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.     

Activation of progelatinase A (MMP-2) by neutrophil elastase, cathepsin G, and proteinase-3: a role for inflammatory cells in tumor invasion and angiogenesis

Gelatinase A (MMP-2), a matrix metalloproteinase (MMP) involved in tumor invasion and angiogenesis, is secreted as an inactive zymogen (proMMP-2) and activated by proteolytic cleavage. Here we report that polymorphonuclear neutrophil (PMN)-derived elastase, cathepsin G, and proteinase-3 activate proMMP-2 through a mechanism that requires membrane-type 1 matrix metalloproteinase (MT1-MMP) expression. Immunoprecipitation of human PMN-conditioned medium with a mixture of antibodies to elastase, cathepsin G, and proteinase-3 abolished proMMP-2 activation, whereas individual antibodies were ineffective. Incubation of HT1080 cells with either purified PMN elastase or cathepsin G or proteinase-3 resulted in dose-and time-dependent proMMP-2 activation. Addition of PMN-conditioned medium to MT1-MMP expressing cells resulted in increased proMMP-2 activation and in vitro invasion of extracellular matrix (ECM), but had no effect with cells that express no MT1-MMP. MMP-2 activation by PMN-conditioned medium or purified elastase was blocked by the elastase inhibitor alpha(1)-antitrypsin but not by Batimastat, an MMP inhibitor, showing that elastase activation of MMP-2 is not mediated by MMP activities. The PMN-conditioned medium-induced increase in cell invasion was blocked by Batimastat as well as by alpha(1)-antitrypsin, showing that PMN serine proteinases trigger a proteinase cascade that entails proMMP-2 activation: this gelatinase is the downstream effector of the proinvasive activity of PMN proteinases. These findings indicate a novel role for PMN-mediated inflammation in a variety of tissue remodeling processes including tumor invasion and angiogenesis.     

Characterization of the M1(Ala213) type of alpha 1-antitrypsin, a newly recognized, common "normal" alpha 1-antitrypsin haplotype

alpha 1-Antitrypsin (alpha 1AT) is a highly pleomorphic 52-kDa serum glycoprotein that functions as the major inhibitor of neutrophil elastase. Of these, the most common normal alpha 1AT haplotypes identified by isoelectric focusing (IEF) of serum are those of the M family, including M1, M2, and M3. In the course of studying the alpha 1AT type Z gene, we identified a restriction endonuclease BstEII polymorphism in the M1 gene that predicted the existence of a previously unidentified, but relatively common, haplotype of M, referred to as M1(Ala213) [Nukiwa, T., Satoh, K., Brantly, M. L., Ogushi, F., Fells, G. A., Courtney, M., & Crystal, R. G. (1986) J. Biol. Chem. 261, 15989-15994]. In this study we have cloned both alpha 1AT genes from an individual heterozygous for the M1(Ala213) and M1(Val213) haplotypes. Sequencing of the coding exons of both demonstrated that they are identical except for the Ala-Val difference at residue 213. The codominant transmission of the M1(Ala213) gene was demonstrated in a family study. Evaluation of 39 genomic samples of Caucasians with the IEF haplotype M1 demonstrated haplotype frequencies of 68% for M1(Val213) and 32% for M1(Ala213). alpha 1AT serum levels of individuals inheriting the M1(Ala213) gene in a homozygous fashion were in the same range as those for homozygous M1(Val213) as was the rate of association of the M1(Ala213) protein with neutrophil elastase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cathepsin L inactivates alpha 1-proteinase inhibitor by cleavage in the reactive site region

The lysosomal cysteine proteinases cathepsin L and cathepsin B were examined for their effect on the neutrophil elastase inhibitory activity of human alpha 1-proteinase inhibitor (alpha 1PI). Human cathepsin L catalytically inactivated human alpha 1PI by cleavage of the bonds Glu354-Ala355 and Met358-Ser359 (the serine proteinase inhibitory site). Cathepsin B did not inactivate alpha 1PI, even when equimolar amounts of enzyme were employed. Cathepsin L is the first human proteinase shown to catalytically inactivate alpha 1PI. These findings, in conjunction with other reports, suggest that alpha 1PI contains a proteolytically sensitive region encompassing residues 350-358. Taken together with the discovery of the elastinolytic activity of cathepsin L (Mason, R. W., Johnson, D. A., Barrett, A. J., and Chapman, H. A. (1986) Biochem. J. 233, 925-927), the present findings emphasize the possible importance of cathepsin L in the pathological proteolysis of elastin and diminish the role that can be attributed to cathepsin B in such processes.     

