The serpin MNEI inhibits elastase-like and chymotrypsin-like serine proteases through efficient reactions at two active sites.

MNEI (monocyte/neutrophil elastase inhibitor) is a 42 kDa serpin superfamily protein characterized initially as a fast-acting inhibitor of neutrophil elastase. Here we show that MNEI has a broader specificity, efficiently inhibiting proteases with elastase- and chymotrypsin-like specificities. Reaction of MNEI with neutrophil proteinase-3, an elastase-like protease, and porcine pancreatic elastase demonstrated rapid inhibition rate constants >10(7) M(-1) s(-1), similar to that observed for neutrophil elastase. Reactions of MNEI with chymotrypsin-like proteases were also rapid: cathepsin G from neutrophils (>10(6) M(-1) s(-1)), mast cell chymase (>10(5) M(-1) s(-1)), chymotrypsin (>10(6) M(-1) s(-1)), and prostate-specific antigen (PSA), which had the slowest rate constant at approximately 10(4) M(-1) s(-1). Inhibition of trypsin-like (plasmin, granzyme A, and thrombin) and caspase-like (granzyme B) serine proteases was not observed or highly inefficient (trypsin), nor was inhibition of proteases from the cysteine (caspase-1 and caspase-3) and metalloprotease (macrophage elastase, MMP-12) families. The stoichiometry of inhibition for all inhibitory reactions was near 1, and inhibitory complexes were resistant to dissociation by SDS, further indicating the specificity of MNEI for elastase- and chymotrypsin-like proteases. Determination of the reactive site of MNEI by N-terminal sequencing and mass analysis of reaction products identified two reactive sites, each with a different specificity. Cys(344), which corresponds to Met(358), the P(1) site of alpha1-antitrypsin, was the inhibitory site for elastase-like proteases and PSA, while the preceding residue, Phe(343), was the inhibitory site for chymotrypsin-like proteases. This study demonstrates that MNEI has two functional reactive sites corresponding to the predicted P(1) and P(2) positions of the reactive center loop. The data suggest that MNEI plays a regulatory role at extravascular sites to limit inflammatory damage due to proteases of cellular origin.     

Discriminating between the activities of human neutrophil elastase and proteinase 3 using serpin-derived fluorogenic substrates

Human neutrophil elastase (HNE) has long been linked to the pathology of a variety of inflammatory diseases and therefore is a potential target for therapeutic intervention. At least two other serine proteases, proteinase 3 (Pr3) and cathepsin G, are stored within the same neutrophil primary granules as HNE and are released from the cell at the same time at inflammatory sites. HNE and Pr3 are structurally and functionally very similar, and no substrate is currently available that is preferentially cleaved by Pr3 rather than HNE. Discrimination between these two proteases is the first step in elucidating their relative contributions to the development and spread of inflammatory diseases. Therefore, we have prepared new fluorescent peptidyl substrates derived from natural target proteins of the serpin family. This was done because serpins are rapidly cleaved within their reactive site loop whether they act as protease substrates or inhibitors. The hydrolysis of peptide substrates reflects the specificity of the parent serpin including those from alpha-1-protease inhibitor and monocyte neutrophil elastase inhibitor, two potent inhibitors of elastase and Pr3. More specific substrates for these proteases were derived from the reactive site loop of plasminogen activator inhibitor 1, proteinase inhibitors 6 and 9, and from the related viral cytokine response modifier A (CrmA). This improved specificity was obtained by using a cysteinyl residue at P1 for Pr3 and an Ile residue for HNE and because of occupation of protease S' subsites. These substrates enabled us to quantify nanomolar concentrations of HNE and Pr3 that were free in solution or bound at the neutrophil surface. As membrane-bound proteases resist inhibition by endogenous inhibitors, measuring their activity at the surface of neutrophils may be a great help in understanding their role during inflammation.     

