Specificity and reactive loop length requirements for crmA inhibition of serine proteases

The viral serpin, crmA, is distinguished by its small size and ability to inhibit both serine and cysteine proteases utilizing a reactive loop shorter than most other serpins. Here, we characterize the mechanism of crmA inhibition of serine proteases and probe the reactive loop length requirements for inhibition with two crmA reactive loop variants. P1 Arg crmA inhibited the trypsin-like proteases, thrombin, and factor Xa, with moderate efficiencies (approximately 10(2)-10(4) M(-1)sec(-1)), near equimolar inhibition stoichiometries, and formation of SDS-stable complexes which were resistant to dissociation (k(diss) approximately 10(-7) sec(-1)), consistent with a serpin-type inhibition mechanism. Trypsin was not inhibited, but efficiently cleaved the variant crmA as a substrate (k(cat)/K(M) of approximately 10(6) M(-1) sec(-1)). N-terminal sequencing confirmed that the P1 Arg-P1'Cys bond was the site of cleavage. Altering the placement of the Arg in a double mutant P1 Gly-P1'Arg crmA resulted in minimal ability to inhibit any of the trypsin family proteases. This variant was cleaved by the proteases approximately 10-fold less efficiently than P1 Arg crmA. Surprisingly, pancreatic elastase was rapidly inhibited by wild-type and P1 Arg crmAs (10(5)-10(6) M(-1)sec(-1)), although with elevated inhibition stoichiometries and higher rates of complex dissociation. N-terminal sequencing showed that elastase attacked the P1'Cys-P2'Ala bond, indicating that crmA can inhibit proteases using a reactive loop length similar to that used by other serpins, but with variations in this inhibition arising from different effective P2 residues. These results indicate that crmA inhibits serine proteases by the established serpin conformational trapping mechanism, but is unusual in inhibiting through either of two adjacent reactive sites.     

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.     

Crystal structure of viral serpin crmA provides insights into its mechanism of cysteine proteinase inhibition

CrmA is an unusual viral serpin that inhibits both cysteine and serine proteinases involved in the regulation of host inflammatory and apoptosis processes. It differs from other members of the serpin superfamily by having a reactive center loop that is one residue shorter, and by its apparent inability to form SDS-stable covalent complexes with cysteine proteinases. To obtain insight into the inhibitory mechanism of crmA, we determined the crystal structure of reactive center loop-cleaved crmA to 2.9 A resolution. The structure, which is the first of a viral serpin, suggests that crmA can inhibit cysteine proteinases by a mechanism analogous to that used by other serpins against serine proteinases. However, one striking difference from other serpins, which may be significant for in vivo function, is an additional highly charged antiparallel strand for b sheet A, whose sequence and length are unique to crmA.     

Pathogenic alpha 1-antitrypsin polymers are formed by reactive loop-beta-sheet A linkage

alpha(1)-Antitrypsin is the most abundant circulating protease inhibitor and the archetype of the serine protease inhibitor or serpin superfamily. Members of this family may be inactivated by point mutations that favor transition to a polymeric conformation. This polymeric conformation underlies diseases as diverse as alpha(1)-antitrypsin deficiency-related cirrhosis, thrombosis, angio-edema, and dementia. The precise structural linkage within a polymer has been the subject of much debate with evidence for reactive loop insertion into beta-sheet A or C or as strand 7A. We have used site directed cysteine mutants and fluorescence resonance energy transfer (FRET) to measure a number of distances between monomeric units in polymeric alpha(1)-antitrypsin. We have then used a combinatorial approach to compare distances determined from FRET with distances obtained from 2.9 x 10(6) different possible orientations of the alpha(1)-antitrypsin polymer. The closest matches between experimental FRET measurements and theoretical structures show conclusively that polymers of alpha(1)-antitrypsin form by insertion of the reactive loop into beta-sheet A.     

