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.     

Comparative study on specificities of rat cathepsin L and papain: amino acid differences at substrate-binding sites are involved in their specificities

Sixty-nine rat cathepsin L-susceptible peptide bonds were analyzed employing various peptide substrates. The proteolytic specificities of rat cathepsin L and papain were compared and the results are discussed in relation to differences in amino acid residues around their binding sites. The specificity of cathepsin L, which is characterized by a remarkable preference for hydrophobic amino acids at the P2 site of the scissile peptide bonds, was analogous to that of papain as a whole. This analogous specificity suggests that the binding sites of the two proteases are analogous, as expected from their homologous amino acid sequences. However, there is a slight difference in the preference for S3 site between them. That is, cathepsin L showed a greater preference for bulky and hydrophobic amino acids at the S3 site than did papain. Based on the computer-graphically deduced structure of the binding sites of cathepsin L, the preferences for hydrophobic amino acids at the S2 site and for bulky and hydrophobic amino acids at the S3 site of the protease are supposed to be related to the compensating amino acid substitutions at the S2 site (V133A and V157L) and the reduction in size at the S3 site (Y61Q and Y67L), respectively. The discussion of the effect of the amino acid substitutions on the proteolytic activities of cathepsin L and papain in this paper provides a basis for more advanced studies of the relationship between structure and function of proteases belonging to the papain superfamily by means of protein engineering.     

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.     

Purification of an acid proteinase from Aspergillus saitoi and determination of peptide bond specificity.

The specificity and mode of action of an acid proteinase (EC 3.4.23.6) from Aspergillus saitoi were investigated with oxidized B-chain of insulin, angiotensin II and bradykinin. Further purification of acid proteinase was performed with N,O-dibenzyloxycarbonyl-tyrosine hexamethylene-diamino-Sepharose 4B affinity chromatography and isoelectric focusing. The purified enzyme was free of any other proteolytic activity demonstrated in Asp. saitoi. Acid proteinase from Asp. saitoi hydrolyzed primarily two peptide bonds in the oxidized B-chain of insulin, the Leu(15)-Tyr(16) bond and the Phe(24)-Phe(25) bond. Additional cleavages of the bonds His(10)-Leu(11), Ala(14)-Leu(15) and Tyr(16)-Leu(17) were also noted. Primary splitting sites at Leu(15)-Tyr(16) and Phe(24-)-Phe(25) with acid proteinase from Asp. saitoi were identical with those reported in the work of cathepsin D (EC 3.4.23.5) from human erythrocyte. Hydrolysis of angiotensin II was observed at the Tyr(4)-Ile(5) bond. In conclusion, peptide bonds which have a hydrophobic amino acid such as phenylalanine, tyrosine, leucine and isoleucine in the P'1 position (as defined by Berger and Schechter, [29]) are preferentially cleaved by the trypsinogenactivating acid proteinase from Asp. saitoi.     

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.     

Action of human liver cathepsin B on the oxidized insulin B chain.

The lysosomal cysteine proteinase cathepsin B (from human liver) was tested for its peptide-bond specificity against the oxidized B-chain of insulin. Sixteen peptide degradation products were separated by high-pressure liquid chromatography and thin-layer chromatography and were analysed for their amino acid content and N-terminal amino acid residue. Five major and six minor cleavage sites were identified; the major cleavage sites were Gln(4)-His(5), Ser(9)-His(10), Glu(13)-Ala(14), Tyr(16)-Leu(17) and Gly(23)-Phe(24). The findings indicate that human cathepsin B has a broad specificity, with no clearly defined requirement for any particular amino acid residues in the vicinity of the cleavage sites. The enzyme did not display peptidyldipeptidase activity with this substrate, and showed a specificity different from those reported for two other cysteine proteinases, papain and rat cathepsin L.     

Exogenous adenosine 3': 5'-monophosphate can release yeast from catabolite repression.