Elastase inhibition by the inter-alpha-trypsin inhibitor and derived inhibitors of man and cattle

The inhibitory properties of HI-14 and BI-14, the active 14-kDa parts released from the corresponding human and bovine inter-alpha-trypsin inhibitors, are compared. The structurally homologous inhibitors composed of two tandem Kunitz-type domains differ in their inhibitory specificity, although the reactive site residue in position P1 is occupied by identical (arginine in the C-terminal domain II) or similar (methionine and leucine in the N-terminal domain I of HI-14 and BI-14, respectively) amino-acid residues. The N-terminal domain I of HI-14 is completely inactive against chymotrypsin and pancreatic elastase, whereas BI-14 is a strong inhibitor of these enzymes. Elastase from polymorphonuclear granulocytes interacts with both inhibitors but with different affinities. Compared with the bovine inhibitor, the human inhibitor shows a much lower affinity from this enzyme. Human ITI and its physiological 30-kDa derivative (HI-30) show the same inhibitory properties as HI-14. The differences between human and bovine inhibitors might be explained by a preceding oxidation of Met in vivo of the reactive site residue in position P1 and/or by the influence of the environmental parts connected with this antielastase reactive site region in human ITI or in the active domains thereof.     

The effects of reactive site location on the inhibitory properties of the serpin alpha(1)-antichymotrypsin

The large size of the serpin reactive site loop (RSL) suggests that the role of the RSL in protease inhibition is more complex than that of presenting the reactive site (P1 residue) to the protease. This study examines the effect on inhibition of relocating the reactive site (Leu-358) of the serpin alpha(1)-antichymotrypsin either one residue closer (P2) or further (P1') from the base of the RSL (Glu-342). alpha(1)-Antichymotrypsin variants were produced by mutation within the P4-P2' region; the sequence ITLLSA was changed to ITLSSA to relocate the reactive site to P2 (Leu-357) and to ITITLS to relocate it to P1' (Leu-359). Inhibition of the chymotrypsin-like proteases human chymase and chymotrypsin and the non-target protease human neutrophil elastase (HNE) were analyzed. The P2 variant inhibited chymase and chymotrypsin but not HNE. Relative to P1, interaction at P2 was characterized by greater complex stability, lower inhibition rate constants, and increased stoichiometry of inhibition values. In contrast, the P1' variant inhibited HNE (stoichiometry of inhibition = 4) but not chymase or chymotrypsin. However, inhibition of HNE was by interaction with Ile-357, the P2 residue. The P1' site was recognized by all proteases as a cleavage site. Covalent-complexes resistant to SDS-PAGE were observed in all inhibitory reactions, consistent with the trapping of the protease as a serpin-acyl protease complex. The complete loss in inhibitory activity associated with lengthening the Glu-342-reactive site distance by a single residue and the enhanced stability of complexes associated with shortening this distance by a single residue are compatible with the distorted-protease model of inhibition requiring full insertion of the RSL into the body of the serpin and translocation of the linked protease to the pole opposite from that of encounter.     

Mutational and immunochemical analysis of plasminogen activator inhibitor 1

We have undertaken a structural and functional analysis of recombinant plasminogen activator inhibitor type 1 (PAI-1) produced in Escherichia coli using site-directed mutagenesis and immunochemistry. Expression of recombinant PAI-1 yielded an inhibitor that was functionally indistinguishable from PAI-1 made in human endothelial cells. Mutations in both the reactive center P1 and P1' residues (Arg-Met) and a putative secondary binding site for plasminogen activators on PAI-1 have been engineered to assess their functional effects. The inhibition of a panel of serine proteases, including plasminogen activators, trypsin, elastase, and thrombin, has been studied. Substitution of the P1 arginine residue with lysine or the P1' residue with either valine or serine had no detectable effect on the rate of inhibition of plasminogen activators. However, replacement of both P1 and P1' by Met-Ser produced a variant with no detectable plasminogen activator inhibitor activity. Mutations introduced into either Asp102 or Lys104 in the second site did not affect the rate of inhibition of plasminogen activators. Complementary immunochemical experiments using antibodies directed against the same two regions of the PAI-1 protein confirm that the reactive center is the primary determinant of inhibitory activity and that the putative second site is not a necessary functional region.     

