Identification of signalling and non-signalling binding contributions to enzyme reactivity. Alternative combinations of binding interactions provide for change in transition-state geometry in reactions of papain.

1. 2-(N'-Acetyl-L-phenylalanyl)hydroxyethyl 2'-pyridyl disulphide (compound V) was synthesized, and a study of the pH-dependence of the second-order rate constant (k) for its reaction with the catalytic-site thiol group of papain (EC 3.4.22.2) was used to evaluate the consequences for transition-state geometry of the presence of a hydrophobic occupant for the S2 subsite of the enzyme in the absence of the N-H component of the P1-P2 amide bond. 2. Comparison of the pH-dependences of K for reactions of compound (V), 2-(acetamido)ethyl 2'-pyridyl disulphide (compound I) and 2-(acetoxy)ethyl 2'-pyridyl disulphide (compound III) with the cysteine-proteinase minimal catalytic-site model, benzimidazol-2-ylmethanethiol, established the activation of all of these pyridyl disulphides by hydronation and that their reactivities are relatively insensitive to structural change in the non-pyridyl part of the molecule. The marked differences in their reactivities towards papain therefore derive from binding, either directly, or indirectly via signalling mechanisms. 3. Comparison of the kinetic data for the reaction of papain with compound (V) with those for analogous reactions with reactivity probes that provide opportunities for a variety of binding interactions in the S1-S2 intersubsite region and in the S2 subsite itself lead to the following conclusions: (a) the (Gly-66) N-H...O = C less than (P1-P2 ester) interaction of papain with compound (III) provides for better binding relative to that for a probe with a simple hydrocarbon side chain, but no signalling to the catalytic site to provide a (His-159)-ImH+-assisted transition state; (b) when this interaction is augmented either by a (P1-P2 amide) N-H...O = C less than (Asp-158) interaction (compound I) or hydrophobic P2/S2 contacts (compound V), signalling to the catalytic region occurs to provide the assisted transition state; (c) when both the P2/S2 contacts and the interaction involving Gly-66 exist, provision additionally of the (P1-P2 amide) N-H...O = C less than (Asp-158) interaction [as in 2-(N'-acetyl-L-phenylalanylamino)ethyl 2'-pyridyl disulphide] serves only to assist the binding without an additional signalling effect. 4. Such studies promise to allow binding interactions that merely locate substrates in appropriate enzyme loci to be distinguished from those that transmit signals with a chemical consequence to catalytic sites.     

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)     

Consequences of molecular recognition in the S1-S2 intersubsite region of papain for catalytic-site chemistry. Change in pH-dependence characteristics and generation of an inverse solvent kinetic isotope effect by introduction of a P1-P2 amide bond into a two-protonic-state reactivity probe.

