Selective cleavage of glycyl bonds by papaya proteinase IV

The specificity of papaya proteinase IV (PPIV) has been examined with small substrates and a protein. With both classes of substrate, the enzyme shows a marked selectivity for cleaving glycyl bonds. Boc-Ala-Ala-Gly-NHPhNO₂ is a convenient substrate for routine assays that discriminate well against chymopapain, the most common contaminant of PPIV. Sixteen cleavage points in β-trypsin were identified, of which 13 are glycyl bonds. Tentative suggestions are made as to the reasons for lack of cleavage of some other glycyl bonds. The structure of PPIV has been modelled on that of papain, and we suggest that the replacement of the highly conserved residues Gly-65 and Gly-23 by arginine and glutamic acid, respectively, can account for the specificity of PPIV.     

Interactions of papaya proteinase IV with inhibitors.

Papaya proteinase IV (PPIV) is not inhibited by chicken cystatin, or human cystatins A or C, unlike most other proteinases of the papain superfamily. The enzyme inactivates chicken cystatin and human cystatin C by limited proteolysis of the glycyl bond previously shown to be involved in the inhibitory inactivity of the cystatins, but has no action on cystatin A. Contamination of commercial crystalline papain with PPIV accounts for the limited proteolysis of cystatins by 'papain' reported previously. PPIV is slowly bound by human alpha 2-macroglobulin. The enzyme is irreversibly inactivated by E-64, and by peptidyl diazomethanes containing glycine in P1 and a hydrophobic side-chain in P2. The reaction of PPIV with iodoacetate is extremely slow. PPIV is inhibited by peptide aldehydes despite the presence of bulky sidechains in P1, suggesting that these reversible inhibitors do not bind as substrate analogues.     

The thiol proteinases from the latex of Carica papaya L. III. The primary structure of chymopapain

The amino-acid sequence of chymopapain is presented. It was isolated from the latex of the fruits from the tropical species Carica papaya L. and is, besides papain and papaya proteinase omega, the third thiol proteinase from this source. The primary structure contains 218 amino-acid residues. It was deduced from sequence analysis of the native enzyme and of peptides obtained by tryptic, chymotryptic, peptic, thermolysinolytic and mild acidic hydrolysis. Out of a total of eight cysteine residues, six are involved in the formation of three disulfide bonds, the location of which has been established with the help of peptic and thermolysinolytic peptides and fragments, obtained by mild acidic hydrolysis. Chymopapain shares 126 identical amino-acid residues (58%) with papain and 141 (65%) with papaya proteinase omega, including the three disulfide bridges and the free cysteine in position 25, required for activity. Except some amino-acid residues in the substrate-binding site, all residues involved in the catalytic mechanism are conserved. The homology between papaya proteinases is discussed.     

Chromatographic and electrophoretic analyses of papaya proteinases

Although it is known that unripe fruit from Carica papaya contains several proteinase enzymes which are used industrially, only one of these, papain, has been extensively characterized. Recently, the separate use of other enzymes of the family has been considered but information on their hydrodynamic properties is contradictory. The use of newer methods of separation has enabled us to separate a proteinase which runs slowly on acidic polyacrylamide gels (papain) from the four other proteinases. The proteinase which runs fastest on acidic polyacrylamide gels has an M, of 25 k and a pI of 11.0. This latter pI is the same as that of a proteinase which has an M, of 28 k and runs more quickly than papain but more slowly than chymopapain on acidic gels. We therefore have data showing that the proteinase enzymes from papaya can be classified by pI and M, into papain (pI 8.75, M, 23 k), chymopapains A and B (pI 10.3–10.4 or 10.6–10.7 and M, 24 k), papaya proteinase A (Ω) (pI 11.0, M, 24 k) and papaya proteinase β (pI 11.0, M, 28 K).     

