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.     

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.     

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.     

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.     

Papaya proteinase IV amino acid sequence

The amino acid sequence of papaya proteinase IV (PPIV), a major proteinase from the latex of Carica papaya [(1989) Biochem. J. 261, 469-476] is described. The enzyme has a high degree of sequence identity with papaya proteinase III, chymopapain and papain (81, 70 and 67%, respectively), and is clearly a member of the papain superfamily of cysteine proteinases. Nevertheless, the sequence shows substitution of certain residues conserved in all other known members of the superfamily. It is suggested that some of these substitutions may account for the unusual specificity of PPIV.     

Isolation and primary structure of the CCI papain-like cysteine proteinases from the latex of Carica candamarcensis hook.

The dried latex of the mountain papaya, Carica candamarcensis, was chromatographed on CM-Sephadex C50, giving rise to three peaks (CCI, CCII and CCIII) with amidase activity on N-alpha-benzoyl-DL-arginine-4-nitroanilide. The less basic, most active, peak, CCI, was separated into two components, CCIa and CCIb, by reverse-phase HPLC under denaturing conditions. The primary structures of CCIa and CCIb are presented. They were deduced from sequence analysis of the whole proteins and peptides resulting from enzymatic digestions. Both proteinases are made of 213 amino acid residues, CCIb sharing 88-89% similarity with the three subvariants (G90/R212, E90/R212, E90/K212) of CCIa. 139-140 amino acid residues (65.8%) of CCIa and 141 residues (66.5%) of CCIb are common to papain. The seven cysteine residues are aligned with those of papain and the catalytic triad (Cys25, His159, Asn175) of all cysteine peptidases of the papain family is conserved. The similarity with the other cysteine proteases from Carica papaya is discussed.     

Chymopapain A. Purification and investigation by covalent chromatography and characterization by two-protonic-state reactivity-probe kinetics, steady-state kinetics and resonance Raman spectroscopy of some dithioacyl derivatives.

Chymopapain A was isolated from the dried latex of papaya (Carica papaya) by ion-exchange chromatography followed by covalent chromatography by thiol-disulphide interchange. The latter procedure was used to produce fully active enzyme containing one essential thiol group per molecule of protein, to establish that the chymopapain A molecule contains, in addition, one non-essential thiol group per molecule and to recalculate the literature value of epsilon 280 for the enzyme as 36 000 M-1 X cm -1. The Michaelis parameters for the hydrolysis of L-benzoylarginine p-nitroanilide and of benzyloxy-carbonyl-lysine nitrophenyl ester at 25 degrees C, and I 0.1 at several pH values catalysed by chymopapain A, papaya proteinase omega, papain (EC 3.4.22.2) and actinidin (EC 3.4.22.14) were determined. Towards these substrates chymopapain A has kcat./km values similar to those of actinidin and of papaya proteinase omega and significantly lower than those of papain or ficin. The environment of the catalytic site of chymopapain A is markedly different from those of other cysteine proteinases studied to date, as evidenced by the pH-dependence of the second-order rate constant (k) for the reaction of the catalytic-site thiol group with 2,2'-dipyridyl disulphide. The striking bell-shaped component that is a characteristic feature of the reactions of S-/ImH+ (thiolate/imidazolium) ion-pair components of many cysteine-proteinase catalytic sites with the 2,2'-dipyridyl disulphide univalent cation is not present in the pH-k profile for the chymopapain A reaction. The result is consistent with the presence of an additional positive charge in, or near, the catalytic site that repels the cationic form of the probe reagent. Resonance Raman spectra were collected at pH values 2.5, 6.0 and 8.0 for each of the following dithioacyl derivatives of chymopapain A: N-benzoylglycine-, N-(Beta-phenylpropionl)glycine- and N-methoxycarbonylphenylalanylglycine-. The main conclusion of the spectral study is that in each case the acyl group binds as a single population known as conformer B in which the glycinic N atom is in close contact with the thiol S atom of the catalytic-site cysteine residue, as is the case also for papain and other cysteine proteinases studied. Thus the abnormal catalytic-site environment of chymopapain A detected by the reactivity-probe studies, which may have consequences for the acylation step of the catalytic act, does not perturb the conformation of the bound acyl group at the acyl-enzyme-intermediate stage of catalysis.     

Chymotryptic inhibitor I from potatoes. The amino acid sequence of subunit A

The amino acid sequence of subunit A of the potato chymotryptic inhibitor I was determined. The sequence was deduced from analysis of fragments and peptides derived from the protein by cleavage with cyanogen bromide, N-bromosuccinimide and dilute acid, and by digestion with trypsin, thermolysin, pepsin and papain. The molecule consists of a single polypeptide chain of 84 residues, which contains two homologous regions each of 13 amino acids. The protein does not appear to be homologous with any other known proteinase inhibitors.     

