Quantitation and immunohistochemical localization of cathepsins E and D in rat tissues and blood cells

The distribution of cathepsins E and D in various rat tissues and blood cells was determined by immunoprecipitation and by immunohistochemistry with discriminative antibodies specific for each enzyme. While cathepsin D was detected in all of the tissues and blood cells tested (except for erythrocytes), cathepsin E had a relatively limited distribution. The cathepsin E content was highest in the stomach and was succeeded in the following order by the urinary bladder, thymus, spleen, cervical lymph node and bone marrow. Significant amounts of cathepsin E were also found in the colon, rectum, jejunum, skin, lung, kidney and submandibular gland. The other tissues tested had little or no detectable cathepsin E content. Of the blood cells tested, lymphocytes and peritoneal neutrophils contained high levels of cathepsin E. Erythrocytes had cathepsin E only as aspartic proteinases. When the subcellular localization of cathepsin E in the neutrophils was investigated by fractionation of the postnuclear supernatants, the enzyme behaved as a soluble cytosolic enzyme. In contrast, cathepsin D was mainly associated with the granular fraction. The immunohistochemical localization of cathepsins E and D was clearly different in the stomach, large intestines, kidney and urinary bladder, but was similar in the lymph node and spleen. The tissue-fixed macrophages, which were notable in the skeletal and cardiac muscle tissues, submucosal layers of the gastrointestinal tracts, salivary gland, lung and trachea, also exhibited similar intense immunoreactivities demonstrative of both cathepsins E and D.     

Species-specific distribution of cathepsin E in mammalian blood cells

The distribution of cathepsins D and E in leukocytes and erythrocyte ghosts of several mammalian species, and in HL-60 and K-562 cells was examined by means of a combined application of electrophoretic and immunochemical methods. Cathepsin D was found in leukocytes of all species examined, but the distribution of cathepsin E was found to be species-specific: pigs, cows and goats had no cathepsin E activity in leukocytes or erythrocytes at all. In humans, cathepsin E occurred in erythrocytes but not in leukocytes, which contrasted with the guinea pig pattern of its presence in leukocytes and its absence in erythrocytes. No cathepsin E-related enzymes were found in HL-60 or K-562 cells, but these human leukemic cells contained cathepsin D-related enzyme forms that are electrophoretically distinct from normal leukocyte cathepsin D. The present results are inconsistent with the view that cathepsin E may be involved as an essential factor in the biological functions of leukocytes or erythrocytes.     

A particle-associated ATP-dependent proteolytic activity in erythroleukemia cells

An ATP-dependent proteolytic activity has been detected in both mouse erythroleukemia (Friend) cells and human (K562) erythroleukemia cells. Exposure of the Friend cells to dimethyl sulfoxide, which stimulates differentiation, increased ATP-dependent proteolysis approximately 2-fold although inducing differentiation in the K562 line had no significant effect on proteolysis. In contrast to the previously described soluble ATP-dependent proteolytic system of reticulocytes, the activity in the more primative erythroid cells is associated with a particulate fraction and is readily sedimentable by centrifugation at 100,000 X g for 1 h. Like the soluble reticulocyte system, the particulate activity requires divalent cation and is inhibited by hemin as well as vanadate. The activity was isolated on a sucrose cushion (30%) and did not appear to be associated with membranes, cytoskeleton, or polysomes. This enzymatic activity which degrades abnormal globin chains may initially reside in a particulate fraction and then become solubilized during erythroid maturation to the reticulocyte stage. Alternatively, the particulate activity may disappear with cell maturation being replaced by a distinct soluble activity. ATP-dependent proteolytic activity is eventually lost with reticulocyte maturation and further aging of erythrocytes.     

Cathepsin D of mouse leukemia L12010 cells unusual intracellular localization and biochemical properties

Mouse leukemia L1210 cells contain lysosomes, but cathepsin D, a typical lysosomal enzyme, has an unusual localization. After fractionation of homogenates of L1210 cells by isopynic density gradient centrifugation, most of the activity for all of the acid hydrolases studied, except cathepsin D, is sedimentable and shows a similar density distribution around a peak having a modal density of 1.16. In contrast, much more of the total activity for cathepsin D is not sedimentable, while the sedimentable activity has a distribution around a peak at a higher density of 1.18.After chromatography on Sephadex G-100 of cell extracts, two molecular weight forms of cathepsin D are found. One has an apparent molecular weight of approx. 45 000, similar to rat liver cathepsin D, while the apparent molecular weight of the second form is approx. 95 000. Both forms are 4–5 times more active than rat liver cathepsin D. The high molecular weight L1210 cathepsin D converts to the low molecular weight form with no loss activity after treatment with β-mercaptoethanol. In all respects the unusual intracellular localization and molecular weight forms of cathepsin D in mouse luekemia L1210 cells are similar to the situation found for rat thoratic duct lymphocytes.     