The proteolytic activities of chymopapain, papain, and papaya proteinase III

The three proteinases present in papaya latex: papain (EC 3.4.22.2) chymopapain and papaya proteinase III (EC 3.4.22.6), were standardized by active-site titration, and compared in proteolytic activity against azocasein, serum albumin and cartilage proteoglycan. The activities were all of the same order, although there were differences in pH dependence. SDS-polyacrylamide gel electrophoresis of the early products of digestion of albumin and phosphorylase a showed very similar patterns for the three papaya proteinases. Kinetic parameters for hydrolysis of benzyloxycarbonyl-phenylalanyl-arginyl-7(4-methyl)coumarylamide were determined for the three enzymes. Values for kcat/Km varied only within a factor of 2, but the individual constants were much higher for papain than for chymopapain and papaya proteinase III. In contrast to the results obtained with the synthetic substrate, the kinetic parameters for the initial hydrolysis of succinyl-albumin were very similar for the three papaya proteinases. This was consistent with their similar proteolytic activities in other assays.     

The thiol proteinases from the latex of Carica papaya L. IV. Proteolytic specificities of chymopapain and papaya proteinase omega determined by digestion of alpha-globin chains

The proteolytic specificities of chymopapain and papaya proteinase omega were investigated by using the alpha-chains of manatee and mole haemoglobin, whose primary structures are known, as substrates. The resulting peptides from each enzymatic cleavage were isolated by gel filtration on Sephadex G-25, followed by reversed-phase HPLC of the separated peaks and, in some cases, further purified by preparative thin-layer electrophoresis. The purified peptides were then identified on the basis of their amino-acid composition. The proteolytic specificities of chymopapain and papaya proteinase omega, deduced from the experimental cleavage patterns, are compared to that of papain. As in the case of papain, the specificity-determining factor is the amino-acid residue of the substrate that will be bound in subsite S2 (the next but one from the scissible bond). Aromatic residues in this position, preferred by papain, are not important for chymopapain and papaya proteinase omega. Cleavages preferentially occur when S2 is occupied by leucine, valine or threonine. For chymopapain, proline in position S2 also causes cleavage.     

Affinity purification of the novel cysteine proteinase papaya proteinase IV, and papain from papaya latex.

A procedure is described for the purification of a previously undetected cysteine proteinase, which we have called papaya proteinase IV, from spray-dried latex of the papaya (Carica papaya) plant. The purification involves affinity chromatography on Gly-Phe-aminoacetonitrile linked to CH-Sepharose 4B, with elution by 2-hydroxyethyl disulphide at pH 4.5. The product thus obtained is a mixture of almost fully active papain and papay proteinase IV, which are then separated by cation-exchange chromatography. A preliminary characterization of papaya proteinase IV showed it to be very similar to chymopapain in both molecular size and charge. However, the new enzyme is immunologically distinct from the previously characterized cysteine proteinases of papaya latex. It also differs in its lack of activity against the synthetic substrates of the other papaya proteinases, in its narrow specificity against protein substrates and its lack of inhibition by chicken cystatin. Papaya proteinase IV is abundant, contributing almost 30% of the protein in spray-dried papaya latex, and contamination of chymopapain preparations with this enzyme may account for some of the previously reported heterogeneity of chymopapain.     

A marked gradation in active-centre properties in the cysteine proteinases revealed by neutral and anionic reactivity probes. Reactivity characteristics of the thiol groups of actinidin, ficin, papain and papaya peptidase A towards 4,4'-dipyridyl disulphide and 5,5'-dithiobis-(2-nitrobenzoate) dianion.

1. The kinetics of the reactions of the catalytic-site thiol groups of actinidin (the cysteine proteinase from Actinidia chinensis), ficin (EC 3.4.22.3), papain (EC 3.4.22.2) and papaya peptidase A (the other monothiol cysteine proteinase component of Carica papaya) with 4,4'-dipyridyl disulphide (4-Py-S-S-4-Py) and with 5,5'-dithiobis-(2-nitrobenzoate) dianion (Nbs22-) were studied in the pH range approx. 6-10. These studies provided the pH-independent second-order rate constants (k) for the reactions of the two probe reagents with the catalytic-site thiolate anions each in the environment of a neutral histidine side chain where an active-centre carboxy group would be ionized. 2. The ratio R equal to kNbs22-/k4-Py-S-S-4-Py provides an index of the catalytic-site solvation properties of the four cysteine proteinases and varies markedly from one enzyme to another, being 0.80 for papaya peptidase A (0.86 for the model thiol, 2-mercaptoethanol), 29 for actinidin, 0.18 for ficin and 0.015 for papain. These differences appear to derive mainly from the response of the enzyme to the negative charge on Nbs22-. 3. Possible implications of these results for (a) mechanisms of cysteine proteinase catalysis and (b) the possibility of using series of functionally related enzymes in the study of mechanism are discussed.     