Isolation, characterization, and amino-terminal amino acid sequence analysis of human neutrophil cathepsin G from normal donors

Human neutrophil cathepsin G from normal donors has been purified 82-fold using an isolation procedure which included sequential sodium chloride extraction, Aprotonin-Sepharose affinity chromatography, CM-cellulose ion-exchange chromatography, and AcA44 gel filtration chromatography. The inclusion of this last purification step was crucial for separating inactive lower molecular weight species from the active forms of neutrophil cathepsin G and resulted in a higher specific activity of the final preparation. SDS polyacrylamide gradient gel electrophoresis of the purified reduced protein demonstrated three discrete polypeptides of Mr 31,000, 30,000, and 29,500. Peptide analysis of tryptic digests indicated that these three polypeptides are structurally related to each other and represent microheterogeneity of the purified protein. The cathepsin G peptide maps were distinctly different from the peptide maps of neutrophil elastase. The apparent isoelectric points of these forms as determined by two-dimensional electrophoresis was approximately 8.0. Utilizing microsequencing techniques, the first 25 residues of normal neutrophil cathepsin G have been determined and shown to be identical (except for residue 11) with the sequence of 21 residues of cathepsin G isolated from leukemic myeloid cells. A high degree of homology was found when the amino-terminal regions of neutrophil cathepsin G, rat mast cell protease II (65%) and two human serine proteinases, factor D (52%) and neutrophil elastase (48%), were compared. A precipitating monospecific antiserum to cathepsin G was produced by repeated immunizations of guinea pigs. This antiserum has been used in immunoblotting experiments to demonstrate that the intracellular form(s) of this enzyme is the same approximate Mr as the purified enzyme, and to develop a solid-phase radioimmunoassay for measuring neutrophil cathepsin G in the range 5-50 ng/ml.     

Inhibitors of elastase and cathepsin G in Chédiak-Higashi (beige) neutrophils

Previous studies have established that mature neutrophils from the peritoneal cavity, blood, and bone marrow of beige (Chédiak-Higashi syndrome) mice essentially lack activities of two lysosomal proteinases: elastase and cathepsin G. There are, however, significant levels of each enzyme in early neutrophil precursors in bone marrow. In the present experiments, it was found that the addition of extracts from mature beige neutrophils to extracts of normal neutrophils or to purified human neutrophil elastase and cathepsin G resulted in a significant inhibition of elastase and cathepsin G G activities. 125I-Labeled human neutrophil elastase formed high molecular mass complexes at 64 and 52 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis when added to beige neutrophil extracts. The molecular masses of the inhibitor-125I-elastase complexes suggested that the molecular masses of the inhibitors are approximately 36 and 24 kDa, respectively. These results were confirmed by gel filtration on Superose 12 under nondenaturing conditions. Cathepsin G was inhibited only by the 36-kDa component. The inhibitors formed a covalent complex with the active sites of elastase and cathepsin G. No inhibitory activity was present in mature neutrophil extracts of genetically normal mice or in extracts of bone marrow of beige mice. These results thus represent an unusual example of an enzyme deficiency state caused by the presence of excess inhibitors. Inactivation of neutrophil elastase and cathepsin G in mature circulating and tissue neutrophils may contribute to the increased susceptibility of Chédiak-Higashi patients to infection.     

Kinetics of association of human proteinases with human alpha 2-macroglobulin

Association rates have been determined for the interaction of human alpha 2-macroglobulin with human neutrophil elastase, cathepsin G, and human plasma kallikrein. Both of the neutrophil enzymes are rapidly inactivated by this inhibitor; however, the inactivation of plasma kallikrein is much slower. Comparison of the rates of inactivation with those already established for other inhibitors clearly indicate that alpha 1-proteinase inhibitor is the controlling inhibitor for neutrophil elastase and alpha 1-antichymotrypsin for cathepsin G, alpha 2-macroglobulin acting only as a secondary inhibitor. The control of plasma kallikrein would appear to be rather poor since neither alpha 2-macroglobulin nor C1-inhibitor appears to react very rapidly with this proteinase. Thus, a primary role for alpha 2-macroglobulin in directly inactivating proteinases in blood, under normal physiological conditions, remains to be established.     

