Inhibition of the activation of multiple serine proteases with a cathepsin C inhibitor requires sustained exposure to prevent pro-enzyme processing

Cathepsin C is a cysteine protease required for the activation of several pro-inflammatory serine proteases and, as such, is of interest as a therapeutic target. In cathepsin C-deficient mice and humans, the N-terminal processing and activation of neutrophil elastase, cathepsin G, and proteinase-3 is abolished and is accompanied by a reduction of protein levels. Pharmacologically, the consequence of cathepsin C inhibition on the activation of these serine proteases has not been described, due to the lack of stable and non-toxic inhibitors and the absence of appropriate experimental cell systems. Using novel reversible peptide nitrile inhibitors of cathepsin C, and cell-based assays with U937 and EcoM-G cells, we determined the effects of pharmacological inhibition of cathepsin C on serine protease activity. We show that indirect and complete inhibition of neutrophil elastase, cathepsin G, and proteinase-3 is achievable in intact cells with selective and non-cytotoxic cathepsin C inhibitors, at concentrations approximately 10-fold higher than those required to inhibit purified cathepsin C. The concentration of inhibitor needed to block processing of these three serine proteases was similar, regardless of the cell system used. Importantly, cathepsin C inhibition must be sustained to maintain serine protease inhibition, because removal of the reversible inhibitors resulted in the activation of pro-enzymes in intact cells. These findings demonstrate that near complete inhibition of multiple serine proteases can be achieved with cathepsin C inhibitors and that cathepsin C inhibition represents a viable but challenging approach for the treatment of neutrophil-based inflammatory diseases.     

Processing of the human transferrin receptor at distinct positions within the stalk region by neutrophil elastase and cathepsin G

The ectodomain of the human transferrin receptor (TfR) is released as soluble TfR into the blood by cleavage within a stalk. The major cleavage site is located C-terminally of Arg-100; alternative cleavage sites are also present. Since the cleavage process is still unclear, we looked for proteases involved in TfR ectodomain release. In the supernatant of U937 histiocytic cells we detected alternatively cleaved TfR (at Glu-110). In membrane fractions of these cells we identified two distinct proteolytic activities responsible for TfR cleavage within the stalk at either Val-108 or Lys-95. Both activities could be inhibited by serine protease inhibitors, but not by inhibitors of any other class of proteases. Protein purification yielded a 28 kDa protein that generated the Val-108 terminus. The protease activity could be ascribed to neutrophil elastase according to the substrate specificity determined by amino acid substitution analysis of synthetic peptides, an inhibitor profile, the size of the protease and the use of specific antibodies. The results of analogous experiments suggest that the second activity is represented by another serine protease, cathepsin G. Thus, membrane-associated forms of neutrophil elastase and cathepsin G may be involved in alternative TfR shedding in U937 cells.     

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.     

Proteolytic regulation of the urokinase receptor/CD87 on monocytic cells by neutrophil elastase and cathepsin G

The urokinase receptor (CD87) participates to the pericellular proteolytic potential of migrating cells and to the recruitment of leukocytes during inflammation. It consists of three structurally homologous domains, with the C-terminal domain D3 attached to cell membranes through a GPI anchor. CD87 is susceptible to an endoproteolytic processing removing the N-terminal domain D1 and generating truncated D2D3 membrane species, thus modulating CD87-associated functions. Full-length or truncated CD87 can be also released from cells via juxtamembrane cleavage by phospholipases and/or by yet unidentified proteinases. Using a recombinant CD87 and the CD87-positive monocytic U937 cell line and isolated blood monocytes, we show by protein immunoblotting and flow immunocytometry that the human neutrophil serine-proteinases elastase and cathepsin G cleave CD87 within the D1-D2 linker sequence, while in addition cathepsin G is highly efficient in cleaving the C terminus of D3. The combination of cathepsin G and elastase provided by degranulated neutrophils results in enzymatic cooperation leading to the release from monocytic cells of a truncated D2D3 species resembling that previously described in pathological body fluids. Using mass spectrometry analysis, the proteolytic fragmentation of synthetic peptides mapping the D1-D2 linker and D3 C-terminal domains identifies potential cleavage sites for each enzyme and suggests the existence of a mechanism regulating the CD87(D1-D2)-associated chemotactic activity. Finally, isolated or combined elastase and cathepsin G drastically reduce the capacity of cells to bind urokinase. Secretable leukocyte serine-proteinases are thus endowed with high potential for the regulation of CD87 expression and function on inflammatory cells.     