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).     

Chymopapain. Chromatographic purification and immunological characterization.

Chymopapain (EC 3.4.22.6) was purified from commercially available spray-dried latex of papaya (Carica papaya) fruit by (NH4)2SO4 fractionation and fast protein chromatography on the Mono S cation-exchange column. Multiple forms of chymopapain separated chromatographically were shown to be immunologically identical. A major form was isolated and found to be homogeneous by several criteria, and fully active, and its N-terminal amino acid was identified as tyrosine. Latex from fresh unripe papaya fruit contained predominantly one form of chymopapain, and it is concluded that chymopapain is a single enzyme distinct from the other cysteine proteinases of C. papaya latex.     

A two-step procedure for purification of papain from extract of papaya latex

A method is presented for purifying papain from extracts of papaya latex. The procedure involves precipitation of the extract of papaya latex with sodium chloride followed by affinity chromatography of the redissolved precipitate. Precipitation of the protein from the latex extract is necessary to separate the papain from material which interferes with the binding of papain to the affinity column. During affinity chromatography, the affinity column is overloaded to insure absence in the final product of impurities which are capable of binding to the affinity column.The papain prepared by this procedure yielded an amino acid analysis and an N-terminal amino acid analysis expected for a sample of pure papain. No Met was detected on amino acid analysis nor was the presence of N-terminal residues other than He detected. On polyacrylamide disc gel electrophoresis at pH 4.3, papain prepared by the method described in this work was indistinguishable from crystalline papain which was prepared by the method of Kimmel and Smith, and further purified by affinity chromatography. Both disc gel patterns consisted of a single band and a trailing shadow which was less than 5% of the main band. In routine spectrophotometric assays, the specific activity toward N,α-benzoyl-l-arginine ethyl ester of papain prepared by the procedure described in this work was indistinguishable from crystalline papain prepared by the method of Kimmel and Smith, and further purified by affinity chromatography. Values of 24 sec^?1' and 15 mm were obtained from the turnover number and K_m for the papain-catalyzed hydrolysis of N,α-benzoyl-l-arginine ethyl ester at 25 °C, pH 6.00, $\text{Γ}\text{2 0.30}$ using a pH stat.     

Similarity in gene organization and homology between proteins of animal picornaviruses and a plant comovirus suggest common ancestry of these virus families

The amino acid sequences deduced from the nucleic acid sequences of several animal picornaviruses and cowpea mosaic virus (CPMV), a plant virus, were compared. Good homology was found between CPMV and the picornaviruses in the region of the picornavirus 2C (P2-X protein), VPg, 3C pro (proteinase) and 3D pol (RNA polymerase) regions. The CPMV B genome was found to have a similar gene organization to the picornaviruses. A comparison of the 3C pro (proteinase) regions of all of the available picornavirus sequences and CPMV allowed us to identify residues that are completely conserved; of these only two residues, Cys-147 and His-161 (poliovirus proteinase) could be the reactive residues of the active site of a proteinase with analogous mechanism to a known proteinase. We conclude that the proteinases encoded by these viruses are probably cysteine proteinases, mechanistically related, but not homologous to papain.     

The preparation of fully active chymopapain free of contaminating proteinases

Chymopapain (EC 3.4.22.6) was purified from commercially available dried latex of papaya (Carica papaya) by extraction at acidic pH, cation-exchange chromatography and active site-directed affinity chromatography on immobilized alanyl-phenyl-alaninaldehyde semicarbazone, with elution by mercuric chloride. The product was found by immunoassay to be essentially free of the other cysteine proteinases from papaya, including papaya proteinase IV, and was fully active. The rate of alkylation of the active site cysteine of chymopapain by iodoacetate was found to be sufficiently rapid and selective for this reagent to be used as an active-site titrant.     