Purification of a 29-kDa hemocyte proteinase of Sarcophaga peregrina.

Previously, we suggested the participation of a hemocyte proteinase in the dissociation of fat body of Sarcophaga peregrina (flesh fly) at metamorphosis. We have now purified this proteinase to near homogeneity from pupal hemocytes. It is a cysteine proteinase with a molecular mass of 29 kDa and has a unique substrate specificity hydrolyzing both Suc-Leu-Leu-Val-Tyr-MCA and Z-Phe-Arg-MCA (Suc, succinyl; MCA, methylcoumaryl-7-amide; Z, carbobenzoxy), which are substrates for chymotrypsin and cathepsin B, respectively. Partial similarity was found between the amino-terminal sequence of this proteinase and that of cathepsin B, including Pro, Glu and Arg residues conserved in the papain superfamily of enzymes.     

Molecular cloning of two cysteine proteinases from paw-paw (Carica papaya).

Two cDNA clones for plant cysteine proteinases have been isolated from a Carica papaya (paw-paw, papaya) leaf tissue cDNA library by using a mixture of 16 synthetic oligodeoxyribonucleotides as a hybridization probe. The inserted regions are 311 and 440 base-pairs in length and have the potential to encode a region corresponding to the C-terminal region of two proteins which are homologous with the known plant cysteine proteinases and the mammalian thiol cathepsins. One of the sequences shows a high (greater than 77%) homology with the plant cysteine proteinase papain, the other is closely related to papaya chymopapain. One sequence contains all, and the other most, of the 3' untranslated region of the mRNA. The inserts were used as specific probes in Northern Blot analyses giving an estimated size for the two mRNA species of 1.45 kilobases.     

The thiol proteinases from the latex of Carica papaya L. I. Fractionation, purification and preliminary characterization

Three thiol proteinases, namely papain, chymopapain and proteinase omega were purified to homogeneity from the latex of Carica papaya L. During the purification procedure, the thiol function of the cysteinyl residues were protected either as mixed disulfides with cysteamine or 2-thiopyridone or as S-sulphenylthiosulfate derivative or after blocking with p-chloromercuribenzoic acid. In marked contrast with earlier publications, chymopapain also was found to be a monothiol proteinase as papain and proteinase omega. The active sites of chymopapain and proteinase omega could not be distinguished from that of papain neither by the analysis of the pH dependence of kcat/Km nor by the examination of the pH dependence of the fluorescence emission spectra.     

Subsite differences between the active centres of papaya peptidase A and papain as revealed by affinity chromatography. Purification of papaya peptidase A by ionic-strength-dependent affinity adsorption on an immobilized peptide inhibitor of papain.

An affinity column consisting of the specific peptide inhibitor of papain, Gly-Gly (O-benzyl)Tyr-Arg, attached to Sepharose was found to bind the active thiol proteinase papaya peptidase A specifically, but only at an ionic strength significantly higher than the one at which papain is bound. When a mixture of active papaya peptidase A and its irreversibly oxidized contaminant was applied to the column, the active enzyme was bound whereas the inactive material was not. The bound enzyme was released by deionized water and found to contain 1 mol of SH group/mol of protein. The different conditions required for the binding of the two enzymes to the immobilized peptide was shown to reflect different ionic-strength-dependences of the affinity of the two enzymes for the peptide in solution. Whereas the affinity of papain for the inhibitor appears to be insensitive to ionic strength over the range studied, that of papaya peptidase A is ionic-strength-dependent and always lower than that of papain. A rate assay is devised for papaya peptidase A with N-benzyloxycarbonylglycine p-nitrophenyl ester as the substrate at pH 5.5. After calibration against an active-site titration the assay yields the thiol-group concentration without interference from inactive contaminants. For the papaya peptidase A-catalysed hydrolysis of N-benzyloxycarbonylglycine p-nitrophenyl ester at pH 5.5 kcat. was found to be 16.7s-1, which is about 3 times the value found for the same reaction catalysed by papain.     

