Characterization of the mode of binding of substrates to the active site of Tetrahymena self-splicing RNA using 5-fluorouracil-substituted mini-exons

Splice-site selection specificity in Tetrahymena self-splicing RNA is thought to be mediated by a base-paired complex between a CUCUCU sequence on the end of the 5' exon and a GGGAGG guide sequence in the intron. The substitution of uracil (U) in oligonucleotide mini-exons with 5-fluorouracil (UF), an analogue bearing a much more acidic N-3 proton, allowed us to test the role of hydrogen bonding between complementary bases in the splice-site selection process. The affinities of (U) and (UF) mini-exons for the ribozyme active site were similar and several orders of magnitude greater than expected from base pairing alone. In contrast to CUCU, the CUFCUF mini-exon lost substrate activity with increasing pH, presumably due to ionization of the UF residues. However, the apparent pK values of these residues were several pK units above that of free UF, indicating that the mini-exon is shielded from the solvent by an active site of low polarity. Loss of the pyrimidine N-3 hydrogen bond by selective ionization of the UF residues decreased the binding of CUFCUF to the ribozyme only 3-fold but did prevent its ligation to the 3' exon. Temperature dependence of substrate activity was identical for both (U) and (UF) mini-exons, whereas the UF-substituted ribozyme lost activity at a considerably lower temperature than did the natural (U) ribozyme. These observations indicate that hydrogen-bonded base pairs involving the U residues contribute little to the total binding energy of the 5' splice site with the active site of the ribozyme, but probably help to align the splice sites properly for ligation.     

Investigating a catalytic mechanism of hyperthermophilic L-threonine dehydrogenase from Pyrococcus horikoshii

Based on our first structural data of L-threonine dehydrogenase (TDH) of Pyrococcus horikoshii (PhTDH), we examined its catalytic mechanism. The structural analysis indicated that a catalytic zinc atom at the active centre of PhTDH is coordinated by four residues (Cys42, His67, Glu68 and Glu152) with low affinity. These residues are highly conserved in alcohol dehydrogenases (ADHs) and TDHs. Several PhTDH mutants were prepared with respect to Glu152 and other residues, relating to the proton relay system that is substantially a rate-limiting step in ADH. It was found that the E152D mutant showed 3-fold higher turnover rate and reduced affinities toward L-threonine and NAD(+), compared to wild-type PhTDH. The kinetic analysis of Glu152 mutants indicated that the carboxyl group of Glu152 is important for expressing the catalytic activity. The results obtained from pH dependency of kinetic parameters suggested that Glu152 to Asp substitution causes the enhancement of deprotonation of His47 or ionization of zinc-bound water and threonine in the enzyme-NAD(+) complex. Furthermore, it was predicted that the access of threonine substrate to the enzyme-NAD(+) complex induces a large conformational change in the active domain of PhTDH. From these results, we propose here that the proton relay system works as a catalytic mechanism of PhTDH.     

Kinetic analysis of multiple proton shuttles in the active site of human carbonic anhydrase

We have prepared a site-specific mutant of human carbonic anhydrase (HCA) II with histidine residues at positions 7 and 64 in the active site cavity. Using a different isozyme, we have placed histidine residues in HCA III at positions 64 and 67 and in another mutant at positions 64 and 7. Each of these histidine residues can act as a proton transfer group in catalysis when it is the only nonliganding histidine in the active site cavity, except His(7) in HCA III. Using an (18)O exchange method to measure rate constants for intramolecular proton transfer, we have found that inserting two histidine residues into the active site cavity of either isozyme II or III of carbonic anhydrase results in rates of proton transfer to the zinc-bound hydroxide that are antagonistic or suppressive with respect to the corresponding single mutants. The crystal structure of Y7H HCA II, which contains both His(7) and His(64) within the active site cavity, shows the conformation of the side chain of His(64) moved from its position in the wild type and hydrogen-bonded through an intervening water molecule with the side chain of His(7). This suggests a cause of decreased proton transfer in catalysis.     

The effects of chemical modification on the refolding transition of alpha-chymotrypsin.

