Pericellular proteolysis by neutrophils in the presence of proteinase inhibitors: effects of substrate opsonization

Inflammatory cells are capable of degrading extracellular matrix macromolecules in vivo in the presence of proteinase inhibitors. We and others have hypothesized that such proteolysis is permitted in large part by mechanisms operative in the immediate pericellular environment, especially at zones of contact between inflammatory cells and insoluble matrix components. To further test this hypothesis in vitro, we have used a model system in which viable polymorphonuclear neutrophils (PMN) are allowed to contact a surface coated with proteinase-sensitive substrate, and in which PMN interaction with the surface can be modulated. We have evaluated proteolysis of the surface-bound protein in the presence and absence of proteinase inhibitors. Our results were: (a) In the presence (but not in the absence) of proteinase inhibitors, proteolysis was confined to sharply marginated zones subjacent to the cells; (b) opsonization of the surface enhanced spreading of the PMN, (c) opsonization diminished the effectiveness of alpha-1-proteinase inhibitor (alpha-1-PI) and alpha-2-macroglobulin as inhibitors of proteolysis of surface-bound protein; (d) anti-oxidants did not alter the effectiveness of alpha-1-PI in inhibiting proteolysis of opsonized substrate by PMN; and (e) PMN could restrict entry of alpha-1-PI into zones of contact with opsonized surfaces. We conclude that: (a) In the presence of proteinase inhibitors, PMN can express sharply marginated and exclusively pericellular proteolytic activity; (b) locally high proteinase concentrations and/or exclusion of proteinase inhibitors from pericellular microenvironments may be important mechanisms for pericellular matrix degradation by PMN; and (c) these observations may have general relevance to extracellular matrix remodeling by a variety of inflammatory and other cell types.     

Purification and biochemical characterization of ovine alpha-1-proteinase inhibitor: mechanistic adaptations and role of Phe350 and Met356

The glycoprotein alpha-1-proteinase inhibitor (alpha-1-PI) is a member of the serpin super family that causes rapid and irreversible inhibition of redundant serine protease activity. A homogenous preparation of ovine alpha-1-PI, a 60 kDa protein was obtained by serially subjecting ovine serum to 40-70% (NH(4))(2)SO(4) precipitation, Blue Sepharose, size-exclusion, and concanavalin-A chromatography. Extensive insights into the trypsin, chymotrypsin, and elastase interaction with ovine alpha-1-PI, point towards the involvement of Phe(350) besides the largely conserved Met(356) in serine protease recognition and consequent inhibition. The N-terminal of C-terminal peptides cleaved on interaction with elastase, trypsin, and chymotrypsin prove the presence of diffused sub-sites in the vicinity of Met(356) and the strategically positioned Pro anchored peptide stretch. Further, human alpha-1-PI is more thermolabile compared to ovine alpha-1-PI, higher thermolability is mainly attributed to poorer glycosylation. The enzymatic deglycosylation of human and ovine alpha-1-PI results in diminished thermostability of the inhibitors, with sharp decrease in thermal transition temperatures but retaining their inhibitory potency. Homology modeling of the deduced amino acid sequence of ovine alpha-1-PI using the human alpha-1-PI template has been used to explain the observed inhibitor-protease interactions.     

Proteinase-proteinase inhibitor system in aged rats with stimulated hypertension exposed to cord blood

The proteinases, nontrypsinlike proteinases (NTLP), alpha-1-proteinase inhibitor, alpha-2-macroglobulin (alpha-2-MG) activities were researched in serum, tissues of hypothalamus, cerebral cortices, lung, heart, liver, kidneys in old rats with hypertension caused by electricity current at introduction of cord and mature blood preparations. The increase of proteinase and NTLP activities were revealed on the background of alpha-2-MG level reduction. The changes caused by stimulated hypertension, can be corrected by introduction of blood preparations and the effect of cord blood is more manifested.     

