Characterization of Förster resonance energy transfer in a botulinum neurotoxin protease assay

Using the cell-permeable, radioiodinated, irreversible inhibitor BIL-DMK, we probed active cysteine cathepsins in blood. Incubation of the probe in human whole blood followed by separation of white blood cells by dextran sedimentation led to the labeling of one major band at 24 kDa. Two-dimensional gel electrophoresis showed that the band resolved in a single protein spot and corresponded to cathepsin S based on its molecular mass, isoelectric point, and Western blot analysis using anti-human cathepsin S antibodies. Cathepsin S activity in human whole blood was dependent on the time of blood collection, suggesting that cathepsin S activity is subject to circadian variations. Separation of white blood cell populations using a magnetic cell sorter and further characterization by FACS (fluorescent-activated cell sorting) analysis demonstrated that the majority of active cathepsin S resided in the monocyte and neutrophil populations, whereas on a cell basis cathepsin S activity in granulocytes is 10-fold lower than that in monocytes. A whole blood cathepsin S assay was developed and used to measure cathepsin S inhibition in both in vitro and ex vivo conditions. To determine the correlation between the in vitro and ex vivo assays, a reversible cathepsin S inhibitor was dosed intravenously to a rhesus monkey. The inhibitor concentration required to inhibit 50% of the cathepsin S activity ex vivo correlated well with the concentration required to inhibit the enzyme in rhesus monkey whole blood in vitro. The results reported here demonstrate the utility of the activity-based probe BIL-DMK for the ex vivo assessment of cathepsin S inhibition.     

Potency and selectivity of inhibition of cathepsin K, L and S by their respective propeptides.

The prodomains of several cysteine proteases of the papain family have been shown to be potent inhibitors of their parent enzymes. An increased interest in cysteine proteases inhibitors has been generated with potential therapeutic targets such as cathepsin K for osteoporosis and cathepsin S for immune modulation. The propeptides of cathepsin S, L and K were expressed as glutathione S-transferase-fusion proteins in Escherichia coli. The proteins were purified on glutathione affinity columns and the glutathione S-transferase was removed by thrombin cleavage. All three propeptides were tested for inhibitor potency and found to be selective within the cathepsin L subfamily (cathepsins K, L and S) compared with cathepsin B or papain. Inhibition of cathepsin K by either procathepsin K, L or S was time-dependent and occurred by an apparent one-step mechanism. The cathepsin K propeptide had a Ki of 3.6-6.3 nM for each of the three cathepsins K, L and S. The cathepsin L propeptide was at least a 240-fold selective inhibitor of cathepsin K (Ki = 0.27 nM) and cathepsin L (Ki = 0.12 nM) compared with cathepsin S (Ki = 65 nM). Interestingly, the cathepsin S propeptide was more selective for inhibition of cathepsin L (Ki = 0.46 nM) than cathepsin S (Ki = 7.6 nM) itself or cathepsin K (Ki = 7.0 nM). This is in sharp contrast to previously published data demonstrating that the cathepsin S propeptide is equipotent for inhibition of human cathepsin S and rat and paramecium cathepsin L [Maubach, G., Schilling, K., Rommerskirch, W., Wenz, I., Schultz, J. E., Weber, E. & Wiederanders, B. (1997), Eur J. Biochem. 250, 745-750]. These results demonstrate that limited selectivity of inhibition can be measured for the procathepsins K, L and S vs. the parent enzymes, but selective inhibition vs. cathepsin B and papain was obtained.     

Microplate assay for quantitative determination of cathepsin activities in viable cells using derivatives of 4-methoxy-beta-naphthylamide

A method is described allowing the selective determination of four cathepsins (B, H, K, and L) in live cells. Adherently growing cells are incubated with partially selective substrates for each cathepsin (peptidic derivatives of 4-methoxy-beta-naphthylamine) in microtiter plates together with nitrosalicylaldehyde. Using an appropriate reader accumulating fluorescent products may be detected continously or by end point measurement. Selectivity is achieved by running parallel assays containing inhibitors that are partially selective for each of the cathepsins (in case of cathepsin H, the nonlysosomal aminopeptidases are inhibited by bestatin). Individual cathepsin activities can then be calculated by the difference between the uninhibited and the inhibited assay. The method was validated by measurements in cells isolated from cathepsin B(-/-)-, K(-/-)-, and L(-/-)- mice. This strategy suggests that the combination of two partially selective reaction partners, substrate and inhibitor can yield selective cathepsin assays.     