Cathepsin D of mouse leukemia L1210 cells. Unusual intracellular localization and biochemical properties.

Mouse leukemia L1210 cells contain lysosomes, but cathepsin D, a typical lysosomal enzyme, has an unusual localization. After fractionation of homogenates of L1210 cells by isopycnic density gradient centrifugation, most of the activity for all of the acid hydrolases studied, except cathepsin D, is sedimentable and shows a similar density distribution around a peak having a modal density of 1.16. In contrast, much more of the total activity for cathepsin D is not sedimentable, while the sedimentable activity has a distribution around a peak at a higher density of 1.18. After chromatography on Sephadex G-100 of cell extracts, two molecular weight forms of cathepsin D are found. One has an apparent molecular weight of approx. 45,000, similar to rat liver cathepsin D, while the apparent molecular weight of the second form is approx. 95,000. Both forms are 4-5 times more active than rat liver cathepsin D. The high molecular weight L1210 cathepsin D converts to the low molecular weight form with no loss in activity after treatment with beta-mercaptoethanol. In all respects the unusual intracellular localization and molecular weight forms of cathepsin D in mouse leukemia L1210 cells are similar to the situation found for rat thoracic duct lymphocytes.     

Differential requirement for cathepsin D for processing of the full length and C-terminal fragment of the malaria antigen MSP1

Merozoite Surface Protein 1 is expressed on the surface of malaria merozoites and is important for invasion of the malaria parasite into erythrocytes. MSP1-specific CD4 T cell responses and antibody can confer protective immunity in experimental models of malaria. In this study we explore the contributions of cathepsins D and E, two aspartic proteinases previously implicated in antigen processing, to generating MSP1 CD4 T-cell epitopes for presentation. The absence of cathepsin D, a late endosome/lysosomal enzyme, is associated with a reduced presentation of MSP1 both following in vitro processing of the epitope MSP1 from infected erythrocytes by bone marrow-derived dendritic cells, and following in vivo processing by splenic CD11c+ dendritic cells. By contrast, processing and presentation of the soluble recombinant protein fragment of MSP1 is unaffected by the absence of cathepsin D, but is inhibited when both cathepsin D and E are absent. The role of different proteinases in generating the CD4 T cell repertoire, therefore, depends on the context in which an antigen is introduced to the immune system.     

Structural differences between rabbit cathepsin E and cathepsin D

Rabbit cathepsins D and E were isolated from bone marrow. Both enzymes were purified by affinity chromatography on pepstatin-Sepharose 4B and Con A-Sepharose 4B. Purity of the enzymes was ascertained by two-dimensional gel electrophoresis after iodination. The isoelectric point of cathepsin D was found to be 6.95. Cathepsin E was shown to consist of two subunits having molecular masses each of 40 kDa and isoelectric points of 4.60 and 4.65, respectively. The amino-acid composition of cathepsin E was found to be different from that of cathepsin D.     

Specific inactivation of cysteine protease-type cathepsin by singlet oxygen generated from naphthalene endoperoxides

Singlet oxygen is a causal factor in light-induced skin photoaging and the cytotoxic process of tumor cells in photodynamic chemotherapy. To develop a better understanding of the functional consequences of protein modification by singlet oxygen, the effects of naphthalene endoperoxide on lysosomal protease, cathepsin, were examined. When the soluble fraction of normal human fetal skin fibroblast cells was treated with the endoperoxide, the activities of cysteine proteases, cathepsins B and L/S, were inhibited, but that of aspartate protease, cathepsin D/E, was not. The reduction of the endoperoxide-treated soluble fractions by treatment with dithiothreitol barely recovered the activities. Cathepsin B, purified from normal human liver, exhibited similar profiles to that in cytosol. These data suggest that singlet oxygen oxidatively modifies an amino acid residue essential for catalysis and consequently results in the irreversible inactivation of cysteine protease-type cathepsin.     