The role of several active site residues of alpha-chymotrypsin in the prototypical refolding transition between active and inactive forms of this enzyme is examined using chemical modification. Oxidation of Met-192 to the sulfoxide results in a derivative which remains entirely in an active state from pH 6 to 9. The derivative becomes inactive only at high pH with pKa = 10.3, delta H0 = 9.5 kcal and delta S0 = -15 eu., indicating the sulfoxide group supplies about 2.1 kcal of active state stabilization relative to the unoxidized methionine side chain. The refolding transition of N-methyl-His-57-alpha-chymotrypsin, in which a nitrogen of the "charge relay" histidine is methylated, displays one ionization process with an apparent pKa of 9.45. The absence of an additional ionization process with a pKa near 7 provides evidence that one of the ionizations in the six state mechanism which describes this transition in alpha-chymotrypsin is linked to the charge relay system. We also demonstrate, using alpha-chymotrypsin, Met-192-sulfoxide-alpha-chymotrypsin and N-methyl-His-57-alpha-chymotrypsin, that the 230 nm circular dichroism band is a quantitative probe of the active-inactive equilibrium, although the chromophore or chromophores responsible for this and another very large negative band at 202 nm have not been identified. Circular dichroism was used to observe the active-inactive equilibrium in methan sulfonyl-alpha-chymotrypsin and phenylmethane sulfonyl-alpha-chymotrypsin. The enhanced stability of the active state of these derivatives relative to alpha-chymotrypsin can be rationalized in terms of steric effects in the substrate side chain binding site.     

High resolution structures of an oxidized and reduced flavoprotein. The water switch in a soluble form of (S)-mandelate dehydrogenase

The crystal structures of a soluble mutant of the flavoenzyme mandelate dehydrogenase (MDH) from Pseudomonas putida and of the substrate-reduced enzyme have been analyzed at 1.35-A resolution. The mutant (MDH-GOX2) is a fully active chimeric enzyme in which residues 177-215 of the membrane-bound MDH are replaced by residues 176-195 of glycolate oxidase from spinach. Both structures permit full tracing of the polypeptide backbone chain from residues 4-356, including a 4-residue segment that was disordered in an earlier study of the oxidized protein at 2.15 A resolution. The structures of MDH-GOX2 in the oxidized and reduced states are virtually identical with only a slight increase in the bending angle of the flavin ring upon reduction. The only other structural changes within the protein interior are a 10 degrees rotation of an active site tyrosine side chain, the loss of an active site water, and a significant movement of six other water molecules in the active site by 0.45 to 0.78 A. Consistent with solution studies, there is no apparent binding of either the substrate, mandelate, or the oxidation product, benzoylformate, to the reduced enzyme. The observed structural changes upon enzyme reduction have been interpreted as a rearrangement of the hydrogen bonding pattern within the active site that results from binding of a proton to the N-5 position of the anionic hydroquinone form of the reduced flavin prosthetic group. Implications for the low oxidase activity of the reduced enzyme are also discussed.     

Nuclear magnetic resonance titration curves of histidine ring protons. Conformational transition affecting three of the histidine residues of ribonuclease.

NMR titration curves are reported for the 4 histidine residues of ribonuclease A in sodium acetate and for ribonuclease S in sodium acetate, phosphate, and sulfate solutions. Evidence is presented that the imidazole side chain of histidine residue 48 undergoes a conformational change, probably also involving the carboxyl side chain of aspartic acid residue 14. This group is considered to be responsible for the low pH inflection with pKa 4.2 present in the NMR titration curve of the C-2 proton resonance of histidine 48. The NMR titration curves of the active site histidine residues 12 and 119 also exhibit inflections at low pH values, although there is no carboxyl group within 9 A of the imidazole side chain of histidine residue 12 in the structure of ribonuclease S determined by x-ray crystallography (Wyckoff, H. W., Tsernoglou, D., Hanson, A. W. Knox, J. R., Lee, B., and Richards, F. M. (1970) J. Biol. Chem. 245, 305-328). Curve fitting was carried out on 11 sets of NMR titration data using a model in which the 3 histidine residues 12, 119, and 48 are assumed to be affected by a common carboxyl group. The results obtained indicate that such a model with fewer parameters gives as good a representation of the data as the model in which each histidine residue is assumed to interact separately with a different carboxyl group. Therefore, it is concluded that the ionization of aspartic acid residue 14 is indirectly experienced by the active site histidine residues through the conformational change at histidine 48. A model assuming mutual interaction of the active site histidine residues does not account for the low pH inflections in these curves.     

