Probing electrostatic interactions along the reaction pathway of a glycoside hydrolase: histidine characterization by NMR spectroscopy

We have characterized by NMR spectroscopy the three active site (His80, His85, and His205) and two non-active site (His107 and His114) histidines in the 34 kDa catalytic domain of Cellulomonas fimi xylanase Cex in its apo, noncovalently aza-sugar-inhibited, and trapped glycosyl-enzyme intermediate states. Due to protection from hydrogen exchange, the level of which increased upon inhibition, the labile 1Hdelta1 and 1H epsilon1 atoms of four histidines (t1/2 approximately 0.1-300 s at 30 degrees C and pH approximately 7), as well as the nitrogen-bonded protons in the xylobio-imidazole and -isofagomine inhibitors, could be observed with chemical shifts between 10.2 and 17.6 ppm. The histidine pKa values and neutral tautomeric forms were determined from their pH-dependent 13C epsilon1-1H epsilon1 chemical shifts, combined with multiple-bond 1H delta2/epsilon1-15N delta1/epsilon2 scalar coupling patterns. Remarkably, these pKa values span more than 8 log units such that at the pH optimum of approximately 6 for Cex activity, His107 and His205 are positively charged (pKa > 10.4), His85 is neutral (pKa < 2.8), and both His80 (pKa = 7.9) and His114 (pKa = 8.1) are titrating between charged and neutral states. Furthermore, upon formation of the glycosyl-enzyme intermediate, the pKa value of His80 drops from 7.9 to <2.8, becoming neutral and accepting a hydrogen bond from an exocyclic oxygen of the bound sugar moiety. Changes in the pH-dependent activity of Cex due to mutation of His80 to an alanine confirm the importance of this interaction. The diverse ionization behaviors of the histidine residues are discussed in terms of their structural and functional roles in this model glycoside hydrolase.     

Recruitment of both uniform and differential binding energy in enzymatic catalysis: xylanases from families 10 and 11

The contributions of enzyme-substrate hydrogen-binding interactions to catalysis by two different families of xylanases were evaluated through kinetic studies with two representative wild-type enzymes, Cellulomonas fimi xylanase (Cex) and Bacillus circulans xylanase (Bcx), on a series of monodeoxygenated and monodeoxyfluorinated p-nitrophenyl xylobioside substrates. Effects of substitution in the distal (-2 subsite) sugar on kcat/Km for Cex were moderately large (up to 2.9 kcal mol-1), with no effect seen on kcat. By contrast, substantial effects upon both kcat and kcat/Km were seen for substrates modified in the proximal (-1 subsite) sugar. Very similar results were obtained with Bcx. Kinetic analyses with a series of eight mutants of Cex in which active site residues interacting with the substrate were mutated yielded complementary insights. Again, interactions with the distal (-2) sugar were seen to contribute substantially to kcat/Km (up to 3.7 kcal mol-1), thus to the formation of the glycosyl-enzyme intermediate, but not to kcat, thus to the hydrolysis of the glycosyl-enzyme. Interactions with the proximal (-1) sugar are much more significant, contributing up to 6.7 kcal mol-1 to both kcat/Km and kcat. These results together indicate that interactions with the distal sugar maintain similar magnitudes in the transition states for glycosylation and deglycosylation as well as in the glycosyl-enzyme intermediate and can be referred to as "uniform binding interactions" in the parlance of Albery and Knowles (Albery, W. J., and Knowles, J. R. (1976) Biochemistry 15, 5631-5640). Interactions with the proximal sugar are considerably stronger at the deglycosylation transition state than in the intermediate, and fall into the category of differential binding interactions. This behavior likely has its origins in the changes in ring conformation of the proximal sugar but not of the distal sugar between the ground state and the reaction transition state. Correlation of these individual interaction energies with the hydrogen-bonding pattern seen in the glycosyl-enzyme intermediate allows for the assignment of hydrogen-bond strengths to each interaction, with good correlation between the two approaches. These findings are relevant to the discussion of remote binding effects upon enzymatic catalysis.     