Purification and complex formation analysis of a cysteine proteinase inhibitor (cystatin) from seeds of Wisteria floribunda

Seeds of Wisteria floribunda contain several kinds of cysteine proteinase inhibitor (cystatin). We purified and characterized one of these inhibitors, named WCPI-3. The molecular weight of WCPI-3 was estimated to be 17,500 and 15,700 by gel filtration and SDS-PAGE, respectively. The isoelectric point was 5.7. WCPI-3 formed an equimolar complex with native papain and the dissociation constant was estimated to be 6.1 nM. Complex formation between WCPI-3 and Cys25-modified papain, such as S-carboxy-methylated or S-carbamoylmethylated papain, could not be observed by gel filtration or native PAGE analysis. A peptide fragment derived from WCPI-3 digested by Achromobacter proteinase (lysyl endopeptidase) had the amino acid sequence of VVAGVNYRFVLK. The VVAG sequence in this fragment corresponds to the conserved sequence QVVAG which is considered to be one of binding regions to cysteine proteinases. The amino acid sequence of the amino-terminal portion (34 residues) of WCPI-3 was highly homologous to that of oryzacystatin from rice seeds.     

Molecular cloning and functional expression of cDNA encoding the cysteine proteinase inhibitor with three cystatin domains from sunflower seeds

Two cysteine proteinase inhibitors, cystatins Sca and Scb, were previously isolated from sunflower seeds [Kouzuma et al. J. Biochem. 119 (1996) 1106-1113]. A cDNA clone encoding a novel phytocystatin with three repetitive cystatin domains was isolated from a cDNA library of sunflower seeds using the Sca cDNA fragment as a hybridization probe. The cDNA insert comprises 1,093 bp and encodes 282 amino acid residues. The deduced amino acid sequences of the domains are highly similar to each other (66-81%), sharing 65-90% identical residues with Sca. The cDNA was expressed in Escherichia coli cells, and then the recombinant sunflower multicystatin (SMC) was purified and its inhibitory activity toward papain was examined. SMC exhibited strong inhibitory activity toward papain, with a stoichiometry of 1:3, indicating that each cystatin domain independently functions as a potent cysteine proteinase inhibitor. Proteolysis of SMC with Asn-specific proteinase suggested that post-translational processing by an Asn-specific proteinase may give rise to mature Sca-like phytocystatins.     

Molecular cloning of cDNA for rat cathepsin C. Cathepsin C, a cysteine proteinase with an extremely long propeptide

A cDNA for rat cathepsin C (dipeptidylaminopeptidase I) was isolated. The deduced amino acid sequence of cathepsin C comprises 462 amino acid residues: 28 NH2-terminal residues corresponding to the signal peptide, 201 residues corresponding to the propeptide, and 233 COOH-terminal residues corresponding to the mature enzyme region. Four potential glycosylation sites were found, three located in the propeptide region, and one in the mature enzyme region. The amino acid sequence of mature cathepsin C has 39.5% identity to that of cathepsin H, 35.1% to that of cathepsin L, 30.1% to that of cathepsin B, and 33.3% to that of papain. Cathepsin C, therefore, is a member of the papain family, although its propeptide region is much longer than those of other cysteine proteinases and shows no significant amino acid sequence similarity to any other cysteine proteinase.     

Conformational changes of papain induced on interaction with thiol proteinase inhibitors from newborn rat epidermis

The conformational changes of the papain molecular on interaction with two thiol proteinase inhibitors (TPI(1) and TPI(2] from newborn rat epidermis were studied by measuring circular dichroism (CD), the difference absorption spectrum, and the fluorescence spectrum due to tryptophan residues in papain. The far-ultraviolet CD band of papain between 210 and 230 nm was distinctly reduced on interaction with both inhibitors. Also, the near-ultraviolet CD spectrum of TPI(1)-bound papain changed between 285 and 320 nm as well as that of the TPI(2)-bound enzyme. The difference absorption spectrum for TPI(1)-bound papain exhibited two distinct peaks at 276.5 and 282 nm, indicating perturbation of aromatic amino acid residues. The fluorescence intensity of papain was significantly decreased on interaction with both inhibitors, which showed pH-dependency on an ionizable group, with pK values of 8.5 and 7.9 for TPI(1) and TPI(2), respectively. The complex formation of papain with both inhibitors caused a reduction of the susceptibility of a tryptophan residue, probably tryptophan-177, to chemical modification with N-bromosuccinimide. These results suggest that the active site involving histidine-159 in the papain molecule was much influenced by the alteration of the microenvironment of tryptophan-177 as a part of the interaction site for these two thiol proteinase inhibitors.     

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 purification and some properties of two proteases from papaya latex.

Two proteases, one of which is papaya peptidase A and the other a previously unknown enzyme in papaya latex have been purified to homogeneity in a simple two stage process. Both are markedly less reactive than papain or chymopapain. Each has a molecular weight of 24,000, N-terminal sequences commencing Leu-Pro-Glu, and contains no carbohydrate. Their amino acid compositions differ for several residues. The essential -SH groups of the enzymes examined appear to be 'masked' in the native state.     

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.