The amino acid sequence of chymopapain from Carica papaya.

Chymopapain is a polypeptide of 218 amino acid residues. It has considerable structural similarity with papain and papaya proteinase omega, including conservation of the catalytic site and of the disulphide bonding. Chymopapain is like papaya proteinase omega in carrying four extra residues between papain positions 168 and 169, but differs from both papaya proteinases in the composition of its S2 subsite, as well as in having a second thiol group, Cys-117. Some evidence for the amino acid sequence of chymopapain has been deposited as Supplementary Publication SUP 50153 (12 pages) at the British Library Document Supply Centre, Boston Spa., Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies may be obtained on the terms indicated in Biochem. J. (1990) 265, 5. The information comprises Supplement Tables 1-4, which contain, in order, amino acid compositions of peptides from tryptic, peptic, CNBr and mild acid cleavages, Supplement Fig. 1, showing re-fractionation of selected peaks from Fig. 2 of the main paper. Supplement Fig. 2, showing cation-exchange chromatography of the earliest-eluted peak of Fig. 3 of the main paper, Supplement Fig. 3, showing reverse-phase h.p.l.c. of the later-eluted peak from Fig. 3 of the main paper, and Supplement Fig. 4, showing the separation of peptides after mild acid hydrolysis of CNBr-cleavage fragment CB3.     

Proteolysis of the 85-kilodalton crystalline cysteine proteinase inhibitor from potato releases functional cystatin domains.

The protein crystals found in potato (Solanum tuberosum L.) tuber cells consist of a single 85-kD polypeptide. This polypeptide is an inhibitor of papain and other cysteine proteinases and is capable of binding several proteinase molecules simultaneously (P. Rodis, J.E. Hoff [1984] Plant Physiol 74: 907-911). We have characterized this unusual inhibitor in more detail. Titrations of papain activity with the potato papain inhibitor showed that there are eight papain binding sites per inhibitor molecule. The inhibition constant (Ki) value for papain inhibition was 0.1 nM. Treatment of the inhibitor with trypsin resulted in fragmentation of the 85-kD polypeptide into a 32-kD polypeptide and five 10-kD polypeptides. The 32-kD and 10-kD fragments all retained the ability to potently inhibit papain (Ki values against papain were 0.5 and 0.7 nM, respectively) and the molar stoichiometries of papain binding were 2 to 3:1 and 1:1, respectively. Other nonspecific proteinases such as chymotrypsin, subtilisin Carlsberg, thermolysin, and proteinase K also cleaved the 85-kD inhibitor polypeptide into functional 22-kD and several 10-kD fragments. The fragments obtained by digestion of the potato papain inhibitor with trypsin were purified by reverse-phase high-performance liquid chromatography, and the N-terminal amino acid sequence was obtained for each fragment. Comparison of these sequences showed that the fragments shared a high degree of homology but were not identical. The sequences were homologous to the N termini of members of the cystatin superfamily of cysteine proteinase inhibitors. Therefore, the inhibitor appears to comprise eight tandem cystatin domains linked by preteolytically sensitive junctions. We have called the inhibitor potato multicystatin (PMC). By immunoblot analysis and measurement of papain inhibitory activity, PMC was found at high levels in potato leaves (up to 0.6 microgram/g fresh weight tissue), where it accumulated under conditions that induce the accumulation of other proteinase inhibitors linked to plant defense. PMC may have a similar defensive role, for example in protecting the plant from phytophagous insects that utilize cysteine proteinases for dietary protein digestion.     

The thiol proteinases from the latex of Carica papaya L. II. The primary structure of proteinase omega

The complete primary structure of the proteinase omega isolated from the latex of the Carica papaya fruits is given. The polypeptide chain contains 216 amino-acid residues, the alignment of which was deduced from sequence analyses of the native enzyme, the tryptic, chymotryptic, peptic and thermolysinolytic peptides and facilitated due to the considerable degree of homology with papain and actinidin. The location of the three disulfide bridges could be established with the help of peptic and thermolysinolytic fragments. Proteinase omega shares 148 identical amino-acid residues (68.5%) with papain and 108 ones (50%) with actinidin, including the three disulfide bridges and the free cysteine residue required for activity, as well as most of the other amino-acid residues involved in the catalytic mechanism and two thirds of the glycine residues which are of structural significance. The homology with other cysteine proteinases of different origin is discussed.     