Mechanistic analysis of trehalose synthase from Mycobacterium smegmatis

Trehalose synthase (TreS) catalyzes the reversible interconversion of maltose and trehalose and has been shown recently to function primarily in the mobilization of trehalose as a glycogen precursor. Consequently, the mechanism of this intriguing isomerase is of both academic and potential pharmacological interest. TreS catalyzes the hydrolytic cleavage of α-aryl glucosides as well as α-glucosyl fluoride, thereby allowing facile, continuous assays. Reaction of TreS with 5-fluoroglycosyl fluorides results in the trapping of a covalent glycosyl-enzyme intermediate consistent with TreS being a member of the retaining glycoside hydrolase family 13 enzyme family, thus likely following a two-step, double displacement mechanism. This trapped intermediate was subjected to protease digestion followed by LC-MS/MS analysis, and Asp(230) was thereby identified as the catalytic nucleophile. The isomerization reaction was shown to be an intramolecular process by demonstration of the inability of TreS to incorporate isotope-labeled exogenous glucose into maltose or trehalose consistent with previous studies on other TreS enzymes. The absence of a secondary deuterium kinetic isotope effect and the general independence of k(cat) upon leaving group ability both point to a rate-determining conformational change, likely the opening and closing of the enzyme active site.     

The synthesis, testing and use of 5-fluoro-alpha-D-galactosyl fluoride to trap an intermediate on green coffee bean alpha-galactosidase and identify the catalytic nucleophile

5-Fluoro-alpha-D-galactopyranosyl fluoride was synthesized and its interaction with the active site of an alpha-galactosidase from green coffee bean (Coffea arabica), a retaining glycosidase, characterized kinetically and structurally. The compound behaves as an apparently tight binding (Ki = 600 nM) competitive inhibitor, achieving this high affinity through reaction as a slow substrate that accumulates a high steady-state concentration of the glycosyl-enzyme intermediate, as evidenced by ESiMS. Proteolysis of the trapped enzyme coupled with HPLC/MS analysis allowed the localization of a labeled peptide that was subsequently sequenced. Comparison of this sequence information to that of other members of the same glycosidase family revealed the active site nucleophile to be Asp145 within the sequence LKYDNCNNN. The importance of this residue to catalysis has been confirmed by mutagenesis studies.     

Mechanism-based labeling defines the free energy change for formation of the covalent glycosyl-enzyme intermediate in a xyloglucan endo-transglycosylase

Xyloglucan endo-transglycosylases (XETs) are key enzymes involved in the restructuring of plant cell walls during morphogenesis. As members of glycoside hydrolase family 16 (GH16), XETs are predicted to employ the canonical retaining mechanism of glycosyl transfer involving a covalent glycosyl-enzyme intermediate. Here, we report the accumulation and direct observation of such intermediates of PttXET16-34 from hybrid aspen by electrospray mass spectrometry in combination with synthetic "blocked" substrates, which function as glycosyl donors but are incapable of acting as glycosyl acceptors. Thus, GalGXXXGGG and GalGXXXGXXXG react with the wild-type enzyme to yield relatively stable, kinetically competent, covalent GalG-enzyme and GalGXXXG-enzyme complexes, respectively (Gal=Galbeta(1-->4), G=Glcbeta(1-->4), and X=Xylalpha(1-->6)Glcbeta(1-->4)). Quantitation of ratios of protein and saccharide species at pseudo-equilibrium allowed us to estimate the free energy change (DeltaG(0)) for the formation of the covalent GalGXXXG-enzyme as 6.3-8.5 kJ/mol (1.5-2.0 kcal/mol). The data indicate that the free energy of the beta(1-->4) glucosidic bond in xyloglucans is preserved in the glycosyl-enzyme intermediate and harnessed for religation of the polysaccharide in vivo.     

The mechanism of action of glycosidases.

The factors that may contribute to the rate enhancement observed with enzymatic versus non-enzymatic hydrolysis of glycosides are discussed. The nature of the active site as deduced from labelling studies with beta-glucosidases is described. A two-step mechanism involving either an enzyme stabilized glycosyl ion or a covalent glycosyl-enzyme intermediate is proposed. Experiments with a beta-glucosidase from almonds show that even with 2-deoxy glucosides with good leaving groups as aglycon which are hydrolyzed 1000 times more slowly than the corresponding glucosides, the deglucosylation step is faster than the cleavage of the glycosidic bond.     

