Investigation of the catalytic site of actinidin by using benzofuroxan as a reactivity probe with selectivity for the thiolate-imidazolium ion-pair systems of cysteine proteinases. Evidence that the reaction of the ion-pair of actinidin (pKI 3.0, pKII 9.6) is modulated by the state of ionization of a group associated with a molecular pKa of 5.5

The interplay of electrostatic fields and binding interactions determining catalytic-site reactivity in actinidin. A possible origin of differences in the behaviour of actinidin and papain

1. The pH-dependence of the second-order rate constant (k) for the reaction of actinidin (EC 3.4.22.14) with 2-(N'-acetyl-L-phenylalanylamino)ethyl 2'-pyridyl disulphide was determined and the contributions to k of various hydronic states were evaluated. 2. The data were used to assess the consequences for transition-state geometry of providing P2/S2 hydrophobic contacts in addition to hydrogen-bonding opportunities in the S1-S2 intersubsite region. 3. The P2/S2 contacts (a) substantially improve enzyme-ligand binding, (b) greatly enhance the contribution to reactivity of the hydronic state bounded by pKa 3 (the pKa characteristic of the formation of catalytic-site-S-/-ImH+ state) and pKa 5 (a relatively minor contributor in reactions that lack the P2/S2 contacts), such that the major rate optimum occurs at pH 4 instead of at pH 2.8-2.9, and (c) reveal the kinetic influence of a pKa approx. 6.3 not hitherto observed in reactions of actinidin. 4. Possibilities for the interplay of electrostatic effects and binding interactions in both actinidin and papain (EC 3.4.22.2) are discussed.

Supracrystallographic resolution of interactions contributing to enzyme catalysis by use of natural structural variants and reactivity-probe kinetics

1. The influence on the reactivities of the catalytic sites of papain (EC 3.4.22.2) and actinidin (3.4.22.14) of providing for interactions involving the S1-S2 intersubsite regions of the enzymes was evaluated by using as a series of thiol-specific two-hydronic-state reactivity probes: n-propyl 2-pyridyl disulphide (I) (a 'featureless' probe), 2-(acetamido)ethyl 2'-pyridyl disulphide (II) (containing a P1-P2 amide bond), 2-(acetoxy)ethyl 2'-pyridyl disulphide (III) [the ester analogue of probe (II)] and 2-carboxyethyl 2'-pyridyl disulphide N-methylamide (IV) [the retroamide analogue of probe (II)]. Syntheses of compounds (I), (III) and (IV) are reported. 2. The reactivities of the two enzymes towards the four reactivity probes (I)-(IV) and also that of papain towards 2-(N'-acetyl-L-phenylalanylamino)ethyl 2'-pyridyl disulphide (VII) (containing both a P1-P2 amide bond and an L-phenylalanyl side chain as an occupant for the S2 subsite), in up to four hydronic (previously called protonic) states, were evaluated by analysis of pH-dependent stopped-flow kinetic data (for the release of pyridine-2-thione) by using an eight-parameter rate equation [described in the Appendix: Brocklehurst & Brocklehurst (1988) Biochem. J. 256, 556-558] to provide pH-independent rate constants and macroscopic pKa values. The analysis reveals the various ways in which the two enzymes respond very differently to the binding of ligands in the S1-S2 intersubsite regions despite the virtually superimposable crystal structures in these regions of the molecules. 3. Particularly striking differences between the behaviour of papain and that of actinidin are that (a) only papain responds to the presence of a P1-P2 amide bond in the probe such that a rate maximum at pH 6-7 is produced in the pH-k profile in place of the rate minimum, (b) only in the papain reactions does the pKa value of the alkaline limb of the pH-k profile change from 9.5 to approx. 8.2 [the value characteristic of a pH-(kcat./Km) profile] when the probe contains a P1-P2 amide bond, (c) only papain reactivity is affected by two positively co-operative hydronic dissociations with pKI congruent to pKII congruent to 4 and (d) modulation of the reactivity of the common -S(-)-ImH+ catalytic-site ion-pair (Cys-25/His-159 in papain and Cys-25/His-162 in actinidin) by hydronic dissociation with pKa approx. 5 is more marked and occurs more generally in reactions of actinidin than is the case for papain reactions.(ABSTRACT TRUNCATED AT 400 WORDS)