Alpha-1-proteinase inhibitor is a heparin binding serpin: molecular interactions with the Lys rich cluster of helix-F domain

Alpha-1-proteinase (alpha-1-PI) inhibitor is the major circulating serine protease inhibitor in humans. The porcine elastase and trypsin inhibitory activity of human and ovine alpha-1-PI is activated several fold in the presence of anti-coagulant heparin. The activation is allosteric and appears to be characterized by two steps of binding; a weak followed by a strong binding. The Kass for ovine and human alpha-1-PI inhibition of porcine pancreatic elastase was increased approximately 45 fold and 38 fold respectively. Using a combinatorial approach of multiple sequence alignment, surface topology, chemical modification and tryptic peptide mapping to identify the sequence of the heparin bound peptide; we demonstrate that heparin binds to the lysyl rich region of the F-helix of alpha-1-PI, which differs from that of heparin-antithrombin (AT) interactions. Molecular docking prediction using the MEDock algorithm approximates the three positively charged lysines (K154, K155, K174) of human alpha-1-PI in this interaction. This heparin alpha-1-PI interaction has been exploited to develop an affinity purification method, which can be used universally to obtain homogenous preparations of mammalian alpha-1-PIs useful for augmentation therapy. Collectively, all these findings imply that alpha-1-PI has a major role in regulating extra cellular protease activity and the physiological activator is heparin.     

Affinity chromatography of alpha-1-protease inhibitor using Sepharose-4B-bound anhydrochymotrypsin

Sepharose 4B-bound bovine anhydrochymotrypsin (AnhCT), a catalytically inactive form of chymotrypsin, was shown to be effective for retaining active alpha-1-protease inhibitor (alpha-1-PI, also alpha-1-antitrypsin) from human plasma, while showing no measurable affinity for oxidized or protease complexed alpha-1-PI, or for most other plasma proteins. alpha-1-PI eluted from this resin with 0.1 M chymostatin retained full activity against trypsin, chymotrypsin, and elastase. In addition to alpha-1-PI, AnhCT-Sepharose binds a limited number of other plasma proteins. Using monospecific antisera to plasma protease inhibitors, one of these proteins was identified as inter-alpha-trypsin inhibitor, and it was recoverable in active form. Therefore, an AnhCT-Sepharose 4B resin has been demonstrated to be of value for isolating active forms of alpha-1-PI from solutions, and may also be useful for the isolation of inter-alpha-trypsin inhibitor.     

Rapid inactivation of alpha-1-proteinase inhibitor by neutrophil specific leukolysin/membrane-type matrix metalloproteinase 6

Leukolysin/MT6-MMP is a GPI-anchored matrix metalloproteinase (MMP) primarily expressed by neutrophils. It is stored in intracellular granules at resting state, but rapidly discharged upon stimulations into the extracellular milieu, presumably to promote tissue remodeling or destruction. The proteolytic targets for leukolysin at the inflammatory sites remain unknown. Here, we show that alpha-1-proteinase inhibitor, or alpha1-PI, a known protective shield against destructive serine proteinases, is a physiological target for leukolysin. We show that alpha1-PI failed to accumulate in media conditioned by cells co-expressing alpha1-PI and leukolysin. Purified leukolysin cleaves alpha1-PI efficiently at the Phe376Leu and Pro381Met bonds and the cleaved alpha1-PI lost its anti-proteolytic activity against human neutrophil elastase, cathepsin G (CatG) and proteinase 3 (PR3). In fact, leukolysin preferentially cleaves alpha1-PI when co-incubated with other extracellular molecules such as laminin and gelatin. Kinetically, leukolysin is more active than two known neutrophil MMPs, MMP8 and MMP9, in cleaving and inactivating alpha1-PI. Taken together, these results suggest that neutrophils may mediate tissue destruction by deploying leukolysin to weaken the alpha1-PI protective shield at inflammatory sites.     

