Model for "charge-relay": acceleration by carboxylate anion in intramolecular general base-catalyzed ester hydrolysis by the imidazolyl group

Modulating the cobalt redox potential through imidazole hydrogen bonding interactions in a supramolecular biomimetic protein-cofactor model

This paper describes a supramolecular biomimetic model of the “His-on” configuration and the charge relay system present in certain types of B₁₂-dependent enzymes.

A realistic model for the active site of histidine-on cobalamin@protein complexes is reported and studied under homogeneous and immobilized conditions. Analysis of lower ligand modulation and its influence on the properties of the biomimetic compound are presented. The cofactor attachment by a protein's histidine residue was imitated by covalently linking an artificial imidazole-containing linker to cobyric acid. The resulting intramolecular coordination complex is an excellent structural model of its natural archetype, according to 2D ¹H-NMR studies and molecular modeling. The effect of deprotonation of the axially coordinating imidazole ligand – as proposed for natural cofactor complexes – tunes significantly the position of the cathodic peak (ΔV = –203 mV) and stabilizes thereby the Co^III form. Partial deprotonation of the imidazole moiety through hydrogen bonding interactions was then achieved by immobilizing the biomimetic model on hydrophobic C18 silica, which yielded an unprecedented insight on how this class of Cbl-dependent proteins may fine-tune their properties in biological systems.

A catalyst selection protocol that identifies biomimetic motifs from β-hairpin libraries

Assaying a solid-phase library of histidine-containing β-hairpin peptides by a reactive tagging scheme in organic solvents selects for catalysts that reproduce the strategies used by His-based enzyme active sites to accelerate acyl- and phosphonyl-transfer reactions. Rate accelerations (k(rel)) in organic solvents of up to 2.4 × 10(8) are observed.

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.

Benzoate catalysis in the hydrolysis of endo-5-[4'(5')imidazolyl]-bicyclo[2.2.1]hept-endo- 2-yl trans-cinnamate: Implications for the charge-transfer mechanism of catalysis by serine proteases

The acceleration, by a factor of 2500, of the hydrolysis of endo-5-[4'(5')imidazolyl]bicyclo[2.2.1]hept-endo- 2-yl trans-cinnamate by 0.5 M sodium benzoate in 42 mol% dioxane in water can be explained without resort to operation of a "charge-relay" mechanism similar to that often postulated to account for the enzymatic activity of serine proteases. The degree of ionization of 4-methylimidazole and of sodium benzoate in 42 mol% dioxane in water at 60 degrees C have been measured by NMR spectroscopy.

On the rate of proton exchange with solvent of the catalytic histidine in flavocytochrome b2 (yeast L-lactate dehydrogenase)

The family of FMN-dependent, alpha-hydroxy acid-oxidizing enzymes catalyzes substrate dehydrogenation by a mechanism the first step of which is abstraction of the substrate alpha-proton (so-called carbanion mechanism). For flavocytochrome b2 and lactate oxidase, it was shown that once on the enzyme this proton is lost only slowly to the solvent (Lederer F, 1984, In: Bray RC, Engel PC, Mayhew SG, eds, Flavins & flavoproteins, Berlin: Walter de Gruyter & Co., pp 513-526; Urban P, Lederer F, 1985, J Biol Chem 260:11115-11122). This suggested the occurrence of a pKa increase of the catalytic histidine upon enzyme reduction by substrate. For flavocytochrome b2, the crystal structure indicated 2 possible origins for the stabilization of the imidazolium form of His 373: either a network of hydrogen bonds involving His 373, Tyr 254, flavin N5 and O4, a heme propionate, and solvent molecules, and/or electrostatic interactions with Asp 282 and with the reduced cofactor N1 anion. In this work, we probe the effect of the hydrogen bond network at the active site by studying proton exchange with solvent for 2 mutants: Y254F and the recombinant flavodehydrogenase domain, in which this network should be disrupted. The rate of proton exchange, as determined by intermolecular hydrogen transfer experiments, appears identical in the flavodehydrogenase domain and the wild-type enzyme, whereas it is about 3-fold faster in the Y254F mutant. It thus appears that specific hydrogen bonds to the solvent do not play a major role in stabilizing the acid form of His 373 in reduced flavocytochrome b2. Removal of the Y254 phenol group induces a pKa drop of about half a pH unit for His 373 in the reduced enzyme. Even then, the rate of exchange of the imidazolium proton with solvent is still lower by several orders of magnitude than that of a normally ionizing histidine. Other factors must then also contribute to the pKa increase, such as the electrostatic interactions with D282 and the anionic reduced cofactor, as suggested by the crystal structure.

A study of the stabilization of tetrahedral adducts by trypsin and delta-chymotrypsin

