Proteolytic inactivation of alpha 1-proteinase inhibitor and alpha 1-antichymotrypsin by oxidatively activated human neutrophil metalloproteinases.

Human neutrophils use the H2O2-myeloperoxidase-chloride system to generate chlorinated oxidants capable of activating metalloproteinase zymogens that hydrolyze not only native and denatured collagens, but also the serine proteinase inhibitor (serpin) alpha 1-proteinase inhibitor (alpha 1 PI). To identify the metalloenzyme that hydrolyzes and inactivates alpha 1 PI, neutrophil releasates were chromatographed over gelatin-Sepharose and divided into fractions containing either progelatinase or procollagenase. The gelatinase-containing fraction cleaved alpha 1 PI in a manner inhibitable by native type V, but not type I, collagen. Conversely, while the collagenase-containing fraction also cleaved alpha 1 PI, this activity was inhibited by type I, but not type V, collagen. Because type I and V collagens are competitive substrates for collagenase and gelatinase, respectively, each of the metalloproteinase zymogens were purified to apparent homogeneity and examined for alpha 1 PI-hydrolytic activities. Both purified gelatinase and collagenase inactivated alpha 1PI by hydrolyzing the serpin within its active-site loop at the Phe352-Leu353 and Pro357-Met358 bonds, albeit with distinct kinetic properties. Furthermore, purified collagenase, but not gelatinase, cleaved a second serpin, alpha 1-antichymotrypsin, by hydrolyzing the Ala362-Leu363 bond within its active-site loop. These data demonstrate that human neutrophils use chlorinated oxidants to activate collagenolytic metalloproteinases whose substrate specificities can be extended to members of the serpin superfamily.     

Involvement of hyposialylated immunoglobulins in the inactivation of alpha 1-proteinase inhibitor

The elastase inhibitory capacity of alpha 1-proteinase inhibitor (alpha 1-PI) was measured, using a direct and reproducible method, with phagocytic cells maintained in the tissue culture plate through the assay. The oxidative inactivation of alpha 1-PI is known to be mediated by the action of myeloperoxidase (MPO). The fact that hyposialylated IgG (hs IgG) induce the release of MPO prompted us to investigate the effects of such hs IgG on the inhibitory capacity of alpha 1-PI. The results show that 1-PI inactivation was observed only when phagocytic cells were activated by aggregated hs IgG, and not by unaggregated hs IgG. These observations indicate that hyposialylation should be completed by aggregation to perpetuate the oxidative reactions characteristic of inflammatory diseases.     

The inactivation of plasma alpha 1-proteinase inhibitor by nitrous acid

Exposure of alpha 1-PI to nitrous acid resulted in a complete inactivation of either of its elastase or trypsin inhibitors activities. Amino acid analyses of the nitrous acid treated inhibitor revealed only losses of one tryphanyl and three lysyl residues. Reductive methylation of alpha 1-PI offered no protection against loss of activity by nitrous acid. Since no further loss of lysyl residues was observed upon exposure of fully active reductively methylated alpha 1-PI to nitrous acid, modification of one tryptophanyl residue appears to be responsible for the inhibitor's sensitivity to nitrous acid. Absorption spectral studies of the nitrous acid treated alpha 1-PI indicated that the tryptophanyl residue was modified to its N-nitroso derivative.     

Leukocyte-mediated inactivation of alpha 1-proteinase inhibitor is inhibited by amino analogues of alpha-tocopherol.