Evaluation of Cathepsins D and G and EC 3.4.24.15 as Candidate β-Secretase Proteases Using Peptide and Amyloid Precursor Protein Substrates

Abstract: No single protease has emerged that possesses all the expected properties for β-secretase, including brain localization, appropriate peptide cleavage specificity, and the ability to cleave amyloid precursor protein exactly at the amino-terminus of β-amyloid peptide. We have isolated and purified a brain-derived activity that cleaves the synthetic peptide substrate SEVKMDAEF between methionine and aspartate residues, as required to generate the amino-terminus of β-amyloid peptide. Its molecular size of 55–60 kDa and inhibitory profile indicate that we have purified the metalloprotease EC 3.4.24.15. We have compared the sequence specificity of EC 3.4.24.15, cathepsin D, and cathepsin G for their ability to cleave the model peptide SEVKMDAEF or related peptides that contain substitutions reported to modulate β-amyloid peptide production. We have also tested the ability of these enzymes to form carboxy-terminal fragments from full-length, membrane-embedded amyloid precursor protein substrate or amyloid precursor protein that contains the Swedish KM → NL mutation. The correct cleavage was tested with an antibody specific for the free amino-terminus of β-amyloid peptide. Our results exclude EC 3.4.24.15 as a candidate β-secretase. Although cathepsin G cleaves the model peptide correctly, it displays poor ability to cleave the Swedish KM → NL peptide and does not generate carboxy-terminal fragments that are immunoreactive with amino-terminal-specific antiserum. Cathepsin D does not cleave the model peptide or show specificity for wild-type amyloid precursor protein; however, it cleaves the Swedish "NL peptide" and "NL precursor" substrates appropriately. Our results suggest that cathepsin D could act as β-secretase in the Swedish type of familial Alzheimer's disease and demonstrate the importance of using full-length substrate to verify the sequence specificity of candidate proteases.     

Various properties of cathepsin G and elastase from swine peripheral blood neutrophils

Using gel filtration through Sephadex G-100 and bioaffinity chromatography on contrical-Sepharose, cathepsin G and elastase were isolated from pig peripheral blood neutrophil granules and purified to homogeneity. Both enzymes hydrolyzed the total histone from calf thymus as well as synthetic substrates--tert-butoxy-L-alanine p-nitrophenyl ester (elastase) and benzoyltyrosine ethyl ester (cathepsin G). The use of natural and synthetic protease inhibitors showed that both enzymes were related to the group of serine proteases. The molecular mass of the cathepsin G subunit as determined by SDS polyacrylamide gel electrophoresis is 28-29 kD, that of elastase--30-31 kD. The pH optima for the hydrolysis of proteinaceous and synthetic substrates for cathepsin G and elastase are 8.0-8.5 and 7.0-7.5, respectively. The isoelectric points for elastase and cathepsin G are 9.7-10.0 and greater than 10, respectively; the temperature optima--30-40 degrees C and 50-60 degrees C, respectively. The amino acid composition of the two enzymes from pig granulocytes revealed a high content of arginine and was similar to that of human granulocytes.     