Neutrophil-mediated solubilization of the subendothelial matrix: oxidative and nonoxidative mechanisms of proteolysis used by normal and chronic granulomatous disease phagocytes

Both normal and chronic granulomatous disease (CGD) neutrophils were able to degrade the subendothelial matrix secreted by human endothelial cells via an elastase-dependent process. In the absence of the plasma antiproteinase, alpha-1-proteinase inhibitor (alpha-1-PI), normal neutrophils protect their released elastase from inactivation by using the chlorinated oxidants hypochlorous acid and endogenous N-chloroamines to suppress the antiproteinase's activity. In contrast, CGD neutrophils were unable to generate either class of chlorinated oxidant or to inactivate the porcine pancreatic elastase inhibitory capacity of alpha-1-PI unless the cells were supplemented with exogenous hydrogen peroxide. Despite the reliance of normal neutrophils on chlorinated oxidants to inactivate alpha-1-PI, neutrophils triggered in the presence of agents that block the generation of these reactive species continued to degrade the subendothelial matrix at a suppressed but significant rate in the presence of a 50-fold excess of the antiproteinase. The continued solubilization of the matrix by normal neutrophils was not due to the incomplete inhibition of oxidant generation because triggered CGD neutrophils were also able to degrade the matrix in the presence of excess alpha-1-PI. If CGD neutrophils were stimulated in the presence of an exogenous source of H2O2 and alpha-1-PI, the proteolytic potential of the cells was identical to that observed with normal stimulated neutrophils. We conclude that normal neutrophils can enhance their ability to degrade the subendothelial matrix by oxidatively protecting elastase from inactivation by alpha-1-PI but both normal and CGD neutrophils possess non-oxidatively linked mechanisms for sequestering and using elastase to mediate proteolytic effects in the presence of native antiproteinase.     

Activation-coupled membrane-type 1 matrix metalloproteinase membrane trafficking

The transmembrane collagenase MT1-MMP (membrane-type 1 matrix metalloproteinase), also known as MMP-14, has a critical function both in normal development and in cancer progression, and is subject to extensive controls at the post-translational level which affect proteinase activity. As zymogen activation is crucial for MT1-MMP activity, an alpha1-PI (alpha1-proteinase inhibitor)-based inhibitor was designed by incorporating the MT1-MMP propeptide cleavage sequence into the alpha1-PI reactive-site loop (designated alpha1-PI(MT1)) and this was compared with wild-type alpha1-PI (alpha1-PI(WT)) and the furin inhibitory mutant alpha1-PI(PDX). Alpha1-PI(MT1) formed an SDS-stable complex with furin and inhibited proMT1-MMP activation. A consequence of the loss of MT1-MMP activity was the activation of proMMP-2 and the inhibition of MT1-MMP-mediated collagen invasion. alpha1-PI(MT1) expression also resulted in the intracellular accumulation of a glycosylated species of proMT1-MMP that was retained in the perinuclear region, leading to significantly decreased cell-surface accumulation of proMT1-MMP. These observations suggest that both the subcellular localization and the activity of MT1-MMP are regulated in a coordinated fashion, such that proMT1-MMP is retained intracellularly until activation of its zymogen, then proMT1-MMP traffics to the cell surface in order to cleave extracellular substrates.     

Comparative properties of human alpha-1-proteinase inhibitor glycosylation variants

Variant forms of human alpha-1-proteinase inhibitor (alpha-1-PI), obtained by the treatment of human Hep G2 cells with specific inhibitors of glycosylation were tested for both inhibitory activity and heat stability. All were found to have the same second-order association rate with human neutrophil elastase, indicating a lack of importance of the carbohydrate moiety. In contrast, incompletely glycosylated forms of alpha-1-PI were found to be heat sensitive relative to the mature protein, suggesting a role for carbohydrate in protein stabilization.     

Alternative changes of activity of alpha2-macroglobulin and alpha1-antitrypsin in rat blood following damage in capsaicin-sensitive nerves

Effects of functional ablation of peptidergic sensory nerves with neurotoxic doses of capsaicin (150 mg/kg, s/c) as well as of their stimulation with small doses of capsaicin (5 mg/kg, i/p) on activity of proteinase inhibitors: alpha1-antitrypsin (alpha1-AT)-serine proteinase inhibitor and alpha2-macroglobulin (alpha2-MG)-nonspecific inhibitor were investigated in rat blood. The present results indicate alternative changes in activity of these proteinase inhibitors after damage of capsaicin-sensitive nerves: increasing decline in activity of alpha1-AT 1 and 3 or 14 days after administration of capsaicin and increase in activity of alpha2-MG land 3 day after the injection. The stimulation of afferent nerves with capsaicin did not change activity of the proteinase inhibitors 1 and 24 hours after the injection. It is suggested that the stable decrease in activity of alpha1-AT during a long period after the damage of capsaicin-sensitive nerves indicates an important role for these nerves in the regulating alpha1-AT that may exert a tonic effect on the activity alpha1-AT.     