Monoclonal antibodies to the two most basic papaya proteinases

The proteinases fromCarica papaya include papain, isoenzymes of chymopapain and two proteinases A and B distinguished by their unusually high pI. The identity of one of the most basic proteinases has been questioned. The present report describes the preparation and characterisation of two monoclonal antibodies that react specifically with papaya proteinases A and B respectively and a third that identifies a common structural feature found in papain and proteinase A.     

Characterization of papaya peptidase A as a cysteine proteinase of Carica papaya L. with active-centre properties that differ from those of papain by using 2,2''-dipyridyl disulphide and 4-chloro-7-nitrobenzofurazan as reactivity probes. Use of two-protonic-state electrophiles in the identification of catalytic-site thiol groups.

1. The proteinase papaya peptidase A, one of the major components of the latex of Carica papaya L., was shown to contain 1 thiol group per molecule; this thiol group is essential for catalytic activity and is part of the catalytic site. 2. The usefulness of two-protonic-state reactivity probes coupled with modification/activity-loss data in assigning a thiol group as an integral part of the catalytic site as against merely 'essential' for activity is discussed. 3. The active centre of papaya peptidase A was investigated by using 2,2'-dipyridyl disulphide and 4-chloro-7-nitrobenzofurazan as reactivity probes. The presence in the enzyme in weakly acidic media of an interactive system containing a nucleophile S atom (pKI3.9,pKII7.9) was demonstrated. 5. Papaya peptidase A resembles ficin (EC 3.4.22.3) and actinidin (the cysteine proteinase from Actinidin chinenis) in that it does not appear to possess a carboxy group able to influence the reactivity of the thiol group by change of ionization state at pH values of about 4, a situation that contrasts markedly with that which obtains in papain. 6. Implications of the results for possible variations in cysteine proteinase mechanism are discussed.     

The amino acid sequence of a novel inhibitor of cathepsin D from potato

The amino acid sequence of a cathepsin D inhibitor isolated from potato is described. It was determined by analysis of peptides generated by use of the glycine-specific proteinase PPIV. The order of the peptides was established by examination of tryptic peptides derived from the two cyanogen bromide peptides. The inhibitor comprises 187 amino acid residues, and has a calculated Mr of 20,450.     

The characteristics of cysteine proteinases of parasitic protozoa.

Cysteine proteinases have now been detected in most of the important species of parasitic protozoa. Characterization of the enzymes and sequence determinations have revealed that the enzymes are related to papain and the mammalian cathepsins. All of the protozoan enzymes analyzed to date are members of the cathepsin L/cathepsin H/papain branch of the papain superfamily and are more distantly related to cathepsin B. They thus share some characteristics with the cysteine proteinases of their hosts. Individual enzymes, however, are likely to have sufficient novel features to be potential targets for specific antiprotozoal drugs, and a number of proteinase inhibitors and substrates are currently being tested as possible chemotherapeutic agents.     

Active papain renatured and processed from insoluble recombinant propapain expressed in Escherichia coli.

For the first time the pro-form of a recombinant cysteine proteinase has been expressed at a high level in Escherichia coli. This inactive precursor can subsequently be processed to yield active enzyme. Sufficient protein can be produced using this system for X-ray crystallographic structure studies of engineered proteinases. A cDNA clone encoding propapain, a precursor of the papaya proteinase, papain, was expressed in E. coli using a T7 polymerase expression system. Insoluble recombinant protein was solubilized in 6 M guanidine hydrochloride and 10 mM dithiothreitol, at pH 8.6. A protein-glutathione mixed disulphide was formed by dilution into oxidized glutathione and 6 M GuHCl, also at pH 8.6. Final refolding and disulphide bond formation was induced by dilution into 3 mM cysteine at pH 8.6. Renatured propapain was processed to active papain at pH 4.0 in the presence of excess cysteine. Final processing could be inhibited by the specific cysteine proteinase inhibitors E64 and leupeptin, but not by pepstatin, PMSF or EDTA. This indicates that final processing was due to a cysteine proteinase and suggests that an autocatalytic event is required for papain maturation.