Conversion of the Alzheimer's beta-amyloid precursor protein (APP) Kunitz domain into a potent human neutrophil elastase inhibitor

Site-specific mutagenesis techniques have been used to construct active site variants of the Kunitz-type protease inhibitor domain present in the Alzheimer's beta-amyloid precursor protein (APP-KD). Striking alteration of its protease inhibitory properties were obtained when the putative P1 residue, arginine, was replaced with the small hydrophobic residue valine. The altered protein was no longer inhibitory toward bovine pancreatic trypsin, human Factor XIa, mouse epidermal growth factor-binding protein, or bovine chymotrypsin, all of which are strongly inhibited by the unaltered APP-KD (Sinha, S., Dovey, H. F., Seubert, P., Ward, P. J., Blacher, R. W., Blaber, M., Bradshaw, R. A., Arici, M., Mobley, W. C., and Lieberburg, I. (1990) J. Biol. Chem. 265, 8983-8985). Instead, the P1-Val-APP-KD was a potent inhibitor of human neutrophil elastase, with a Ki = 0.8 nM, as estimated by the inhibition of the activity of human neutrophil elastase measured using a chromogenic substrate. It also inhibited the degradation of insoluble elastin by the enzyme virtually stoichiometrically. Replacement of the P1' (Ala) and P2' (Met) residues of P1-Val-MKD with the corresponding residues (Ser, Ile) from alpha 1-proteinase inhibitor resulted in an inactive protein, underscoring the mechanistic differences between the serpins from the Kunitz-type protease inhibitor family. These results confirm the importance of the P1 arginine residue of APP-KD in determining inhibitory specificity, and are also the first time that a single amino acid replacement has been shown to generate a specific potent human neutrophil elastase inhibitor from a human KD sequence.     

Expression and mutagenesis of the novel serpin endopin 2 demonstrates a requirement for cysteine-374 for dithiothreitol-sensitive inhibition of elastase

The primary sequence of the serpin endopin 2 predicts a reactive site loop (RSL) region that possesses high homology to bovine elastase inhibitor, suggesting inhibition of elastase. Moreover, endopin 2 possesses two cysteine residues that implicate roles for reduced Cys residue(s) for inhibitory activity. To test these predicted properties, mutagenesis and chemical modification of recombinant endopin 2 were performed to examine the influence of dithiothreitol (DTT), a reducing agent, on endopin 2 activity. Endopin 2 inhibited elastase in a DTT-dependent manner, with enhanced inhibition in the presence of DTT. The stoichiometry of inhibition in the presence of DTT occurred at a molar ratio of endopin 2 to elastase of 8/1, resulting in complete inhibition of elastase. However, a higher molar ratio (25/1) was required in the absence of DTT. DTT enhanced the formation of SDS-stable complexes of endopin 2 and elastase, a characteristic property of serpins. Site-directed mutagenesis of endopin 2, with substitution of Ala for Cys-232 or Cys-374, demonstrated that Cys-374 (but not Cys-232) was required for the DTT-sensitive nature of endopin 2. Chemical modification of Cys-374 by bis(maleimido)ethane also reduced inhibitory activity. Modified electrophoretic mobilities of mutant endopin 2 suggested the presence of intramolecular disulfide bonds; in addition, chemical modification suggested that Cys-374 influences the electrophoretic and conformational properties of endopin 2. Moreover, the reducing agent glutathione enhanced endopin 2 activity, suggesting that glutathione can function as an endogenous reducing agent for endopin 2 in vivo. These findings demonstrate the importance of Cys-374 for DTT-sensitive inhibition of elastase by endopin 2.     