Isolation and characterization of alpha-1-proteinase inhibitor from goat plasma

Alpha-1-proteinase inhibitor (alpha-1-PI) was isolated from goat plasma by salt fractionation, and chromatography on a DEAE-cellulose column. The inhibitor was found to be homogeneous by gel chromatography, SDS-PAGE and PAGE.Mr values by gel filtration (57 kDa), and by SDS-PAGE (52 kDa), under reducing conditions were nearly the same suggesting that the inhibitor consists of a single polypeptide chain. It contained 13.8% neutral hexose but no sialic acid residue. The values of isoionic pH, and extinction coefficient at 278 nm were 4.84, and 4.6, respectively. Fluorescence spectral properties showed tryptophan residues in the inhibitor. Solvent perturbation difference spectra suggested 74% exposure of the tryptophan residues in the native molecule. Gel filtration behaviour of the inhibitor was consistent with a Stokes radius of 3.16 nm, diffusion coefficient of 7.02 X 10(-7) cm2-sec-1 and a frictional ratio of 1.24 suggesting asymmetry and/or excessive hydration of the inhibitor molecule. Goat alpha-1-PI, unlike human alpha-1-PI was found to be potent inhibitor of bovine trypsin but a poor inhibitor of porcine pancreatic elastase. It was virtually devoid of antichymotryptic activity.     

Inactivation of alpha-1-proteinase inhibitor in serum by stimulated human polymorphonuclear leucocytes. Evidence for a myeloperoxidase-dependent mechanism

Triggered polymorphonuclear leucocytes (PMNL) can decrease the elastase inhibitory capacity of serum by inactivating the main inhibitor of elastase alpha-1-proteinase inhibitor (alpha-1-PI). Maximal inactivation occurs with stimuli that release myeloperoxidase from PMNL along with hydrogen peroxide. Specific protection of alpha-1-PI function is obtained with antioxidants that interfere with this system. PMNL that are activated with phorbol myristate acetate release hydrogen peroxide but not myeloperoxidase, and only inactivate alpha-1-PI in the presence of exogenously-added PMNL-derived supernatants which contain this enzyme. Cell-free inactivation requires both active enzyme and hydrogen peroxide, and is greatest at pH 6.2, the pH optimum for myeloperoxidase-catalysed inactivation of alpha-1-PI. This data supports the notion that leucocyte myeloperoxidase may act to suppress the antiprotease screen afforded by alpha-1-PI by generating hypochlorous acid in the presence of chloride and respiratory burst-derived hydrogen peroxide, and in the microenvironment of lowered pH associated with degranulation. Pulmonary emphysema seems to be associated with an imbalance between elastase and its inhibitors at the lung surface. PMNL are likely to play an important role in the pathogenesis of emphysema since they contain both elastase, which can solubilize connective tissue elastin, and the constituents of an oxidative system which can inactivate the most important antielastase, alpha-1-PI.     

Inactivation of enzymes and an enzyme inhibitor by oxidative modification with chlorinated amines and metal-catalyzed oxidation systems.

Oxidative inactivation of various key enzymes and alpha-1-proteinase inhibitor (alpha-1-PI) was studied by treatment with N-chloramines and the metal-catalyzed oxidation (MCO)-systems ascorbate/Fe(III) and ascorbate/Cu(II). Chlorinated amines completely inhibited alpha-1-PI, fructose-1,6-bis phosphatase (Fru-P2ase) and glyceraldehyde phosphate dehydrogenase (GAPD) at a low molar excess, and glucose-6-phosphate dehydrogenase (G6PD) at a high molar excess, but did not impair beta-N-acetylglucosaminidase (beta-NAG), alkaline phosphatase (AP) or lactate dehydrogenase (LDH). MCO-systems affected the activities of Fru-P2ase, GAPD, AP, LDH and G6PD, but not those of beta-NAG or alpha-1-PI. EDTA prevented inactivation of Fru-P2ase, G6PD and LDH by ascorbate/Cu(II) and of Fru-P2ase by ascorbate/Fe(III) suggesting a site-specific oxidation catalyzed by a protein-bound metal ion. In conclusion, N-chloramines and MCO-systems exhibited different properties with regard to oxidative inactivation, sulfhydryl-enzymes were susceptible to both systems, but other enzymes were only susceptible to one or neither system.     

