Identification of Tyr241 as a key catalytic base in the family 4 glycoside hydrolase BglT from Thermotoga maritima.

While the vast majority of glycosidases catalyze glycoside hydrolysis via oxocarbenium ion-like transition states and typically employ carboxylic acid residues as acid/base or nucleophile catalysts, two subfamilies of these enzymes (GH4 and GH109 in the CAZY classification) conduct hydrolysis via a redox-assisted mechanism involving anionic transition states. While good evidence of this mechanism has been obtained, the identities of the catalytic residues involved have not yet been confirmed. Mechanistic analyses of mutants of the 6-phospho-ß-glucosidase from Thermotoga maritima (BglT), in which the active site tyrosine residue (Tyr 241) has been replaced with Phe and Ala, provide support for its role as a catalytic base. The pH dependence of k(cat) and k(cat)/K(m), particularly of the acidic limb corresponding to the base, is shifted relative to that of the wild-type enzyme. Kinetic isotope effects for hydrolysis of substrates deuterated at C1, C2, and C3 by the Tyr 241 mutants are strongly pH-dependent, with essentially full primary kinetic isotope effects being observed for the 2-deutero substrate at low pH with the Tyr241Ala mutant. This is consistent with a slowing of the deprotonation step upon removal of the base.

Mechanism of GlvA from Bacillus subtilis: a detailed kinetic analysis of a 6-phospho-alpha-glucosidase from glycoside hydrolase family 4.

GlvA, a 6-phospho-alpha-glucosidase from Bacillus subtilis assigned to glycoside hydrolase family 4, catalyzes the hydrolysis of maltose 6'-phosphate via a redox-elimination-addition mechanism requiring NAD+ as cofactor. In contrast to previous reports and consistent with the proposed mechanism, GlvA is only activated in the presence of the nicotinamide cofactor in its oxidized, and not the reduced NADH, form. Significantly, GlvA catalyzes the hydrolysis of both 6-phospho-alpha- and 6-phospho-beta-glucosides containing activated leaving groups such as p-nitrophenol and does so with retention and inversion, respectively, of anomeric configuration. Mechanistic details of the individual bond cleaving and forming steps were probed using a series of 6-phospho-alpha- and 6-phospho-beta-glucosides. Primary deuterium kinetic isotope effects (KIEs) were measured for both classes of substrates in which either the C2 or the C3 protons have been substituted with a deuterium, consistent with C-H bond cleavage at each center being partially rate-limiting. Kinetic parameters were also determined for 1-[2H]-substituted substrates, and depending on the substrates and the reaction conditions, the measurements of kcat and kcat/KM produced either no KIEs or inverse KIEs. In conjunction with results of Brønsted analyses with both aryl 6-phospho-alpha- and beta-glucosides, the kinetic data suggest that GlvA utilizes an E1cb mechanism analogous to that proposed for the Thermotoga maritima BglT, a 6-phospho-beta-glucosidase in glycoside hydrolase family 4 (Yip, V.L.Y et al. (2006) Biochemistry 45, 571-580). The pattern of isotope effects measured and the observation of very similar kcat values for all substrates, including unactivated and natural substrates, indicate that the oxidation and deprotonation steps are rate-limiting steps in essentially all cases. This mechanism permits the cleavage of both alpha- and beta-glycosides within the same active site motif and, for activated substrates that do not require acid catalysis for cleavage, within the same active site, yielding the product sugar-6-phosphate in the same anomeric form in the two cases.

Breakdown of oligosaccharides by the process of elimination.

Several new mechanisms for enzyme-catalyzed breakdown of oligosaccharides have been uncovered in recent years. A common feature is the recruitment of elimination steps rather than direct displacements. Bond cleavage can proceed via E1 mechanisms with cationic transition states or E1(cb) mechanisms with anionic transition states, and can even involve NAD(+)-mediated redox steps. A common feature emerging from studies on disparate syn-eliminating enzymes is the use of a single catalytic residue, often tyrosine, as both general acid and base.

Mechanistic analysis of the unusual redox-elimination sequence employed by Thermotoga maritima BglT: a 6-phospho-beta-glucosidase from glycoside hydrolase family 4.