A new simple fast and reproducible purification procedure for the proteinase from rat liver mitochondria has been worked out. The specificity of cleavage of peptide bonds in glucagon, oxidized A and B chains of insulin and yeast proteinase B inhibitor by the proteinase of the inner mitochondrial membrane has been studied. The proteinase hydrolyzed three peptide bonds in glucagon, Tyr (13) - Leu (14), Trp (25) - Leu (26) and Phe (22) - Val (23) (minor cleavage site); none in the insulin A chain; one in the B chain of insulin, Tyr (16) - Leu (17); and three in the yeast proteinase B inhibitor, Phe (4) - Ile (5), Phe (20) - Leu (21) and Tyr (41) - Thr (42) (minor cleavage site).Thus, the mitochondrial proteinase cleaves peptide bonds at the carboxyl site of an aromatic amino acid and the amino site of a leucine, isoleucine, threonine or valine. The comparison with chymotrypsin A shows that the mitochondrial proteinase cleaves peptide bonds in a more restricted manner.     

The specificity of bovine spleen cathepsin S. A comparison with rat liver cathepsins L and B.

The peptide-bond-specificity of bovine spleen cathepsin S in the cleavage of the oxidized insulin B-chain and peptide methylcoumarylamide substrates was investigated and the results are compared with those obtained with rat liver cathepsins L and B. Major cleavage sites in the oxidized insulin B-chain generated by cathepsin S are the bonds Glu13-Ala14, Leu17-Val18 and Phe23-Tyr26; minor cleavage sites are the bonds Asn3-Gln4, Ser9-His10 and Leu15-Tyr16. The bond-specificity of this proteinase is in part similar to the specificities of cathepsin L and cathepsin N. Larger differences are discernible in the reaction with synthetic peptide substrates. Cathepsin S prefers smaller neutral amino acid residues in the subsites S2 and S3, whereas cathepsin L efficiently hydrolyses substrates with bulky hydrophobic residues in the P2 and P3 positions. The results obtained from inhibitor studies differ somewhat from those based on substrates. Z-Phe-Ala-CH2F (where Z- represents benzyloxycarbonyl-) is a very potent time-dependent inhibitor for cathepsin S, and inhibits this proteinase 30 times more efficiently than it does cathepsin L and about 300 times better than it does cathepsin B. By contrast, the peptidylmethanes Z-Val-Phe-CH3 and Z-Phe-Lys(Z)-CH3 inhibit competitively both cathepsin S and cathepsin L in the micromolar range.     

Synthesis and hydrolysis by cathepsin B of fluorogenic substrates with the general structure benzoyl-X-ARG-MCA containing non-natural basic amino acids at position X

We synthesized one series of fluorogenic substrates for cathepsin B derived from the peptide Bz-F-R-MCA (Bz=benzoyl, MCA=7-methyl-coumarin amide) substituting Phe at the P(2) position by non-natural basic amino acids that combine a positively charged group with aromatic or aliphatic radicals at the same side chain, namely, 4-aminomethyl-phenylalanine, 4-guanidine-phenylalanine, 4-aminomethyl-N-isopropyl-phenylalanine, 3-pyridyl-alanine, 4-piperidinyl-alanine, 4-aminomethyl-cyclohexyl-alanine, 4-aminocyclohexyl-alanine, and N(im)-dimethyl-histidine. Bz-F-R-MCA was the best substrate for cathepsin B but also hydrolyzed Bz-R-R-MCA with lower efficiency, since the protease accepts Arg at S(2) due to the presence of Glu(245) at the bottom of this subsite. The presence of the basic non-natural amino acids at the P(2) position of the substrate partially restored the catalytic efficiency of cathepsin B. All the kinetic parameters for hydrolysis of the peptides described in this paper are in accordance with the structures of the S(2) pocket previously described. In addition, the substrate with 4-aminocyclohexyl-alanine presented the highest affinity to cathepsin B although the peptide was obtained from a mixture of cis/trans isomers of the amino acid and we were not able to separate them. For comparison all the obtained substrates were assayed with cathepsin L and papain.     