Catalytic roles for two water bridged residues (Asp-98 and His-255) in the active site of copper-containing nitrite reductase

Two active site residues, Asp-98 and His-255, of copper-containing nitrite reductase (NIR) from Alcaligenes faecalis have been mutated to probe the catalytic mechanism. Three mutations at these two sites (D98N, H255D, and H255N) result in large reductions in activity relative to native NIR, suggesting that both residues are involved intimately in the reaction mechanism. Crystal structures of these mutants have been determined using data collected to better than 1. 9-A resolution. In the native structure, His-255 Nepsilon2 forms a hydrogen bond through a bridging water molecule to the side chain of Asp-98, which also forms a hydrogen bond to a water or nitrite oxygen ligated to the active site copper. In the D98N mutant, reorientation of the Asn-98 side chain results in the loss of the hydrogen bond to the copper ligand water, consistent with a negatively charged Asp-98 directing the binding and protonation of nitrite in the native enzyme. An additional solvent molecule is situated between residues 255 and the bridging water in the H255N and H255D mutants and likely inhibits nitrite binding. The interaction of His-255 with the bridging water appears to be necessary for catalysis and may donate a proton to reaction intermediates in addition to Asp-98.     

The catalytic reaction and inhibition mechanism of Drosophila alcohol dehydrogenase: observation of an enzyme-bound NAD-ketone adduct at 1.4 A resolution by X-ray crystallography.

Drosophila alcohol dehydrogenase (DADH) is an NAD+-dependent enzyme that catalyzes the oxidation of alcohols to aldehydes/ketones. DADH is the member of the short-chain dehydrogenases/reductases family (SDR) for which the largest amount of biochemical data has been gathered during the last three decades. The crystal structures of one binary form (NAD+) and three ternary complexes with NAD+.acetone, NAD+.3-pentanone and NAD+.cyclohexanone were solved at 2.4, 2.2, 1. 4 and 1.6 A resolution, respectively. From the molecular interactions observed, the reaction mechanism could be inferred. The structure of DADH undergoes a conformational change in order to bind the coenzyme. Furthermore, upon binding of the ketone, a region that was disordered in the apo form (186-191) gets stabilized and closes the active site cavity by creating either a small helix (NAD+. acetone, NAD+.3-pentanone) or an ordered loop (NAD+.cyclohexanone). The active site pocket comprises a hydrophobic bifurcated cavity which explains why the enzyme is more efficient in oxidizing secondary aliphatic alcohols (preferably R form) than primary ones. Difference Fourier maps showed that the ketone inhibitor molecule has undergone a covalent reaction with the coenzyme in all three ternary complexes. Due to the presence of the positively charged ring of the coenzyme (NAD+) and the residue Lys155, the amino acid Tyr151 is in its deprotonated (tyrosinate) state at physiological pH. Tyr151 can subtract a proton from the enolic form of the ketone and catalyze a nucleophilic attack of the Calphaatom to the C4 position of the coenzyme creating an NAD-ketone adduct. The binding of these NAD-ketone adducts to DADH accounts for the inactivation of the enzyme. The catalytic reaction proceeds in a similar way, involving the same amino acids as in the formation of the NAD-ketone adduct. The p Kavalue of 9-9.5 obtained by kinetic measurements on apo DADH can be assigned to a protonated Tyr151 which is converted to an unprotonated tyrosinate (p Ka7.6) by the influence of the positively charged nicotinamide ring in the binary enzyme-NAD+form. pH independence during the release of NADH from the binary complex enzyme-NADH can be explained by either a lack of electrostatic interaction between the coenzyme and Tyr151 or an apparent p Kavalue for this residue higher than 10.0.     

