Recombinant human cathepsin X is a carboxymonopeptidase only: a comparison with cathepsins B and L

The S1 and S2 subsite specificity of recombinant human cathepsins X was studied using fluorescence resonance energy transfer (FRET) peptides with the general sequences Abz-Phe-Xaa-Lys(Dnp)-OH and Abz-Xaa-Arg-Lys(Dnp)-OH, respectively (Abz=ortho-aminobenzoic acid and Dnp=2,4-dinitrophenyl; Xaa=various amino acids). Cathepsin X cleaved all substrates exclusively as a carboxymonopeptidase and exhibited broad specificity. For comparison, these peptides were also assayed with cathepsins B and L. Cathepsin L hydrolyzed the majority of them with similar or higher catalytic efficiency than cathepsin X, acting as an endopeptidase mimicking a carboxymonopeptidase (pseudo-carboxymonopeptidase). In contrast, cathepsin B exhibited poor catalytic efficiency with these substrates, acting as a carboxydipeptidase or an endopeptidase. The S1' subsite of cathepsin X was mapped with the peptide series Abz-Phe-Arg-Xaa-OH and the enzyme preferentially hydrolyzed substrates with hydrophobic residues in the P1' position.     

Fluorogenic peptide substrates for carboxydipeptidase activity of cathepsin B

Cathepsin B is a lysosomal cysteine protease exhibiting mainly dipeptidyl carboxypeptidase activity, which decreases dramatically above pH 5.5, when the enzyme starts acting as an endopeptidase. Since the common cathepsin B assays are performed at pH 6 and do not distinguish between these activities, we synthesized a series of peptide substrates specifically designed for the carboxydipeptidase activity of cathepsin B. The amino-acid sequences of the P(5)-P(1) part of these substrates were based on the binding fragments of cystatin C and cystatin SA, the natural reversible inhibitors of papain-like cysteine protease. The sequences of the P'(1)-P'(2) dipeptide fragments of the substrates were chosen on the basis of the specificity of the S'(1)-S'(2) sites of the cathepsin B catalytic cleft. The rates of hydrolysis by cathepsin B and papain, the archetypal cysteine protease, were monitored by a continuous fluorescence assay based on internal resonance energy transfer from an Edans to a Dabcyl group. The fluorescence energy donor and acceptor were attached to the C- and the N-terminal amino-acid residues, respectively. The kinetics of hydrolysis followed the Michaelis-Menten model. Out of all the examined peptides Dabcyl-R-L-V-G-F- E(Edans) turned out to be a very good substrate for both papain and cathepsin B at both pH 6 and pH 5. The replacement of Glu by Asp turned this peptide into an exclusive substrate for cathepsin B not hydrolyzed by papain. The substitution of Phe by Nal in the original substrate caused an increase of the specificity constant for cathepsin B at pH 5, and a significant decrease at pH 6. The results of kinetic studies also suggest that Arg in position P(4) is not important for the exopeptidase activity of cathepsin B, and that introducing Glu in place of Val in position P(2) causes an increase of the substrate preference towards this activity.     

Lysosomal peptidases and glycosidases in rheumatoid arthritis

Lysosomal serine and cysteine proteases are reported to play a role in collagen degradation. In this study, the activities of the lysosomal cysteine proteases cathepsin B and H, dipeptidyl peptidase I, and the serine protease tripeptidyl peptidase I and dipeptidyl peptidase II, all ascribed a role in collagen digestion, were compared with those of the aspartate protease cathepsin D, and lysosomal glycosidases in leukocytes from rheumatoid arthritis patients at different stages of the disease. In all patients the activities of cysteine protease cathepsin B, dipeptidyl peptidase I, aspartate protease cathepsin D, and two glycosidases were elevated, but the activities of the serine proteases tripeptidyl peptidase I, dipeptidyl peptidase II, and the cysteine protease cathepsin H was unchanged. The magnitude of the increased activity was correlated with the duration of the disease. Patients with long-standing RA (10 years or more) had higher cysteine protease activity in their leukocytes than did those with disease of shorter duration. This tendency suggests that elevated lysosomal cysteine protease activities, together with aspartate protease cathepsin D and lysosomal glycosidases (but not serine proteases), are associated with progression of rheumatoid arthritis.     