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

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

A new intracellular serine protease inhibitor expressed in the rat pituitary gland complexes with granzyme B

We have cloned a novel serpin (raPIT5a) from a rat pituitary cDNA library which is structurally related to members of the ovalbumin subfamily of serine protease inhibitors. This new cDNA encodes a 374-amino acid protein, designated raPIT5a. raPIT5a was expressed in specific cells in the intermediate and anterior lobes of the pituitary. Recombinant raPIT5a was not secreted suggesting raPIT5a functions to inhibit intracellular proteases. Recombinant raPIT5a formed an SDS-stable complex with human granzyme B, a serine protease which induces apoptosis by activating members of the caspase enzyme family. These data suggest raPIT5a may have a role in regulating granzyme B or related enzymes and apoptosis in the pituitary gland.     

cDNA cloning of granzyme C, a granule-associated serine protease of cytolytic T lymphocytes

A cDNA clone corresponding to the complete amino acid sequence of a putative protease CCP2 of murine cytotoxic T lymphocytes was isolated and sequenced. The clone encodes a 248-residue long serine esterase. The deduced N-terminal amino acid sequence is identical over 40 residues to that of granzyme C, a protease of unknown function present in granules of cytotoxic lymphocytes. Analysis of the sequence of granzyme C/CCP2 reveals high homology to other granzyme proteases, i.e. granzyme A (40%) and granzyme B (67%) and to rat mast cell protease II (46%). The amino acids lining the specificity pocket are well conserved between granzyme B, C, and rat mast cell protease II, but not granzyme A, suggesting a similar general specificity of these three proteases.     

Kinetic Intermediates en Route to the Final Serpin-Protease Complex: STUDIES OF COMPLEXES OF α1-PROTEASE INHIBITOR WITH TRYPSIN*

Serpin protein protease inhibitors inactivate their target proteases through a unique mechanism in which a major serpin conformational change, resulting in a 70-Å translocation of the protease from its initial reactive center loop docking site to the opposite pole of the serpin, kinetically traps the acyl-intermediate complex. Although the initial Michaelis and final trapped acyl-intermediate complexes have been well characterized structurally, the intermediate stages involved in this remarkable transformation are not well understood. To better characterize such intermediate steps, we undertook rapid kinetic studies of the FRET and fluorescence perturbation changes of site-specific fluorophore-labeled derivatives of the serpin, α₁-protease inhibitor (α₁PI), which report the serpin and protease conformational changes involved in transforming the Michaelis complex to the trapped acyl-intermediate complex in reactions with trypsin. Two kinetically resolvable conformational changes were observed in the reactions, ascribable to (i) serpin reactive center loop insertion into sheet A with full protease translocation but incomplete protease distortion followed by, (ii) full conformational distortion and movement of the protease and coupled serpin conformational changes involving the F helix-sheet A interface. Kinetic studies of calcium effects on the labeled α₁PI-trypsin reactions demonstrated both inactive and low activity states of the distorted protease in the final complex that were distinct from the intermediate distorted state. These studies provide new insights into the nature of the serpin and protease conformational changes involved in trapping the acyl-intermediate complex in serpin-protease reactions and support a previously proposed role for helix F in the trapping mechanism.     

Structural similarity of the covalent complexes formed between the serpin plasminogen activator inhibitor-1 and the arginine-specific proteinases trypsin, LMW u-PA, HMW u-PA, and t-PA: use of site-specific fluorescent probes of local environment

We have used two fluorescent probes, NBD and dansyl, attached site-specifically to the serpin plasminogen activator inhibitor-1 (PAI-1) to address the question of whether a common mechanism of proteinase translocation and full insertion of the reactive center loop is used by PAI-1 when it forms covalent SDS-stable complexes with four arginine-specific proteinases, which differ markedly in size and domain composition. Single-cysteine residues were incorporated at position 119 or 302 as sites for specific reporter labeling. These are positions approximately 30 A apart that allow discrimination between different types of complex structure. Fluorescent derivatives were prepared for each of these variants using both NBD and dansyl as reporters of local perturbations. Spectra of native and cleaved forms also allowed discrimination between direct proteinase-induced changes and effects solely due to conformational change within the serpin. Covalent complexes of these derivatized PAI-1 species were made with the proteinases trypsin, LMW u-PA, HMW u-PA, and t-PA. Whereas only minor perturbations of either NBD and dansyl were found for almost all complexes when label was at position 119, major perturbations in both wavelength maximum (blue shifts) and quantum yield (both increases and decreases) were found for all complexes for both NBD and dansyl at position 302. This is consistent with all four complexes having similar location of the proteinase catalytic domain and hence with all four using the same mechanism of full-loop insertion with consequent distortion of the proteinase wedged in at the bottom of the serpin.     