Human leukocytes stimulated by opsonized zymosan increase their NADPH oxidase-catalysed reduction of molecular oxygen. This leads to enhanced formation of superoxyl radicals and subsequently hydrogen peroxide. The leukocyte enzyme myeloperoxidase generates the strong microbicidal oxidant hypochlorite from hydrogen peroxide and chloride anions. Hypochlorite inactivates serum alpha 1-proteinase inhibitor, a protein which protects host tissue from digestion by proteinases, that are also secreted by stimulated leukocytes. Micromolar concentrations of a water-soluble, quaternary ammonium analogue of alpha-tocopherol (vitamin E) (3,4-dihydro-6-hydroxy-N,N,N-2,5,7,8-heptamethyl-2H-1-benzopyran-2 -ethanaminium 4-methylbenzenesulfonate) and its tertiary amine derivative (3,4-dihydro-2- (2-dimethylaminoethyl)-2,5,7,8-tetramethyl-2H-1-benzopyran-6-ol hydrochloride) were able to protect alpha 1-proteinase inhibitor from inactivation by stimulated human leukocytes. The mechanism of action of the quaternary ammonium analogue was further investigated. Selective inhibition of hydrogen peroxide formation is assumed to be the reason for its protective effect. This compound rapidly reacts with superoxyl radicals, but not with hydrogen peroxide, and is only a weak hypochlorite scavenger. It neither impedes exocytosis of elastase, nor effectively inhibits NADPH oxidase or myeloperoxidase. In contrast, superoxide dismutase, which enhances hydrogen peroxide formation, cannot protect alpha 1-proteinase inhibitor from inactivation.     

Methionine oxidation and inactivation of alpha 1-proteinase inhibitor by Cu2+ and glucose.

The effect of glucose/Cu2+ incubation on (a) pure methionine oxidation, (b) the oxidation of active-site methionine in alpha 1-proteinase inhibitor (alpha 1PI) and (c) the resulting activity and structural changes of this inhibitor was investigated. While no methionine was oxidized during a 24 day, 37 degrees C incubation with 0.01 M EDTA and 100 mM glucose, 64.2% oxidation occurred in 6 days when 0.01 mM Cu2+ was added to the 100 mM glucose. The first-order rate constant for oxidation in 10 mM glucose, 0.01 mM Cu2+ was 0.0218 day-1. Oxidation was inhibited by catalase, but accelerated by ascorbate ion. The active-site methionyl residue of alpha 1PI was oxidized 71.3% after a 4 day incubation in 100 mM glucose, 0.01 mM Cu2+ (pH 7.45), 0.1 M phosphate buffer. The elastase and trypsin inhibiting activities were lowered to 3.1 and 1.5% of control samples during this incubation. The inclusion of 1 mM DETAPAC, a transition metal chelator, resulted in a 98 + % retention of activity. Intrinsic fluorescence (350 nm excitation, 415 nm emission) of alpha 1PI increased 576% over control for the sample incubated in 100 mM glucose, 0.01 mM Cu2+ and SDS-PAGE revealed protein fragment molecular weights of 44.4 and 39.8 kDa. These studies suggest that both methionine oxidation and free radical induced fragmentation contribute to loss of alpha 1PI activity during glucose/Cu2+ incubations.     

The inactivation of human plasma alpha 1-proteinase inhibitor by proteinases from Staphylococcus aureus

The interaction of three proteinases (seryl, cysteinyl, and metallo-) from Staphylococcus aureus with human plasma alpha 1-proteinase inhibitor has been investigated. As expected, none of the enzymes was inactivated by this protein, each, instead causing the conversion of the native inhibitor into an inactive form of decreased molecular weight. Amino-terminal sequence analysis indicated that inhibitor inactivation had occurred by peptide bond cleavage near the reactive center of this protein. When the inhibitor was modified by this treatment, it became resistant to both pH and temperature denaturation and, in contrast to the intact denatured protein, did not undergo further proteolytic degradation. This process of inactivation of alpha 1-proteinase inhibitor by pathogenic proteinases could result in a deregulation of its target enzyme, neutrophil elastase, and, therefore, may be important in the consumption of some plasma proteins by this enzyme during septicemia.     