Identification of a peroxide-sensitive redox switch at the CXXC motif in the human mitochondrial branched chain aminotransferase

The human mitochondrial branched chain aminotransferase isoenzyme (hBCATm) must be stored in a reducing environment to remain active. Oxidation or labeling of hBCATm with sulfhydryl reagents results in enzyme inhibition. In this study, we investigated both the structural and biochemical basis for the sensitivity of hBCATm to these reagents. In its native form, hBCATm has two reactive cysteine residues which were identified as Cys315 and Cys318 using iodinated beta-(4-hydroxyphenyl)ethyl maleimide. These are located in the large domain of the homodimer, about 10 A from the active site. The crystal structures show evidence for a thiol-thiolate hydrogen bond between Cys315 and Cys318. Under oxidizing conditions, these cysteine residues can reasonably form a disulfide bond because of the short distance between the sulfur atoms (3.09-3.46 A), requiring only a decrease of 1.1-1.5 A. In addition to Cys315 playing a structural role by anchoring Tyr173, which in the ketimine form increases access to the active site, our evidence indicates that these cysteine residues act as a redox switch in hBCATm. Electrospray ionization mass spectrometry analysis and UV-Vis spectroscopic studies of 5,5'-dithiobis(2-nitrobenzoic acid) labeled hBCATm showed that during labeling, an intrasubunit disulfide bond was formed in a significant portion of the protein. Furthermore, it was established that reaction of hBCATm with H2O2 abolished its activity and resulted in the formation of an intrasubunit disulfide bond between Cys315 and Cys318. Addition of dithiothreitol completely reversed the oxidation and restored activity. Therefore, the results demonstrate that there is redox-linked regulation of hBCATm activity by a peroxide sensitive CXXC center. Future studies will determine if this center has an in vivo role in the regulation of branched chain amino acid metabolism.     

Cofactor activation and substrate binding in pyruvate decarboxylase. Insights into the reaction mechanism from molecular dynamics simulations

We have performed long-term molecular dynamics simulations of pyruvate decarboxylase from Zymomonas mobilis. Nine structures were modeled to investigate mechanistic questions related to binding of the cofactor, thiamin diphosphate (ThDP), and the substrate in the active site. The simulations reveal that the proposed three ThDP-tautomers all can bind in the active site and indicate that the equilibrium is shifted toward 4'-aminopyrimidine ThDP in the absence of substrate. 4'-Aminopyrimidinium ThDP is found to be a likely intermediate in the equilibrium. Mutations of important active site residues, Glu473Ala and Glu50Ala, were modeled to further elucidate their catalytic role. Formation of the catalytic important ylide by deprotonation of ThDP(C2) is investigated. Only the less favored tautomer, 1',4'-iminopyrimidine ThDP (imino-ThDP), could be deprotonated. The two other tautomers of ThDP could not be activated at the C2-position, thus, explaining the mechanistic importance of the less stable imino-ThDP. Finally, binding of pyruvate in the active site with the cofactor modeled as the nucleophilic ylide (ylide-ThDP) is studied. The carbonyl group of the substrate forms a hydrogen bond to Tyr290(OH). No hydrogen bond could be identified between ThDP(N4') and the substrate. The geometry of the substrate binding is well-suited for a nucleophilic attack by ylide-ThDP(C2). We propose that a proton relay from His113 via Asp27 and Tyr290 to the carbonyl oxygen atom of the substrate may be involved in the mechanism.     

Threonine-978 in the transmembrane segment of the multidrug efflux pump AcrB of Escherichia coli is crucial for drug transport as a probable component of the proton relay network

Escherichia coli AcrB is a multidrug efflux transporter that recognizes multiple toxic chemicals and expels them from cells. It is a proton antiporter belonging to the resistance-nodulation-division (RND) superfamily. Asp407, Asp408, Lys940, and Arg971 in transmembrane (TM) helices of this transporter have been identified as essential amino acid residues that probably function as components of the proton relay system. In this study, we identified a novel residue in TM helix 11, Thr978, as an essential residue by alanine scanning mutagenesis. Its location close to Asp407 suggests that it is also a component of the proton translocation pathway, a prediction confirmed by the similar conformations adopted by T978A, D407A, D408A, and K940A mutant proteins (see the accompanying paper). Sequence alignment of 566 RND transporters showed that this threonine residue is conserved in about 96% of cases. Our results suggest the hypotheses that Thr978 functions through hydrogen bonding with Asp407 and that protonation of the latter alters the salt bridging and hydrogen bonding pattern in the proton relay network, thus initiating a series of conformational changes that ultimately result in drug extrusion.     