Further studies on the catalytic mechanism of human liver alpha-L-fucosidase

Radiolabeling of human liver alpha-L-fucosidase (alpha-L-fucoside fucohydrolase, EC 3.2.1.51) with [1-3H]conduritol C trans-epoxide revealed that there are four active sites per tetrameric enzyme complex. Solvent isotope effect experiments give evidence for a proton transfer at the rate-limiting step in catalysis. Transglycosylase activity was observed using methanol as an alternative glycone acceptor to produce methyl alpha-L-fucoside, suggesting that alpha-L-fucose is formed when water is the acceptor. Initial burst kinetics experiments suggest that a glycosyl-enzyme intermediate is formed, although the magnitude of the burst is not stoichiometric with the number of active sites. These data, along with previous results, suggest a general acid-general base catalytic mechanism involving double inversion of stereochemistry at C-1 of fucose, as well as the formation of either a covalent glycosyl-enzyme intermediate or a tight ion pair between a charged active-site residue and a hypothetical fucosyl oxocarbonium ion intermediate.     

N-Acetylglucosaminidases from CAZy Family GH3 Are Really Glycoside Phosphorylases,Thereby Explaining Their Use of Histidine as an Acid/Base Catalyst in Place of Glutamic Acid

CAZy glycoside hydrolase family GH3 consists primarily of stereochemistry-retaining β-glucosidases but also contains a subfamily of β-N-acetylglucosaminidases. Enzymes from this subfamily were recently shown to use a histidine residue within a His-Asp dyad contained in a signature sequence as their catalytic acid/base residue. Reasons for their use of His rather than the Glu or Asp found in other glycosidases were not apparent. Through studies on a representative member, the Nag3 β-N-acetylglucosaminidase from Cellulomonas fimi, we now show that these enzymes act preferentially as glycoside phosphorylases. Their need to accommodate an anionic nucleophile within the enzyme active site explains why histidine is used as an acid/base catalyst in place of the anionic glutamate seen in other GH3 family members. Kinetic and mechanistic studies reveal that these enzymes also employ a double-displacement mechanism involving a covalent glycosyl-enzyme intermediate, which was directly detected by mass spectrometry. Phosphate has no effect on the rates of formation of the glycosyl-enzyme intermediate, but it accelerates turnover of the N-acetylglucosaminyl-enzyme intermediate ∼3-fold, while accelerating turnover of the glucosyl-enzyme intermediate several hundredfold. These represent the first reported examples of retaining β-glycoside phosphorylases, and the first instance of free β-GlcNAc-1-phosphate in a biological context.     

Trapping and characterization of covalent intermediates of mutant retaining glycosyltransferases

The enzymatic mechanism by which retaining glycosyltransferases (GTs) transfer monosaccharides with net retention of the anomeric configuration has, so far, resisted elucidation. Here, direct detection of covalent glycosyl-enzyme intermediates for mutants of two model retaining GTs, the human blood group synthesizing α-(1 → 3)-N-acetylgalactosaminyltransferase (GTA) and α-(1 → 3)-galactosyltransferase (GTB) mutants, by mass spectrometry (MS) is reported. Incubation of mutants of GTA or GTB, in which the putative catalytic nucleophile Glu(303) was replaced with Cys (i.e. GTA(E303C) and GTB(E303C)), with their respective donor substrate results in a covalent intermediate. Tandem MS analysis using collision-induced dissociation confirmed Cys(303) as the site of glycosylation. Exposure of the glycosyl-enzyme intermediates to a disaccharide acceptor results in the formation of the corresponding enzymatic trisaccharide products. These findings suggest that the GTA(E303C) and GTB(E303C) mutants may operate by a double-displacement mechanism.     

Syntheses of model compounds related to an antigenic epitope in pectic polysaccharides from Bupleurum falcatum L

The beta-galactosidases from Xanthomonas manihotis (beta-Gal Xmn) and Bacillus circulans (beta-Gal-3 Bcir) are retaining glycosidases that hydrolyze glycosidic bonds through a double displacement mechanism involving a covalent glycosyl-enzyme intermediate. The mechanism-based inactivator 2,4-dinitrophenyl 2-deoxy-2-fluoro-beta-D-galactopyranoside was shown to inactivate beta-Gal Xmn and beta-Gal-3 Bcir through the accumulation of 2-deoxy-2-fluorogalactosyl enzyme intermediates with half lives of 40 and 625 h, respectively. Peptic digestion of these labeled enzymes and analysis by LC-MS identified Glu(260) and Glu(233) as the catalytic nucleophiles involved in the formation of the glycosyl-enzyme intermediate during catalysis by beta-Gal Xmn and beta-Gal-3 Bcir, respectively. These findings confirm the previous prediction of the position of these residues based on primary sequence similarities to other members of the glycoside hydrolase family 35.     