Thyroglobulin processing by thyroidal proteases. Major sites of cleavage by cathepsins B, D, and L

The normal provision of thyroid hormones to the body requires their release from the prohormone, thyroglobulin (Tg). Previous work established the importance of cathepsins B, D, and L (formerly designated cysteine proteinase I) to this process but had not defined the points of proteolytic attack for each enzyme. In the present study we labeled rabbit Tg in vivo with sodium 125I and performed limited digestions with cathepsins B, D, and L, purified from human thyroids. The resultant peptide fragments were analyzed by amino-terminal sequencing and located within the Tg molecule by comparison with the cDNA-derived sequences from human Tg. We identified three cleavage points for cathepsin B, corresponding to P'1 residues 532, 795, and 2487; four cleavage points for cathepsin L, corresponding to P'1 residues 2389, 2452, 2490, and 2657; and four cleavage points for cathepsin D, corresponding to P'1 residues 551, 1835, 2468, and 2643. None of the cleavage points was near Tgs known hormonogenic sites, but these peptide fragments contained three of the four major hormonogenic sites in rabbit Tg, suggesting some preference for their early proteolytic processing. Cathespin B alone among the three endopeptidases had some exopeptidase activity toward Tg. The cleavage specificities for each of the endopeptidases resembled those described with other protein substrates. Thus, cathepsin D preferentially cleaved bonds between hydrophobic residues, and cathespin L cleaved bonds with hydrophobic residues at P2 and P3. Although cathepsin Bs specificity was less obvious, it produced a major cleavage between 2 leucine residues. The existence of three endopeptidases cleaving at different sites shows that Tg proteolysis is a complex process, suggests synergism among their enzyme activities, and provides a physiological mechanism for selective hormone release, including its regulation by TSH.     

A single amino acid substitution affects substrate specificity in cysteine proteinases from Fasciola hepatica

The trematode Fasciola hepatica secretes a number of cathepsin L-like proteases that are proposed to be involved in feeding, migration, and immune evasion by the parasite. To date, six full cDNA sequences encoding cathepsin L preproproteins have been identified. Previous studies have demonstrated that one of these cathepsins (L2) is unusual in that it is able to cleave substrates with a proline in the P2 position, translating into an unusual ability (for a cysteine proteinase) to clot fibrinogen. In this study, we report the sequence of a novel cathepsin (L5) and compare the substrate specificity of a recombinant enzyme with that of recombinant cathepsin L2. Despite sharing 80% sequence identity with cathepsin L2, cathepsin L5 does not exhibit substantial catalytic activity against substrates containing proline in the P2 position. Molecular modeling studies suggested that a single amino acid change (L69Y) in the mature proteinases may account for the difference in specificity at the S2 subsite. Recombinant cathepsin L5/L69Y was expressed in yeast and a substantial increase in the ability of this variant to accommodate substrates with a proline residue in the P2 position was observed. Thus, we have identified a single amino acid substitution that can substantially influence the architecture of the S2 subsite of F. hepatica cathepsin L proteases.     

Characterisation of cysteine proteinases responsible for digestive proteolysis in guts of larval western corn rootworm (Diabrotica virgifera) by expression in the yeast Pichia pastoris