Differences in the chemical and catalytic characteristics of two crystallographically 'identical' enzyme catalytic sites. Characterization of actinidin and papain by a combination of pH-dependent substrate catalysis kinetics and reactivity probe studies targeted on the catalytic-site thiol group and its immediate microenvironment

The characteristics of actinidin (EC 3.4.22.14) and papain (EC 3.4.22.2), two cysteine proteinases whose catalytic-site regions appear to superimpose to a degree that approaches atomic co-ordinate accuracy of both crystal structures, were evaluated by determining (a) the pH-dependence in acid media of the acylation process of the catalytic act (k+2/Ks) using N alpha-benzoyl-L-arginine p-nitroanilide (L-Bz-Arg-Nan) as substrate and (b) the sensitivity of the reactivity of the catalytic-site thiol group and its pH-dependence to structural change in small, thiol-specific, two-protonic-state reactivity probes (2,2'-dipyridyl disulphide and methyl 2-pyridyl disulphide) where enzyme-probe contacts should be restricted to areas close to the catalytic site. Distortion of the catalytic sites of the two enzymes at pH less than 4 was evaluated over time-scales appropriate for both stopped-flow reactivity probe kinetics (less than or equal to 1-2 s) and steady-state substrate catalysis kinetics (3-5 min) by using the 2,2'-dipyridyl disulphide monocation as a titrant for non-distorted catalytic sites. This permitted a lower pH limit to be defined for valid kinetic analysis of both types. The behaviour of the enzymes at pH less than 4 requires a kinetic model in which the apparently biomolecular reaction of enzyme with probe reagent is separated from the process leading to loss of conformational integrity by a potentially reversible step. The acylation of actinidin with L-Bz-Arg-Nan in acidic media occurs in two protonic states, one produced by raising the pH across pKa less than 4 which probably characterizes the formation of -S-/-ImH+ ion pair (pKa approx. 3) and the other, of higher reactivity, produced by raising the pH across pKa 5.5, which may characterize rearrangement of catalytic-site geometry. The pH-dependence of the acylation of papain by L-Bz-Arg-Nan is quite different and is not influenced by protonic dissociation with pKa values in the range 5-6. The earlier conclusion that the acylation of papain depends on two protonic dissociations each with pKa approx. 4 was confirmed. This argument is now more firmly based because titration with 2,2'-dipyridyl disulphide permits the loss of conformational integrity to be taken into account in the analysis of the kinetic data at very low pH. Methyl 2-pyridyl disulphide was synthesized by reaction of pyridine-2-thione with methyl methanethiolsulphonate and its pKa at I = 0.1 was determined by spectral analysis at 307 nm to be 2.8.(ABSTRACT TRUNCATED AT 400 WORDS)

Chemical evidence for the pH-dependent control of ion-pair geometry in cathepsin B. Benzofuroxan as a reactivity probe sensitive to differences in the mutual disposition of the thiolate and imidazolium components of cysteine proteinase catalytic sites

Benzofuroxan reacts with the catalytic-site thiol group of cathepsin B (EC 3.4.22.1) to produce stoichiometric amount of the chromophoric reduction product, o-benzoquinone dioxime. In a study of the pH-dependence of the kinetics of this reaction, most data were collected for the bovine spleen enzyme, but the more limited data collected for the rat liver enzyme were closely similar both in the magnitude of the values of the second-order rate constants (k) and in the shape of the pH-k profile. In acidic and weakly alkaline media, the reaction is faster than the reactions of benzofuroxan with some other cysteine proteinases. For example, in the pH region around 5-6, the reaction of cathepsin B is about 10 times faster than that of papain, 15 times faster than that of stem bromelain and 6 times faster than that of ficin. The pH-dependence of k for the reaction of cathepsin B with benzofuroxan was determined in the pH range 2.7-8.3. In marked contrast with the analogous reactions of papain, ficin and stem bromelain [reported by Shipton & Brocklehurst (1977) Biochem. J. 167, 799-810], the pH-k profile for the cathepsin B reaction contains a sigmoidal component with pKa 5.2 in which k increases with decrease in pH. This modulation of the reactivity of the catalytic-site -S-/-ImH+ ion-pair state of cathepsin B (produced by protonic dissociation from -SH/-ImH+ with pKa approx. 3) towards a small, rigid, electrophilic reagent, in a reaction that appears to involve both components of the ion-pair for efficient reaction, suggests that the state of ionization of a group associated with a molecular pKa of approx. 5 may control ion-pair geometry. This might account for the remarkable finding [reported by Willenbrock & Brocklehurst (1984) Biochem. J. 222, 805-814] that, although the ion-pair appears to be generated in cathepsin B as the pH is increased across pKa 3.4, catalytic competence is not generated until the pH is increased across pKa 5-6.