Human leukocyte elastase hydrolysis of peptides derived from human elastin exon 24

In normal and pathological tissues, polymorphonuclear leukocyte proteases (elastase, cathepsin G and proteinase 3) may generate soluble peptides through limited proteolysis of elastin, the main component of mature elastic fibres. Elastin-derived peptides display diverse biological activities including cell migration, differentiation, proliferation, chemotaxis, tumor progression and up-regulation of metalloproteinases. To be biologically active, their structures must adopt a beta-turn conformation which accommodates to the cell surface-located elastin binding protein. In this study, we established that human elastin exon 24-derived peptides are hydrolysed by leukocyte elastase, when the active site is fully occupied (from S(5) to S'(3)). As shown by mass spectrometry analyses, a major cleavage site was demonstrated at a Val-Ala bond and a minor one at Gly-Val bond. For longer peptides, the hydrolysed fragments could themselves be re-hydrolysed. If the shortest fragments do not contain the GxxPG sequence known to stimulate cellular effects, some of the intermediates together with hydrolysis fragments generated by other proteases such as proteinase 3, may possess this motif.     

Identification of proteases involved in the proteolysis of vascular endothelium cadherin during neutrophil transmigration

Transmigration of neutrophils across the endothelium occurs at the cell-cell junctions where the vascular endothelium cadherin (VE cadherin) is expressed. This adhesive receptor was previously demonstrated to be involved in the maintenance of endothelium integrity. We propose that neutrophil transmigration across the vascular endothelium goes in parallel with cleavage of VE cadherin by elastase and cathepsin G present on the surface of neutrophils. This hypothesis is supported by the following lines of evidence. 1) Proteolytic fragments of VE cadherin are released into the culture medium upon adhesion of neutrophils to endothelial cell monolayers; 2) conditioned culture medium, obtained after neutrophil adhesion to endothelial monolayers, cleaves the recombinantly expressed VE cadherin extracellular domain; 3) these cleavages are inhibited by inhibitors of elastase; 4) VE cadherin fragments produced by conditioned culture medium or by exogenously added elastase are identical as shown by N-terminal sequencing and mass spectrometry analysis; 5) both elastase- and cathepsin G-specific VE cadherin cleavage patterns are produced upon incubation with tumor necrosis factor alpha-stimulated and fixed neutrophils; 6) transendothelial permeability increases in vitro upon addition of either elastase or cathepsin G; and 7) neutrophil transmigration is reduced in vitro in the presence of elastase and cathepsin G inhibitors. Our results suggest that cleavage of VE cadherin by neutrophil surface-bound proteases induces formation of gaps through which neutrophils transmigrate.     

Dissection of laminin by cathepsin G into its long-arm and short-arm structures and localization of regions involved in calcium dependent stabilization and self-association

Native laminin-nidogen complex isolated from mouse Engelbreth-Holm-Swarm tumor was treated with purified cathepsin G or leucocyte elastase, two neutral serine proteases which play a role in inflammatory processes accompanied by degradation of basement membranes. Both enzymes were found to be more active than porcine pancreatic elastase. In the absence of Ca2+, laminin fragments produced by leucocyte elastase resembled those formed by the pancreatic enzyme but at physiological concentrations of Ca2+ cleavage by cathepsin G was much more selective. Initially laminin (900 kDa) was cleaved at two major sites only with similar rates leading to three fragments. Fragment C1-4 (about 550 kDa) comprises the intact three short arms of the molecule and fragment C8-9 (about 350 kDa) contains the entire triple-coiled region by which its three chains are assembled and the major part of the terminal globular domain of the long arm. The remaining C-terminal region of this domain was recovered as fragment C3 of about 50 kDa. Stabilization against proteolytic attack was restricted to the region of fragment C1-4 and only this fragment exhibited strong Ca2+ dependent self-association similar to that of intact laminin or of its complex with nidogen. The associative properties of fragment C1-4 were dramatically diminished upon removal of the tip of one of the short arms comprising fragment 4. In addition, this provides a clear assignment of the important laminin function to a distinct domain in one of its short arms. The new fragment C8-9 may be employed for exploring the properties and possible functions of the upper long-arm region which so far has not been available as a fragment.     

Proteases produced by activated neutrophils are able to release soluble CD23 fragments endowed with proinflammatory effects.