Coordinated involvement of cathepsins S, D and cystatin C in the commitment of hematopoietic stem cells to dendritic cells

The identity of biochemical players which underpin the commitment of CD34(+) hematopoietic stem cells to immunogenic or tolerogenic dendritic cells is largely unknown. To explore this issue, we employed a previously established cell-based system amenable to shift dendritic cell differentiation from the immunogenic into the tolerogenic pathway upon supplementation with a conventional cytokine cocktail containing thrombopoietin (TPO) and IL-16. We show that stringent regulation of cathepsins S and D, two proteases involved in antigen presentation, is crucial to engage cell commitment to either route. In response to TPO+IL-16-dependent signaling, both cathepsins undergo earlier maturation and down-regulation. Additionally, cystatin C orchestrates cathepsin S expression through a tight but reversible interaction that, based on a screen of adult stem cells from disparate origins, CD14(+) cells, primary fibroblasts and the MCF7 cell line, appears unique to CD34(+) stem cells from peripheral and cord blood. As shown by CD4(+) T cell proliferation in mixed-lymphocyte reactions, cell commitment to either pathway is disrupted upon cathepsin knockdown by RNAi. Surprisingly, similar effects were also observed upon gene overexpression, which prompts atypically accelerated maturation of cathepsins S and D in cells of the immunogenic pathway, similar to the tolerogenic route. Furthermore, RNAi studies revealed that cystatin C is a proteolytic target of cathepsin D and has a direct, causal impact on cell differentiation. Together, these findings uncover a novel biochemical cluster that is subject to time-controlled and rigorously balanced expression to mediate specific stem cell commitment at the crossroads towards tolerance or immunity.     

Distinct cathepsins control necrotic cell death mediated by pyroptosis inducers and lysosome-destabilizing agents

Necrotic cell death triggers a range of biological responses including a strong adaptive immune response, yet we know little about the cellular pathways that control necrotic cell death. Inhibitor studies suggest that proteases, and in particular cathepsins, drive necrotic cell death. The cathepsin B-selective inhibitor CA-074-Me blocks all forms of programmed necrosis by an unknown mechanism. We found that cathepsin B deficiency does not prevent induction of pyroptosis and lysosome-mediated necrosis suggesting that CA-074-Me blocks necrotic cell death by targeting cathepsins other than cathepsin B. A single cathepsin, cathepsin C, drives necrotic cell death mediated by the lysosome-destabilizing agent Leu-Leu-OMe (LLOMe). Here we present evidence that cathepsin C-deficiency and CA-074-Me block LLOMe killing in a distinct and cell type-specific fashion. Cathepsin C-deficiency and CA-074-Me block LLOMe killing of all myeloid cells, except for neutrophils. Cathepsin C-deficiency, but not CA-074-Me, blocks LLOMe killing of neutrophils suggesting that CA-074-Me does not target cathepsin C directly, consistent with inhibitor studies using recombinant cathepsin C. Unlike other cathepsins, cathepsin C lacks endoproteolytic activity, and requires activation by other lysosomal proteases, such as cathepsin D. Consistent with this theory, we found that lysosomotropic agents and cathepsin D downregulation by siRNA block LLOMe-mediated necrosis. Our findings indicate that a proteolytic cascade, involving cathepsins C and D, controls LLOMe-mediated necrosis. In contrast, cathepsins C and D were not required for pyroptotic cell death suggesting that distinct cathepsins control pyroptosis and lysosome-mediated necrosis.     

An immunocytochemical study on distinct intracellular localization of cathepsin E and cathepsin D in human gastric cells and various rat cells.