1. The pH-dependences of the second-order rate constant (k) for the reactions of papain (EC 3.4.22.2) with 2-(acetamido)ethyl 2'-pyridyl disulphide and with ethyl 2-pyridyl disulphide and of k for the reaction of benzimidazol-2-ylmethanethiol (as a minimal model of cysteine proteinase catalytic sites) with the former disulphide were determined in aqueous buffers at 25 degrees C at I 0.1. 2. Of these three pH-k profiles only that for the reaction of papain with 2-(acetamido)ethyl 2'-pyridyl disulphide has a rate maximum at pH approx. 6; the others each have a rate minimum in this pH region and a rate maximum at pH 4, which is characteristic of reactions of papain with other 2-pyridyl disulphides that do not contain a P1-P2 amide bond in the non-pyridyl part of the molecule. 3. The marked change in the form of the pH-k profile consequent upon introduction of a P1-P2 amide bond into the probe molecule for the reaction with papain but not for that with the minimal catalytic-site model is interpreted in terms of the induction by binding of the probe in the S1-S2 intersubsite region of the enzyme of a transition-state geometry in which nucleophilic attack by the -S- component of the catalytic site is assisted by association of the imidazolium ion component with the leaving group. 4. The greater definition of the rate maximum in the pH-k profile for the reaction of papain with an analogous 2-pyridyl disulphide reactivity probe containing both a P1-P2 amide bond and a potential occupant for the S2 subsite [2-(N'-acetyl-L-phenylalanylamino)ethyl 2'-pyridyl disulphide [Brocklehurst, Kowlessur, O'Driscoll, Patel, Quenby, Salih, Templeton, Thomas & Willenbrock (1987) Biochem. J. 244, 173-181]) suggests that a P2-S2 interaction substantially increases the population of transition states for the imidazolium ion-assisted reaction. 5. The overall kinetic solvent 2H-isotope effect at pL 6.0 was determined to be: for the reaction of papain with 2,2'-dipyridyl disulphide, 0.96 (i.e. no kinetic isotope effect), for its reaction with the probe containing only the P1-P2 amide bond, 0.75, for its reaction with the probe containing both the P1-P2 amide bond and the occupant for the S2 subsite, 0.61, and for kcat./Km for its catalysis of the hydrolysis of N-methoxycarbonylglycine 4-nitrophenyl ester, 0.67.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence for a two-state transition in papain that may have no close analogue in ficin. Differences in the disposition of cationic sites and hydrophobic binding areas in the active centres of papain and ficin.

The kinetics of the reactions of the active-centre thiol groups of papain (EC 3.4.22.2) and ficin (EC 3.4.22.3) with the two-protonic-state reactivity probes 2,2'-dipyridyl disulphide, n-propyl 2-pyridyl disulphide and 4-(N-aminoethyl 2'-pyridyl disulphide)- 7-nitrobenzo-2-oxa-1,3-diazole (compound I) were studied over a wide range of pH. Differences between the reactivities of ficin and papain towards the cationic forms of the alkyl 2-pyridyl disulphide probes suggest that ficin contains a cationic site without exact analogue in papain, and the striking difference in the shapes of the pH-rate profiles for the reactions of the two enzymes with compound (1) suggests differences in the mobilities or dispositions of the active-centre histidine imidazole groups with respect to relevant hydrophobic binding areas. The evidence from reactivity-probe studies that the papain catalytic mechanism involves substantial repositioning of the active-centre imidazole group during the catalytic act does not apply also to ficin. If ficin contains an aspartic acid residue analogous to aspartic acid-158 in papain, the pKa of its carboxy group is probably significantly lower than the pKa of the analogous group in papain.     

Evidence that binding to the S2-subsite of papain may be coupled with catalytically relevant structural change involving the cysteine-25–histidine-159 diad. Kinetics of the reaction of papain with a two-protonic-state reactivity probe containing a hydrophobic side chain

A method is proposed by which site-specific reactivity probes that exhibit different reactivities in two ionization states can be used to detect association-activation phenomena that involve repositioning of acid/base groups in enzyme active centres. The pH-dependences of the apparent second-order rate constants (k) for the reactions of the thiol group of papain (EC 3.4.22.2) with a series of two-protonic-state reactivity probes are compared. The short-chain probes, 2,2'-dipyridyl disulphide and n-propyl 2-pyridyl disulphide, react at pH6 in adsorptive complexes and/or transition states with geometries that do not permit hydrogen-bonding of the pyridyl nitrogen atom with the active-centre imidazolium ion, as evidenced by the rate minima at pH6 and the rate maxima at pH4 provided by reagent protonation. Only when the probe molecule, e.g. 4-(N-aminoethyl 2'-pyridyl disulphide)-7-nitrobenzo-2-oxa-1,3-diazole [compound(III)], contains a long hydrophobic side chain is the reaction characterized by maximal rates at about pH6, as in the acylation step of the catalytic act (at pH6, k(compound III)/k(2,2'-dipyridyl disulphide) approximately 100). It is proposed that this striking difference in profile shape may result from binding of the hydrophobic side chain of compound (III) possibly in the S(2)-subsite of papain, which promotes a change in catalytic-site geometry involving repositioning of the imidazolium ion of histidine-159 and hydrogen-bonding with the N atom of the leaving group, as has been postulated to occur in the acylation step of substate hydrolysis.     