The major excreted protein (MEP) of transformed mouse cells and cathepsin L have similar protease specificity

The major excreted protein of transformed mouse cells is an acid activable cysteine protease. In this paper, oxidized insulin B chain is shown to be a substrate for this protease. By isolation and analysis of the insulin B peptides generated by the protease, the bond specificity of this protease was determined. The bonds preferentially cleaved are glu13-ala14, leu17-val18, and tyr26-thr27. No obvious preference for a specific amino acid was found in these studies. The bond specificity of this cysteine protease for oxidized insulin B chain has been compared with that of other proteases, and it is the same as that reported for cathepsin L, suggesting that the major excreted protein and cathepsin L may be the same protein.     

Synthesis and hydrolysis by cysteine and serine proteases of short internally quenched fluorogenic peptides

We developed sensitive substrates for cysteine proteases and specific substrates for serine proteases based on short internally quenched fluorescent peptides, Abz-F-R-X-EDDnp, where Abz (ortho-aminobenzoic acid) is the fluorescent donor, EDDnp [N-(ethylenediamine)-2,4-dinitrophenyl amide] is the fluorescent quencher, and X are natural amino acids. This series of peptides is compared to the commercially available Z-F-R-MCA, where Abz and X replace carbobenzoxy (Z) and methyl-7-aminocoumarin amide (MCA), respectively; and EDDnp can be considered a P(2)' residue. Whereas MCA is the fluorescent probe and cannot be modified, in the series Abz-F-R-X-EDDnp the amino acids X give the choice of matching the specificity of the S(1)' enzyme subsite, increasing the substrate specificity for a particular protease. All Abz-F-R-X-EDDnp synthesized peptides (for X = Phe, Leu, Ile, Ala, Pro, Gln, Ser, Lys, and Arg) were assayed with papain, human cathepsin L and B, trypsin, human plasma, and tissue kallikrein. Abz-F-R-L-EDDnp was the best substrate for papain and Abz-F-R-R-EDDnp or Abz-F-R-A-EDDnp was the more susceptible to cathepsin L. Abz-F-R-L-EDDnp was able to detect papain in the range of 1 to 15 pM. Human plasma kallikrein hydrolyzed Abz-F-R-R-EDDnp with significant efficiency (k(cat)/K(m) = 1833 mM(-1) s(-1)) and tissue kallikrein was very selective, hydrolyzing only the peptides Abz-F-R-A-EDDnp (k(cat)/K(m) = 2852 mM(-1) s(-1)) and Abz-F-R-S-EDDnp (k(cat)/K(m) = 4643 mM(-1) s(-1)). All Abz-F-R-X-EDDnp peptides were resistant to hydrolysis by thrombin and activated factor X.     

Papain-like lysosomal cysteine proteases and their inhibitors: drug discovery targets?

Papain-like lysosomal cysteine proteases are processive and digestive enzymes that are expressed in organisms from bacteria to humans. Increasing knowledge about the physiological and pathological roles of cysteine proteases is bringing them into the focus of drug discovery research. These proteases have rather short active-site clefts, comprising three well defined substrate-binding subsites (S2, S1 and S1') and additional broad binding areas (S4, S3, S2' and S3'). The geometry of the active site distinguishes cysteine proteases from other protease classes, such as serine and aspartic proteases, which have six and eight substrate-binding sites respectively. Exopeptidases (cathepsins B, C, H and X), in contrast with endopeptidases (such as cathepsins L, S, V and F), possess structural features that facilitate the binding of N- and C-terminal groups of substrates into the active-site cleft. Other than a clear preference for free chain termini in the case of exopeptidases, the substrate-binding sites exhibit no strict specificities. Instead, their subsite preferences arise more from the specific exclusion of substrate types. This presents a challenge for the design of inhibitors to target a specific cathepsin: only the cumulative effect of an assembly of inhibitor fragments will bring the desired result.     