Cysteine proteinases are the major class of enzymes responsible for digestive proteolysis in western corn rootworm (Diabrotica virgifera), a serious pest of maize. A larval gut extract hydrolysed typical cathepsin substrates, such as Z-phe-arg-AMC and Z-arg-arg-AMC, and hydrolysis was inhibited by Z-phe-tyr-DMK, specific for cathepsin L. A cDNA library representing larval gut tissue mRNA contained cysteine proteinase-encoding clones at high frequency. Sequence analysis of 11 cysteine proteinase cDNAs showed that 9 encoded cathepsin L-like enzymes, and 2 encoded cathepsin B-like enzymes. Three enzymes (two cathepsin L-like, DvRS5 and DvRS30, and one cathepsin B-like, DvRS40) were expressed as recombinant proteins in culture supernatants of the yeast Pichia pastoris. The cathepsin L-like enzymes were active proteinases, whereas the cathepsin B-like enzyme was inactive until treated with bovine trypsin. The amino acid residue in the S2 binding pocket, the major determinant of substrate specificity in cathepsin cysteine proteinases, predicted that the two cathepsin L-like enzymes, DvRS5 and DvRS30, should differ in substrate specificity, with the latter resembling cathepsin B in hydrolysing substrates with a positively charged residue at P2. This prediction was confirmed; DvRS5 only hydrolysed Z-phe-arg-AMC and not Z-arg-arg-AMC, whereas DvRS30 hydrolysed both substrates. The enzymes showed similar proteolytic activity towards peptide substrates.     

Selective inhibition of the collagenolytic activity of human cathepsin K by altering its S2 subsite specificity

The primary specificity of papain-like cysteine proteases (family C1, clan CA) is determined by S2-P2 interactions. Despite the high amino acid sequence identities and structural similarities between cathepsins K and L, only cathepsin K is capable of cleaving interstitial collagens in their triple helical domains. To investigate this specificity, we have engineered the S2 pocket of human cathepsin K into a cathepsin L-like subsite. Using combinatorial fluorogenic substrate libraries, the P1-P4 substrate specificity of the cathepsin K variant, Tyr67Leu/Leu205Ala, was determined and compared with those of cathepsins K and L. The introduction of the double mutation into the S2 subsite of cathepsin K rendered the unique S2 binding preference of the protease for proline and leucine residues into a cathepsin L-like preference for bulky aromatic residues. Homology modeling and docking calculations supported the experimental findings. The cathepsin L-like S2 specificity of the mutant protein and the integrity of its catalytic site were confirmed by kinetic analysis of synthetic di- and tripeptide substrates as well as pH stability and pH activity profile studies. The loss of the ability to accept proline in the S2 binding pocket by the mutant protease completely abolished the collagenolytic activity of cathepsin K whereas its overall gelatinolytic activity remained unaffected. These results indicate that Tyr67 and Leu205 play a key role in the binding of proline residues in the S2 pocket of cathepsin K and are required for its unique collagenase activity.     

On the substrate specificity of cathepsins B1 and B2 including a new fluorogenic substrate for cathepsin B1.

Cathepsin B1 from bovine spleen exhibited its greatest rates of hydrolysis on peptide β-naphthylamide (βNA) derivatives containing paired basic residues, i.e., Cbz-Arg-Arg-βNA, t-Boc-Lys-Lys-βNA, and t-Boc-Lys-Arg-βNA. Internal peptide bonds were not attacked. At its pH 6.5 optimum, cathepsin B1 hydrolyzed Cbz-Arg-Arg-βNA (K_m 0.18 mM) 64 times faster than Bz-DL-Arg-βNA (K_m 3.3 mM or 1.6 mM for the L isomer) and was therefore chosen to replace the latter as a more soluble and sensitive substrate for the assay of cathepsin B1. Although cathepsin B2 had no action on the β-naphthylamide substrates, it did manifest carboxypeptidase activity by attacking COOH-terminal residues exposed by the action of cathepsin B1. At its pH 5.0 optimum, cathepsin B2 behaved as a SH-dependent, non-specific carboxypeptidase by releasing COOH-terminal amino acids from a variety of Cbz-Gly-X substrates and polypeptides such as glucagon, Val-Leu-Ser-Glu-Gly, and penta-lysine.     

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.     