Keto-1,3,4-oxadiazoles as cathepsin K inhibitors

We have prepared a series of cathepsin K inhibitors bearing the keto-1,3,4-oxadiazole warhead capable of forming a hemithioketal complex with the target enzyme. By modifying binding moieties at the P1, P2, and prime side positions of the inhibitors, we have achieved selectivity over cathepsins B, L, and S, and have achieved sub-nanomolar potency against cathepsin K. This series thus represents a promising chemotype that could be used in diseases implicated by imbalances in cathepsin K activity such as osteoporosis.     

Evolutionary History of Cathepsin L (L-like) Family Genes in Vertebrates

Cathepsin L family, an important cysteine protease found in lysosomes, is categorized into cathepsins B, F, H, K, L, S, and W in vertebrates. This categorization is based on their sequence alignment and traditional functional classification, but the evolutionary relationship of family members is unclear. This study determined the evolutionary relationship of cathepsin L family genes in vertebrates through phylogenetic construction. Results showed that cathepsins F, H, S and K, and L and V were chronologically diverged. Tandem-repeat duplication was found to occur in the evolutionary history of cathepsin L family. Cathepsin L in zebrafish, cathepsins S and K in xenopus, and cathepsin L in mice and rats underwent evident tandem-repeat events. Positive selection was detected in cathepsin L-like members in mice and rats, and amino acid sites under positive selection pressure were calculated. Most of these sites appeared at the connection of secondary structures, suggesting that the sites may slightly change spatial structure. Severe positive selection was also observed in cathepsin V (L2) of primates, indicating that this enzyme had some special functions. Our work provided a brief evolutionary history of cathepsin L family and differentiated cathepsins S and K from cathepsin L based on vertebrate appearance. Positive selection was the specific cause of differentiation of cathepsin L family genes, confirming that gene function variation after expansion events was related to interactions with the environment and adaptability.     

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.     

Breast cancer cells express cathepsins B and L but not cathepsins K or H

Lysosomal cysteine proteinases (cathepsins) are considered to play a role in bone degradation mediated by metastatic breast cancers. To evaluate which cathepsin contributes to the osteolysis, we quantitatively determined the expression levels of four cathepsins in two breast cancer cell lines, MCF-7 and MDA-MB-231, by competitive RT-PCR. Cathepsin K, which is the most abundant cathepsin in osteoclasts, was not detected in either cell lines. We also failed to detect cathepsin H mRNA. By contrast, we found significant expression of cathepsins B and L in both cell lines. By Northern blot analysis cathepsin B mRNA was detected in a single form in these cells, whereas osteoclasts contained multiple forms of the mRNA. Cathepsin B protein was also detected by Western blotting as a single immunoreactive band corresponding to its mature enzyme. These findings suggest that osteolysis associated with metastatic breast cancers takes place in a different way from osteoclast-mediated bone resorption.     

Cytokines regulate cysteine cathepsins during TLR responses

TLR activation is an important component of innate immunity but also contributes to the severity of inflammatory diseases. Cysteine cathepsins (Cat) B, L and S, which are endosomal and lysosomal proteases, participate in numerous physiological systems and are upregulated during various inflammatory disorders and cancers. Macrophages have the highest cathepsin expression and are major contributors to inflammation and tissue damage during chronic inflammatory diseases. We investigated the impact of TLR activation on macrophage Cat B, L and S activities using live-cell enzymatic assays. TLR2, TLR3 and TLR4 ligands increased intracellular activities of these cathepsins in a differential manner. TLR4-induced cytokines increased proteolytic activities without changing mRNA expression of cathepsins or their endogenous inhibitors. Neutralizing antibodies recognizing TNF-α, IL-1β and IFN-β differentially eliminated cathepsin upregulation. These findings indicate cytokines induced by MyD88-dependent and -independent signaling cascades regulate cathepsin activities during macrophage responses to TLR stimulation.     

Insights into the roles of cathepsins in antigen processing and presentation revealed by specific inhibitors

Eleven human cathepsins have been identified, however, the in vivo roles of individual cathepsins are still largely unknown. In this brief review we will summarize the functions of individual cathepsins in antigen processing and presentation, which are the initial steps of the immune response. Two general inhibitors of papain-like cysteine proteases, E-64 and pyridoxal phosphate, can completely suppress antigen presentation in vivo. To evaluate the contribution of individual cathepsins, specific inhibitors have been developed based on cathepsin tertiary structures: CA-074 for cathepsin B, CLIK-148 and -195 for cathepsin L, CLIK-60 for cathepsin S. Administration of CA-074, a cathepsin B inhibitor, suppresses the response to exogenous antigens, such as hepatitis B virus antigen, ovalbumin and Leishmania major antigen, and induces switching of the helper T cell responses from Th-2 to Th-1 of CD4+ T cells, thereby downregulating the production of IgE and IgG1. Administration of the cathepsin S inhibitor CLIK-60 impairs presentation of an autoantigen, alpha-fodrin, in Sjogren's syndrome and suppresses the Th-1 response and autoantibody production.     

