Effects of Mixed H2O—CH3CN and H2O—HCONMe2 Solvents on the Rate of Cleavage of N-Benzylphthalamic Acid

Can a Typical Protein Assist the Rate of its Own Aqueous Cleavage?

A recent finding of a large rate enhancement in the intramolecular secondary amide group-assisted cleavage of an adjacent tertiary amide bond predicts the possibility of the cleavage of the peptide bond of a protein through a similar reaction mechanism. Based upon enzymatic partial model reactions, the usual proton-switch mechanism has been suggested for the acylation step of the chymotrypsin–catalysed cleavage of the peptide bond which does not favour a His57-shift mechanism - an essential component of the classical charge relay mechanism. Also, the proton-switch mechanism does not necessarily require the two proton-transfer of the classical charge relay mechanism. The unique structural feature of the imidazole moiety of His57 is concluded to be essential in decreasing the rate of collapse of the proposed reactive tetrahedral intermediate back to the reactants. The proposed intramolecular intimate ion-pair formation between anionic Asp102 and cationic His57 is attributed to the energetically preferred location of the proton at Nδ1 of the imidazole moiety of His57. Thus, the analysis described in this review does not favour the necessary requirements of a two proton-transfer and His57-shift as proposed in the classical charge relay mechanism as well as the relatively recently proposed His57-flip mechanism.