other serpins in general.     

Components of the Plasminogen Activation System Promote Engraftment of Porous Polyethylene Biomaterial via Common and Distinct Effects

Rapid fibrovascularization is a prerequisite for successful biomaterial engraftment. In addition to their well-known roles in fibrinolysis, urokinase-type plasminogen activator (uPA) and tissue plasminogen activator (tPA) or their inhibitor plasminogen activator inhibitor-1 (PAI-1) have recently been implicated as individual mediators in non-fibrinolytic processes, including cell adhesion, migration, and proliferation. Since these events are critical for fibrovascularization of biomaterial, we hypothesized that the components of the plasminogen activation system contribute to biomaterial engraftment. Employing in vivo and ex vivo microscopy techniques, vessel and collagen network formation within porous polyethylene (PPE) implants engrafted into dorsal skinfold chambers were found to be significantly impaired in uPA-, tPA-, or PAI-1-deficient mice. Consequently, the force required for mechanical disintegration of the implants out of the host tissue was significantly lower in the mutant mice than in wild-type controls. Conversely, surface coating with recombinant uPA, tPA, non-catalytic uPA, or PAI-1, but not with non-catalytic tPA, accelerated implant vascularization in wild-type mice. Thus, uPA, tPA, and PAI-1 contribute to the fibrovascularization of PPE implants through common and distinct effects. As clinical perspective, surface coating with recombinant uPA, tPA, or PAI-1 might provide a novel strategy for accelerating the vascularization of this biomaterial.     

Latency and substrate binding globally reduce solvent accessibility of plasminogen activator inhibitor type 1 (PAI-1). An adaptation of PAI-1 conformer crystal structures by hydrogen-deuterium exchange

Plasminogen activator inhibitor type 1 (PAI-1) plays key regulatory roles in fibrinolysis, cell migration, and tissue remodeling. A regulatory protein without known catalytic activity, PAI-1 modulates plasminogen activators through protein-protein interactions. Although global conformational alterations that occur in PAI-1 determine its regulatory activity, comprehensive assessments of concurrent dynamic, structural, and functional alterations of this critical regulatory protein have not yet been clearly defined. X-ray crystallographic studies have described four distinct PAI-1 conformational states: active, latent, reactive center loop peptide-annealed (RCL-PA), and cleaved mutant. In this study, backbone amide hydrogen-deuterium exchange detected by mass spectrometry was used to characterize dynamic and structural alterations of human PAI-1 (hPAI-1) in relation to its function. hPAI-1 conformers were defined by surface mapping the solvent-accessible sites for strategic secondary structural components of the protein. We observed a global protection from solvent for a majority of peptides in the latent conformer relative to the active conformer. Significant differences were observed in the RCL, helix A, helix D, and sheet 1C, and these regions were markedly more dynamic or solvent-exposed in the active conformation. The RCL-PA form adopts an intermediate conformational state between the active and the latent conformers. Our results demonstrate that the most dynamic regions of PAI-1 (the RCL, helices D and A, and sheet 5A) are flexible in the transition toward latency. They also show that the dynamic surface structures of the active, latent, and peptide-annealed conformers of PAI-1 are underestimated by theoretical solvent accessibility calculations derived from crystallographic data.