Inactivation of α1-Proteinase Inhibitor as a Broad Screen for Detecting Proteolytic Activities in Unknown Samples

The need for a quick, simple screening method for the detection of general proteolytic activity prompted us to determine whether cleavage within the reactive site loop region (RSL) of α₁-proteinase inhibitor (α₁-PI), a well-characterized member of the serpin family known to be susceptible to proteolytic inactivation, can be utilized for this purpose. Inactivation of α₁-PI in the RSL region can be measured by loss of residual inhibitory capacity of α₁-PI against its target proteinase. While we originally utilized this assay to detect a new proteinase from culture supernatants ofPorphyromonas gingivalis, the feasibility of extending this assay to scan for proteolytic activity from other systems was also assessed. As an example, we found that the serine proteinase fromStaphylococcus aureus(SSP) had virtually the same catalytic efficiency in inactivating α₁-PI in our assay as it did in the hydrolysis of the synthetic substrate Z-Phe-Leu-Glu–pNA (k_cat/K_mvalue of 2 × 10⁴M⁻¹s⁻¹vs 2.6 × 10⁴M⁻¹s⁻¹, respectively). Additionally, in both assays activity could be readily detected in less than a 1 h incubation at SSP concentrations in the picomolar range. This assay is unique in that proteinases which hydrolyze peptide bonds within the RSL of α₁-PI can readily be detected as measured by loss of α₁-PI inhibitory activity.     

Reaction of human skin chymotrypsin-like proteinase chymase with plasma proteinase inhibitors

The ability of plasma proteinase inhibitors to inactivate human chymase, a chymotrypsin-like proteinase stored within mast cell secretory granules, was investigated. Incubation with plasma resulted in over 80% inhibition of chymase hydrolytic activity for small substrates, suggesting that inhibitors other than alpha 2-macroglobulin were primarily responsible for chymase inactivation. Depletion of specific inhibitors from plasma by immunoadsorption using antisera against individual inhibitors established that alpha 1-antichymotrypsin (alpha 1-AC) and alpha 1-proteinase inhibitor (alpha 1-PI) were responsible for the inactivation. Characterization of the reaction between chymase and each inhibitor demonstrated in both cases the presence of two concurrent reactions proceeding at fixed relative rates. One reaction, which led to inhibitor inactivation, was about 3.5 and 4.0-fold faster than the other, which led to chymase inactivation. This was demonstrated in linear titrations of proteinase activity which exhibited endpoint stoichiometries of 4.5 (alpha 1-AC) and 5.0 (alpha 1-PI) instead of unity, and SDS gels of reaction products which exhibited a banding pattern indicative of both an SDS-stable proteinase-inhibitor complex and two lower Mr inhibitor degradation products which appear to have formed by hydrolysis within the reactive loop of each inhibitor. At inhibitor concentrations approaching those in plasma where inhibitor to chymase concentration ratios were in far excess of 4.5 and 5.0, the rate of chymase inactivation by both serpin inhibitors appeared to follow pseudo-first order kinetics. The "apparent" second order rate constants of inactivation determined from these data were about 3000-fold lower than the rate constants reported for human neutrophil cathepsin G and elastase with alpha 1-AC and alpha 1-PI, respectively. This suggests that chymase would be inhibited about 650-fold more slowly than these proteinases when released into plasma. These studies demonstrate that although chymase is inactivated by serpin inhibitors of plasma, both inhibitors are better substrates for the proteinase than they are inhibitors. This finding along with the slow rates of inactivation indicates that regulation of human chymase activity may not be a primary function of plasma.     