Immunocytochemical localization of two distinct intracellular aspartic proteinases, cathepsins E and D, in human gastric mucosal cells and various rat cells was investigated by immunogold technique using discriminative antibodies specific for each enzyme. Cathepsin D was exclusively confined to primary or secondary lysosomes in almost all the cell types tested, whereas cathepsin E was not detected in the lysosomal system. The localization of cathepsin E varied with different cell types. Microvillous localization of cathepsin E was found in the intracellular canaliculi of human and rat gastric parietal cells, rat renal proximal tubule cells, and the bile canaliculi of rat hepatic cells. The immunolocalization of each enzyme in gastric cells were essentially the same in humans and rats. In the gastric feveolar epithelial cells and parietal cells, definite immunolabeling for cathepsin E was observed in the cytoplasmic matrix, the cisternae of the rough endoplasmic reticulum, and the dilated perinuclear envelope. In rat kidney, cathepsin E was detected only in the proximal tubule cells, while cathepsin D was found mainly in the lysosomes of the distal tubule cells but not in those of the proximal tubule cells. These results clearly indicate the distinct intracytoplasmic localization of cathepsins E and D and suggest the possible involvement of cathepsin E in extralysosomal proteolysis that is related to specialized functions of each cell type.     

Rabbit red blood cell hexokinase:intracellular distribution during reticulocytes maturation

Summary The intracellular localization and isozyme distribution of hexokinase were studied during rabbit reticulocyte maturation and aging. In reticulocytes 50% of the enzyme was particulate while in the mature erythrocytes all the hexokinase activity was soluble. The bound enzyme co-sediments with mitochondria and by column chromatography it was found to be hexokinase Ia. The cytosol of reticulocytes contains hexokinase Ia (38%) and hexokinase Ib (62%) while the mature erythrocytes contain only hexokinase Ia. The amount of bound hexokinase decreases very quickly during cell maturation and aging as was shown by following in vivo reticulocyte maturation or by analysis of hexokinase compartmentation in cells of different ages, obtained by density gradient ultracentrifugations. A role for this intracellular distribution of hexokinase is suggested.     

The effect of heme on intracellular iron pools during differentiation of friend erythroleukemia cells

The inhibition of cellular iron uptake by hemin described previously in reticulocytes was studied in murine erythroleukemia (Friend) cells that can be induced to differentiate in culture by dimethyl sulfoxide (DMSO). Hemin had no effect on iron uptake into noninduced cells. After the induction by DMSO, hemin inhibited iron uptake into Friend cells and this effect of hemin became more pronounced with the further progress of differentiation. The reduction of cellular iron accumulation was caused mainly by inhibition of iron incorporation into heme, iron uptake into the non-heme pool was influenced by hemin treatment. Inhibition of heme synthesis by isonicotinic acid hydrazide (INH) caused an accumulation of iron in mitochondria in DMSO-induced cells but not in uninduced cells. On the basis of these results, a specific system transporting iron to mitochondria induced by DMSO treatment is suggested as a target for the inhibitory action of hemin. In Friend cells of the Fw line which are deficient in ferrochelatase, heme has no effect on iron uptake. The addition of INH to the Fw cells does not enhance the iron accumulatoni in mitochondria.     

Inherited persistence of immature type pyruvate kinase and hexokinase isozymes in dog erythrocytes

1. Red cell pyruvate kinase (EC 2.7.1.40) and hexokinase (EC 2.7.1.1) in high and low potassium (K) dogs were shown to exist as multiple forms which were separable by electrophoresis and ion-exchange chromatography. The R2-type pyruvate kinase, which was determined to be a young type enzyme in canine red cells, was shown to be the predominant form of pyruvate kinase in high K cells. 2. The M2-type pyruvate kinase, a prototype isozyme in erythroid cells, existed in high K dog erythrocytes as well as in high K and low K dog reticulocytes. 3. Isozyme analysis of high K red cell hexokinase also showed a profile similar to that obtained for low K reticulocytes. 4. These results seem to reflect the immaturity of high K erythrocytes, which suggest that an abnormal cell differentiation or maturation may occur at an early stage of erythroid cell proliferation in high K dogs.     

Cell type dependent inhibition of transport of cathepsin D in HepG2 cells and fibroblasts exposed to deoxy-manno-nojirimycin and deoxynojirimycin