Protein kinase C-alpha and -delta are required for NADPH oxidase activation in WKYMVm-stimulated IMR90 human fibroblasts

Gene duplications in rodents have given rise to a family of proteases that are expressed exclusively in placenta. To define the biological role of these enzymes specific inhibitors are needed to differentiate their activities from other more ubiquitously expressed proteases, such as cathepsins B and L. Libraries of peptidyl inhibitors based upon a 4-cyclohexanone pharmacophore were screened for inhibition of cathepsins P, L, and B. The tightest binding dipeptidyl inhibitor for cathepsin P contained Tyr in P(2) and Trp in P(2)('), consistent with the specificity of this enzyme for hydrophobic amino acids at these sites in synthetic substrates. An inhibitor containing Trp in both P(2) and P(2)(') provided better discrimination between cathepsin P and cathepsins B and L. Extension of the inhibitors to include P(3), and P(3)(') amino acids identified an inhibitor with Trp in P(2), P(2)('), and P(3), and Phe in P(3)(') that bound to cathepsin P with a K(i) of 32 nM. This specificity for inhibitors with hydrophobic aromatic amino acids in these four positions is unique among the lysosomal cysteine proteases. This inhibitor bound to cathepsin P an order of magnitude tighter than to mouse and human cathepsin L and two orders of magnitude tighter than to human cathepsin B. Cbz-Trp-Trp-4-cyclohexanone-Trp-Phe-OMe can discriminate cathepsin P from cathepsins B and L and consequently can be used to specifically inhibit and identify cathepsin P in cellular systems.     

Specificity of human cathepsin S determined by processing of peptide substrates and MHC class II-associated invariant chain

Cathepsin S (CatS) is a lysosomal cysteine protease of the papain family, the members of which possess relatively broad substrate specificities. It has distinct roles in major histocompatibility complex (MHC) class II-associated peptide loading and in antigen processing in both the MHC class I and class II pathways. It may therefore represent a target for interference with antigen presentation, which could be of value in the therapy of (auto)immune diseases. To obtain more detailed information on the specificity of CatS, we mapped its cleavage site preferences at subsites S3-S1' by in vitro processing of a peptide library. Only five amino acid residues at the substrate's P2 position allowed for cleavage by CatS under time-limited conditions. Preferences for groups of amino acid residues were also observed at positions P3, P1 and P1'. Based on these results, we developed highly CatS-sensitive peptides. After processing of MHC class II-associated invariant chain (Ii), a natural protein substrate of CatS, we identified CatS cleavage sites in Ii of which a majority matched the amino acid residue preference data obtained with peptides. These observed cleavage sites in Ii might be of relevance for its in vivo processing by CatS.     

High throughput substrate specificity profiling of serine and cysteine proteases using solution-phase fluorogenic peptide microarrays

Proteases regulate numerous biological processes with a degree of specificity often dictated by the amino acid sequence of the substrate cleavage site. To map protease/substrate interactions, a 722-member library of fluorogenic protease substrates of the general format Ac-Ala-X-X-(Arg/Lys)-coumarin was synthesized (X=all natural amino acids except cysteine) and microarrayed with fluorescent calibration standards in glycerol nanodroplets on glass slides. Specificities of 13 serine proteases (activated protein C, plasma kallikrein, factor VIIa, factor IXabeta, factor XIa and factor alpha XIIa, activated complement C1s, C1r, and D, tryptase, trypsin, subtilisin Carlsberg, and cathepsin G) and 11 papain-like cysteine proteases (cathepsin B, H, K, L, S, and V, rhodesain, papain, chymopapain, ficin, and stem bromelain) were obtained from 103,968 separate microarray fluorogenic reactions (722 substrates x 24 different proteases x 6 replicates). This is the first comprehensive study to report the substrate specificity of rhodesain, a papain-like cysteine protease expressed by Trypanasoma brucei rhodesiense, a parasitic protozoa responsible for causing sleeping sickness. Rhodesain displayed a strong P2 preference for Leu, Val, Phe, and Tyr in both the P1=Lys and Arg libraries. Solution-phase microarrays facilitate protease/substrate specificity profiling in a rapid manner with minimal peptide library or enzyme usage.     