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.     

Differences in the interaction of the catalytic groups of the active centres of actinidin and papain. Rapid purification of fully active actinidin by covalent chromatography and characterization of its active centre by use of two-protonic-state reactivity probes.

1. A rapid method of isolation of fully active actinidin, the cysteine proteinase from Actinidia chinensis (Chinese gooseberry or kiwifruit), by covalent chromatography, was devised. 2. The active centre of actinidin was investigated by using n-propyl 2-pyridyl disulphide, 4-(N-aminoethyl 2'-pyridyl disulphide)-7-nitrobenzo-2-oxa-1,3-diazole and 4-chloro-7-nitrobenzofurazan as reactivity probes. 3. The presence in actinidin in weakly acidic media of an interactive system containing a nucleophilic sulphur atom was demonstrated. 4. The pKa values (3.1 and 9.6) that characterize this interactive system are more widely separated than those that characterize the interactive active centre systems of ficin (EC 3.4.22.3) and papain (EC 3.4.22.2) (3.8 and 8.6, and 3.9 and 8.8 respectively). 5. Actinidin was shown to resemble ficin rather than papain in (i) the disposition of the active-centre imidazole group with respect to hydrophobic binding areas, and (ii) the inability of the active-centre aspartic acid carboxy group to influence the reactivity of the active-centre thiol group at pH values of about 4. 6. The implications of the results for one-state and two-state mechanisms for cysteine-proteinase catalysis are discussed.     

A re-appraisal of the structural basis of stereochemical recognition in papain. Insensitivity of binding-site-catalytic-site signalling to P2-chirality in a time-dependent inhibition.

1. 2-(N'-Acetyl-D-phenylalanylamino)ethyl 2'-pyridyl disulphide (compound I) [m.p. 123-124 degrees C; [alpha]20D -7.1 degrees (c 0.042 in methanol)] was synthesized, and the results of a study of the pH-dependence of the second-order rate constant (k) for its reaction with the catalytic-site thiol group of papain (EC 3.4.22.2), together with existing kinetic data for the analogous reaction of the L-enantiomer (compound II), were used to evaluate the consequences for transition-state geometry of the difference in chirality at the P2 position of the probe molecule. 2. The kinetic data suggest that the D-enantiomer binds approx. 40-fold less tightly to papain than the L-enantiomer but that the binding-site--catalytic-site signalling that results in a (His-159)-Im(+)-H-assisted transition state occurs equally effectively in the interaction of the former probe as in that of the latter. This results in pH-k profiles for the reactions of both enantiomers each characterized by four macroscopic pKa values (3.7-3.9, 4.1-4.3, 7.9-8.3 and 9.4-9.5) in which k is maximal at pH approx. 6 where the -Im(+)-H-assisted transition state is most fully developed. 3. Model building indicates that both enantiomers can bind to papain such that the phenyl ring of the N-acetylphenylalanyl group makes hydrophobic contacts in the binding pocket of the S2 subsite with preservation of the three hydrogen-bonding interactions involving the substrate analogue reagent and (Asp-158) C = O, (Gly-66) C = O, and (Gly-66)-N-H of papain. Earlier predictions that binding of N-acyl-D-phenylalanine derivatives to papain would be prevented on steric grounds [Berger & Schechter (1970) Philos. Trans. R. Soc. London B 257, 249-264; Lowe & Yuthavong (1971) Biochem. J. 124, 107-115; Lowe (1976) Tetrahedron 32, 291-302] were based on assumed models that are not consistent with the X-ray-diffraction data for papain inhibited by alkylation of Cys-25 with N-benzyloxycarbonyl-Phe-Ala-chloromethane [Drenth, Kalk & Swen (1976) Biochemistry 15, 3731-3738]. 4. The possibility that the kinetic expression of P2-S2 stereospecificity may depend on the nature of the chemistry occurring in the catalytic site of papain is discussed.(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)     

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.     