Structure-based development of pyridoxal propionate derivatives as specific inhibitors of cathepsin K in vitro and in vivo

We found that pyridoxal phosphate shows considerable inhibition of cathepsins. CLIK-071, in which the phosphate ester of position 3 of pyridoxal phosphate was replaced by propionate, strongly inhibited cathepsin B. Three new types of synthetic pyridoxal propionate derivatives showing specific inhibition of cathepsin K were developed. New synthetic pyridoxal propionate derivatives, -162, -163, and -164, in which the methyl arm of position 6 of CLIK-071 was additionally modified, strongly inhibited cathepsin K and cathepsin S weakly, but other cathepsins were not inhibited. CLIK-166, in which the position 4 aldehyde of CLIK-071 is replaced by a vinyl radical and position 5 is additionally modified, showed cathepsin K-specific inhibition at 10(-5) M. Pit formation due to bone collagen degradation by cathepsin K of rat osteoclasts was specifically suppressed by administration of CLIK-164, but not by inhibitors of cathepsin L or B.     

Identification and discrimination of extracellularly active cathepsins B and L in high-invasive melanoma cells

We established a novel protocol for lithium dodecyl sulfate (LDS) gelatin zymography, which operates under reducing conditions and at a slightly acidic pH value (6.5). This zymographic assay is based on polyacrylamide gel electrophoresis and facilitates the electrophoretic separation of human cathepsins in an active state. By this technique, activity of purified human liver cathepsin B was detected at a concentration as low as 50 ng and was blocked only in the presence of the cysteine protease inhibitor E-64 and the specific cathepsin B inhibitor CA-074 but not by aspartate, serine, or matrix metalloprotease inhibitors. The method was applied to analyze cathepsin activities in cell culture supernatants of the high-invasive melanoma cell line MV3. Interestingly, LDS zymography of MV3 cell supernatants in combination with specific inhibitors of cathepsins B and L identified three forms of extracellularly active cathepsin B and two forms of proteolytically active cathepsin L. We herein describe the generation and biochemical significance of acidic LDS zymography. This novel method permits not only the enzymatic analysis of purified cysteine proteases but also the identification and discrimination of different cathepsin activities in biological fluids, cell lysates, or supernatants, especially of cathepsins B and L, which are closely linked to major inflammatory and malignant processes.     

Cysteine proteinases in chondrosarcomas

The aim of the present study was to define the role of cathepsins B, H, K, L and S in the pathogenesis of human chondrosarcomas. For this purpose 40 tumour samples obtained from 12 patients with the diagnosis of conventional chondrosarcoma were systematically investigated for the expression of cathepsin mRNAs by Northern hybridisation, and for immunohistochemical localisation of the proteins. Northern analysis demonstrated the highest levels of cathepsins B and L in a recurring grade 1 chondrosarcoma, and in a grade 3 chondrosarcoma and in fibrous histiocytomas. Increased expression of cathepsin K mRNA was seen in seven chondrosarcomas, as well as in control tumours; fibrous histiocytomas, osteosarcomas, enchondromas and a giant cell tumour of bone. Cathepsin L was immunolocalised within the large chondrocytes, while cathepsin K was predominantly localised in large multinucleated osteoclastic cells and in some hypertrophic chondrocytes. These results suggest that chondrosarcoma can be included in the growing list of tumours, where cathepsins may well be involved in tumour progression. The simultaneous upregulation of cathepsins B and L, together with matrix metalloproteinase-13, and the association of cathepsin K with negative prognostic parameters suggests that an aggressive biological behaviour of chondrosarcoma may be related to the synthesis of cysteine proteinases and activation of other proteolytic enzymes. If this turns out to be the case, cathepsin inhibitors could provide the much needed adjuvant therapy for chondrosarcomas.     