Modeling the intact form of the alpha 1-proteinase inhibitor

The structure of the intact form of the serpin alpha 1-proteinase inhibitor has been modeled based on the assumption that the central strand s4A of the six-stranded beta-sheet A of the cleaved inhibitor is not incorporated into the sheet of intact alpha 1-proteinase inhibitor. This strand was removed from its position in the center of the sheet by suitable rotations about the backbone dihedrals of Lys343 using molecular graphics. The resulting structure was then annealed using molecular dynamics (MD) while applying progressive distance restraints to the reactive peptide bond (Met358-Ser359) for 50 ps. During this time, the disrupted beta-sheet reformed to create a five-stranded beta-sheet with strands 3 and 5 in a parallel arrangement. This change and accompanying structural rearrangements are largely confirmed by the X-ray structure of plakalbumin, whose structure reflects the overall structure of intact serpins. The successful modeling experiment demonstrates the utility of MD for making gross structural predictions based on related structures. The binding loop of the intact form is modeled to allow docking with serine proteinases, in particular thrombin, which most highly constrains the possible conformations of the binding loop.     

Inactivation of alpha- and beta-thrombin by antithrombin-III, alpha 2-macroglobulin and alpha 1-proteinase inhibitor.

Inactivation of alpha- and beta-thrombin by alpha 2-macroglobulin, by alpha 1-proteinase inhibitor and by antithrombin-III and heparin was studied. The amount of alpha- and beta-thrombin inactivated by antithrombin-III was proportional to the concentration of the inhibitor, but the inactivation rates of the two forms of thrombin were different. Heparin facilitated complex-formation between alpha-thrombin and antithrombin-III, whereas inactivation of beta-thrombin by antithrombin was only slightly influenced, even at a heparin concentration two orders of magnitude higher. alpha 2-Macroglobulin inhibited both alpha- and beta-thrombin activity similarly, i.e. the amount of alpha- and beta-thrombin inactivated as well as the rates of their inhibition were the same. alpha 1-Proteinase inhibitor also formed a complex with alpha- and beta-thrombin, similarly to antithrombin-III, although the inactivation of the enzyme needed high inhibitor concentration and long incubation time. These results suggest that the inactivation of beta-thrombin, if it occurs in the plasma, is also controlled by plasma inhibitors.     

Inactivation of human alpha 1-proteinase inhibitor by thiol proteinases.

Human plasma alpha1 proteinase inhibitor is the body's principal modulator of serine proteinases (such as those released from phagocytic cells). Cysteine-active-site proteinases, which are not inhibited, have now been found to inactivate this important inhibitor by proteolytic cleavage of a scissile peptide bond. Papain carries out this inactivation catalytically, whereas cathepsin B1 acts stoicheiometrically. Thus thiol proteinases could easily disrupt the delicately regulated balance between serine proteinases and alpha1 proteinase inhibitor.     

Enzymatic inactivation of human alpha-1-proteinase inhibitor by neutrophil myeloperoxidase.

Peanut agglutinin was acylated with a new heterobifunctional, cleavable photosensitive crosslinking reagent, N-[4-(p-azidophenylazo)benzoyl]-3-aminopropyl-N′-oxysuccinimide ester. The lectin derivative binds specifically and reversibly to neuraminidase-treated human erythrocyte ghosts and upon irradiation covalent attachment of over 35% of the bound lectin occurs. The affinity-crosslinked ghosts were solublized in deoxycholate, immunoprecipitated with anti-peanut agglutinin antiserum, and analyzed by sodium dodecylsulfate polyacrylamine gel electrophoresis. Bands containing both peanut agglutinin and membrane glycoproteins were detected with apparent molecular weights of 58 000, 85 000, 110 000 and 135 000. Upon subsequent cleavage with sodium dithionite, asialoglycophorin A (apparent M.W. 41 000 and 85 000) and a second glycoprotein (apparent M.W. 58 000 – 61 000) were tentatively identified as the receptors for peanut agglutinin in the intact membrane.     