Solid-phase radioimmunoassay for human neutrophil elastase: a sensitive method for determining secreted and cell-associated enzyme

A solid-phase radioimmunoassay for measuring neutrophil elastase in the range 0.08-4 ng/ml has been developed. A monospecific, precipitating antibody capable of inhibiting elastinolysis was produced by repeated immunizations of a goat. The IgG fraction and affinity-purified antibodies of this serum were then obtained and used to develop this radioimmunoassay. There was no cross-reactivity in binding of the radiolabeled antisera with lactoferrin, cathepsin G, or serine proteinases with amino-terminal amino acid sequence homology. Although serum influences the measurement of catalytically active neutrophil elastase when compared to diisopropylfluorophosphate-treated neutrophil elastase, antigenic elastase may still be measured in body fluids. Furthermore, this assay is more sensitive than commercially available substrates used for quantitating neutrophil elastase by functional activity. We have found this quantitative assay extremely useful in balance studies to measure secreted and cell-associated elastase and in screening of biological fluids for the presence of the enzyme.     

Degradation of cartilage matrix proteoglycan by human neutrophils involves both elastase and cathepsin G

The granule proteases of human neutrophils are thought to be responsible for the connective tissue destruction associated with certain inflammatory diseases. Using a model system for the degradation of a macromolecular connective tissue substrate, purified neutrophil elastase and cathepsin G were both individually able to degrade cartilage matrix proteoglycan and this degradation was blocked by the appropriate specific inhibitors. Neutrophil granule lysate also produced cartilage matrix degradation but little inhibition of degradation occurred when either elastase or cathepsin G inhibitor was used alone. However, a combination of elastase and cathepsin G inhibitors each at 100 microM or each at 10 microM blocked cartilage matrix degradation by 89% +/- 1 and 65% +/- 9 (mean +/- SEM, n = 3), respectively. The magnitude of the cartilage degradation mediated by neutrophil lysate, and its sensitivity to specific inhibitors, was reproduced using purified elastase and cathepsin G at the concentrations at which they are present in neutrophil lysate. Human neutrophils stimulated with opsonized zymosan degraded cartilage matrix in a dose-dependent manner in the presence of serum antiproteases. Supernatants from stimulated neutrophils cultured in the presence of serum did not degrade cartilage matrix, indicating that neutrophil mediated degradation in the presence of serum was confined to the protected subjacent region between the inflammatory cell and the substratum. A combination of elastase and cathepsin G inhibitors each at 500 microM or each at 100 microM blocked subjacent cartilage matrix degradation by stimulated human neutrophils by 91% +/- 3 and 54% +/- 8 (mean +/- SEM, n = 5), respectively, whereas either the elastase or cathepsin G inhibitor alone was much less effective. These studies demonstrate that neutrophil-mediated cartilage matrix degradation is produced primarily by elastase and cathepsin G. Furthermore, these results support the hypothesis that inflammatory neutrophils form zones of close contact with substratum that exclude serum antiproteases and that this subjacent degradation of cartilage matrix by stimulated neutrophils can be blocked by a combination of synthetic elastase and cathepsin G inhibitors.     

Purification and Characterization of a Soluble Phosphatidylinositol 4-Kinase from Carrot Suspension Culture Cells

Previously we reported the presence of a soluble phosphatidylinositol 4-kinase (PI 4-Kinase) in carrot (Daucus carota L.) suspension culture cells (C.M. Okpodu, W. Gross, W.F. Boss [1990] Plant Physiol 93: S-63). We have purified the enzyme over 1000-fold using Q-Sepharose ion exchange, hydroxylapatite, and G-100 gel filtration column chromatography. The Mr of the enzyme was estimated to be 83,000 by gel filtration. PI 4-kinase activity was recovered after renaturation of the 80-kD region of polyacrylamide gels, and an 80-kD peptide cross-reacted with antibodies to the yeast 55-kD membrane-associated PI 4-kinase on western blots. The isolated lipid kinase phosphorylated PI but not lysophosphatidylinositol or phosphatidylinositol monophosphate. Maximal PI kinase activity occurred when the substrate was added as Triton X-100/PI mixed micelles at pH 8. The enzyme required divalent cations. At low concentrations (1-5 mM), Mn2+ was more effective than Mg2+ in increasing enzyme activity; however, maximal activity occurred at 25 to 40 mM Mg2+. Calcium from 0.01 [mu]M to 1 mM had no effect on the enzyme activity. The Km of the enzyme for ATP was estimated to be between 400 and 463 [mu]M. The enzyme was inhibited by adenosine (100 [mu]M); however, ADP (up to 100 [mu]M) had no effect on the activity. The biochemical characteristics of the carrot soluble PI 4-kinase are compared with the previously reported PI 4-kinases from animals and yeast.     