Comparison of the binding affinity of chlorogenic acid with two serum albumins

Chlorogenic acid (CA) is a well-known ester of caffeic acid present in some food. It is also an active component in traditional Chinese medicines which are used to treat various diseases, but the molecular basis of CA is not clear. In the present work, the proton selective relaxation rate and the affinity index were used to investigate the interaction of CA with human serum albumin and bovine serum albumin under the same buffer conditions. The results indicated that the binding affinity of chlorogenic acid to BSA was stronger than that to HSA. The binding site of the ligand-protein complex was elucidated by molecular docking, and the specific interaction was observed from those hydrogen bonds formed by the ligand and active residues. Using a combination of TR-NOE detection, the optimal ligand conformation was illustrated. Further conformational analysis of the complex revealed that the ability of hydrogen bond formation by polar side chain residues in the binding site of BSA might contribute to the greater binding affinity. The results provide a better understanding of CA binding and should contribute towards the design of modifications of CA for therapeutic purposes.     

Direct NMR observation of the Cys-14 thiol proton of reduced Escherichia coli glutaredoxin-3 supports the presence of an active site thiol-thiolate hydrogen bond.

The active site of Escherichia coli glutaredoxin-3 (Grx3) consists of two redox active cysteine residues in the sequence -C11-P-Y-C14-H-. The 1H NMR resonance of the cysteine thiol proton of Cys-14 in reduced Grx3 is observed at 7.6 ppm. The large downfield shift and NOEs observed with this thiol proton resonance suggest the presence of a hydrogen bond with the Cys-11 thiolate, which is shown to have an abnormally low pKa value. A hydrogen bond would also agree with activity data of Grx3 active site mutants. Furthermore, the activity is reduced in a Grx3 H15V mutant, indicating electrostatic contributions to the stabilization of the Cys-11 thiolate.     

Characterization of the protonation and hydrogen bonding state of the histidine residues in IIAmtl, a domain of the phosphoenolpyruvate-dependent mannitol-specific transport protein.

The A domain of the mannitol-specific EII, IIAmtl, was subcloned and proven to be functional in the isolated form (Van Weeghel et al., 1991). It contains a histidine phosphorylation site, the first of two phosphorylation sites in the parent protein. In this paper, we describe the characterization of the three histidine residues in IIAmtl with respect to their protonation and hydrogen bonding state, using 1H[15N] heteronuclear NMR techniques and protein selectively enriched with [delta 1,epsilon 2-15N]histidine. The active site residue has a low pKa (less than 5.8) and shows no hydrogen bond interactions. The proton in the neutral ring is located at the N epsilon 2 position, which also proved to be the site of phosphorylation. The phosphorylation raises the pKa of the active site histidine considerably but does not change the hydrogen bond situation. The other two histidine residues, one of which is probably located on the surface of the protein, were also characterized. Both show hydrogen bond interactions in the unphosphorylated protein, but these are disturbed by the phosphorylation process. These observations, combined with small changes in pKa and titration behavior, indicate that the IIAmtl changes its conformation upon phosphorylation.     

Tyrosine 387 and arginine 404 are critical in the hydrolytic mechanism of Escherichia coli aminopeptidase P

Analysis of the pH-rate profile for catalysis of bradykinin cleavage by aminopeptidase P (AMPP), a manganese-containing hydrolase from Escherichia coli, was carried out to show that optimal catalytic function is obtained at neutral pH. On the basis of information derived from the crystal structure, peptidase sequence alignments, and the hydrolysis of organophosphate triesters, active site residues Arg153, Arg370, Trp88, Tyr387, and Arg404 were identified as potential catalytic residues. Site-directed mutagenesis was used to substitute these residues with Leu, Ala, Trp, Lys, or Phe. The kcat values for the Arg153, Arg370, and Trp88 mutants were nearly the same as that for the wild-type enzyme. The kcat values of the R404K, R404A, and Y387A mutants were lower by factors of 285, 400, and 16, respectively. Inductively coupled plasma mass spectrometry and circular dichroism spectroscopy showed that Arg404 is not required for metal chelation or stabilization of protein secondary structure. The hydrogen bond network observed between the side chains of conserved residues Asp260, Arg404, and Tyr387 indicated that Arg404 participates in proton relay. This was further evidenced by the return of activity in the R404A mutant by the addition of guanidine. Also, reduced catalytic efficiency in the R404K mutant, which conserves the positive charge at the bridge site, shows that only the arginine group of Arg404 (not the ammonium group of Lys404) can participate in the hydrogen bond network. The hydrogen bond interaction between the Arg404 and the Tyr387 ring hydroxyl group is suggested by the reduced catalytic efficiency of the Y387F mutant.     