The S2 subsites of cathepsins K and L and their contribution to collagen degradation

The exchange of residues 67 and 205 of the S2 pocket of human cysteine cathepsins K and L induces a permutation of their substrate specificity toward fluorogenic peptide substrates. While the cathepsin L-like cathepsin K (Tyr67Leu/Leu205Ala) mutant has a marked preference for Phe, the Leu67Tyr/Ala205Leu cathepsin L variant shows an effective cathepsin K-like preference for Leu and Pro. A similar turnaround of inhibition was observed by using specific inhibitors of cathepsin K [1-(N-Benzyloxycarbonyl-leucyl)-5-(N-Boc-phenylalanyl-leucyl)carbohydrazide] and cathepsin L [N-(4-biphenylacetyl)-S-methylcysteine-(D)-Arg-Phe-beta-phenethylamide]. Molecular modeling studies indicated that mutations alter the character of both S2 and S3 subsites, while docking calculations were consistent with kinetics data. The cathepsin K-like cathepsin L was unable to mimic the collagen-degrading activity of cathepsin K against collagens I and II, DQ-collagens I and IV, and elastin-Congo Red. In summary, double mutations of the S2 pocket of cathepsins K (Y67L/L205A) and L (L67Y/A205L) induce a switch of their enzymatic specificity toward small selective inhibitors and peptidyl substrates, confirming the key role of residues 67 and 205. However, mutations in the S2 subsite pocket of cathepsin L alone without engineering of binding sites to chondroitin sulfate are not sufficient to generate a cathepsin K-like collagenase, emphasizing the pivotal role of the complex formation between glycosaminoglycans and cathepsin K for its unique collagenolytic activity.     

Ovarian cysteine proteinases in the teleost Fundulus heteroclitus: molecular cloning and gene expression during vitellogenesis and oocyte maturation

The cysteine proteinases cathepsins B and L are members of the multigene family of lysosomal proteases that have been implicated in the processing of yolk proteins (YPs) in teleost oocytes. However, the full identification of the type of cathepsins expressed in fish ovarian follicles and embryos, as well as their regulatory mechanisms and specific function(s), are not yet elucidated. In this study, cDNAs encoding cathepsins B, L, F, K, S, Z, C, and H have been isolated from the teleost Fundulus heteroclitus, and the analysis of their deduced amino acid sequences revealed highly similar structural features to vertebrate orthologs, and confirmed in this species the existence of cathepsin L-like, cathepsin B-like, and cathepsin F-like subfamilies of cysteine proteinases. While all identified cathepsins were expressed in ovarian follicles, the corresponding mRNAs showed different temporal expression patterns. Thus, similar mRNA levels of cathepsins L, F, S, B, C, and Z were found throughout the oocyte growth or vitellogenesis period, whereas those for cathepsin H and K appeared to decrease as vitellogenesis advanced. During oocyte maturation, a transient accumulation of cathepsins L, S, H, and F mRNAs, approximately a 3-, 1.5-, 1.6-, and 6-fold increase, respectively, was detected in ovarian follicles within the 20-25 hr after hormone stimulation, coincident with the maximum proteolysis of the oocyte major YPs. The specific temporal pattern of expression of these genes may indicate a potential role of cathepsin L-like and cathepsin F proteases in the YP processing events occurring during fish oocyte maturation and/or early embryogenesis.     

L-trans-Epoxysuccinyl-leucylamido(4-guanidino)butane (E-64) and its analogues as inhibitors of cysteine proteinases including cathepsins B, H and L.

1. L-trans-Epoxysuccinyl-leucylamido(4-guanidino)butane (E-64) at a concentration of 0.5 mM had no effect on the serine proteinases plasma kallikrein and leucocyte elastase or the metalloproteinases thermolysin and clostridial collagenase. In contrast, 10 muM-E-64 rapidly inactivated the cysteine proteinases cathepsins B, H and L and papain (t0.5 = 0.1-17.3s). The streptococcal cysteine proteinase reacted much more slowly, and there was no irreversible inactivation of clostripain. The cysteine-dependent exopeptidase dipeptidyl peptidase I was very slowly inactivated by E-64. 2. the active-site-directed nature of the interaction of cathepsin B and papain with E-64 was established by protection of the enzyme in the presence of the reversible competitive inhibitor leupeptin and by the stereospecificity for inhibition by the L as opposed to the D compound. 3. It was shown that the rapid stoichiometric reaction of the cysteine proteinases related to papain can be used to determine the operational molarity of solutions of the enzymes and thus to calibrate rate assays. 4. The apparent second-order rate constants for the inactivation of human cathepsins B and H and rat cathepsin L by a series of structural analogues of E-64 are reported, and compared with those for some other active-site-directed inhibitors of cysteine proteinases. 5. L-trans-Epoxysuccinyl-leucylamido(3-methyl)butane (Ep-475) was found to inhibit cathepsins B and L more rapidly than E-64. 6. Fumaryl-leucylamido(3-methyl)butane (Dc-11) was 100-fold less reactive than the corresponding epoxide, but was nevertheless about as effective as iodoacetate.     