The synthesis, transport and processing of lysosomal enzymes was examined in human hepatoma HepG2 cells and in human fibroblasts exposed to the Golgi alpha-mannosidase I inhibitor 1-deoxy-manno-nojirimycin. In HepG2 cells cathepsin D, beta-hexosaminidase and arylsulfatase B synthesized in the presence of 5 mM 1-deoxy-manno-nojirimycin contained exclusively endo-beta-N-acetylglucosaminidase H-cleavable oligosaccharides, indicating that alpha-mannosidase I had been inhibited efficiently. The proteolytic processing of intracellularly retained cathepsin D was retarded and the fraction of secreted cathepsin D was increased two-fold. In fibroblasts neither segregation nor maturation of cathepsin D were affected by 1-deoxy-manno-nojirimycin in spite of the inhibition of oligosaccharide processing. In the presence of the glucosidase I inhibitor 1-deoxynojirimycin, the precursor of cathepsin D (larger by about 1 kDa than the secreted form) accumulated transiently in light membranes in HepG2 cells. Release from the site of accumulation was accompanied by a decrease in size by about 1 kDa. This change was attributed to the removal of glucose residues. In fibroblasts the transient accumulation of larger precursors in the presence of 1-deoxynojirimycin was more pronounced than in HepG2 cells. The differential effects of alpha-mannosidase I and glucosidase I inhibitors on the transport of cathepsin D in HepG2 cells and fibroblasts may indicate that different intermediates in the biosynthetic pathway of asparagine-linked oligosaccharides participate in the transport of lysosomal enzymes in the two cell types.     

Localization and characterization of N-ethylmaleimide sensitive inhibitor(s) of thiol cathepsin activity from cultured nil and polyoma virus-transformed nil hamster cells

Exposure of cultured Nil (a stable line of fibroblast cells from Syrian hamsters) or polyoma virus-transformed (PyNil) hamster fibroblasts to 0.5 mM N-ethylmaleimide for 5 minutes resulted in striking increases in thiol cathepsin activity in unfractionated cell-free lysates. The paradoxical increase in activity of the normally N-ethylmaleimide-sensitive cathepsins apparently occurred as the result of the protective compartmentalization of the cathepsins in the lysosomes (20,000 X g sedimented fraction) and the unprotected localization of an inhibitor(s) in the soluble cytoplasm (175,000 X g supernatant fraction). Under continuous exposure of the cells to N-ethylmaleimide, a rapid increase in cathepsin activity (seen in the first 5 minutes) was followed by a steady decrease in activity (half inactivation time, 90 minutes). The relative difference in rates of N-ethylmaleimide inactivation of thiol cathepsins and thiol cathepsin inhibitors provides a means for estimating lysosomal cathepsin activity in whole cell extracts without the need for more time-consuming fractionation procedure. In reciprocal inhibition tests, it was found that, regardless of the source of cathepsins, the Nil and PyNil cathepsin inhibitor(s) inactivated the cathepsins to approximately the same extent. The inhibitors were heat stable (90-100 degrees C for 15 minutes) at pH 4, but were totally inactivated when boiled at pH 8.5. On a calibrated Sephadex G-100 column, the relative molecular weight (Mr) of the inhibitor(s) was 13,000 daltons. On the same column, the Mr of the cathepsins was 24,000 daltons. Compared with the cathepsin activity from Nil cells, there was about five times less cathepsin activity recoverable from the PyNil cells.     

Mitogenic effects of certain cathepsins and calciferin on the intact liver in vivo

Calciferin, a new parathyroid hormone stimulating the release of cathepsins D and L (but not B) from isolated lysosomes, or the release of cathepsin D from erythrocytes or ghosts in vitro, elevated free cathepsin D in the blood, and at the same time stimulated DNA synthesis in the intact liver when it was injected into mice. Both calciferin and free cathepsin D in the blood (rats) were elevated concomitantly soon after 70% hepatectomy, reaching a peak around 5 hr. The cathepsin D-elevation was almost proportional to fractional hepatectomies. Cathepsin L (but not B), when injected intraperitoneally into mice, stimulated DNA synthesis and mitosis in the intact liver much like cathepsin D, the effect of which was reported earlier. In contrast to the mitogenic effects of calciferin or cathepsins (D and L) in vivo, only cathepsin L (but not cathepsin D or calciferin) in low concentrations appeared to stimulate DNA synthesis in the cultured liver cells, and also stimulated adenylate cyclase of isolated liver plasma membranes in vitro. Dibutyryl-cyclic AMP in concentrations lower than 10(-5) M also stimulated DNA synthesis in cultured liver cells.     