Enzyme-substrate complex structures of a GH39 beta-xylosidase from Geobacillus stearothermophilus

Beta-D-Xylosidases are glycoside hydrolases that catalyse the release of xylose units from short xylooligosaccharides and are engaged in the final breakdown of plant cell-wall hemicelluloses. beta-D-Xylosidases are found in glycoside hydrolase families 3, 39, 43, 52 and 54. The first crystal structure of a GH39 beta-xylosidase revealed a multi-domain organization with the catalytic domain having the canonical (beta/alpha)8 barrel fold. Here, we report the crystal structure of the GH39 Geobacillus stearothermophilus beta-D-xylosidase, inactivated by a point mutation of the general acid-base residue E160A, in complex with the chromogenic substrate molecule 2,5-dinitrophenyl-beta-D-xyloside. Surprisingly, six of the eight active sites present in the crystallographic asymmetric unit contain the trapped covalent glycosyl-enzyme intermediate, while two of them still contain the uncleaved substrate. The structural characterization of these two critical species along the reaction coordinate of this enzyme identifies the residues forming its xyloside-binding pocket as well as those essential for its aglycone recognition.     

Analysis of the dynamic properties of Bacillus circulans xylanase upon formation of a covalent glycosyl-enzyme intermediate

NMR spectroscopy was used to search for mechanistically significant differences in the local mobility of the main-chain amides of Bacillus circulans xylanase (BCX) in its native and catalytically competent covalent glycosyl-enzyme intermediate states. 15N T1, T2, and 15N[1H] NOE values were measured for approximately 120 out of 178 peptide groups in both the apo form of the protein and in BCX covalently modified at position Glu78 with a mechanism-based 2-deoxy-2-fluoro-beta-xylobioside inactivator. Employing the model-free formalism of Lipari and Szabo, the measured relaxation parameters were used to calculate a global correlation time (tau(m)) for the protein in each form (9.2 +/- 0.2 ns for apo-BCX; 9.8 +/- 0.3 ns for the modified protein), as well as individual order parameters for the main-chain NH bond vectors. Average values of the order parameters for the protein in the apo and complexed forms were S2 = 0.86 +/- 0.04 and S2 = 0.91 +/- 0.04, respectively. No correlation is observed between these order parameters and the secondary structure, solvent accessibility, or hydrogen bonding patterns of amides in either form of the protein. These results demonstrate that the backbone of BCX is well ordered in both states and that formation of the glycosyl-enzyme intermediate leads to little change, in any, in the dynamic properties of BCX on the time scales sampled by 15N-NMR relaxation measurements.     

Sugar ring distortion in the glycosyl-enzyme intermediate of a family G/11 xylanase

The 1.8 A resolution structure of the glycosyl-enzyme intermediate formed on the retaining beta-1,4-xylanase from Bacillus circulans has been determined using X-ray crystallographic techniques. The 2-fluoro-xylose residue bound in the -1 subsite adopts a 2,5B (boat) conformation, allowing atoms C5, O5, C1, and C2 of the sugar to achieve coplanarity as required at the oxocarbenium ion-like transition states of the double-displacement catalytic mechanism. Comparison of this structure to that of a mutant of this same enzyme noncovalently complexed with xylotetraose [Wakarchuk et al. (1994) Protein Sci. 3, 467-475] reveals a number of differences beyond the distortion of the sugar moiety. Most notably, a bifurcated hydrogen bond interaction is formed in the glycosyl-enzyme intermediate involving Heta of Tyr69, the endocyclic oxygen (O5) of the xylose residue in the -1 subsite, and Oepsilon2 of the catalytic nucleophile, Glu78. To gain additional understanding of the role of Tyr69 at the active site of this enzyme, we also determined the 1.5 A resolution structure of the catalytically inactive Tyr69Phe mutant. Interestingly, no significant structural perturbation due to the loss of the phenolic group is observed. These results suggest that the interactions involving the phenolic group of Tyr69, O5 of the proximal saccharide, and Glu78 Oepsilon2 are important for the catalytic mechanism of this enzyme, and it is proposed that, through charge redistribution, these interactions serve to stabilize the oxocarbenium-like ion of the transition state. Studies of the covalent glycosyl-enzyme intermediate of this xylanase also provide insight into specificity, as contacts with C5 of the xylose moiety exclude sugars with hydroxymethyl substituents, and the mechanism of catalysis, including aspects of stereoelectronic theory as applied to glycoside hydrolysis.     