Dissecting the electrostatic interactions and pH-dependent activity of a family 11 glycosidase

Previous studies of the low molecular mass family 11 xylanase from Bacillus circulans show that the ionization state of the nucleophile (Glu78, pK(a) 4.6) and the acid/base catalyst (Glu172, pK(a) 6.7) gives rise to its pH-dependent activity profile. Inspection of the crystal structure of BCX reveals that Glu78 and Glu172 are in very similar environments and are surrounded by several chemically equivalent and highly conserved active site residues. Hence, there are no obvious reasons why their apparent pK(a) values are different. To address this question, a mutagenic approach was implemented to determine what features establish the pK(a) values (measured directly by (13)C NMR and indirectly by pH-dependent activity profiles) of these two catalytic carboxylic acids. Analysis of several BCX variants indicates that the ionized form of Glu78 is preferentially stabilized over that of Glu172 in part by stronger hydrogen bonds contributed by two well-ordered residues, namely, Tyr69 and Gln127. In addition, theoretical pK(a) calculations show that Glu78 has a lower pK(a) value than Glu172 due to a smaller desolvation energy and more favorable background interactions with permanent partial charges and ionizable groups within the protein. The pK(a) value of Glu172 is in turn elevated due to electrostatic repulsion from the negatively charged glutamate at position 78. The results also indicate that all of the conserved active site residues act concertedly in establishing the pK(a) values of Glu78 and Glu172, with no particular residue being singly more important than any of the others. In general, residues that contribute positive charges and hydrogen bonds serve to lower the pK(a) values of Glu78 and Glu172. The degree to which a hydrogen bond lowers a pK(a) value is largely dependent on the length of the hydrogen bond (shorter bonds lower pK(a) values more) and the chemical nature of the donor (COOH > OH > CONH(2)). In contrast, neighboring carboxyl groups can either lower or raise the pK(a) values of the catalytic glutamic acids depending upon the electrostatic linkage of the ionization constants of the residues involved in the interaction. While the pH optimum of BCX can be shifted from -1.1 to +0.6 pH units by mutating neighboring residues within the active site, activity is usually compromised due to the loss of important ground and/or transition state interactions. These results suggest that the pH optima of an enzyme might be best engineered by making strategic amino acid substitutions, at positions outside of the "core" active site, that electrostatically influence catalytic residues without perturbing their immediate structural environment.     

A computational method for design of connected catalytic networks in proteins

Computational design of new active sites has generally proceeded by geometrically defining interactions between the reaction transition state(s) and surrounding side‐chain functional groups which maximize transition‐state stabilization, and then searching for sites in protein scaffolds where the specified side‐chain–transition‐state interactions can be realized. A limitation of this approach is that the interactions between the side chains themselves are not constrained. An extensive connected hydrogen bond network involving the catalytic residues was observed in a designed retroaldolase following directed evolution. Such connected networks could increase catalytic activity by preorganizing active site residues in catalytically competent orientations, and enabling concerted interactions between side chains during catalysis, for example, proton shuffling. We developed a method for designing active sites in which the catalytic side chains, in addition to making interactions with the transition state, are also involved in extensive hydrogen bond networks. Because of the added constraint of hydrogen‐bond connectivity between the catalytic side chains, to find solutions, a wider range of interactions between these side chains and the transition state must be considered. Our new method starts from a ChemDraw‐like two‐dimensional representation of the transition state with hydrogen‐bond donors, acceptors, and covalent interaction sites indicated, and all placements of side‐chain functional groups that make the indicated interactions with the transition state, and are fully connected in a single hydrogen‐bond network are systematically enumerated. The RosettaMatch method can then be used to identify realizations of these fully‐connected active sites in protein scaffolds. The method generates many fully‐connected active site solutions for a set of model reactions that are promising starting points for the design of fully‐preorganized enzyme catalysts.     