Polymorphonuclear neutrophils (PMNs) are the major source of proteolytic activities involved mainly in tissue injuries observed in chronic inflammatory disorders. High levels of soluble forms of CD23 (the low-affinity receptor for IgE) were found in biological fluids from these patients, and recent reports focused on a CD23-mediated regulation of inflammatory response. In this context, we show here that co-culture of activated PMN with CD23+ B cells resulted in a drastic release of soluble CD23 fragments from the cell surface. This cleavage was inhibited by serine proteases inhibitors, including a1-antitrypsin. We next demonstrated that purified human leukocyte elastase or cathepsin G efficiently cleaved membrane CD23 on B cells with a high specificity. Soluble fragments released by serine proteases-mediated CD23 proteolysis stimulated resting monocytes to produce oxidative burst and proinflammatory cytokine without any co-stimulatory signal. This work strongly supports the idea that the capacity of PMN-derived proteases to release soluble forms of CD23 participates in the inflammatory process mediated by these cells.     

The reactive site of human inter-alpha-trypsin inhibitor is in the amino-terminal half of the protein

Human inter-alpha-trypsin inhibitor has been found to inactivate human trypsin, chymotrypsin, neutrophil elastase and cathepsin G. The protein was cleaved into two major fragments without loss of activity by incubation with Serratia marcescens metalloproteinase, and these were separated by ion-exchange chromatography. Inhibitory activity was found in only one of the fragments, the amino-terminal sequence of which was found to be identical with that of the native protein, as well as with that reported earlier for the urinary trypsin inhibitor. It may thus be concluded that the reactive site of the inter-alpha-trypsin inhibitor is located in the amino-terminal region.     

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).     

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.     

Secretion, cleavage and binding of complement component C3 by the human monocytic cell line U937.

Secretion of complement component C3 by U937 cells was studied. Preliminary evidence for a cell-associated proteolytic activity specific for C3 is given, as well as for a covalent-like binding of C3 fragments to the cell membranes. Secretion of C3, in the presence of 10 ng of phorbol 12-myristate 13-acetate/ml, is 120-140 ng/10(6) cells per 24 h on the third day after addition of the activator. As shown by SDS/polyacrylamide-gel electrophoresis, the intracellular pro-C3 (200 kDa) and the extracellular secreted C3 (alpha-chain 110 kDa and beta-chain 75 kDa) are identical with the forms of C3 previously characterized from human serum. Incubation of U937 cells in the presence of exogenous radiolabelled C3 shows that membrane-bound proteinase(s), not related to the classical-pathway or the alternative-pathway C3 convertases, is (are) able to cleave C3; this cleavage leads to the binding of the resulting C3 fragments to the cell membrane through reaction of membrane acceptors with the carbonyl group of C3 revealed after disruption of the intramolecular thioester bond. The proteolysis appears to be fairly specific to C3, as C4, which also possesses an intramolecular thioester bond, is not cleaved and does not bind to the cells. p-Nitrophenyl p'-guanidinobenzoate (1 mM) and di-isopropyl phosphorofluoridate (2 mM) are potent inhibitors of the proteolysis, whereas soya-bean trypsin inhibitor (1 mM), leupeptin (0.1 mg/ml) and 1,10-phenanthroline (1 mM) were ineffective. Immunological characterization of the cell-bound C3 fragments with monoclonal antibodies shows an evolution of the proteolysis of the fragments from iC3b to C3dg epitopes. Extraction of membrane-bound fragments by detergent, followed by SDS/polyacrylamide-gel electrophoresis, shows two fragments, of 43 kDa and 46 kDa, with C3dg-like characteristics.     

Limited proteolysis of T-kininogen (thiostatin). Release of comparable fragments by different endopeptidases

Limited proteolysis of T-kininogen by heterologous and homologous endopeptidases (bovine trypsin, human leukocyte elastase, rat submaxillary gland endopeptidase k, and rat mast cell chymase) produced similar fragmentation. Amino-terminal sequence analysis of whole T-kininogen lysates and purified proteolytic fragments identified four susceptible regions which contained all the preferential cleavage sites for these proteinases. Two of these susceptible regions were close to the junction between heavy chain cystatin-like domains, the third was in the kinin-containing region, and the fourth was close to the carboxyl terminus of the T-kininogen light chain. There was only one primary site for each proteinase in the kinin-containing region, which explains why catalytic amounts of these proteinases did not release immunoreactive kinin from this kininogen. However, preferential cleavage of T-kininogen close to the junction between cystatin-like domains released fragments which, provided they included cystatin-like domains 2 and/or 3, strongly inhibited papain and cathepsin L. The fragments were inhibitory even when parts of the amino-terminal ends of the domains were lacking. The highly conserved glycyl residue, thought to be involved in the inhibitory reactive site of cystatin-like inhibitors, was not required in purified domain 3 for inhibition of cathepsin L.     