Inhibitory activity and conformational transition of alpha 1-proteinase inhibitor variants.

Several variants of alpha 1-proteinase inhibitor (alpha 1-PI) were investigated by spectroscopic methods and characterized according to their inhibitory activity. Replacement of Thr345 (P14) with Arg in alpha 1-PI containing an Arg residue in position 358 (yielding [Thr345----Arg, Met358----Arg]alpha 1-PI) results in complete loss of its inhibitory activity against human alpha-thrombin; whereas an exchange of residue Met351 (P8) by Glu [( Met351----Glu, Met358----Arg]alpha 1-PI) does not alter activity. [Thr345----Arg, Met358----Arg]alpha 1-PI is rapidly cleaved by thrombin, while [Met358----Arg]alpha 1-PI and [Met351----Glu, Met358----Arg]alpha 1-PI form stable proteinase-inhibitor complexes. The stability of [Thr345----Arg, Met358----Arg]alpha 1-PI against guanidinium chloride denaturation is significantly enhanced compared to wild-type alpha 1-PI, and does not change after cleavage, resembling ovalbumin, a serpin with no inhibitory activity, from which the Thr345----Arg amino acid exchange had been derived. [Met351----Glu, Met358----Arg]alpha 1-PI and [Met358----Arg]alpha 1-PI resemble the wild-type protein in this respect. The CD spectra of intact and cleaved alpha 1-PI variants do not compare well with the wild-type protein, probably reflecting local structural differences. Insertion of a synthetic peptide, which corresponds to residues Thr345----Met358 of human alpha 1-PI, leads to the formation of binary complexes with all variants having the characteristic features of the binary complex between peptide and wild-type protein.     

The identification of epitopic sites in human alpha 1-proteinase inhibitor.

Human alpha 1-proteinase inhibitor (alpha 1-PI) yielded nine fragments on cleavage with CNBr. The amino acid sequences of these fragments were determined. Three of these CNBr-cleavage fragments, namely fragment I (residues 64-220), fragment II (residues 243-351) and fragment III (residues 1-63), were found to bind rabbit polyclonal antibodies against chemically oxidized alpha 1-PI and mouse polyclonal antibodies against native alpha 1-PI by the Bio-Dot method (enzyme-linked immunosorbent assay on nitrocellulose). These fragments, I, II and III, inhibited by 60%, 25% and 5% respectively the binding between alpha 1-PI and the rabbit antibodies. Fragments I, II and III were subjected to proteolytic digestion, and 15, ten and five peptides were obtained from these fragments respectively. Only four of these peptides showed binding to the mouse antibodies against native alpha 1-PI. These were residues 40-63, 79-86, 176-206 and 299-323. A panel of monoclonal antibodies was prepared by conventional hybridoma technology, with chemically oxidized alpha 1-PI as the antigen. The ability of the monoclonal antibodies to bind native alpha 1-PI and CNBr-cleavage fragments I-III was determined. The monoclonal antibodies fell into three categories. Most (over 90%) belonged to group I, which was capable of binding alpha 1-PI and only fragment I. Antibodies in groups II and III bound alpha 1-PI and either fragment II or fragment III respectively. The ability of the peptides derived from proteolytic digestion of fragments I, II and III to bind three monoclonal antibodies representing each of the three groups was determined. Among all the peptides tested, only one (residues 176-206) derived from fragment I showed binding to the antibodies from group I, one (residues 299-323) derived from fragment II showed binding to the antibodies from group II, and one (residues 40-63) from fragment III showed binding to the antibodies from group III. Each of these three peptides also inhibited the binding between alpha 1-PI and the corresponding monoclonal antibodies. From these data we concluded that at least four epitopic regions (residues 40-63, 79-86, 176-206 and 299-323) were present in alpha 1-PI. Specific monoclonal antibodies to three of these sites were obtained.     