delta-Chymotrypsin has been alkylated by 1-13C- and 2-13C-enriched tosylphenylalanylchloromethane. In the intact inhibitor derivative, signals due to the 1-13C- and 2-13C-enriched carbon atoms have chemical shifts which titrate from 55.10 to 59.50 p.p.m. and from 99.10 to 103.66 p.p.m. respectively with similar pKa values of 8.99 and 8.85 respectively. These signals are assigned to a tetrahedral adduct formed between the hydroxy group of serine-195 and the inhibitor. An additional signal at 58.09 p.p.m. and at 204.85 p.p.m. in the 1-13C- and 2-13C-enzyme-inhibitor derivatives respectively does not titrate when the pH is changed and it is assigned to alkylated methionine-192. On denaturation/autolysis of the 1-13C-enriched enzyme-inhibitor derivative these signals associated with the intact inhibitor derivative are no longer detected, and a new signal, which titrates from 56.28 to 54.84 p.p.m. with a pKa of 5.26, is detected. The titration shift of this signal is assigned to the deprotonation of the imidazolium cation of alkylated histidine-57 in the denatured/autolysed enzyme-inhibitor derivative. Model compounds which form stable hydrates and hemiketals in aqueous solutions have been synthesized. By comparing the 13C titration shifts of these model compounds with those of the 13C enriched trypsin- and delta-chymotrypsin-inhibitor derivatives, we deduce that, in both of the intact enzyme-inhibitor derivatives, the zwitterionic tetrahedral adduct containing the imidazolium cation of histidine-57 and the hemiketal oxyanion predominates at alkaline pH values. It is estimated that in both the trypsin and delta-chymotrypsin-inhibitor derivatives the concentration of this zwitterionic tetrahedral adduct is 10,000-fold greater than it would be in water. We conclude that the pKa of the oxyanion of the hemiketal in the presence of the imidazolium cation of histidine-57 is 7.9 and 8.9 in the trypsin and delta-chymotrypsin-inhibitor derivatives respectively and that the pKa of the imidazolium cation of histidine-57 is greater than 7.9 and greater than 8.9 when the oxyanion is present as its conjugate acid, whereas, when the oxyanion is present, the pKa of the imidazolium cation is greater than 11 in both enzyme-inhibitor derivatives. We discuss how these enzymes preferentially stabilize zwitterionic tetrahedral adducts in the intact enzyme-inhibitor derivatives and how they could stabilize similar tetrahedral intermediates during catalysis. It is suggested that substrate binding could raise the pKa of the imidazolium cation of histidine-57 before tetrahedral-intermediate formation which would explain the enhanced nucleophilicity of the hydroxy group of serine-195.(ABSTRACT TRUNCATED AT 400 WORDS)

Extreme pKa displacements at the active sites of FMN-dependent alpha-hydroxy acid-oxidizing enzymes

Flavocytochrome b2 (or L-lactate dehydrogenase) from baker's yeast is thought to operate by the initial formation of a carbanion, as do the evolutionarily related alpha-hydroxy acid-oxidizing FMN-dependent oxidases. Previous work has shown that, in the active site of the unligated reduced flavocytochrome b2, the group that has captured the substrate alpha-proton has a high pKapp, calculated to lie around 15 through the use of Eigen's equation. A detailed inspection of the now known three-dimensional structure of the enzyme leads to the conclusion that the high pKa belongs to His 373, an active site group that plays the role of general base in the forward reaction and of general acid in the reverse direction. Moreover, consideration of the kinetics of proton transfer during the catalytic cycle suggests that the pKa of the reduced FMN N5 position should be lowered by several pH units compared to its pKa of 20 or more when free. The features of the three-dimensional structure possibly responsible for these pK shifts are analyzed; they are proposed to consist of a network of hydrogen bonds with the solvent and of a mutual electrostatic stabilization of anionic reduced flavin and the imidazolium ion. Finally, it is suggested that similar pK shifts affect the active sites of the alpha-hydroxy acid-oxidizing flavooxidases, which are homologous to flavocytochrome b2. The functional significance of these pK shifts in terms of catalysis and semiquinone stabilization is discussed.

Synthesis and conformational properties of a synthetic cyclic peptide for the active site of alpha-chymotrypsin

A nonapeptide Ac-His-Phe-Gly-Cys-D-Phe-Ser-Gly-Glu-Cys-NH2 (XI) cyclized through the cysteines at positions 4 and 9 is synthesized as a model active site for the enzyme alpha-chymotrypsin. A CPK model of XI indicates that the peptide will have a high probability of folding into a conformation in which the two beta-phenyls interact to form a hydrophobic site to one side of the cyclohexyl structure, and the Ser-His-Glu side chains form a hydrogen bonded triad over the plane of cyclopeptidyl structure. Substrates can then bind at the hydrophobic pocket formed by the beta-phenyls and be acted upon by the Ser-His-Glu catalytic triad, as in the enzyme. 1H. n.m.r. shows: (i) multiplet peaks for the phenyl protons in D2O that condense to a singlet in DMSO-d6, (ii) a perturbation of the phenyl protons chemical shift on proflavin association to XI, and (iii) perturbation of the His pKa to a higher value on association of proflavin to XI. These data support the existence of a hydrophobic site and a Glu-His interaction in the peptide. Furthermore, the greater than 10(2) better affinity of proflavin to XI than to AcTrp supports the existence of a hydrophobic site. However, no acceleration of p-nitrophenyl acetate or trans-cinnamoyl imidazole hydrolysis over that of imidazole is observed. The possible reasons for a lack of esterase activity in XI and other peptidyl models of serine protease active sites are discussed.

Catalytic mechanism of serine proteases: reexamination of the pH dependence of the histidyl 1J13C2-H coupling constant in the catalytic triad of alpha-lytic protease

L-Histidine, 90% 13C enriched at the C2 position, was incorporated into the catalytic triad of alpha-lytic protease (EC 3.4.21.12) with the aid of histidine-requiring mutant of Lysobacter enzymogenes (ATC 29487), and the pH dependence of the coupling constant between this carbon atom and its directly bonded proton was reinvestigated. The high degree of specific 13C isotopic enrichment attainable with the auxotroph permits direct observation and measurement of this coupling constant in proton-coupled 13C NMR spectra at 67.89 MHz and at 15.1 MHz. In contrast to the earlier study, the present study indicate that this coupling constant does respond to a microscopic ionization with pKa near 7.0; moreover, the magnitude of the values of 1JC-H observed are in accord with those expected for titration of the histidyl residue. We conclude that the original measurement must be in error and that this coupling constant now also supports a histidyl residue that titrates more or less normally as a component of the catalytic triad of serine proteases.