Evidence for a crucial role of neutrophil-derived serine proteases in the inactivation of interleukin-6 at sites of inflammation

The bioactivity of interleukin-6 (IL-6) was found to be dramatically reduced in fluids from sites of inflammation. Here, we provide evidence that the neutrophil-derived serine proteases elastase, proteinase 3 and cathepsin G are mainly involved in its degradation and subsequent inactivation. The initially hydrolyzed peptide bonds were detected to be Val(11)-Ala(12) and Leu(19)-Thr(20) (elastase), Phe(78)-Asn(79) (cathepsin G) and Ala(145)-Ser(146) (proteinase 3). The soluble IL-6 receptor elicits a protective effect against the IL-6 inactivation by cathepsin G only. The inactivation of IL-6 by neutrophil-derived serine proteases might act as a feedback mechanism terminating the IL-6-induced activation of neutrophils.     

Purification of human leukocyte elastase and cathepsin G by chromatography on immobilized elastin

Human leukocyte elastase and cathepsin G were isolated from purulent sputum by a simple procedure involving chromatography on elastin-agarose. Salt extracts of sputum were prepared, treated with DNase, and the precipitate which formed extracted and applied to a column of soluble elastin-Sepharose 4B. Contaminating protein was eluted with 50 mM Tris, 50 mM NaCl, pH 8.0 and then two column volumes of 50 mM acetate, 1.0 M NaCl, pH 5.0. The tightly bound elastase and cathepsin G together with a trypsin-like serine protease could finally be eluted with 50 mM acetate, 1.0 M NaCl, 20% DMSO, pH 5.0. Resolution of the proteases was accomplished by cation-exchange chromatography. Disc gel electrophoresis established the purity of elastase and cathepsin G and confirmed the existence of several isozymes for each.     

The novel bovine serpin endopin 2C demonstrates selective inhibition of the cysteine protease cathepsin L compared to the serine protease elastase, in cross-class inhibition

Molecular cloning revealed the unique serpin endopin 2C that demonstrates selective inhibition of cathepsin L compared to papain or elastase. Endopin 2C, thus, functions as a serpin with the property of cross-class inhibition. Endopin 2C possesses homology in primary sequence to endopin 2A and other isoforms of endopins related to alpha1-antichymotrypsin, yet endopin 2C differs in its target protease specificity. Recombinant endopin 2C showed effective inhibition of cathepsin L with a stoichiometry of inhibition (SI) of 1/1 (molar ratio of inhibitor/protease), with the second-order rate constant, k(ass), of 7.2 x 10(5) M(-1) s(-1). Less effective endopin 2C inhibition of papain and elastase occurred with k(ass) association rate constants of approximately 1 x 10(4) M(-1) s(-1) with high SI values. Endopin 2C formed SDS-stable complexes with cathepsin L, papain, and elastase that are typical of serpins. These results are among the first to demonstrate stable serpin complexes with target cysteine proteases. Interactions of endopin 2C with cathepsin L and elastase were indicated by protease cleavage of the RSL region between P1-P1' residues of Thr-Ser. The hydrophobic Phe residue in the P2 position of the RSL region is consistent with the specificity of cathepsin L for hydrophobic residues in the P2 position of its substrate cleavage site. The NH2-terminal signal sequence of endopin 2C, like that of cathepsin L, predicts their colocalization to subcellular organelles. These findings demonstrate endopin 2C as a novel serpin that possesses cross-class inhibition with selectivity for inhibition of cathepsin L.