Development-dependent expression of cathepsins d and e in various rat tissues, with special reference to the high expression of cathepsin e in fetal liver

The levels of cathepsins D and E in various rat tissues during development were determined with the sensitive assay method we have developed. The level of cathepsin D increased gradually in each tissue during fetal development suggesting the gradual maturation of the lysosomal system in a cell. The level of cathepsin E differed significantly between tissues at various developmental stages. The level in liver increased rapidly from 13-day-gestation fetal stage and decreased gradually at later fetal stages. The level in other tissues such as stomach and spleen began to increase at later fetal stages or the infant stage. Cathepsin E was found in fetal hepatocytes and its gene was hypomethylated when the expression of the gene was elevated. The enzyme was found to be present mainly as a proform suggesting that, after working, an active form is rapidly inactivated.     

Products of lipid peroxidation induce missorting of the principal lysosomal protease in retinal pigment epithelium

Phagocytosis of photoreceptor outer segments (OS) by retinal pigment epithelium (RPE) is essential for OS renewal and survival of photoreceptors. Internalized, oxidatively modified macromolecules perturb the lysosomal function of the RPE and can lead to impaired processing of photoreceptor outer segments. In this study, we sought to investigate the impact of intracellular accumulation of oxidatively damaged lipid-protein complexes on maturation and distribution of cathepsin D, the major lysosomal protease in the RPE. Primary cultures of human RPE cells were treated with copper-oxidized low density lipoprotein (LDL) and then challenged with serum-coated latex beads to stimulate phagocytosis. Three observations were noted to occur in this experimental system. First, immature forms of cathepsin D (52 and 46 kDa) were exclusively associated with latex-containing phagosomes. Second, maturation of cathepsin D was severely impaired in RPE cells loaded with oxidized LDL (oxLDL) prior to the phagocytic challenge. Third, pre-treatment with oxLDL caused sustained secretion of pro-cathepsin D and the latent form of gelatinase A into the extracellular space in a dose-dependent manner. These data stimulate the hypothesis that intracellular accumulation of poorly degradable, oxidized lipid-protein cross-links, may alter the turnover of cathepsin D, causing its mistargeting into the extracellular space together with the enhanced secretion of a gelatinase.     

Characterization of new fluorogenic substrates for the rapid and sensitive assay of cathepsin E and cathepsin D.

Cathepsin E and cathepsin D are two major intracellular aspartic proteinases implicated in the physiological and pathological degradation of intra- and extracellular proteins. In this study, we designed and constructed highly sensitive synthetic decapeptide substrates for assays of cathepsins E and D based on the known sequence specificities of their cleavage sites. These substrates contain a highly fluorescent (7-methoxycoumarin-4-yl)acetyl (MOCAc) moiety and a quenching 2,4-dinitrophenyl (Dnp) group. When the Phe-Phe bond is cleaved, the fluorescence at an excitation wavelength of 328 nm and emission wavelength of 393 increases due to diminished quenching resulting from the separation of the fluorescent and quenching moieties. The first substrate, MOCAc-Gly-Lys-Pro-Ile-Leu-Phe-Phe-Arg-Le u-Lys(Dnp)gamma-NH2, in which the Lys-Pro combination at positions P5 and P4 was designed for specific interaction with cathepsin E, is hydrolyzed equally well by cathepsins E and D (kcat/Km = 10.9 microM(-1) x s(-1) for cathepsin E and 15.6 microM(-1) x s(-1) for cathepsin D). A very acidic pH optimum o was obtained for both enzymes. The second substrate, MOCAc-Gly-Lys-Pro-Ile-Ile-Phe-Phe-Arg-Le u-Lys(Dnp)gamma-NH2, in which the isoleucine residue at position P2 was meant to increase the specificity for cathepsin E, is also hydrolyzed equally by both enzymes (kcat/Km = 12.2 microM(-1) x s(-1) for cathepsin E and 16.3 microM(-1) x s(-1) for cathepsin D). The kcat/Km values for both substrates are greater than those for the best substrates for cathepsins E and D described so far. Unfortunately, each substrate shows little discrimination between cathepsin E and cathepsin D, suggesting that amino acids at positions far from the cleavage site are important for discrimination between the two enzymes. However, in combination with aspartic proteinase inhibitors, such as pepstatin A and Ascaris pepsin inhibitor, these substrates enable a rapid and sensitive determination of the precise levels of cathepsins E and D in crude cell extracts of various tissues and cells. Thus these substrates represent a potentially valuable tool for routine assays and for mechanistic studies on cathepsins E and D.