Evidence that serpin architecture intrinsically supports papain-like cysteine protease inhibition: engineering alpha(1)-antitrypsin to inhibit cathepsin proteases

The closely related serpins squamous cell carcinoma antigen-1 and -2 (SCCA-1 and -2, respectively) are capable of inhibiting cysteine proteases of the papain superfamily. To ascertain whether the ability to inhibit cysteine proteases is an intrinsic property of serpins in general, the reactive center loop (RCL) of the archetypal serine protease inhibitor alpha(1)-antitrypsin was replaced with that of SCCA-1. It was found that this simple substitution could convert alpha(1)-antitrypsin into a cysteine protease inhibitor, albeit an inefficient one. The RCL of SCCA-1 is three residues longer than that of alpha(1)-antitrypsin, and therefore, the effect of loop length on the cysteine protease inhibitory activity was investigated. Mutants in which the RCL was shortened by one, two, or three residues were effective inhibitors with second-order rate constants of 10(5)-10(7) M(-)(1) s(-)(1). In addition to loop length, the identity of the cysteine protease was of considerable importance, since the chimeric molecules inhibited cathepsins L, V, and K efficiently, but not papain or cathepsin B. By testing complexes between an RCL-mimicking peptide and the mutants, it was found that the formation of a stable serpin-cysteine protease complex and the inhibition of a cysteine protease were both critically dependent on RCL insertion. The results strongly indicate that the serpin body is intrinsically capable of supporting cysteine protease inhibition, and that the complex with a papain-like cysteine protease would be expected to be analogous to that seen with serine proteases.     

Conformational equilibrium of the reactive center loop of antithrombin examined by steady state and time-resolved fluorescence measurements: consequences for the mechanism of factor Xa inhibition by antithrombin-heparin complexes

Activation of antithrombin by high-affinity heparin as an inhibitor of factor Xa has been ascribed to an allosteric switch between two conformations of the reactive center loop. However, we have previously shown that other, weaker binding, charged polysaccharides can give intermediate degrees of activation [Gettins, P. G. W., et al. (1993) Biochemistry 32, 8385-8389]. To examine whether such intermediate activation results from different reactive center loop conformations or, more simply, from a different equilibrium constant between the same two extreme conformations, we have used NBD covalently bound at the P1 position of an engineered R393C variant of antithrombin as a fluorescent reporter group and measured fluorescence lifetimes of the label in free antithrombin as well as in antithrombin saturated with long-chain high-affinity heparin, high-affinity heparin pentasaccharide, long-chain low-affinity heparin, and dextran sulfate. Steady state emission spectra, anisotropies, and dynamic quenching measurements were also recorded. We found that the large steady state fluorescence enhancements produced by binding of activators resulted from relief of a static quench of fluorescence of NBD in approximately 50% of the labeled antithrombin molecules rather than from any large change in lifetimes, and that similar lifetimes were found for NBD in all activated antithrombin-oligosaccharide complexes. Similar anisotropies and positions of the NBD emission maxima were also found in the absence and presence of activators. In addition, NBD was accessible to quenching agents in both the absence and presence of activators, with an at most 2-fold increase in quenching constants between these two extremes. The simplest interpretation of the partial static quench in the absence of activators, the different degrees of enhancement by different antithrombin activators, and the similar fluorescence properties and quenching behavior of the different states is that there are two distinct types of conformational equilibrium involving three distinct states of antithrombin, which we designate A, A', and B. A and A' represent low-affinity or inactive states of approximately equal energy, both having the hinge residues inserted into beta-sheet A. A is fluorescent, while A' is statically quenched. State B represents the activated loop-expelled conformation in which none of the NBD fluorophores are statically quenched, as a result of the loop, including the P1-NBD, moving away from the body of the antithrombin. Different activators are able to shift the equilibrium to the high-activity (B) state to different extents and hence give different degrees of measured activity, and different degrees of relief of static quench. The similar properties and accessibility of the NBD in the A and B conformations also indicate that the P1 side chain is not buried in the low-activity A conformation, suggesting that an earlier proposal that activation involves exposure of the P1 side chain cannot be the explanation for activation. As an alternative explanation, heparin activation may give access to an exosite on antithrombin for binding to factor Xa and hence be the principal basis for enhancement of the rate of inhibition.     