Temperature-dependences of the kinetics of reactions of papain and actinidin with a series of reactivity probes differing in key molecular recognition features

The temperature-dependences of the second-order rate constants (k) of the reactions of the catalytic site thiol groups of two cysteine peptidases papain (EC 3.4.22.2) and actinidin (EC 3.4.22.14) with a series of seven 2-pyridyl disulphide reactivity probes (R-S-S-2-Py, in which R provides variation in recognition features) were determined at pH 6.7 at temperatures in the range 4-30 degrees C by stopped-flow methodology and were used to calculate values of DeltaS++, DeltaH++ and DeltaG++. The marked changes in DeltaS++ from negative to positive in the papain reactions consequent on provision of increase in the opportunities for key non-covalent recognition interactions may implicate microsite desolvation in binding site-catalytic site signalling to provide a catalytically relevant transition state. The substantially different behaviour of actinidin including apparent masking of changes in DeltaH++ by an endothermic conformational change suggests a difference in mechanism involving kinetically significant conformational change.     

Binding specificity of papain and cathepsin B

In order to obtain useful information for the design of inhibitors of cathepsin B, an important enzyme in both physiological and pathological processes, the modes of interaction between ligands and thiol proteases (papain and cathepsin B) were analyzed. A new and powerful method was developed to quantitatively understand geometrical features of the interaction. Fairly good electrostatic complementarities were found for the oxygen atoms of P1 and P2 amide, and for the hydrogen atom of P2 amide. Electrostatic correlation potentials on the side chains of P1 and P2 were nearly neutral, so that interacting conformations in these regions are anticipated to be stabilized by hydrophobic forces rather than electrostatic ones. A three-dimensional structure of rat liver cathepsin B was deduced based on the assumption that the tertiary structure of cathepsin B is similar to that of actinidin. Furthermore, an inhibitor of the thiol proteases, benzyloxycarbonyl-L-phenylalanyl-L-alanine chloromethyl ketone was model fitted to cathepsin B, in order to investigate its mode of interaction with the enzyme. It was possible to account for some structure-activity relationships in the enzyme-ligand interactions.     

A reporter group delivery system with both absolute and selective specificity for thiol groups and an improved fluorescent probe containing the 7-nitrobenzo-2-oxa-1,3-diazole moiety.

1. 4-(N-2-Aminoethyl2'-pyridyl disulphide)-7-nitrobenzo-2-oxa-1,3-diazole (compound I) was synthesized and evaluated as a fluorescent labelling reagent for thiol groups. 2. The design of compound (I) as one example of a general type of reporter group delivery reagent (2-pyridyl-S-S-X, where X contains an environmentally sensitive spectroscopic probe) is discussed. 3. The electronic absorption spectrum of compound (I) was determined over a wide range of pH and the spectral changes that accompany its reaction with low-molecular-weight thiols, e.g. L-cysteine, and with papain (EC 3.4.22.2) and bovine serum albumin are discussed. 4. A new value of epsilon343 for 2-thiopyridone (Py-2-SH) was determined as 8.08 X 10(3) +/- 0.08 X 10(3)M-1-cm-1. 5. Spectral analysis of the reactions of compound (I) with L-cysteine and with papain (in the pH range 3.5-8.0) showed that even under equimolar conditions the reaction (thiol-disulphide interchange to release Py-2-SH) is essentially stoicheimoetric and probably proceeds by specific attack at the sulphur atom distal from the pyridyl ring of compound (I). 6. The fluorescence-emission spectra of compound (I) and of the products of its reaction with papain and with ficin (EC 3.4.22.3) were determined. Compound (I) is highly fluorescent in aqueous solution. Excitation within the intense visible absorption band (lambda max. 481 nm, epsilon max. 2.52 X 10(4)M-1-cm-1) provides green fluorescence with an emission maximum at 540 nm. Both papain and ficin labelled by reaction with compound (I) are characterized by fluorescence-emission maxima (535 nm and 530 nm respectively) of even higher intensity. The fluorescence emission of the product of the reaction of papain with compound (I) was shown to be 25 times more intense than that of the product of the reaction of papain with 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole (Nbd chloride). 7. The second-order rate constants (k2) for the reactions of compound (I) and of Nbd chloride with GSH, papain, albumin, ficin, 2-benzimidazolylmethanethiol and 2-benzimidazolylethanethiol were determined at 25.0 degrees C and various pH values. At pH4 the values of k2(compound I)/k2(Nbd chloride) are: GSH, 288; albumin, 36; papain 3 X 10(3); ficin, 3 X 10(4). 8. The pH-k2 profiles for the reactions of compound (I) and of Nbd chloride with the two 2-benzimidazolylalkanethiols were determined. Of the four profiles only that for the reaction of compound (I) with 2-benzimidazolylmethanethiol is characterized by a striking rate maximum in acidic media.     