Isolation of tri-antennary enriched and tri-antennary depleted alpha-1-protease inhibitor

Alpha-1-protease inhibitor, (alpha-1-PI), the major inhibitor of serine proteases in human plasma, has three asparagine-linked carbohydrate chains located at positions 46, 83 and 247. The protein has a microheterogeneity which is seen on isoelectric focusing and which is a result of whether the various carbohydrate chains are in bi- or tri-antennary forms. Tri-antennary enriched forms of alpha-1-PI are associated with inflammation. By using a combination of three methods, reductive salting out, Sepharose-bound Concanavalin A affinity chromatography, and Sepharose-bound anhydrochymotrypsin, biologically active alpha-1-PI was obtained in tri-antennary enriched and tri-antennary depleted forms. These preparations should be useful for studies on the physiological role of the carbohydrate moiety in alpha-1-PI.     

Effect of pentoxyphylline on certain indicators of the proteinase-proteinase inhibitor system in rats upon administration of cycloheximide

The pentoxifylline influence on neutral proteinase, alpha-2-macroglobulin, trypsin-alpha-1-proteinase inhibitor and elastaseinhibitory activity under cycloheximide injection has been investigated. Two hours after cycloheximide injection the activity of neutral proteinases increases in rats serum, lungs, heart, liver and kidneys. The preliminary injection of pentoxifylline prevents increase of neutral proteinases activity. Cycloheximide also decreases alpha-2-macroglobulin activity in serum and liver and trypsin-, elastaseinhibitory activity of alpha-1-proteinase inhibitor in all investigated organs. At using pentoxifylline the alpha-2-macroglobulin activity doesn't change in liver and increases in serum in comparison with only cycloheximide and there are no observed any alpha-1 inhibitor proteinase activity changes in rats serum and organs.     

Inhibition of rat tissue kallikrein gene family members by rat kallikrein-binding protein and alpha 1-proteinase inhibitor.

The regulation of tissue kallikrein activity by plasma serine proteinase inhibitors (serpins) was investigated by measuring the association rate constants of six tissue-kallikrein family members isolated from the rat submandibular gland, with rat kallikrein-binding protein (rKBP) and alpha 1-proteinase inhibitor (alpha 1-PI). Both these serpins inhibited kallikreins rK2, rK7, rK8, rK9 and rK10 with association rate constants in the 10(3)-10(4) M-1.s-1 range, whereas only 'true' tissue kallikrein rK1 was not susceptible to alpha 1-PI. This results in slow inhibition of rK1 by plasma serpins, which could explain why this kallikrein is the only member of the gene family identified so far that induces a transient decrease in blood pressure when injected in minute amounts into the circulation.     

Functional diversification during evolution of the murine alpha(1)-proteinase inhibitor family: role of the hypervariable reactive center loop

Alpha(1)-proteinase inhibitor (alpha(1)-PI) is a member of the serpin superfamily of serine proteinase inhibitors that are involved in the regulation of a number of proteolytic processes. Alpha(1)-PI, like most serpins, functions by covalent binding to, and inhibition of, target proteinases. The interaction between alpha(1)-PI and its target is directed by the so-called reactive center loop (RCL), an approximately 20 residue domain that extends out from the body of the alpha(1)-PI polypeptide and determines the inhibitor's specificity. Mice express at least seven closely related alpha(1)-PI isoforms, encoded by a family of genes clustered at the Spi1 locus on chromosome 12. The amino acid sequence of the RCL region is hypervariable among alpha(1)-PIs, a phenomenon that has been attributed to high rates of evolution driven by positive Darwinian selection. This suggests that the various isoforms are functionally diverse. To test this notion, we have compared the proteinase specificities of individual alpha(1)-PIs from each of the two mouse species. As predicted from the positive Darwinian selection hypothesis, the various alpha(1)-PIs differ in their ability to form covalent complexes with serine proteinases, such as elastase, trypsin, chymotrypsin, and cathepsin G. In addition, they differ in their binding ability to proteinases in crude snake venoms. Importantly, the RCL region of the alpha(1)-PI polypeptide is the primary determinant of isoform-specific differences in proteinase recognition, indicating that hypervariability within this region drives the functional diversification of alpha(1)-PIs during evolution. The possible physiological benefits of alpha(1)-PI diversity are discussed.     

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.