Structural and kinetic analysis of two covalent sialosyl-enzyme intermediates on Trypanosoma rangeli sialidase

Trypanosoma rangeli sialidase is a glycoside hydrolase (family GH33) that catalyzes the cleavage of alpha-2-->3-linked sialic acid residues from sialoglycoconjugates with overall retention of anomeric configuration. Retaining glycosidases usually operate through a ping-pong mechanism, wherein a covalent intermediate is formed between the carbohydrate and an active site carboxylic acid of the enzyme. Sialidases, instead, appear to use a tyrosine as the catalytic nucleophile, leaving the possibility of an essentially different catalytic mechanism. Indeed, a direct nucleophilic role for a tyrosine was shown for the homologous trans-sialidase from Trypanosoma cruzi, although itself not a typical sialidase. Here we present the three-dimensional structures of the covalent glycosyl-enzyme complexes formed by the T. rangeli sialidase with two different mechanism-based inactivators at 1.9 and 1.7 Angstroms resolution. To our knowledge, these are the first reported structures of enzymatically competent covalent intermediates for a strictly hydrolytic sialidase. Kinetic analyses have been carried out on the formation and turnover of both intermediates, showing that structural modifications to these inactivators can be used to modify the lifetimes of covalent intermediates. These results provide further evidence that all sialidases likely operate through a similar mechanism involving the transient formation of a covalently sialylated enzyme. Furthermore, we believe that the ability to "tune" the inactivation and reactivation rates of mechanism-based inactivators toward specific enzymes represents an important step toward developing this class of inactivators into therapeutically useful compounds.     

Crystal Structures Capture Three States in the Catalytic Cycle of a Pyridoxal Phosphate (PLP) Synthase

PLP synthase (PLPS) is a remarkable single-enzyme biosynthetic pathway that produces pyridoxal 5′-phosphate (PLP) from glutamine, ribose 5-phosphate, and glyceraldehyde 3-phosphate. The intact enzyme includes 12 synthase and 12 glutaminase subunits. PLP synthesis occurs in the synthase active site by a complicated mechanism involving at least two covalent intermediates at a catalytic lysine. The first intermediate forms with ribose 5-phosphate. The glutaminase subunit is a glutamine amidotransferase that hydrolyzes glutamine and channels ammonia to the synthase active site. Ammonia attack on the first covalent intermediate forms the second intermediate. Glyceraldehyde 3-phosphate reacts with the second intermediate to form PLP. To investigate the mechanism of the synthase subunit, crystal structures were obtained for three intermediate states of the Geobacillus stearothermophilus intact PLPS or its synthase subunit. The structures capture the synthase active site at three distinct steps in its complicated catalytic cycle, provide insights into the elusive mechanism, and illustrate the coordinated motions within the synthase subunit that separate the catalytic states. In the intact PLPS with a Michaelis-like intermediate in the glutaminase active site, the first covalent intermediate of the synthase is fully sequestered within the enzyme by the ordering of a generally disordered 20-residue C-terminal tail. Following addition of ammonia, the synthase active site opens and admits the Lys-149 side chain, which participates in formation of the second intermediate and PLP. Roles are identified for conserved Asp-24 in the formation of the first intermediate and for conserved Arg-147 in the conversion of the first to the second intermediate.     