Characterization of the papain active centre by using two-protonic-state electrophiles as reactivity probes. Evidence for nucleophilic reactivity in the un-interrupted cysteine-25-histidine-159 interactive system.

1.2,2'-Dipyridyl disulphide (2-Py-S-S-2-Py) and n-propyl 2-pyridyl disulphide (propyl-S-S-2-Py) were used as two-protonic-state reactivity probes to investigate the active centre of papain (EC 3.4.22.2).2. The existence of a striking rate optimum at pH approx. 4 in the reaction of papain not only with the symmetrical probe but also with the unsymmetrical probe is shown to constitute compelling evidence that the thiolate ion component of the cysteine-25-histidine-159 interactive system of papain possesses appreciable nucleophilic character. It is not a necessary requirement that the probe reagent should engage the imidazolium ion of histidine-159 in hydrogen-bonding for the sulphur atom of the interactive system to display nucleophilic character. The single proton-binding site of propyl-S-S-2-Py cannot simultaneously interrupt the active-centre ion pair and provide for rate enhancement as the pH is lowered towards 4. The possible implication of this for the mechanism of papain-catalysed hydrolysis is discussed. 3. The suspected difference in the active centres of papain and ficin (EC 3.4.22.3), which could be a lack in ficin of a carboxy group conformationally equivalent to that of aspartic acid-158 of papain is confirmed. The reactivity of the papain thiol group towards both probe reagents is controlled by two ionizations with pKa close to 4 that are positively co-operative. 4. In the reaction of papain with 2-Py-S-S-2-Py. the reactivity appears to be controlled also by an addition ionization with pKa approx. 5. Possible origins of this additional ionization are discussed. K. The spectral and ionization characteristics of propyl-S-S-2-Py are reported. 6. The reagent reacts rapidly with thiol groups at the sulphur atom distal from the pyridyl ring to provide, at pH values below 9, stoicheiometric release of 2-thiopyridone. This property, together with the ability of the reagent markedly to increase its electrophilicity consequent on protonation, suggests alkyl-2-pyridyl disulphides in general as valuable two-protonic-state reactivity probes with exceptional specificity for thiol groups.     

Reactivities of neutral and cationic forms of 2,2''-dipyridyl disulphide towards thiolate anions. Detection of differences between the active centres of actinidin, papain and ficin by a three-protonic-state reactivity probe.