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.

A general framework of cysteine-proteinase mechanism deduced from studies on enzymes with structurally different analogous catalytic-site residues Asp-158 and -161 (papain and actinidin), Gly-196 (cathepsin B) and Asn-165 (cathepsin H). Kinetic studies up to pH 8 of the hydrolysis of N-alpha-benzyloxycarbonyl-L-arginyl-L-arginine 2-naphthylamide catalysed by cathepsin B and of L-arginine 2-naphthylamide catalysed by cathepsin H

The pH-dependences of kcat, Km and kcat./Km for the hydrolysis at 25 degrees C at I 0.1 of L-arginine 2-naphthylamide catalysed by cathepsin H from bovine spleen were determined in the pH range approx. 4-8. The pH-dependences of these kinetic parameters were determined also for the hydrolysis at 25 degrees C at I 0.1 of N-alpha-benzyloxycarbonyl-L-arginyl-L-arginine 2-naphthylamide catalysed by cathepsin B (EC 3.4.22.1) from bovine spleen in the pH range 7-8, which extends the studies in acidic media reported by Willenbrock & Brocklehurst [(1984) Biochem. J. 222, 805-814]. These results are discussed and related to those from the reactivity-probe kinetics reported in the preceding paper [Willenbrock & Brocklehurst (1985) Biochem. J. 227, 511-519] and to known structural features present in rat liver cathepsins B and H and in papain (EC 3.4.22.2) and actinidin (EC 3.4.22.14). Consideration of the kinetic data leads to the suggestion that in the cysteine proteinases rearrangement of intimate S-/ImH+ ion-pairs in catalytic sites is brought about by a combination of field effects in the immediate vicinity of the ion-pair and consequences of protonic dissociation of a group with pKa 5-6 remote from the catalytic site. The contributions of the two types of effect seem to differ from enzyme to enzyme. Of the four cysteine proteinases considered, only cathepsin B exerts an absolute requirement for the proton-deficient form of a group with pKa 5-6 for catalytic activity. Protonic dissociation with pKa 5-6 enhances catalytic activity in cathepsin H and in actinidin and appears to have little or no effect in papain. Only cathepsin B lacks a polar or negatively charged side chain in the residue analogous to Asp-158 in papain, and this is suggested to account for its total dependence on a protonic dissociation remote from the catalytic site.

Preparation of cathepsins B and H by covalent chromatography and characterization of their catalytic sites by reaction with a thiol-specific two-protonic-state reactivity probe. Kinetic study of cathepsins B and H extending into alkaline media and a rapid spectroscopic titration of cathepsin H at pH 3-4

A procedure for the isolation of cathepsin B (EC 3.4.22.1) and of cathepsin H from bovine spleen involving covalent chromatography by thiol-disulphide interchange and ion-exchange chromatography was devised. The stabilities of both cathepsins in alkaline media are markedly temperature-dependent, and reliable kinetic data can be obtained at pH values up to 8 by working at 25 degrees C with a continuous spectrophotometric assay. Both enzyme preparations contain only one type of thiol group as judged by reactivity characteristics towards 2,2'-dipyridyl disulphide at pH values up to 8; in each case this thiol group is essential for catalytic activity. Cathepsin H was characterized by kinetic analysis of the reactions of its thiol group with 2,2'-dipyridyl disulphide in the pH range approx. 2-8 and the analogous study on cathepsin B [Willenbrock & Brocklehurst (1984) Biochem. J. 222, 805-814] was extended to include reaction at pH values up to approx. 8. Cathepsin H, like the other cysteine proteinases, was shown to contain an interactive catalytic-site system in which the nucleophilic character of the sulphur atom is maintained in acidic media. The considerable differences in catalytic site characteristics detected by this two-protonic-state reactivity probe between cathepsin B, cathepsin H, papain (EC 3.4.22.2) and actinidin (EC 3.4.22.14) are discussed. Reaction with 2,2'-dipyridyl disulphide in acidic media, which is known to provide a rapid spectrophotometric active centre titration for many cysteine proteinases, is applicable to cathepsin H. This is useful because other active-centre titrations have proved unsuitable in view of the relatively low reactivity of the thiol group in cathepsin H.