Human brain cathepsin H as a neuropeptide and bradykinin metabolizing enzyme

Highly purified human brain cathepsin H (EC 3.4.22.16) was used to study its involvement in degradation of different brain peptides. Its action was determined to be selective. On Leu-enkephalin, dynorphin (1-6), dynorphin (1-13), alpha-neoendorphin, and Lys-bradykinin, it showed a preferential aminopeptidase activity by cleaving off hydrophobic or basic amino acids. It showed no aminopeptidase activity on bradykinin, which has Pro adjacent to its N-terminal amino acid, on neurotensin with blocked N-terminal amino acid, or on dermorphin with second amino acid D-alanine. After prolonged incubation, cathepsin H acted as an endopeptidase. Dermorphin and dynorphin (1-13) were cleaved at bonds with Phe in the P2 position, while dynorphin (1-6), alpha-neoendorphin, bradykinin and Lys-bradykinin were cleaved at bonds with Gly in the P2 position. Further on, it was shown that human brain cathepsin H activity could be controlled in vivo by cystatin C in its full-length form or its [delta1-10] variant, already known to be co-localized in astrocytes, since the Ki values for the inhibition are in the 10(-10) M range.     

Analysis of Fasciola cathepsin L5 by S2 subsite substitutions and determination of the P1-P4 specificity reveals an unusual preference

Fasciola parasites (liver flukes) express numerous cathepsin L proteases that are believed to be involved in important functions related to host invasion and parasite survival. These proteases are evolutionarily divided into clades that are proposed to reflect their substrate specificity, most noticeably through the S(2) subsite. Single amino acid substitutions to residues lining this site, including amino acid residue 69 (aa69; mature cathepsin L5 numbering) can have profound influences on subsite architecture and influence enzyme specificity. Variations at aa69 among known Fasciola cathepsin L proteases include leucine, tyrosine, tryptophan, phenylalanine and glycine. Other amino acids (cysteine, serine) might have been expected at this site due to codon usage as cathepsin L isoenzymes evolved, but C69 and S69 have not been observed. The introduction of L69C and L69S substitutions into FhCatL5 resulted in low overall activity indicating their expression provides no functional advantage, thus explaining the absence of such variants in Fasciola. An FhCatL5 L69F variant showed an increase in the ability to cleave substrates with P(2) proline, indicating F69 variants expressed by the fluke would likely have this ability. An FhCatL2 Y69L variant showed a decreased acceptance of P(2) proline, further highlighting the importance of Y69 for FhCatL2 P(2) proline acceptance. Finally, the P(1)-P(4) specificity of Fasciola cathepsin L5 was determined and, unexpectedly, aspartic acid was shown to be well accepted at P(2,) which is unique amongst Fasciola cathepsins examined to date.     

Studies on cathepsins of rat liver lysosomes. III. Hydrolysis of peptides, and inactivation of angiotensin and bradykinin by cathepsin A.

Systematic analysis of the hydrolysis of benzyloxycarbonyl (Cbz)-dipeptides by cathepsin A [EC 3.4.12.1] purified from rat liver lysosomes showed that multiple forms of cathepsin A preferentially cleave peptide bonds with leucine, methionine, and phenylalanine. Cbz-Met-Met, -Met-Phe, -Phe-Met, and -Phe-Ala were hydrolyzed 6 to 8 times faster than the standard substrates, Cbz-Glu-Phe and Cbz-Glu-Tyr. The pH optima of the hydrolyses were 4.6 to 5.8. Hydrolysis of peptide bonds with glycine, isoleucine, and proline was very slow, but the rate depended on the nature of the adjacent amino acids. Proteins such as albumin, cytochrome c, gamma-globulin, hemoglobin, histone, myoglobin, and myosin were scarecely degraded. Peptide hormones, such as glucagon and adrenocorticotropic hormone (ACTH) were hydrolyzed markedly with optimum pH's of 4.5 and 4.6, respectively. Angiotensin I, II, bradykinin, Lys- and Met-Lysbradykinin (kallidin and Met-kallidin), and substance P were also hydrolyzed at appreciable rates. pH optima for these peptide hormones were 5.2 to 5.6. On the other hand, insulin and its A chain, luteinizing hormone-releasing hormone (LH-RH), oxytocin and vasopressin were cleaved slowly. In the hydrolyses of glucagon and other peptides, multiple forms of rat liver lysosomal cathepsin A again showed a carboxypeptidase nature, cleaving peptide bonds sequentially from the carboxyl terminal. Almost all of the amino acids were cleaved on prolonged incubation. Vaso-activites of angiotensin II and bradykinin were rapidly lost on hydrolysis by cathepsin A. Lysosomal cathepsin C [dipeptidylaminopeptidase I, EC 3.4.14.1] also activated angiotensin II, but did not inactive bradykinin. Cathepsin A, therefore, can be regarded as one of the lysosomal angiotensinases and kinases. No distinct differences were observed between the multiple forms of cathepsin A in these hydrolyses and inactivations of peptides.     