Antiprotease targeting: altered specificity of alpha 1-antitrypsin by amino acid replacement at the reactive centre

Alpha-1 antitrypsin (alpha 1AT) is an efficient inhibitor of the human neutrophil proteases, elastase and cathepsin G. The reactive centre P1 residue (Met358) of alpha 1AT is important in defining the specificity of inhibition; furthermore, oxidation of this residue results in a loss of inhibitor activity. There is evidence that oxidative inactivation of alpha 1AT may be involved in the pathogenesis of pulmonary emphysema associated with cigarette smoking. We have studied the effect of a series of amino acid replacements at the active centre on the inhibition properties of alpha 1AT. The mutant proteins were produced in E. coli following in vitro mutagenesis of the alpha 1AT cDNA. Alpha-1-AT (Ile358), (Ala358) and (Val358) were efficient inhibitors of both neutrophil and pancreatic elastase, but not cathepsin G. Alpha-1-AT (Ala356, Val358) and alpha 1AT (Phe358) were specific for pancreatic elastase and cathepsin G respectively. Alpha-1-AT (Leu358) inhibited both neutrophil elastase and cathepsin G. These data show that, for effective inhibition, a potential cleavage site for the protease must be displayed at the alpha 1AT active centre. In each case, replacement of Met358 led to resistance to oxidative inactivation. Since alpha 1AT (Leu358) inhibits both neutrophil proteases and is resistant to oxidation, this variant may be of increased potential for the therapy of destructive lung disorders.     

Characterization of human pre-elafin mutants: full antipeptidase activity is essential to preserve lung tissue integrity in experimental emphysema

Pre-elafin is a tight-binding inhibitor of neutrophil elastase and myeloblastin; two enzymes thought to contribute to tissue damage in lung emphysema. Previous studies have established that pre-elafin is also an effective anti-inflammatory molecule. However, it is not clear whether both functions are linked to the antipeptidase activity of pre-elafin. As a first step toward elucidating the structure/function relationship of this protein, we describe here the construction and characterization of pre-elafin variants with attenuated antipeptidase potential. In these mutants, the P1' methionine residue of the inhibitory loop is replaced by either a lysine (pre-elafinM25K) or a glycine (pre-elafinM25G) residue. Both mutated variants are stable and display biochemical properties undistinguishable from WT (wild-type) pre-elafin. However, compared with WT pre-elafin, their inhibitory constants are increased by one to four orders of magnitude toward neutrophil elastase, myeloblastin and pancreatic elastase, depending on the variants and enzymes tested. As suggested by molecular modelling, this attenuated inhibitory potential correlates with decreased van der Waals interactions between the variants and the enzymes S1' subsite. In elastase-induced experimental emphysema in mice, only WT pre-elafin protected against tissue destruction, as assessed by the relative airspace enlargement measured using lung histopathological sections. Pre-elafin and both mutants prevented transient neutrophil alveolitis. However, even the modestly affected pre-elafinM25K mutant, as assayed in vitro with small synthetic substrates, was a poor inhibitor of the neutrophil elastase and myeloblastin elastolytic activity measured with insoluble elastin. We therefore conclude that full antipeptidase activity of pre-elafin is essential to protect against lung tissue lesions in this experimental model.     

The reactive site of human alpha 2-antiplasmin

Human alpha 2-antiplasmin rapidly forms a stable, equimolar complex with either its target enzyme, plasmin, or with trypsin. Perturbation of the inhibitor-trypsin complex results in peptide bond cleavage at the reactive site of the inhibitor with the concomitant release of a small peptide fragment which apparently represents the carboxyl-terminal segment of the inhibitor. Sequence analysis of this fragment, together with that of an overlapping peptide obtained by treatment of native inhibitor with either Staphylococcus aureus V8 proteinase or human neutrophil elastase, yields data which indicate that the reactive site of alpha 2-antiplasmin encompasses a P1-P'1 Arg-Met sequence. However, unlike alpha 1-1-proteinase inhibitor which has a Met residue in the P1-position, oxidation of alpha 2-antiplasmin has no effect on its inhibitory activity toward either plasmin, trypsin, or chymotrypsin, indicating the lesser mechanistic importance of the P'1-residue during enzyme inactivation by this inhibitor.     

