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. 1993 Aug 15;294(Pt 1):201–210. doi: 10.1042/bj2940201

Clarification of the pH-dependent kinetic behaviour of papain by using reactivity probes and analysis of alkylation and catalysed acylation reactions in terms of multihydronic state models: implications for electrostatics calculations and interpretation of the consequences of site-specific mutations such as Asp-158-Asn and Asp-158-Glu.

G W Mellor 1, M Patel 1, E W Thomas 1, K Brocklehurst 1
PMCID: PMC1134585  PMID: 8103322

Abstract

1. The complex behaviour of papain (EC 3.4.22.2) in acidic media has been investigated by (a) stopped-flow reactivity probe kinetics using 4,4'-dipyrimidyl disulphide (I) and 2,2'-dipyridyl disulphide (II) as thiol-specific time-dependent inhibitors with markedly different susceptibilities to activation by hydronation (protonation) and (b) using the multitasking application program SKETCHER for the rapid evaluation of pH-dependent kinetic data by means of interactive manipulation of calculated curves. 2. The substantially lower basicity of (I) (pKa 0.91) than that of (II) (pKa 2.45) combined with retention of high reactivity permitted the pKa for the formation of the (Cys-25)-S-/(His-159)-Im+H ion-pair state of papain to be determined kinetically as 3.4, a value close to that (3.3) deduced by potentiometric difference titration [Lewis, Johnson and Shafer (1976) Biochemistry 15, 5009-5017] and lower than the value (approx. 4) often reported from pH-dependent kinetic studies. The higher values are now known to arise from inadequate data analysis that does not take account of other overlapping kinetically influential ionizations. 3. Re-evaluation of the extensive sets of pH-kcat/Km data for the hydrolysis of nine substrates by papain reported by Polgár and Halász (1978) (Eur. J. Biochem. 88, 513-521) by making use of SKETCHER, the known pKa value (3.4) from the reaction with compound (I) and two additional kinetically influential pKa values deduced from the reaction with compound (II) now permits the identification of the pH-dependent events in reactions of papain with inhibitors and substrates. 4. A major conclusion is that, whereas in reactions of simple alkylating agents and compound (I) full nucleophilic character of (Cys-25)-S-/(His-159)-Im+H is provided by hydronic dissociation with pKa 3.3-3.4, in catalysis relatively little catalytic competence is produced consequent upon ion-pair formation. Substantial catalytic competence requires further hydronic dissociation with pKa approx. 4, and for cationic substrates further enhancement is produced by hydronic dissociation with pKa approx. 5. 5. The present work, together with the kinetic analysis of reactions of papain in alkaline media reported by Mellor, Thomas, Topham and Brocklehurst [Biochem. J. (1993) 290, 289-296], defines the kinetically influential ionizations of papain as 3.4, 4.0, 5.0, 8.3 and 10.0 of which 3.4 and 8.3 relate to the formation and subsequent dehydronation of the ion-pair state.(ABSTRACT TRUNCATED AT 400 WORDS)

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Selected References

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