Interdependency of sequence and positional specificities for cysteine proteases of the papain family

The specificity of cysteine proteases is characterized by the nature of the amino acid sequence recognized by the enzymes (sequence specificity) as well as by the position of the scissile peptide bond (positional specificity, i.e., endopeptidase, aminopeptidase, or carboxypeptidase). In this paper, the interdependency of sequence and positional specificities for selected members of this class of enzymes has been investigated using fluorogenic substrates where both the position of the cleavable peptide bond and the nature of the sequence of residues in P2-P1 are varied. The results show that cathepsins K and L and papain, typically considered to act strictly as endopeptidases, can also display dipeptidyl carboxypeptidase activity against the substrate Abz-FRF(4NO2)A and dipeptidyl aminopeptidase activity against FR-MCA. In some cases the activity is even equal to or greater than that observed with cathepsin B and DPP-I (dipeptidyl peptidase I), which have been characterized previously as exopeptidases. In contrast, the exopeptidase activities of cathepsins K and L and papain are extremely low when the P2-P1 residues are A-A, indicating that, as observed for the normal endopeptidase activity, the exopeptidase activities rely heavily on interactions in subsite S2 (and possibly S1). However, cathepsin B and DPP-I are able to hydrolyze substrates through the exopeptidase route even in absence of preferred interactions in subsites S2 and S1. This is attributed to the presence in cathepsin B and DPP-I of specific structural elements which serve as an anchor for the C- or N-terminus of a substrate, thereby allowing favorable enzyme-substrate interaction independently of the P2-P1 sequence. As a consequence, the nature of the residue at position P2 of a substrate, which is usually the main factor determining the specificity for cysteine proteases of the papain family, does not have the same contribution for the exopeptidase activities of cathepsin B and DPP-I.     

Cathepsin B-related proteases in the insulin secretory granule

The distribution of proteases potentially reactive with peptide sequences containing pairs of basic amino acids or single basic amino acids was studied in subcellular fractions of a transplantable rat insulinoma using the affinity probes 125I-Tyr-Ala-Lys- ArgCH2Cl and 125I-Tyr-Ala-norleucine- ArgCH2Cl . Both probes labeled predominantly proteins of Mr = 39,000, 31,500, and 25,000. The Mr = 25,000 component appeared to be of lysosomal origin, while the Mr = 39,000 and 31,500 proteins were present in both the lysosomes and insulin granules. The Mr = 39,000 and 31,500 proteins were identified as precursor/product forms of the cysteine protease cathepsin B, while assays performed with fluorigenic peptide substrates suggested that the Mr = 25,000 protein was probably cathepsin L and/or H. The greater reactivity of the Mr = 39,000 form with the dibasic probe suggests that the relative proportions of the Mr = 39,000 and 31,500 forms of cathepsin B in different organelles may determine the extent to which the enzyme expresses activity as a specific (prohormone processing) endopeptidase or a more general (degradative) peptidase.     

A new approach for distinguishing cathepsin E and D activity in antigen-processing organelles

Cathepsin E (CatE) and D (CatD) are the major aspartic proteinases in the endolysosomal pathway. They have similar specificity and therefore it is difficult to distinguish between them, as known substrates are not exclusively specific for one or the other. In this paper we present a substrate-based assay, which is highly relevant for immunological investigations because it detects both CatE and CatD in antigen-processing organelles. Therefore it could be used to study the involvement of these proteinases in protein degradation and the processing of invariant chain. An assay combining a new monospecific CatE antibody and the substrate, MOCAc-Gly-Lys-Pro-Ile-Leu-Phe-Phe-Arg-Leu-Lys(Dnp)-D-Arg-NH2[where MOCAc is (7-methoxycoumarin-4-yl)acetyl and Dnp is dinitrophenyl], is presented. This substrate is digested by both proteinases and therefore can be used to detect total aspartic proteinase activity in biological samples. After depletion of CatE by immunoprecipitation, the remaining activity is due to CatD, and the decrease in activity can be assigned to CatE. The activity of CatE and CatD in cytosolic, endosomal and lysosomal fractions of B cells, dendritic cells and human keratinocytes was determined. The data clearly indicate that CatE activity is mainly located in endosomal compartments, and that of CatD in lysosomal compartments. Hence this assay can also be used to characterize subcellular fractions using CatE as an endosomal marker, whereas CatD is a well-known lysosomal marker. The highest total aspartic proteinase activity was detected in dendritic cells, and the lowest in B cells. The assay presented exhibits a lower detection limit than common antibody-based methods without lacking the specificity.     