Chemical replacement of P1' arginine residue at the first reactive site of peanut protease inhibitor B-III

The contribution of the P1' residue at the first reactive site of peanut protease inhibitor B-III to the inhibition was analyzed by replacement of the P1' Arg(11) with other amino acids (Arg, Ser, Ala, Leu, Phe, Asp) after selective modification of the second reactive site. The Arg derivative had the same trypsin inhibitory activity as the native inhibitor (Ki = 2 X 10(-9) M). The Ser derivative inhibited more weakly (Ki = 2 X 10(-8) M). The Ala and Leu derivatives inhibited trypsin very weakly (Ki = 2 X 10(-7) M and 4 X 10(-7) M, respectively), and the Phe and Asp derivatives not at all. These results suggest that the P1' arginine residue is best for inhibitory activity at the first reactive site of B-III, although it has been suggested that a P1' serine residue at the reactive site is best for inhibitory activity of Bowman-Birk type inhibitors.     

Mutations on the hinge region of leukocyte elastase inhibitor determine the loss of inhibitory function

Leukocyte elastase inhibitor (LEI) is a cytosolic component of lung macrophages and blood leukocytes that inhibits neutrophil elastase. LEI is a member of the serpin superfamily, these proteins, mostly protease inhibitors, are thought to undergo a conformational change upon complex formation with proteinase that involves partial insertion of the hinge region of the reactive centre loop into a beta-sheet of the inhibitor. In this work three mutations were produced in the hinge region of elastase inhibitor that abolish the inhibition activity of LEI and transform the protein in a substrate of the elastase. This result demonstrates that the inhibitory mechanism of serpin is common to LEI.     

S. mansoni SmKI-1 Kunitz-domain: Leucine point mutation at P1 site generates enhanced neutrophil elastase inhibitory activity

The Schistosoma mansoni SmKI-1 protein is composed of two domains: a Kunitz-type serine protease inhibitor motif (KD) and a C-terminus domain with no similarity outside the genera. Our previous work has demonstrated that KD plays an essential role in neutrophil elastase (NE) binding blockage, in neutrophil influx and as a potential anti-inflammatory molecule. In order to enhance NE blocking capacity, we analyzed the KD sequence from a structure-function point of view and designed specific point mutations in order to enhance NE affinity. We substituted the P1 site residue at the reactive site for a leucine (termed RL-KD), given its central role for KD’s inhibition to NE. We have also substituted a glutamic acid that strongly interacts with the P1 residue for an alanine, to help KD to be buried on NE S1 site (termed EA-KD). KD and the mutant proteins were evaluated in silico by molecular docking to human NE, expressed in Escherichia coli and tested towards its NE inhibitory activity. Both mutated proteins presented enhanced NE inhibitory activity in vitro and RL-KD presented the best performance. We further tested RL-KD in vivo in an experimental model of monosodium urate (MSU)-induced acute arthritis. RL-KD showed reduced numbers of total cells and neutrophils in the mouse knee cavity when compared to KD. Nevertheless, both RL-KD and KD reduced mice hypernociception in a similar fashion. In summary, our results demonstrated that both mutated proteins showed enhanced NE inhibitory activity in vitro. However, RL-KD had a prominent effect in diminishing inflammatory parameters in vivo.     

Purification and characterization of elastase-specific inhibitor. Sequence homology with mucus proteinase inhibitor

Elastase-specific inhibitor (ESI) was purified from sputum of patients with chronic bronchitis and compared with mucus proteinase inhibitor (MPI, BrI) isolated, without the use of affinity chromatography on an enzyme, from non-purulent sputum of a patient with bronchial carcinoma. The N-terminal sequence of 27 residues of the latter was determined and showed serine as the only N-terminus. The partial N-terminal amino-acid sequence of ESI shows some homology with MPI, especially around the reactive site of MPI for human neutrophil elastase. This region could therefore be the reactive site of ESI. The thermodynamic and kinetic constants of the reactions of ESI with human neutrophil elastase and with porcine pancreatic elastase show that ESI is a fast-acting inhibitor.     