Conformational similarities between one-chain and two-chain tissue plasminogen activator (t-PA): implications to the activation mechanism on one-chain t-PA.

Tissue plasminogen activator (t-PA) is an exceptional serine protease, because unlike most other serine protease zymogens single-chain tissue plasminogen activator (sct-PA) possesses a substantial amount of proteolytic activity. The unusual reaction of sct-PA afforded the opportunity to directly compare the active site environment of sct-PA and two-chain tissue plasminogen activator (tct-PA) in solution through the application of a series of nitroxide spin labels and fluorophores. These labels, which have been previously shown to covalently label the catalytic serine of other serine proteases, inactivated both sct-PA and tct-PA. The labels can be divided into two classes: those which form tetrahedral complexes (sulfonates) and those which form trigonal complexes (anthranilates). Those which formed tetrahedral complexes were found to be insensitive to structural differences between sct-PA and tct-PA at the active site. In contrast, those which formed trigonal complexes could differentiate and monitor the sct-PA to tct-PA conversion by fluorescence spectroscopy. Models of the structure of sct-PA and tct-PA were constructed on the basis of the known X-ray structures of other serine protease zymogen and active enzyme forms. One of the nitroxide spin labels was modeled into the sct-PA and tct-PA structures in two possible orientations, both of which could be sensitive to structural differences between sct-PA and tct-PA. These models formed the structural rationale used to explain the results obtained with the "tetrahedral" and "trigonal" probes, as well as to offer a possible explanation for the unique reactivity of sct-PA.     

Conformational distributions of protease-serpin complexes: a partially translocated complex

Serpins regulate serine proteases by forming metastable covalent complexes with their targets. The protease docks with the serpin and cleaves the serpin's reactive center loop (RCL) forming an acylenzyme intermediate. Cleavage triggers insertion of the RCL into beta sheet A, translocating the attached protease approximately 70 A and disrupting the protease active site, trapping the acylenzyme intermediate. Using single-pair F?rster resonance energy transfer (spFRET), we have measured the conformational distributions of trypsin and alpha(1)-proteinase inhibitor (alpha(1)PI) covalent complexes. Bovine trypsin (BTryp) complexes display a single set of conformations consistent with the full translocation of BTryp (E(full)I*). However, the range of spFRET efficiencies is large, suggesting that the region around the trypsin label is mobile. Most complexes between alpha(1)PI variants and the more stable rat trypsin (RTryp) also show a single set of conformations, but the conformational distribution is narrower, indicating less disruption of RTryp. Surprisingly, RTryp complexes containing alpha(1)PI labeled at Cys232 with a cationic fluorophore display two equally populated conformations, E(full)I* and a conformation in which RTryp is only partially translocated (E(part)I*). Destabilizing the RTryp active site, by substituting Ala for Ile16, increases the E(full)I* population. Thus, interactions between anionic RTryp and cationic dyes likely exert a restraining force on alpha(1)PI, increasing the energy needed to translocate trypsin, and this force can be counteracted by active site destabilization. These results highlight the role of protease stability in determining the conformational distributions of protease-serpin covalent complexes and show that full translocation is not required for the formation of metastable complexes.     