Family 39 alpha-l-iduronidases and beta-D-xylosidases react through similar glycosyl-enzyme intermediates: identification of the human iduronidase nucleophile

The inclusion of both beta-D-xylosidases and alpha-L-iduronidases within the same sequence-related family (family 39), despite the considerable difference in substrate structures and poor sequence conservation around the putative nucleophile, raises concerns about whether a common mechanism is followed by the two enzymes. A novel anchimeric assistance mechanism for iduronidases involving a lactone intermediate is one possibility. NMR analysis of the methanolysis reaction catalyzed by human alpha-L-iduronidase reveals that, as with the beta-D-xylosidases, alpha-L-iduronidase is a retaining glycosidase. Using two different mechanism-based inactivators, 5-fluoro-alpha-L-iduronyl fluoride and 2-deoxy-2-fluoro-alpha-L-iduronyl fluoride, the active site nucleophile in the human alpha-L-iduronidase was identified as Glu299 within the (295)IYNDEAD(301) sequence. The equivalent, though loosely predicted, glutamic acid was identified as the nucleophile in the family 39 beta-D-xylosidase from Bacillus sp. [Vocadlo, D., et al. (1998) Biochem. J. 335, 449-455]; thus, a common mechanism involving a covalent glycosyl-enzyme intermediate that adopts the rather uncommon (2,5)B conformation is predicted.     

Trapping of transition metal-nucleotide complexes in myosin subfragment 1 by cross-linking thiols; divalent transition metal probes of the active site

Recent experiments [Wells, J., & Yount, R. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 4966] have shown it is possible to trap MgADP and other nucleotides stably at the active site of myosin by cross-linking two thiol groups. A variety of cross-linking reagents including chelation of the two thiols by cobalt (III) phenanthroline or covalent reaction with N,N'-p-phenylenedimaleimide (pPDM) are effective trapping agents. No trapping of nucleotides occurs in the absence of divalent metals. Thus far Mg2+, Mn2+, Co2+, Ni2+, and Ca2+ but not Zn2+ all function to promote trapping of the 1:1 divalent metal-ADP complex and to enhance the rate of ATPase inactivation. Substitution-inert Cr(III) complexes of ADP, ATP, or pyrophosphate that bind very weakly or not at all to the active site are not trapped by cross-linking. While the stability of the trapped divalent metals varies, e.g., t1/2 of 0.5-7 days at 0 degree C, they are stable enough to permit accurate spectral measurements of the Mn2+ and Co2+ trapped complexes. Electron paramagnetic resonance (EPR) measurements of Mn2+ bound to 5'-adenylyl imidodiphosphate or complexed to myosin chymotryptic subfragment 1 indicate that the metal is bound at the active site. Circular dichroism (CD) and visible absorption studies of the Co2+ . ADP trapped complex indicate the metal ion is in an asymmetric octahedral environment. EPR and CD measurements show that the environment of the metal nucleotide is the same whether bound reversibly or stably trapped at the active site.     

Mechanism of Gly-Pro-pNA cleavage catalyzed by dipeptidyl peptidase-IV and its inhibition by saxagliptin (BMS-477118)

Dipeptidyl peptidase-IV (DPP-IV) is a serine protease with a signature Asp-His-Ser motif at the active site. Our pH data suggest that Gly-Pro-pNA cleavage catalyzed by DPP-IV is facilitated by an ionization of a residue with a pK of 7.2 +/- 0.1. By analogy to other serine proteases this pK is suggestive of His-Asp assisted Ser addition to the P1 carbonyl carbon of the substrate to form a tetrahedral intermediate. Solvent kinetic isotope effect studies yielded a D2Okcat/Km=2.9+/-0.2 and a D2Okcat=1.7+/-0.2 suggesting that kinetically significant proton transfers contribute to rate limitation during acyl intermediate formation (leaving group release) and hydrolysis. A "burst" of product release during pre steady-state Gly-Pro-pNA cleavage indicated rate limitation in the deacylation half-reaction. Nevertheless, the amplitude of the burst exceeded the enzyme concentration significantly (approximately 15-fold), which is consistent with a branching deacylation step. All of these data allowed us to better understand DPP-IV inhibition by saxagliptin (BMS-477118). We propose a two-step inhibition mechanism wherein an initial encounter complex is followed by covalent intermediate formation. Final inhibitory complex assembly (kon) depends upon the ionization of an enzyme residue with a pK of 6.2 +/- 0.1, and we assigned it to the catalytic His-Asp pair which enhances Ser nucleophilicity for covalent addition. An ionization with a pK of 7.9 +/- 0.2 likely reflects the P2 terminal amine of the inhibitor hydrogen bonding to Glu205/Glu206 in the enzyme active site. The formation of the covalent enzyme-inhibitor complex was reversible and dissociated with a koff of (5.5 +/- 0.4) x 10(-5) s(-1), thus yielding a Ki* (as koff/kon) of 0.35 nM, which is in good agreement with the value of 0.6 nM obtained from steady-state inhibition studies. Proton NMR spectra of DPP-IV showed a downfield resonance at 16.1 ppm. Two additional peaks in the 1H NMR spectra at 17.4 and 14.1 ppm were observed upon mixing the enzyme with saxagliptin. Fractionation factors (phi) of 0.6 and 0.5 for the 17.4 and 14.1 ppm peaks, respectively, are suggestive of short strong hydrogen bonds in the enzyme-inhibitor complex.     