An elastase inhibitor from equine leukocyte cytosol belongs to the serpin superfamily. Further characterization and amino acid sequence of the reactive center

Horse leukocyte elastase inhibitor rapidly forms stable, equimolar complexes with both human leukocyte elastase and cathepsin G, porcine pancreatic elastase, and bovine alpha-chymotrypsin. Formation of the inhibitor-pancreatic elastase complex results in peptide bond cleavage at the reactive site of the inhibitor so that a small peptide fragment representing the carboxyl-terminal sequence of the inhibitor is released. Sequence analysis of both this peptide, as well as that of an overlapping peptide obtained by enzymatic inactivation of native inhibitor with either Staphylococcus aureus metalloproteinase, Pseudomonas aeruginosa elastase, or cathepsin B, yields data which indicate that the reactive site encompasses a P1-P1' Ala-Met sequence. However, unlike the human endothelial plasminogen activator inhibitor, which also has a Met residue in the P1' position, oxidation of the horse inhibitor only slightly reduces its association rate constant with either of the elastolytic enzymes tested or with chymotrypsin. Comparison of the amino acid sequence at or near the reactive site of the horse inhibitor (P2-P18') with members of the serpin superfamily of proteinase inhibitors indicates that it not only belongs in this class but also represents the first example of a functionally active intracellular serpin.     

Full or partial substitution of the reactive center loop of alpha-1-proteinase inhibitor by that of heparin cofactor II: P1 Arg is required for maximal thrombin inhibition

The abundant plasma protein alpha(1)-proteinase inhibitor (alpha(1)-PI) physiologically inhibits neutrophil elastase (NE) and factor XIa and belongs to the serine protease inhibitor (serpin) protein superfamily. Inhibitory serpins possess a surface peptide domain called the reactive center loop (RCL), which contains the P1-P1' scissile peptide bond. Conversion of this bond in alpha(1)-PI from Met-Ser to Arg-Ser in alpha(1)-PI Pittsburgh (M358R) redirects alpha(1)-PI from inhibiting NE to inhibiting thrombin (IIa), activated protein C (APC), and other proteases. In contrast to either the wild-type or M358R alpha(1)-PI, heparin cofactor II (HCII) is a IIa-specific inhibitor with an atypical Leu-Ser reactive center. We examined the effects of replacement of all or part of the RCL of alpha(1)-PI with the corresponding parts of the HCII RCL on the activity and specificity of the resulting chimeric inhibitors. A series of 12 N-terminally His-tagged alpha(1)-PI proteins differing only in their RCL residues were expressed as soluble proteins in Escherichia coli. Substitution of the P16-P3' loop of alpha(1)-PI with that of HCII increased the low intrinsic antithrombin activity of alpha(1)-PI to near that of heparin-free HCII, while analogous substitution of the P2'-P3' dipeptide surpassed this level. However, gel-based complexing and quantitative kinetic assays showed that all mutant proteins inhibited thrombin at less than 2% of the rate of alpha(1)-PI (M358R) unless the P1 residue was also mutated to Arg. An alpha(1)-PI (P16-P3' HCII/M358R) variant was only 3-fold less active than M358R against IIa but 70-fold less active against APC. The reduction in anti-APC activity is desired in an antithrombotic agent, but the improvement in inhibitory profile came at the cost of a 3.5-fold increase in the stoichiometry of inhibition. Our results suggest that, while P1 Arg is essential for maximal antithrombin activity in engineered alpha(1)-PI proteins, substitution of the corresponding HCII residues can enhance thrombin specificity.     

Comparative cleavage sites within the reactive-site loop of native and oxidized alpha1-proteinase inhibitor by selected bacterial proteinases

Human alpha1-proteinase inhibitor (alpha1-PI) is responsible for the tight control of neutrophil elastase activity which, if down regulated, may cause local excessive tissue degradation. Many bacterial proteinases can inactivate alpha1-PI by hydrolytic cleavage within its reactive site, resulting in the down regulation of elastase, and this mechanism is likely to contribute to the connective tissue damage often associated with bacterial infections. Another pathway of the inactivation of alpha1-PI is reversible and involves oxidation of a critical active-site methionine residue that may influence inhibitor susceptibility to proteolytic inactivation. Hence, the aim of this work was to determine whether this oxidation event might affectthe rate and pattern of the cleavage of the alpha1-PI reactive-site loop by selected bacterial proteinases, including thermolysin, aureolysin, serralysin, pseudolysin, Staphylococcus aureus serine proteinase, streptopain, and periodontain. A shift of cleavage specificity was observed after alpha1-PI oxidation, with a preference for the Glu354-Ala355 bond by most of the proteinases tested. Only aureolysin and serralysin cleave the oxidized form of alpha1-PI faster than the native inhibitor, suggesting that bacteria which secrete these metalloproteinases may specifically take advantage of the host defense oxidative mechanism to accelerate elimination of alpha1-PI and, consequently, tissue degradation by neutrophil elastase.     