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.     

Enzymatic and Molecular Biochemical Characterizations of Human Neutrophil Elastases and a Cathepsin G-like Enzyme

Human neutrophil elastase (HNE, EC 3. 4. 21. 37) is a causative factor of inflammatory diseases, including emphysema and rheumatoid arthritis. Enzymatic characterization is important for the development of new drugs involved in the regulation of this enzyme. In this study, we investigated the enzymatic and biochemical properties of five different elastolytic enzymes, with a molecular mass between 24 kDa and 72 kDa. Three elastases, molecular masses of 27, 29, 31 kDa, might be elastase isozymes that have the same NH₂-terminal amino acid sequences of Ile-Val-Gly-Gly-Arg-Arg-Ala. The 24-kDa enzyme, which showed the identical NH₂-terminal amino acid sequences to elastase, was a degraded fragment of native elastase. The elastolytic activity was conserved at the 6/7 domain of the NH₂-terminal region. The inhibitory characteristics of PMSF, DipF were the same as those of native elastases. The 72-kDa molecule, which showed elastolytic activity, might be a trimer formed between native elastases (31 kDa and 29 kDa) and a cathepsin G-like enzyme, which did not show elastolytic activity but enhanced the elastolytic activity of neutrophil elastase. Although this cathepsin G-like enzyme showed weak cathepsin G activity, it has distinguishable NH₂-terminal sequences of Ile-Val-Gly-Gly-Ser-Arg-Ala- from those of elastase or cathepsin G. The potentiation of elastolytic activity could be a result of the trimerization of native elastase with a cathepsin G-like enzyme, and was then weakly inhibited by serine protease inhibitors, such as PMSF, DipF. Therefore, we suggest the cathepsin G-like enzyme to be a novel enzyme, which has an important role in the development of inflammation.     

Cathepsin G is a strong platelet agonist released by neutrophils.

The present studies were undertaken to characterize a serine protease released by N-formyl-L-Met-L-Leu-L-Phe (fMet-Leu-Phe)-stimulated neutrophils that rapidly induces platelet calcium mobilization, secretion and aggregation. The biological activity associated with this protease was unaffected by leupeptin, was only weakly diminished by N-p-tosyl-L-Lys-chloromethane, but was strongly inhibited by alpha 1-antitrypsin, soyabean trypsin inhibitor, N-tosyl-L-Phe-chloromethane and benzoyloxycarbonyl-Gly-Leu-Phe-chloromethane (Z-Gly-Leu-PheCH2Cl). These observations indicated that the biological activity of neutrophil supernatants could be attributed to a chymotrypsin-like enzyme such as cathepsin G. Furthermore, platelet aggregation and 5-hydroxytryptamine release induced by cell-free supernatants from fMet-Leu-Phe-stimulated neutrophils were found to be blocked by antiserum to cathepsin G in a concentration-dependent manner but were unaffected by antiserum to elastase. The biological activity present in neutrophil supernatants co-purified with enzymic activity for cathepsin G during sequential Aprotinin-Sepharose affinity chromatography and carboxymethyl-Sephadex chromatography. SDS/polyacrylamide-gel electrophoresis of the reduced, purified protein, demonstrated three polypeptides with apparent Mr values of 31,500, 29,000 and 28,000 and four polypeptides were resolved on acid-gel electrophoresis. Purified cathepsin G from neutrophils cross-reacted with anti-(cathepsin G) serum in a double immunodiffusion assay and elicited platelet calcium mobilization, 5-hydroxytryptamine secretion and aggregation. Calcium mobilization and secretion induced by low concentrations of cathepsin G were partially dependent on arachidonic acid metabolites and ADP, while stimulation by higher enzyme concentrations was independent of amplification pathways, indicating that cathepsin G is a strong platelet agonist. These results suggest that pathological processes which stimulate neutrophils and release cathepsin G can in turn result in the recruitment and activation of platelets.     