Fluorescence labeling of a single sulfhydryl group in human plasma alpha 1-proteinase inhibitor and characterization of the labeled inhibitor

A single cysteine residue present in human plasma alpha 1-proteinase inhibitor was labeled with a fluorescent sulfhydryl reagent, N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine. The resulting fluorescent inhibitor retained nearly full inhibitory activity and formed complexes with bovine chymotrypsin, porcine pancreatic elastase, and bovine trypsin as revealed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Association rate constants for the interactions of the labeled inhibitor with the proteinases were determined to be 1.5 (+/- 0.4) X 10(6), 3.3 (+/- 0.3) X 10(5), and 1.4 (+/- 0.3) X 10(5) M-1 X s-1 for chymotrypsin, elastase, and trypsin, respectively. These values were found to be only slightly lower than those of the unlabeled inhibitor. Fluorescence emission spectra of the labeled inhibitor in the absence and presence of each proteinase were also examined, and little difference was observed between them.     

In vivo metabolism of inter-alpha-trypsin inhibitor and its proteinase complexes: evidence for proteinase transfer to alpha 2-macroglobulin and alpha 1-proteinase inhibitor

Inter-alpha-trypsin inhibitor was purified by a modification of published procedures which involved fewer steps and resulted in higher yields. The preparation was used to study the clearance of the inhibitor and its complex with trypsin from the plasma of mice and to examine degradation of the inhibitor in vivo. Unlike other plasma proteinase inhibitor-proteinase complexes, inter-alpha-trypsin inhibitor reacted with trypsin did not clear faster than the unreacted inhibitor. Studies using 125I-trypsin provided evidence for the dissociation of complexes of proteinase and inter-alpha-trypsin inhibitor in vivo, followed by rapid removal of proteinase by other plasma proteinase inhibitors, particularly alpha 2-macroglobulin and alpha 1-proteinase inhibitor. Studies in vitro also demonstrated the transfer of trypsin from inter-alpha-trypsin inhibitor to alpha 2-macroglobulin and alpha 1-proteinase inhibitor but at a much slower rate. The clearance of unreacted 125I-inter-alpha-trypsin inhibitor was characterized by a half-life ranging from 30 min to more than 1 h. Murine and human inhibitors exhibited identical behavior. Multiphasic clearance of the inhibitor was not due to degradation, aggregation, or carbohydrate heterogeneity, as shown by competition studies with asialoorosomucoid and macroalbumin, but was probably a result of extravascular distribution or endothelial binding. 125I-inter-alpha-trypsin inhibitor cleared primarily in the liver. Analysis of liver and kidney tissue by gel filtration chromatography and sodium dodecyl sulfate gel electrophoresis showed internalization and limited degradation of 125I-inter-alpha-trypsin inhibitor in these tissues. No evidence for the production of smaller proteinase inhibitors from 125I-inter-alpha-trypsin inhibitor injected intravenously or intraperitoneally was detected, even in casein-induced peritoneal inflammation. No species of molecular weight similar to that of urinary proteinase inhibitors, 19,000-70,000, appeared in plasma, liver, kidney, or urine following injection of inter-alpha-trypsin inhibitor.     

Characterization of the inactive fragment resulting from limited proteolysis of human alpha1-proteinase inhibitor by Crotalus adamanteus proteinase II.

The inactive 50,000-dalton fragment of human plasma alpha1-proteinase inhibitor resulting from limited proteolysis of the inhibitor by Crotalus adamanteus proteinase II has been isolated and partially characterized. The amino acid composition of the inactivated inhibitor indicates the loss of a peptide fragment from the intact inhibitor. Both intact and inactivated inhibitor contain COOH-terminal lysine. However, the NH2 terminus of the intact inhibitor is Glx, whereas that of inactivated inhibitor is methionine. NH2-terminal analysis of the inactive inhibitor fragment revealed the following sequence: -Met-Phe-Leu-Glu-Ala-Ile-Pro-Met-Ser-Ile-Pro-Pro-Gln-Val-Lys-Phe-Asn. The data show that the venom proteinase has inactivated alpha1- proteinase inhibitor by cleavage of a single bond which differs from that reported for trypsin or papain.     