Comparative resonance Raman spectroscopic and kinetic studies of acyl-enzymes involving papain, actinidin and papaya peptidase II

Resonance Raman spectra are reported for a series of dithioacyl-enzymes involving actinidin (EC 3.4.22.14) and papaya peptidase II (the more basic monothiol cysteine proteinase of Carica papaya). The acyl groups are N-benzoylglycine and N-(beta-phenylpropionyl)glycine containing C = S or 13C = S at the ester function. Comparison of the data with those for the corresponding papain (EC 3.4.22.2) analogues [Storer, Lee & Carey (1983) Biochemistry 22, 4789-4796] allows us to define the conformation of the dithioacyl group in the catalytic site. In each case the dithioacyl group is bound in a single conformation known as conformer B, in which the glycinic nitrogen atom comes into close contact with the sulphur atom of the catalytic-site cysteine residue. For the N-(beta-phenylpropionyl)glycine dithioacyl-enzymes the torsional angles of the NH-CH2-C(= S) bonds assume values typical of an essentially relaxed non-strained state. However, for the N-benzoylglycine dithioacyl-enzymes there is evidence for a slightly perturbed conformer B, and the perturbation is most pronounced for N-benzoylglycine dithioacyl-actinidin. Values of k+2/Ks and k+3 for the reactions of papain, actinidin and papaya peptidase II with N-benzoylglycine and N-(beta-phenylpropionyl)glycine methyl thionoesters were obtained by a pre-steady-state kinetic study. Wide variation was found in k+2/Ks, but the values of k+3 are all similar. This general picture is supported by the results from a steady-state kinetic study of the reactions of the three enzymes with N-benzoyl-L-arginine-p-nitroanilide and with N-benzyloxycarbonyl-L-lysine p-nitrophenyl ester. The similarity of the values of k+3, together with the invariance of conformer B geometry at the P1 site, suggests that the chemistry of the deacylation process is highly conserved among these three cysteine proteinases.

Differences between the electric fields of the catalytic sites of papain and actinidin detected by using the thiol-located nitrobenzofurazan label as a spectroscopic reporter group

The catalytic-site thiol groups of papain (EC 3.4.22.2) and actinidin (EC 3.4.22.14) were each labelled with the nitrobenzofurazan (Nbf) chromophore by reaction with 4-chloro-7-nitrobenzofurazan at pH 4.4. The electronic-absorption spectra of both labelled enzymes were determined in aqueous solution, in the pH ranges approx. 2-5 for S-Nbf-papain and approx. 3.3-8 for S-Nbf-actinidin, and for the latter also in 6 M-guanidinium chloride. The spectrum of S-Nbf-papain is characterized by lambda max. = 402 nm at pH 5 and by lambda max. = 422 nm at pH 2.18. The pH-dependent shift in lambda max. accompanies a pH-dependent change in A 430, the nature of which is consistent with its dependence on a single ionizing group with pKa 3.7. The spectrum of S-Nbf-actinidin is pH-independent in the pH range approx. 3.3-8 and is characterized by lambda max. = 413 nm. This absorption maximum shifts to 425 nm in 6M-guanidinium chloride. These results are discussed and related to those reported previously from studies on papain and actinidin with various reactivity probes. Despite the close similarity in the catalytic sites of papain and actinidin deduced from X-ray-diffraction studies, the considerable differences in their reactivity characteristics are mirrored by differences in their electric fields detected by the Nbf spectroscopic label. The microenvironment in the catalytic site of actinidin appears to favour the existence of ions significantly more than in the corresponding region in papain.