Kininogen-derived peptides for investigating the putative vasoactive properties of human cathepsins K and L.

Macrophages at an inflammatory site release massive amounts of proteolytic enzymes, including lysosomal cysteine proteases, which colocalize with their circulating, tight-binding inhibitors (cystatins, kininogens), so modifying the protease/antiprotease equilibrium in favor of enhanced proteolysis. We have explored the ability of human cathepsins B, K and L to participate in the production of kinins, using kininogens and synthetic peptides that mimic the insertion sites of bradykinin on human kininogens. Although both cathepsins processed high-molecular weight kininogen under stoichiometric conditions, only cathepsin L generated significant amounts of immunoreactive kinins. Cathepsin L exhibited higher specificity constants (kcat/Km) than tissue kallikrein (hK1), and similar Michaelis constants towards kininogen-derived synthetic substrates. A 20-mer peptide, whose sequence encompassed kininogen residues Ile376 to Ile393, released bradykinin (BK; 80%) and Lys-bradykinin (20%) when incubated with cathepsin L. By contrast, cathepsin K did not release any kinin, but a truncated kinin metabolite BK(5-9) [FSPFR(385-389)]. Accordingly cathepsin K rapidly produced BK(5-9) from bradykinin and Lys-bradykinin, and BK(5-8) from des-Arg9-bradykinin, by cleaving the Gly384-Phe385 bond. Data suggest that extracellular cysteine proteases may participate in the regulation of kinin levels at inflammatory sites, and clearly support that cathepsin K may act as a potent kininase.     

Proteolytic cleavage of ricin A chain in endosomal vesicles. Evidence for the action of endosomal proteases at both neutral and acidic pH

Macrophages actively internalize macromolecules into endosomal vesicles containing proteases. The plant toxin, ricin A chain delivered into this pathway by receptor-mediated endocytosis, was found to be exquisitely sensitive to cleavage by these proteases. Proteolytic fragments of ricin A chain were generated within cells as early as 2-3 min after internalization. Toxin proteolysis was initiated in early endosomal vesicles, and transport to lysosomes was not required. As endosomes transit the cell, their lumenal pH drops from neutral to acidic. Previous studies in macrophages had suggested that endosomal proteolysis is dependent on vesicle acidification. Isolated endosomal vesicles containing ricin A chain catalyzed the cleavage of this protein in vitro; however, proteolysis was observed at both neutral and acidic pH. Experiments using isolated endosomes demonstrated that both cysteine and aspartyl proteases were responsible for the cleavage of ricin A chain. The cysteine protease, cathepsin B, catalyzed toxin proteolysis in endosomes between pH 4.5 and 7.0 while aspartyl protease activity was maximal below pH 5.5. Radiolabeling the lumenal contents of macrophage endosomes confirmed that both the cysteine protease, cathepsin B, and the aspartyl protease, cathepsin D, were present in these vesicles. These proteases were not present on the plasma membrane but were found in early endosomes indicating they are derived from an intracellular source. The presence of proteases with different pH optima in early endosomes suggests that processing in these vesicles may be regulated by changes in endosomal pH. This result represents an important difference in protein processing in endosomes versus lysosomes and provides new insights into the function of endosomal proteases.     