"Classical" glycosidases utilize either direct or double-displacement mechanisms involving oxocarbenium ion-like transition states to catalyze the hydrolysis of glycosidic bonds. By contrast, the mechanism of the glycosidases in glycoside hydrolase family 4 has been recently proposed to involve NAD+-mediated redox steps along with alpha,beta-elimination and addition steps via anionic intermediates. Support for this mechanism in BglT, a 6-phospho-beta-glucosidase in family 4, has been provided through mechanistic and X-ray crystallographic analyses [Yip, V. L.Y., et al. (2004) J. Am. Chem. Soc. 126, 8354-8355] in which primary deuterium kinetic isotope effects for the hydride abstraction at C3 and for the alpha-proton abstraction at C2 indicate that these two steps are both partially rate-limiting. Current data reveal that there is no secondary deuterium kinetic isotope effect associated with the rehybridization of the C1 sp3 center to a sp2 center. Furthermore, a flat linear free energy relationship was established with a series of aryl 6-phospho-beta-D-glucosides of varying leaving group abilities. Taken together, these data indicate that cleavage of the C1-O1 linkage does not occur during a rate-limiting step. Since the deprotonation at C2 is slow and partially rate-limiting while the departure of the leaving group is not, a stepwise E1(cb)-type mechanism rather than an E1 or a concerted E2-syn mechanism is proposed. Direct evidence for the role of NAD+ was obtained by reduction in situ using NaBH4 leading to an inactive enzyme that could be reactivated by the addition of excess NAD+. This was accompanied by the expected UV-vis spectrophotometric changes.

NAD+ and metal-ion dependent hydrolysis by family 4 glycosidases: structural insight into specificity for phospho-beta-D-glucosides.

The import of disaccharides by many bacteria is achieved through their simultaneous translocation and phosphorylation by the phosphoenolpyruvate-dependent phosphotransferase system (PEP-PTS). The imported phospho-disaccharides are, in some cases, subsequently hydrolyzed by members of the unusual glycoside hydrolase family GH4. The GH4 enzymes, occasionally found also in bacteria such as Thermotoga maritima that do not utilise a PEP-PTS system, require both NAD(+) and Mn(2+) for catalysis. A further curiosity of this family is that closely related enzymes may show specificity for either alpha-d- or beta-d-glycosides. Here, we present, for the first time, the three-dimensional structure (using single-wavelength anomalous dispersion methods, harnessing extensive non-crystallographic symmetry) of the 6-phospho-beta-glycosidase, BglT, from T.maritima in native and complexed (NAD(+) and Glc6P) forms. Comparison of the active-center structure with that of the 6-phospho-alpha-glucosidase GlvA from Bacillus subtilis reveals a striking degree of structural similarity that, in light of previous kinetic isotope effect data, allows the postulation of a common reaction mechanism for both alpha and beta-glycosidases. Given that the "chemistry" occurs primarily on the glycone sugar and features no nucleophilic attack on the intact disaccharide substrate, modulation of anomeric specificity for alpha and beta-linkages is accommodated through comparatively minor structural changes.

Nature's many mechanisms for the degradation of oligosaccharides.

Recent work on the mechanistic elucidation of the polysaccharide lyases, the [small alpha]-1,4-glucan lyases, and the Family 4 glycosidases have demonstrated that nature has evolved to use elimination steps for the degradation of oligosaccharides. The polysaccharide lyases (E.C. 4.2.2.-) have been shown to cleave uronic acid-containing polysaccharides via a stepwise E1cB mechanism. The mechanism of the alpha-1,4-glucan lyases (E.C. 4.2.2.13) is similar to the Family 31 glycosidases, forming a covalent glycosyl-enzyme intermediate, which is subsequently cleaved by an E1-like E2 mechanism. Meanwhile, the Family 4 glycosidases (E.C. 3.2.1.6) are suggested to undergo an oxidation-elimination-addition-reduction sequence. These three groups of enzymes are examples of stark contrast to the vast number of well-characterized glycosidases (E.C. 3.2.1.-), which utilize either the direct or double displacement mechanisms as proposed by Koshland over 50 years ago.

Novel catalytic mechanism of glycoside hydrolysis based on the structure of an NAD+/Mn2+ -dependent phospho-alpha-glucosidase from Bacillus subtilis.

GlvA, a 6-phospho-alpha-glucosidase from Bacillus subtilis, catalyzes the hydrolysis of maltose-6'-phosphate and belongs to glycoside hydrolase family GH4. GH4 enzymes are unique in their requirement for NAD(H) and a divalent metal for activity. We have determined the crystal structure of GlvA in complex with its ligands to 2.05 A resolution. Analyses of the active site architecture, in conjunction with mechanistic studies and precedent from the nucleotide diphosphate hexose dehydratases and other systems, suggest a novel mechanism of glycoside hydrolysis by GlvA that involves both the NAD(H) and the metal.

An unusual mechanism of glycoside hydrolysis involving redox and elimination steps by a family 4 beta-glycosidase from Thermotoga maritima.

Among the numerous well-characterized families of glycosidases, family 4 appears to be the anomaly, requiring both catalytic NAD+ and a divalent metal for activity. The unusual cofactor requirement prompted the proposal of a mechanism involving key NAD+-mediated redox steps as well as elimination of the glycosidic oxygen. Primary kinetic isotope effects for the 2- and 3-deutero substrate analogues, isotopic exchange with solvent, and structural analysis of a 6-phospho-beta-glucosidase, BglT (E.C. 3.2.1.6), provided evidence in support of the proposed mechanism, which has striking resemblances to that of the sugar dehydratases. Furthermore, analysis of the stereochemical outcome indicated that family 4 enzymes are retaining glycosidases.