Purification and characterization of a calcium-activated neutral protease from monkey brain and its action on neuropeptides

A calcium-activated neutral protease was purified from Japanese monkey brain by ammonium sulfate fractionation and sequential column chromatographies monitored by assay of caseinolytic activity. The purified enzyme gave a single protein band on non-denaturing polyacrylamide gel electrophoresis, and consisted of two subunits with molecular weights of 74,000 and 20,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme required millimolar order calcium ions for activation, and was optimally active at pH 7.5-8.0. Upon incubation with various neuropeptides as substrates, the enzyme preferentially cleaved the peptide bonds with Arg, Lys, or Tyr at the P1 position and an amino acid residue with a bulky aliphatic side chain, such as Leu, Val, or Ile, at the P2 position. The hydrolytic activity toward neuropeptides as well as casein was strongly inhibited by various thiol protease inhibitors. These results suggested that the brain calcium-activated neutral protease may participate in the degradation of neuropeptides in vivo.     

A membrane-bound metallo-endopeptidase from rat kidney. Characteristics of its hydrolysis of peptide hormones and neuropeptides.

A membrane-bound metallo-endopeptidase that hydrolyzes human parathyroid hormone (1-84) and reduced hen egg lysozyme between hydrophilic amino acid residues was isolated from rat kidney [Yamaguchi et al. (1991) Eur. J. Biochem. 200, 563-571]. In this study, the hydrolyses of various peptide hormones and neuropeptides by the metallo-endopeptidase were examined using an automated gas-phase protein sequencer. The purified enzyme hydrolyzed the oxidized insulin B chain and substance P most rapidly, followed by big endothelin 1, neurotensin, angiotensin 1, endothelin 1, rat alpha-atrial natriuretic peptide and bradykinin, in this order. The enzyme mainly cleaved these peptides at bonds involving a hydrophilic amino acid residue. However, it cleaved bonds between less hydrophilic amino acid pairs in several short peptides, e.g. at the His5-Leu6 bond in oxidized insulin B chain, the Ile28-Val29 bond in big endothelin-1 and the Ile5-His6 and Phe8-His9 bonds in angiotensin 1. The enzyme cleavage sites of oxidized insulin B chain and angiotensin 1 were different from the reported sites cleaved by meprin and by endopeptidase 2, respectively. Kinetic determination of bradykinin hydrolysis by the purified enzyme yielded values of Km = 18.1 microM and kcat = 0.473 s-1, giving a ratio of kcat/Km = 2.62 x 10(4) s-1.M-1. The Km value was about 20-fold lower than that reported for meprin and endopeptidase 2. These results indicate that the membrane-bound metallo-endopeptidase from rat kidney is distinguished from meprin and endopeptidase 2 in its substrate specificity and is not parathyroid hormone specific, but has potential capacities to inactivate various biologically active peptide hormones and neuropeptides in vivo.