The second-order rate constants (k) for the reactions of 2,2'-dipyridyl disulphide (pKa2,45) with 2-mercaptoethanol (pKa9.6) and with benzimidazol-2-ylmethanethiol (pKa values 5.6 and 8.3) were determined at 25 degrees C at I 0.1 by stopped-flow spectral analysis over a wide range of pH. These were used to calculate the pH-independent second-order rate constants (k) for the reactions of neutral 2,2'-dipyridyl disulphide and of its monocation with the 2-mercaptoethanol thiolate anion (associated pKa9.6) and with the benzimidazol-2-ylmethanethiol zwitterion (associated pKa5.6). For both thiolate ions, the rate-enhancement factor (kmonocation/kneutral disulphide) is about 1.5x10(3). The dependence on pH in acidic media of k for the reaction of 2,2'-dipyridyl disulphide with actinidin, the thiol proteinase from Actinidia chinensis, was shown to differ from the forms of pH-dependence observed for the analogous reactions with papain (EC 3.4.22.2) and ficin (3.4.22.3). The reactivity of the 2,2'-dipyridyl disulphide dication and its apparent sensitivity to the presence and location of a positive charge in the attacking thiol are discussed.     

The electrostatic fields in the active-site clefts of actinidin and papain.

The active sites of actinidin (EC 3.4.22.14) and papain (EC 3.4.22.2) display different reactivity characteristics to probes targeted at the active-site cysteine residue despite the close structural similarity of their active sites. The calculated electrostatic fields in the active-site clefts of actinidin and papain differ significantly and may explain the reactivity characteristics of these enzymes. Calculation of electrostatic potential also focuses attention on the electrostatic properties that govern formation of the active-site thiolate-imidazolium ion-pair. These calculations will guide the modification of the pH-activity profile of the cysteine proteinases by site-directed mutagenesis.     

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.

Benzofuroxan reacts with the catalytic-site thiol group of actinidin (EC 3.4.22.14, the cysteine proteinase from Actinidia chinensis) to produce stoicheiometric amounts of the chromophoric reduction product, o-benzoquinone dioxime, and of a catalytically inactive derivative of actinidin that is devoid of thiol and that is assumed to contain, initially at least, the sulphenic acid of cysteine-25. A similar result applies also to papain (EC 3.4.22.2). The rate of o-benzoquinone dioxime formation is neither increased by inclusion of 2-mercaptoethanol or hydroxylamine in the reaction mixture nor decreased by changing the solvent from H2O to 2H2O. The change of solvent was shown to be without effect also on the rate of reaction of benzofuroxan with papain. These results suggest that the reactions of benzofuroxan with both actinidin and papain involve rate-determining attack of the catalytic-site thiol group to produce an intermediate adduct that then reacts rapidly with water to form enzyme sulphenic acid and o-benzoquinone dioxime. The pH-dependence of the second-order rate constant for the reaction of benzofuroxan with actinidin was determined in the pH range 4.3-10.2. In marked contrast with the analogous reaction of papain (reported by Shipton & Brocklehurst [(1977) Biochem. J. 167, 799-810] ) the pH-k profile for the actinidin reaction clearly contains a sigmoidal component with pKa 5.5, in which k increases with decreasing pH. These data together with the molecular pKa values for S-/ImH+ ion-pair formation and decomposition (3.0 and 9.6) suggest that the combined nucleophilic-electrophilic reactivity of the ion-pair of actinidin might be controlled by the state of ionization of another ionizing group, associated with the molecular pKa of 5.5. The pH-dependence of k for the reaction of actinidin with benzofuroxan at 25 degrees C at I 0.1 in aqueous buffers containing 6.7% (v/v) ethanol is probably adequately described by: k = k1/(1 + [H+]/KI + KII/[H+]) + k2/(1 + [H+]/KII + KIII/ [H+] + k3/(1 + [H+]/KIII) in which kI = 2.55 M -1 X s -1, k2 = 1.35 M -1, k3 = 0.93 M -1 X s -1, pKI = 3.0, pKII = 5.5 and pKIII = 9.6. By contrast, the analogous reaction of papain may be described by the same equation but with kI = 0, k2 = 2.2 M -1 X s -1, k3 = 1.3 M -1 X s -1, pKII = 3.6 and pKIII = 9.0.     

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.     

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.     

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.