Inactivation of human thrombin in the presence of human alpha1-proteinase inhibitor.

Both the clotting and esterase activities of thrombin are inhibited by alpha1-proteinase inhibitor (alpha1-antitrypsin). The inhibition is a time-and temperature-dependent reaction which is proportional to the molar ratio of thrombin to inhibitor. Both the active-site serine residue of thrombin and the reactive-site lysine residue of alpha1-proteinase inhibitor are involved. alpha1-Proteinase inhibitor forms a 1:1 complex with thrombin that is comparable with the complex formed with trypsin and other proteinases. Incubation of the inhibitor with excess of thrombin, however, results in inactivation of nearly all the enzyme, even though only as much complex is formed as alpha1-proteinase inhibitor present. A portion of the remaining thrombin apparently aggregates. These results suggest that the mechanism for inhibition of thrombin may not be exactly the same as for trypsin, which is inhibited only to the extent to which complex is formed.     

In vivo catabolism of alpha 1-proteinase inhibitor-trypsin, antithrombin III-thrombin and alpha 2-macroglobulin-methylamine

The clearances of 125I-labeled alpha 1-proteinase inhibitor-trypsin, antithrombin III-thrombin and alpha 2-macroglobulin-methylamine (CH3NH2) were compared in our previously described mouse model. alpha 1-Proteinase inhibitor-trypsin cleared with a t 1/2 of 20 min, antithrombin III-thrombin of 7 min and 125I-labeled alpha 2-macroglobulin-methylamine of 2 min. Competition studies were performed to determine whether one or several pathways clear these three ligands. The clearance of 125I-labeled alpha 1-proteinase inhibitor-trypsin and 125I-labeled antithrombin III-thrombin was blocked by large molar excesses of either ligand, but not by alpha 2-macroglobulin-methylamine. The clearance of 125I-labeled alpha 2-macroglobulin-methylamine can be blocked by a large molar excesses of unlabeled alpha 2-macroglobulin-methylamine but not by alpha 1-proteinase inhibitor-trypsin. These studies demonstrate that the clearance of alpha 1-proteinase inhibitor-trypsin complexes is independent of alpha 2-macroglobulin-methylamine and utilizes the same pathway which is involved in the clearance of antithrombin III-thrombin complexes.     

Purification and characterization of a novel cysteine proteinase (periodontain) from Porphyromonas gingivalis. Evidence for a role in the inactivation of human alpha1-proteinase inhibitor

Periodontal disease is characterized by inflammation of the periodontium manifested by recruitment of neutrophils, which can degranulate, releasing powerful proteinases responsible for destruction of connective tissues, and eventual loss of tooth attachment. Although the presence of host proteinase inhibitors (serpins) should minimize tissue damage by endogenous proteinases, this is not seen clinically, and it has been speculated that proteolytic inactivation of serpins may contribute to progression of the disease. A major pathogen associated with periodontal disease is the Gram-negative anaerobe Porphyromonas gingivalis, and in this report, we describe a novel proteinase that has been isolated from culture supernatants of this organism that is capable of inactivating the human serpin, alpha1-proteinase inhibitor, the primary endogenous regulator of human neutrophil elastase. This new enzyme, referred to as periodontain, belongs to the cysteine proteinase family based on inhibition studies and exists as a 75-kDa heterodimer. Furthermore, periodontain shares significant homology to streptopain, a proteinase from Streptococcus pyogenes, and prtT, a putative proteinase from P. gingivalis. Clearly, the presence of this enzyme, which rapidly inactivates alpha1-proteinase inhibitor, could result in elevated levels of human neutrophil elastase clinically detected in periodontal disease and should be considered as a potential virulence factor for P. gingivalis.