Myxoma Virus Serp2 Is a Weak Inhibitor of Granzyme B and Interleukin-1β-Converting Enzyme In Vitro and Unlike CrmA Cannot Block Apoptosis in Cowpox Virus-Infected Cells

The Serp2 protein encoded by the leporipoxvirus myxoma virus is essential for full virulence (F. Messud-Petit, J. Gelfi, M. Delverdier, M. F. Amardeilh, R. Py, G. Sutter, and S. Bertagnoli, J. Virol. 72:7830-7839, 1998) and, like crmA of cowpox virus (CPV), is reported to inhibit the interleukin-1beta-converting enzyme (ICE, caspase-1) (F. Petit, S. Bertagnoli, J. Gelfi, F. Fassy, C. Boucraut-Baralon, and A. Milon, J. Virol. 70:5860-5866, 1996). Serp2 and CrmA both contain Asp at the P1 position within the serpin reactive site loop and yet are only 35% identical overall. Serp2 protein was cleaved by ICE but, unlike CrmA, did not form a stable complex with ICE that was detectable by native gel electrophoresis. Attempts to covalently cross-link ICE-serpin inhibitory complexes were successful with CrmA, but no complex between ICE and Serp2 was visible after cross-linking. Purified His10-tagged Serp2 protein was a relatively poor inhibitor of ICE, with a Ki of 80 nM compared to 4 pM for CrmA. Serp2 protein resembled CrmA in that a stable complex with the serine proteinase granzyme B was detectable after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. However, Serp2 was less effective at inhibiting granzyme B activity (Ki = 420 nM) than CrmA (Ki = 100 nM). Finally, Serp2 was tested for the ability to replace CrmA and inhibit apoptosis in LLC-PK1 cells infected with a CPV recombinant deleted for CrmA but expressing Serp2. Unlike wild-type-CPV-infected cells, apoptosis was readily observed in cells infected with the recombinant virus, as indicated by the induction of both nuclear fragmentation and caspase-mediated cleavage of DEVD-AMC [acetyl-Asp-Glu-Val-Asp-(amino-4-methyl coumarin)]. These results indicate that Serp2 is unable to functionally substitute for CrmA within the context of CPV and that the inhibition spectra for Serp2 and CrmA are distinct.     

Molecular ordering of the caspase activation cascade initiated by the cytotoxic T lymphocyte/natural killer (CTL/NK) protease granzyme B

Granzyme B is a major cytotoxic T lymphocyte/natural killer (CTL/NK) granule protease that can activate members of the caspase family of cysteine proteases through processing of caspase zymogens. However, the molecular order and relative importance of caspase activation events that occur in target cells during granzyme B-initiated apoptosis has not been established. Here, we have examined the hierarchy of granzyme B-initiated caspase activation events using a cell-free system where all caspases are present at physiological levels. We show that granzyme B initiates a two-tiered caspase activation cascade involving seven caspases, where caspase-3 is required for the second tier of caspase activation events. Using a two-dimensional gel-based proteomics approach we have also examined the scale of granzyme B-initiated alterations to the proteome in the presence or absence of effector caspase-3 or -7. These studies indicate that granzyme B targets a highly restricted range of substrates and orchestrates cellular demolition largely through activation of caspase-3.     

Analysis of protein processing by N-terminal proteomics reveals novel species-specific substrate determinants of granzyme B orthologs

Using a targeted peptide-centric proteomics approach, we performed in vitro protease substrate profiling of the apoptotic serine protease granzyme B resulting in the delineation of more than 800 cleavage sites in 322 human and 282 mouse substrates, encompassing the known substrates Bid, caspase-7, lupus La protein, and fibrillarin. Triple SILAC (stable isotope labeling by amino acids in cell culture) further permitted intra-experimental evaluation of species-specific variations in substrate selection by the mouse or human granzyme B ortholog. For the first time granzyme B substrate specificities were directly mapped on a proteomic scale and revealed unknown cleavage specificities, uncharacterized extended specificity profiles, and macromolecular determinants in substrate selection that were confirmed by molecular modeling. We further tackled a substrate hunt in an in vivo setup of natural killer cell-mediated cell death confirming in vitro characterized granzyme B cleavages next to several other unique and hitherto unreported proteolytic events in target cells.     