Purification of an endopeptidase from bovine adrenal medulla granules which cleaves in vitro at paired but not at single basic residues

An endopeptidase was isolated from bovine adrenomedullary granules by fast protein liquid chromatography, including two ion exchange, one hydrophobic interaction, and one gel filtration step. The enzyme assay was based on the HPLC detection of the degradation of the dodecapeptide BAM 12P from the sequence of proenkephalin. After a 1200-fold purification, the enzyme fraction was homogeneous on polyacrylamide gel electrophoresis. The apparent molecular weight of the monomeric protein was 68,000 and its pH optimum was 5.6, in agreement with the internal pH of the granules. The specificity of the protease was determined initially by analysis of the degradation fragments of BAM 12P which showed that cleavage occurred at the double but not at the single Arg site of BAM 12P. The cleavage pattern of other substrates showed that the enzyme also recognized other pairs of basic amino acids. The behavior of the enzyme toward specific inhibitors showed that it was an acid thiol protease different from serine proteases and from lysosomal cathepsin B. The endopeptidase may act as a maturation enzyme in vivo.     

An activity-based probe for the determination of cysteine cathepsin protease activities in whole cells

We describe a novel diazomethylketone-containing irreversible inhibitor (BIL-DMK) which is specific for a subset of pharmaceutically important cysteine cathepsin proteases. BIL-DMK rapidly inactivates cathepsins B, F, K, L, S, and V in isolated enzyme assays and labels cathepsins in whole cells. The presence of catalytically active cathepsins B, L, and K or S was demonstrated using radioiodinated BIL-DMK in HepG2 (hepatoma), HIG82 (rabbit synoviocyte), and Ramos (B lymphoma) cell lines, respectively. The identity of each protein labeled was confirmed from the isoelectric point and molecular mass of the radioactive spots on two-dimensional gel and by comigration with each cathepsin as identified by immunoblotting. These cell lines were used to establish whole-cell enzyme occupancy assays to determine the potency of both irreversible and reversible inhibitors against each cathepsin in their native cellular lysosomal or endosomal environment. These whole-cell enzyme occupancy assays are useful to determine the cellular permeability of competing inhibitors and have the advantage of not requiring specific substrates for each cathepsin of interest.     

Digestive proteolytic activity in the pistachio green stink bug,Brachynema germari Kolenati (Hemiptera: Pentatomidae)

Proteolytic activity in the digestive system of the pistachio green stink bug, Brachynema germari, was investigated. The maximum total proteolytic activity in the midgut extract was observed at pH 5, suggesting the presence of cysteine proteases. Hydrolyzing the specific substrates for cysteine proteases revealed the presence of cathepsin B and cathepsin L activities in the midgut extract. The presence of cysteine proteases was confirmed by their noticeable inhibition and activation due to specific inhibitors and activators, respectively. The significant inhibition of chymotryptic activity by the inhibitors showed the presence of chymotrypsin in the midgut. No considerable tryptic activity was observed in the midgut extract. There was no detectable total proteolytic activity in the salivary gland extract. Tryptic activity of the salivary gland extract was also inhibited by the specific inhibitors. The substrates for cysteine proteases were also slightly hydrolyzed by the salivary gland extract. Zymogram analysis showed at least one distinct band due to cysteine protease activity in the midgut extract, and the cysteine protease inhibitor caused almost complete disappearance of the band. Cathepsin B and L activities were mainly detected in midgut divisions m₁ and m₃, respectively, and maximum chymotrypsin and trypsin activities were observed in m₃. In general, the results revealed the significant presence of cathepsin B, cathepsin L, and chymotrypsin proteases in the midgut extract. The major proteolytic activity in the salivary glands seems to be conducted by trypsin-like proteases.     