Critical residues for structure and catalysis in short-chain dehydrogenases/reductases

Short-chain dehydrogenases/reductases form a large, evolutionarily old family of NAD(P)(H)-dependent enzymes with over 60 genes found in the human genome. Despite low levels of sequence identity (often 10-30%), the three-dimensional structures display a highly similar alpha/beta folding pattern. We have analyzed the role of several conserved residues regarding folding, stability, steady-state kinetics, and coenzyme binding using bacterial 3beta/17beta-hydroxysteroid dehydrogenase and selected mutants. Structure determination of the wild-type enzyme at 1.2-A resolution by x-ray crystallography and docking analysis was used to interpret the biochemical data. Enzyme kinetic data from mutagenetic replacements emphasize the critical role of residues Thr-12, Asp-60, Asn-86, Asn-87, and Ala-88 in coenzyme binding and catalysis. The data also demonstrate essential interactions of Asn-111 with active site residues. A general role of its side chain interactions for maintenance of the active site configuration to build up a proton relay system is proposed. This extends the previously recognized catalytic triad of Ser-Tyr-Lys residues to form a tetrad of Asn-Ser-Tyr-Lys in the majority of characterized short-chain dehydrogenases/reductase enzymes.     

Implications for an ionized alkyl-enzyme intermediate during StEH1-catalyzed trans-stilbene oxide hydrolysis

The catalytic mechanism of epoxide hydrolase (EC 3.3.2.3) involves acid-assisted ring opening of the oxirane during the alkylation half-reaction of hydrolysis. Two tyrosyl residues in the active site of epoxide hydrolases have been shown to contribute to the catalysis of enzyme alkylation, but their mechanism of action has not been fully described. We have investigated the involvement of the active site Tyr154 and Tyr235 during S,S-trans-stilbene oxide hydrolysis catalyzed by potato epoxide hydrolase StEH1. Tyr phenol ionizations of unliganded enzyme as well as under pre-steady-state conditions during catalysis were studied by direct absorption spectroscopy. A transient UV absorption, indicative of tyrosinate formation, was detected during the lifetime of the alkyl-enzyme intermediate. The apparent pKa of Tyr ionization was 7.3, a value more than 3 pH units below the estimated pKa of protein Tyr residues in the unliganded enzyme. In addition, the pH dependencies of microscopic kinetic rates of catalyzed S,S-trans-stilbene oxide hydrolysis were determined. The alkylation rate increased with pH and displayed a pKa value identical to that of Tyr ionization (7.3), whereas the reverse (epoxidation) reaction did not display any pH dependence. The rate of alkyl-enzyme hydrolysis was inversely dependent on tyrosinate formation, decreasing with its buildup in the active site. Since alkyl-enzyme hydrolysis is the rate-limiting step of the overall reaction, kcat displayed the same decrease with pH as the hydrolysis rate. The compiled results suggested that the role of the Tyr154/Tyr235 pair was not as ultimate proton donor to the alkoxide anion but to stabilize the negatively charged alkyl-enzyme through electrophilic catalysis via hydrogen bonding.     

Potentiometric determination of ionizations at the active site of papain.

The ionization behavior of groups at the active site of papain was determined from the pH dependence of the difference of proton content of papain and the methylthio derivative of the thiol group at the active site of papain (papain-S-SCH3). This difference in proton content was determined directly by two independent methods. One method involved potentiometric measurements of the protons released and demethylthiolation of papain-S-SCH3 with dithiothreitol, as a function of pH. The other method involved analogous measurements of the protons released on methylthiolation of papain with methyl methanethiosulfonate. The methylthio pH-difference titrations generated by these measurements indicate that ionization of the thiol group at the active site of papain is linked to the ionization of His-159. The pK of the thiol group changes from 3.3 to 7.6 on deprotonation of His-159 at 29 degrees C/20.05. Similarly, the pK of His-159 shifts from 4.3 to 8.5 when the active site thiol group is deprotonated. The microscopic ionization constants determined in this work for Cys-25 and His-159 indicate that equilibrium constant for transfer of the proton from Cys-25 to His-159 is 8--12, and that in the physiological pH range the active site thiol group exists mainly as a thiol anion.