Ground-state, transition-state, and metal-cation effects of the 2-hydroxyl group on beta-D-galactopyranosyl transfer catalyzed by beta-galactosidase (Escherichia coli, lac Z)

Substitution of the C2-OH group by C2-H at 4-nitrophenyl-beta-d-galactopyranoside to give 4-nitrophenyl-2-deoxy-beta-d-galactopyranoside causes (1) a change in the rate-determining step for beta-galactosidase-catalyzed sugar hydrolysis from formation to breakdown of a covalent intermediate; (2) a 14 000-fold decrease in the second-order rate constant k(3)/K(d) for enzyme-catalyzed transfer of the beta-d-galactopyranosyl group from the substrate to form a covalent adduct to the enzyme; and (3) a larger 320 000-fold decrease in the first-order rate constant k(s) for hydrolysis of this covalent adduct. Only a small fraction (ca. 7%) of the 2-OH substituent effect is expressed in the ground-state Michaelis complex, so that the (apparent) strong interactions between the enzyme and 2-OH group that stabilize the transition state for beta-d-galactopyranosyl transfer only develop upon moving from the Michaelis complex to the transition state. Mg(2+) activates beta-galactosidase for cleavage of both 4-nitrophenyl-beta-d-galactopyranoside and 4-nitrophenyl-2-deoxy-beta-d-galactopyranoside. This suggests that Mg(2+) activation does not involve interactions with the 2-OH group. The removal of Mg(2+) from beta-galactosidase causes a change in the rate-determining step for enzyme-catalyzed hydrolysis of 4-nitrophenyl-2-deoxy-beta-d-galactopyranoside from breakdown to formation of the covalent intermediate. The observed 2-OH effect would require a very large (10-11 kcal/mol) stabilization of the transition state for beta-d-galactopyranosyl group transfer to water by interactions between beta-galactosidase and the neutral 2-OH group. We suggest that the apparent effect of the neutral substituent is more simply rationalized by ionization of the 2-OH to form a 2-O(-) anion, which provides effective electrostatic stabilization of the cationic transition state for glycoside cleavage at an active site of relatively low dielectric constant.     

Mechanistic Investigations of Unsaturated Glucuronyl Hydrolase from Clostridium perfringens

Experiments were carried out to probe the details of the hydration-initiated hydrolysis catalyzed by the Clostridium perfringens unsaturated glucuronyl hydrolase of glycoside hydrolase family 88 in the CAZy classification system. Direct ¹H NMR monitoring of the enzymatic reaction detected no accumulated reaction intermediates in solution, suggesting that rearrangement of the initial hydration product occurs on-enzyme. An attempt at mechanism-based trapping of on-enzyme intermediates using a 1,1-difluoro-substrate was unsuccessful because the probe was too deactivated to be turned over by the enzyme. Kinetic isotope effects arising from deuterium-for-hydrogen substitution at carbons 1 and 4 provide evidence for separate first-irreversible and overall rate-determining steps in the hydration reaction, with two potential mechanisms proposed to explain these results. Based on the positioning of catalytic residues in the enzyme active site, the lack of efficient turnover of a 2-deoxy-2-fluoro-substrate, and several unsuccessful attempts at confirmation of a simpler mechanism involving a covalent glycosyl-enzyme intermediate, the most plausible mechanism is one involving an intermediate bearing an epoxide on carbons 1 and 2.