Interaction of heparin cofactor II with neutrophil elastase and cathepsin G

We investigated the interaction of the human plasma proteinase inhibitor heparin cofactor II (HC) with human neutrophil elastase and cathepsin G in order to examine 1) proteinase inhibition by HC, 2) inactivation of HC, and 3) the effect of glycosaminoglycans on inhibition and inactivation. We found that HC inhibited cathepsin G, but not elastase, with a rate constant of 6.0 x 10(6) M-1 min-1. Inhibition was stable, with a dissociation rate constant of 1.0 x 10(-3) min-1. Heparin and dermatan sulfate diminished inhibition slightly. Both neutrophil elastase and cathepsin G at catalytic concentrations destroyed the thrombin inhibition activity of HC. Inactivation was accompanied by a dramatic increase in heat stability, as occurs with other serine proteinase inhibitors. Proteolysis of HC (Mr 66,000) produced a species (Mr 58,000) that retained thrombin inhibition activity, and an inactive species of Mr 48,000. Amino acid sequence analysis led to the conclusion that both neutrophil elastase and cathepsin G cleave HC at Ile66, which does not affect HC activity, and at Val439, near the reactive site Leu444, which inactivates HC. Since cathepsin G is inhibited by HC and also inactivates HC, we conclude that cathepsin G participates in both reactions simultaneously so that small amounts of cathepsin G can inactivate a molar excess of HC. High concentrations of heparin and dermatan sulfate accelerated inactivation of HC by neutrophil proteinases, with heparin having a greater effect. Heparin and dermatan sulfate appeared to alter the pattern, and not just the rate, of proteolysis of HC. We conclude that while HC is an effective inhibitor of cathepsin G, it can be proteolyzed by neutrophil proteinases to generate first an active inhibitor and then an inactive molecule. This two-step mechanism might be important in the generation of chemotactic activity from the amino-terminal region of HC.     

Elastase and cathepsin G of human monocytes: heterogeneity and subcellular localization to peroxidase-positive granules

We used antibodies to human leukocyte ("neutrophil") elastase and cathepsin G to localize the corresponding antigens in human neutrophils, monocytes, and alveolar macrophages by immunohistochemistry. Furthermore, we combined immunogold localization with enzyme histochemistry to localize proteinase antigens and endogenous peroxidase activity in the same sections. As expected, all neutrophils contained both elastase and cathepsin G, and the proteinases localized to granules with peroxidase activity. In contrast, marked heterogeneity in monocyte staining for elastase, cathepsin G, and endogenous peroxidase was found. Sixty percent or more were unstained, while the remainder varied greatly in staining intensity. The elastase and cathepsin G in monocytes were localized by immunoelectron microscopy, combined with histochemistry, to cytoplasmic granules which had peroxidase activity. Alveolar macrophages were unstained. Therefore, a subpopulation of peripheral blood monocytes contains leukocyte elastase and cathepsin G in a cell compartment from which these enzymes may potentially be released into the extracellular space. The occurrence of peroxidase and neutral proteinases in the same granules in monocytes could permit the H2O2-myeloperoxidase-halide system and the neutral proteinases to act in concert in such functions as microbe killing and extracellular proteolysis.     

The proteinase: mucus proteinase inhibitor binding stoichiometry.

In the nanomolar enzyme and inhibitor concentration range, 1 mol of mucus proteinase inhibitor (MPI) inhibits 1 mol of neutrophil elastase, cathepsin G, trypsin, and chymotrypsin. In the micromolar concentration range, the enzyme:inhibitor binding stoichiometry is still 1:1 for elastase but shifts to 2:1 for the three other proteinases. These data could be confirmed by three nonenzymatic methods: (i) fluorescence anisotropy measurements of mixtures of proteinases with 5-dimethylaminonaphthalene-1-sulfonylated or fluoresceinylated MPI, (ii) absorption spectrocospy of fluorescein-MPI-proteinase complexes isolated by gel filtration, (iii) analytical ultracentrifugation which showed that the molecular mass of the MPI-chymotrypsin complex is 56 kDa, whereas that of the MPI-elastase complex is 39 kDa. The binary MPI-elastase complex is unable to inhibit trypsin or cathepsin G. On the other hand, 1 mol of elastase displaces 2 mol of trypsin or cathepsin G from their ternary complexes with MPI.     