The novel serpin endopin 2 demonstrates cross-class inhibition of papain and elastase: localization of endopin 2 to regulated secretory vesicles of neuroendocrine chromaffin cells

This study demonstrates that endopin 2 is a unique secretory vesicle serpin that displays cross-class inhibition of cysteine and serine proteases, indicated by effective inhibition of papain and elastase, respectively. Homology of the reactive site loop (RSL) domain of endopin 2, notably at P1-P1' residues, with other serpins that inhibit cysteine and serine proteases predicted that endopin 2 may inhibit similar proteases. Recombinant N-His-tagged endopin 2 inhibited papain and elastase with second-order rate constants (k(ass)) of 1.4 x 10(6) and 1.7 x 10(5) M(-1) s(-1), respectively. Endopin 2 formed SDS-stable complexes with papain and elastase, a characteristic property of serpins. Interactions of the RSL domain of endopin 2 with papain and elastase were indicated by cleavage of endopin 2 near the predicted P1-P1' residues by these proteases. Endopin 2 did not inhibit the cysteine protease cathepsin B, or the serine proteases chymotrypsin, trypsin, plasmin, and furin. Endopin 2 in neuroendocrine chromaffin cells was colocalized with the secretory vesicle component (Met)enkephalin by confocal immunonfluorescence microscopy, and was present in isolated secretory vesicles (chromaffin granules) from chromaffin cells as a glycoprotein of 72-73 kDa. Moreover, regulated secretion of endopin 2 from chromaffin cells was induced by nicotine and KCl depolarization. Overall, these results demonstrate that the serpin endopin 2 possesses dual specificity for inhibiting both papain-like cysteine and elastase-like serine proteases. These findings demonstrate that endopin 2 inhibitory functions may occur in the regulated secretory pathway.     

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

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

Granzyme M mediates a novel form of perforin-dependent cell death

Cell death is mediated by cytotoxic lymphocytes through various granule serine proteases released with perforin. The unique protease activity, restricted expression, and distinct gene locus of granzyme M suggested this enzyme might have a novel biological function or trigger a novel form of cell death. Herein, we demonstrate that in the presence of perforin, the protease activity of granzyme M rapidly and effectively induces target cell death. In contrast to granzyme B, cell death induced by granzyme M does not feature obvious DNA fragmentation, occurs independently of caspases, caspase activation, and perturbation of mitochondria and is not inhibited by overexpression of Bcl-2. These data raise the likelihood that granzyme M represents a third major and specialized perforin-dependent cell death pathway that plays a significant role in death mediated by NK cells.     

Granzyme A binding to target cell proteins. Granzyme A binds to and cleaves nucleolin in vitro.

The physiologic substrates of cytotoxic T lymphocyte granule-associated serine esterases (referred to hereafter as proteases or "granzymes"), and the role of these enzymes in cell-mediated activity remain unclear. We have developed an assay for possible ligands of the trypsin-like dimeric serine protease granzyme A based on Western immunoblotting techniques. This protein-binding assay demonstrates the selective binding of granzyme A to several proteins present in the target cell P815. The binding specificity is preserved when enzyme binding is performed in the presence of excess competing proteins, including such cationic species as lysozyme and RNase. Enzyme binding is inhibited, however, by heat or detergent inactivation of granzyme A. Subcellular fractionation of target cells shows that the nuclear fraction contains most granzyme A binding reactivity, which is recovered in the nuclear salt wash fraction. A protein with Mr = 100,000 and two closely migrating proteins with Mr = 35,000 and 38,000 are the predominant reactive moieties, and the N-terminal sequence of the 100-kDa protein confirmed that this protein was murine nucleolin. Incubation of granzyme A with nucleolin generates a discrete proteolytic cleavage product of Mr = 88,000. Since nucleolin is known to shuttle between nucleus and cytoplasm, the interaction of granzyme A and nucleolin may be important in the process of apoptosis which accompanies cytotoxic T lymphocyte-mediated lysis of target cells.