Positional-scanning combinatorial libraries of fluorescence resonance energy transfer peptides to define substrate specificity of carboxydipeptidases: assays with human cathepsin B

We have developed positional scanning synthetic combinatorial libraries to define the substrate specificity of carboxydipeptidases. The library Abz-GXXZXK(Dnp)-OH, where Abz is ortho-aminobenzoic acid, K(Dnp) is N^ε-2,4-dinitrophenyl-lysine with free carboxyl group, the Z position was successively occupied with 1 of 19 amino acids (cysteine was omitted), and X represents randomly incorporated residues, was assayed initially with human cathepsin B, and arginine was defined as one of the best residues at the P₁ position. To examine the selectivity of , S₂, and S₃ subsites, the sublibraries Abz-GXXRZK(Dnp)-OH, Abz-GXZRXK(Dnp)-OH, and Abz-GZXRXK(Dnp)-OH were then synthesized. The peptide Abz-GIVRAK(Dnp)-OH, which contains the most favorable residues in the positions identified by screening of the libraries with cathepsin B, was hydrolyzed by this enzyme with k_cat/K_m = 7288 mM⁻¹ s⁻¹. This peptide is the most efficient substrate described for cathepsin B to this point, and it is highly selective for the enzyme among the lysosomal cysteine proteases.     

Characterization of an endopeptidase of Trypanosoma brucei brucei.

A soluble 80-kDa endopeptidase has been isolated from Trypanosoma brucei brucei. The enzyme, which has a pI 5.1, is optimally active at about pH 8.2 and has apparent pKa values of 6.0 and greater than or equal to 10. It is inhibited by the serine protease inhibitor diisopropylfluorophosphate and by the serine protease mechanism-based inhibitor 3,4-dichloroisocoumarin. Unexpectedly, the enzyme is inhibited by the cysteine protease inhibitor benzyloxycarbonyl-Leu-Lys-CHN2 but not by the related diazomethane, butoxycarbonyl-Val-Leu-Gly-Lys-CHN2, nor by other cysteine protease specific compounds. Specificity studies with a variety of amidomethylcoumaryl (AMC) derivatives of small peptides show that the enzyme has a highly restricted trypsin-like specificity. The best substrate, based on the magnitude of kcat/Km, was benzyloxycarbonyl-Arg-Arg-AMC; other good substrates were benzyloxycarbonyl-Phe-Arg-AMC, benzoyl-Arg-AMC, and compounds with Arg at P1 and Ala or Gly at P2. The hydrolysis of most substrates obeyed classical Michaelis-Menton kinetics but several exhibited pronounced substrate inhibition. The enzyme did not activate plasminogen nor decrease blood clotting time; it was inhibited by aprotinin but not by chicken ovomucoid. We conclude that the enzyme is a trypsin-like serine endopeptidase with unusually restricted subsite specificities.     

Lysosomal cathepsins B, L, and D in the development of murine experimental leukemias

Lysosomal proteases are actively involved into pathogenesis of malignant tumors. Impairments in the interaction between proteases and their inhibitors are implicated in the processes of tumor invasion and metastasis. Among proteases associated with malignant growth, cysteine cathepsins B and L and aspartic cathepsin D are considered to play the major role in the tumor development. The present study was designed to investigate the activity of cathepsins B, L, and D during the development and treatment of murine experimental leukemias and to determine correlation between these proteases and course of pathological process as well as efficiency of the chemotherapeutic treatment. P-388 leukemia was characterized by a more aggressive development and unfavorable prognosis than L1210/1 leukemia. In mice with P-388 leukemia the activity of lysosomal cathepsins B, D, and L in the tumor tissue, liver and spleen, as well as the activity of cathepsins B and L in serum were lower than activities of these enzymes in mice with L1210/1 leukemia. Changes in the activity of cathepsins in liver and spleen of leukemic mice reflected a level of aggressiveness of the tumor development and invasion of these organs with tumor cells. Treatment of these experimental leukemias resulted in the increase of cathepsin B, L and D activity in the tumor tissue, liver, spleen and the increase in cathepsin B and L activity in serum. The highest protease activity was detected in the groups of mice characterized by the highest inhibition of the tumor growth. These data demonstrate that lysosomal proteases are involved in the progression of murine experimental leukemias and elimination of tumor cells in the result of treatment. Thus, determination of the activity of cysteine and aspartic proteases can be used for evaluation of cancer malignancy, tumor sensitivity for chemotherapy and efficiency of treatment.