Effects of amino acid replacements around the reactive site of chicken ovomucoid domain 3 on the inhibitory activity toward chymotrypsin and trypsin.

We have previously shown that replacing the P1-site residue (Ala) of chicken ovomucoid domain 3 (OMCHI3) with a Met or Lys results in the acquisition of inhibitory activity toward chymotrypsin or trypsin, respectively. However, the inhibitory activities thus induced are not strong. In the present study, we introduced additional amino acid replacements around the reactive site to try to make the P1-site mutants more effective inhibitors of chymotrypsin or trypsin. The amino acid replacement Asp-->Tyr at the P2' site of OMCHI3(P1Met) resulted in conversion to a 35000-fold more effective inhibitor of chymotrypsin with an inhibitor constant (K(i)) of 1. 17x10(-11) M. The K(i) value of OMCHI3(P1Met, P2'Ala) indicated that the effect on the interaction with chymotrypsin of removing a negative charge from the P2' site was greater than that of introducing an aromatic ring. Similarly, enhanced inhibition of trypsin was observed when the Asp-->Tyr replacement was introduced into the P2' site of OMCHI3(P1Lys). Two additional replacements, Asp-->Ala at the P4 site and Arg-->Ala at the P3' site, made the mutant a more effective inhibitor of trypsin with a K(i) value of 1. 44x10(-9) M. By contrast, Arg-->Ala replacement at the P3' site of OMCHI3(P1Met, P2'Tyr) resulted in a greatly reduced inhibition of chymotrypsin, and Asp-->Ala replacement at the P4 site produced only a small change when compared with a natural variant of OMCHI3. These results clearly indicate that not only the P1-site residue but also the characteristics, particularly the electrostatic properties, of the amino acid residues around the reactive site of the protease inhibitor determine the strength of its interactions with proteases. Furthermore, amino acids with different characteristics are required around the reactive site for strong inhibition of chymotrypsin and trypsin.     

Mutants of plasminogen activator inhibitor-1 designed to inhibit neutrophil elastase and cathepsin G are more effective in vivo than their endogenous inhibitors

Neutrophil elastase and cathepsin G are abundant intracellular neutrophil proteinases that have an important role in destroying ingested particles. However, when neutrophils degranulate, these proteinases are released and can cause irreparable damage by degrading host connective tissue proteins. Despite abundant endogenous inhibitors, these proteinases are protected from inhibition because of their ability to bind to anionic surfaces. Plasminogen activator inhibitor type-1 (PAI-1), which is not an inhibitor of these proteinases, possesses properties that could make it an effective inhibitor of neutrophil proteinases if its specificity could be redirected. PAI-1 efficiently inhibits surface-sequestered proteinases, and it efficiently mediates rapid cellular clearance of PAI-1-proteinase complexes. Therefore, we examined whether PAI-1 could be engineered to inhibit and clear neutrophil elastase and cathepsin G. By introducing specific mutations in the reactive center loop of wild-type PAI-1, we generated PAI-1 mutants that are effective inhibitors of both proteinases. Kinetic analysis shows that the inhibition of neutrophil proteinases by these PAI-1 mutants is not affected by the sequestration of neutrophil elastase and cathepsin G onto surfaces. In addition, complexes of these proteinases and PAI-1 mutants are endocytosed and degraded by lung epithelial cells more efficiently than either the neutrophil proteinases alone or in complex with their physiological inhibitors, alpha1-proteinase inhibitor and alpha1-antichymotrypsin. Finally, the PAI-1 mutants were more effective in reducing the neutrophil elastase and cathepsin G activities in an in vivo model of lung inflammation than were their physiological inhibitors.