3-Acylamino-azetidin-2-one as a novel class of cysteine proteases inhibitors

A new class of inhibitors for cysteine proteases cathepsin B, L, K and S is described. These inhibitors are based on the beta-lactam ring designed to interact with the nucleophilic thiol of the cysteine in the active site of cysteine proteases. Some 3-acylamino-azetidin-2-one derivatives showed very potent inhibition activities for cathepsins L, K and S at the nanomolar or subnanomolar IC(50) values.     

Peptidic 1-cyanopyrrolidines: synthesis and SAR of a series of potent,selective cathepsin inhibitors

1-Cyanopyrrolidines have previously been reported to inhibit cysteinyl cathepsins (Falgueyret, J.-P. et al., J. Med. Chem. 2001, 44, 94). In order to optimize binding interactions for a given cathepsin and simultaneously reduce interactions with the other closely related enzymes, small peptidic substituents were introduced to the 1-cyanopyrrolidine scaffold, either at the 2-position starting with proline or at the 3-position of aminopyrrolidines. The resulting novel compounds proved to be micromolar inhibitors of cathepsin B (Cat B) but nanomolar to picomolar inhibitors of cathepsins K, L, and S (Cat K, Cat L, Cat S). Several of the compounds were >20-fold selective versus the other three cathepsins. SAR trends were observed, most notably the remarkable potency of Cat L inhibitors based on the 1-cyano-D-proline scaffold. The selectivity of one such compound, the 94 picomolar Cat L inhibitor 12, was demonstrated at higher concentrations in DLD-1 cells. Although none of the compounds in the proline series that was tested proved to be submicromolar in the in vitro bone resorption assay, two Cat K inhibitors in the 3-substituted pyrrolidine series, 24 and 25 were relatively potent in that assay.     

Cathepsins as effector proteases in hepatocyte apoptosis

Conclusion Cathepsins B and D appear to act as part of the effector protease cascade in hepatocyte apoptosis, both in bile salt-induced apoptosis and CPT-induced apoptosis of hepatocellular cancer cell lines. It is important to note that these proteases do not appear to participate in many models of apoptosis studied to date; in fact, cathepsin inhibitors have been used as negative controls to show that enzymes other than caspases are not involved in apoptosis. In particular, it has been shown that cathepsin B inhibitors do not prevent many models of apoptosis in lymphocytes (43). Further, our experiments have shown that not all models of hepatocyte apoptosis are mediated by cathepsins. For example, staurosporine-induced apoptosis is not inhibited by cathepsin B inhibitors in primary hepatocytes or in cell lines stably transfected with the cathepsin B antisense construct. Although the signaling pathways leading to activation of cathepsins B and D in hepatocyte apoptosis are not completely understood, we hypothesize that a caspase 8-like protein may be involved proximal to cathepsins D and B (Fig. 6). The precise mechanism by which cathepsin B is translocated from lysosomes to “apoptotic targets” is currently under investigation in our laboratory. Because of the relative promiscuity of cathepsin B as protease, it is likely that it is involved in nonspecific protein degradation in apoptotic bodies; however, cathepsin B has also been shown to degrade certain specific proteins, such as histones, which may be directly relevant to the apoptotic process. Further evaluation of the role of cathepsins B and D in apoptosis should include the determination of specific proteolytic targets that result in the biochemical and morphologic manifestations of apoptosis.     

Cathepsins K, L, B, X and W are differentially expressed in normal and chronically inflamed gastric mucosa

The expression of cathepsins K, L, B, X and W was studied by quantitative RT-PCR in normal and inflamed gastric mucosa (antrum, corpus, cardia). Cathepsins B, L, K and X were expressed ubiquitously. In contrast, cathepsin W was expressed at very low levels. Infection by Helicobacter pylori caused a significant induction of cathepsin X (p<0.008), whereas the other cathepsins were not or only locally affected by H. pylori infection or reflux disease. Immunohistochemistry revealed specific expression of cathepsin X (macrophages), cathepsin K (parietal cells) and cathepsin W (lymphocytes), whereas cathepsins B and L were predominantly expressed in epithelial cells.