Human cationic and anionic trypsins: differences of interaction with alpha 1-proteinase inhibitor

Human cationic (trypsin 1) and anionic (trypsin 2) trypsins were obtained by controlled activation of purified trypsinogens 1 and 2, respectively. The interactions of trypsin 1 and trypsin 2 with human alpha 1-proteinase inhibitor (alpha 1PI) were analysed and compared by studies in vitro. The enzymatic activity and inhibitory capacity measurements were assessed using Glp-Gly-Arg-Nan as substrate. The association rate constants showed that the inhibition of trypsin 2 occurred more than 10 times faster than that of trypsin 1. The equimolar complexes obtained between either trypsin and alpha 1PI were visualized by electrophoresis followed by immunoblotting. The inhibition of the two trypsins was temporary i.e. the complexes trypsin 1-alpha 1PI and trypsin 2-alpha 1PI broke down with time yielding inactive alpha 1PI (Mr 50,000) and active enzyme. But the stability time for trypsin 1-alpha 1PI was much larger than that of trypsin 2-alpha 1PI. In vivo, alpha 1PI is not able to control the activity of trypsin 1 except when alpha 2-macroglobulin (alpha 2M) is already saturated. According to the delay times of inhibition calculated from normal concentrations in serum, alpha 1PI inhibits trypsin 2 as fast as alpha 2M inhibits trypsin 1. These results suggest that a significant role can be assigned to alpha 1PI in the inhibition of trypsin 2 in physiological conditions and of trypsin 1 in pathological ones.     

Effect of neutrophil cathepsin G on elastin degradation by neutrophil elastase

Human neutrophil cathepsin G was found to be unable to significantly stimulate the degradation of either bovine or human elastin by neutrophil elastase, using four different procedures to monitor digestion. A range of stimulations from 1.1 to 2.9-fold was found, with a 2.0-fold stimulation being the average found with the assays tested. These results contrast with those reported by Boudier et al. [(1981) J. Biol. Chem. 256, 10256-10258] who reported a five- to seven-fold stimulation of elastolysis of human lung elastin by cathepsin G, when present at a 2:1 molar ratio relative to elastase. Significantly, we found little stimulation of elastolysis with either human or bovine lung elastin as substrate while Boudier et al. found stimulation only with the human elastin. Thus, it would appear that cathepsin G does not play a predominant role as an elastolytic enzyme; rather, its role in this case may be one of binding to non-productive sites on the elastin surface.     

Inhibition of neutrophil cathepsin G by oxidized mucus proteinase inhibitor. Effect of heparin.

Oxidation of mucus proteinase inhibitor (MPI) transforms Met73, the P'1 residue of its active center into methionine sulfoxide and lowers its affinity for neutrophil elastase [Boudier, C., and Bieth, J. G. (1994) Biochem. J. 303, 61-68]. Here, we show that the oxidized inhibitor has also a decreased affinity for neutrophil cathepsin G and pancreatic chymotrypsin. The Ki of the oxidized MPI-cathepsin G complex (1.2 microM) is probably too high to be compatible with significant inhibition of cathepsin G in inflammatory lung secretions. Stopped-flow kinetics shows that, within the inhibitor concentration range used, the mechanism of inhibition of cathepsin G and chymotrypsin by oxidized MPI is consistent with a one-step reaction, [equation in text] whereas the inhibition of elastase takes place in two steps, [equation in text]. Heparin, which accelerates the inhibition of the three proteinases by native MPI, also favors their interaction with oxidized MPI. Flow calorimetry shows that heparin binds oxidized MPI with Kd, Delta H degrees, and Delta S degrees values close to those reported for native MPI. In the presence of heparin, oxidized MPI inhibits cathepsin G via a two-step reaction characterized by Ki = 0.22 microM, k2 = 0.1 s-1, k-2 = 0.023 s-1, and Ki = 42 nM. Under these conditions, in vivo inhibition of cathepsin G is again possible. Heparin also improves the inhibition of chymotrypsin and elastase by oxidized MPI by increasing their kass or k2/Ki and decreasing their Ki. Our data suggest that oxidation of MPI during chronic bronchitis may lead to cathepsin G-mediated lung tissue degradation and that heparin may be a useful adjuvant of MPI-based therapy of acute lung inflammation in cystic fibrosis.     

The inhibition of human neutrophil elastase and cathepsin G by peptidyl 1,2-dicarbonyl derivatives

Neutrophil elastase and cathepsin G are serine proteases that can damage connective tissue and trigger other pathological reactions. Compounds containing a peptide sequence to impart specificity and bearing an alpha-dicarbonyl unit (alpha-diketone or alpha-keto ester) at the carboxy terminus are potent inhibitors of the neutrophil serine proteases (human neutrophil elastase: R-Val-COCH3, Ki = 0.017 microM; R-Val-COOCH3, Ki = 0.002 microM; human neutrophil cathepsin G: R-Phe-COCH3, Ki = 0.8 microM; R-Phe-COOCH3, Ki = 0.44 microM; R = N-(4-[(4-chlorophenyl)sulfonylaminocarbonyl]phenylcarbonyl)+ ++ValylProlyl).