Characterization of a beta-N-acetylhexosaminidase and a beta-N-acetylglucosaminidase/beta-glucosidase from Cellulomonas fimi.

The gram-positive soil bacterium Cellulomonas fimi is shown to produce at least two intracellular beta-N-acetylglucosaminidases, a family 20 beta-N-acetylhexosaminidase (Hex20), and a novel family 3-beta-N-acetylglucosaminidase/beta-glucosidase (Nag3), through screening of a genomic expression library, cloning of genes and analysis of their sequences. Nag3 exhibits broad substrate specificity for substituents at the C2 position of the glycone: kcat/Km values at 25 degrees C were 0.066 s(-1) x mM(-1) and 0.076 s(-1) x mM(-1) for 4'-nitrophenyl beta-N-acetyl-D-glucosaminide and 4'-nitrophenyl beta-D-glucoside, respectively. The first glycosidase with this broad specificity to be described, Nag3, suggests an interesting evolutionary link between beta-N-acetylglucosaminidases and beta-glucosidases of family 3. Reaction by a double-displacement mechanism was confirmed for Nag3 through the identification of a glycosyl-enzyme species trapped with the slow substrate 2',4'-dinitrophenyl 2-deoxy-2-fluoro-beta-D-glucopyranoside. Hex20 requires the acetamido group at C2 of the substrate, being unable to cleave beta-glucosides, since its mechanism involves an oxazolinium ion intermediate. However, it is broad in its specificity for the D-glucosyl/D-galactosyl configuration of the glycone: Km and kcat values were 53 microM and 482.3 s(-1) for 4'-nitrophenyl beta-N-acetyl-D-glucosaminide and 66 microM and 129.1 s(-1) for 4'-nitrophenyl beta-N-acetyl-D-galactosaminide.

Fluorescent glycosidase inhibiting 1,5-dideoxy-1,5-iminoalditols.

1,5-Dideoxy-1,5-iminoalditols of various configurations as well as isofagomine were N-alkylated with non-polar straight chain spacer-arms by a set of simple standard procedures. The spacer-arms' terminal functional groups, primary amines, were employed to introduce fluorescent tags such as dansyl and dapoxyl moieties. Resulting derivatives in the D-xylo, D-gluco, D-galacto as well as GlcNAc series showed distinctly improved glycosidase inhibitory activities compared to parent compounds and are designed to be useful analytical tools.

Probing the aglycon binding site of a beta-glucosidase: a collection of C-1-modified 2,5-dideoxy-2,5-imino-D-mannitol derivatives and their structure-activity relationships as competitive inhibitors.

A range of new C-1 modified derivatives of the powerful glucosidase inhibitor 2,5-dideoxy-2,5-imino-D-mannitol has been synthesised and their biological activities probed with the beta-glucosidase from Agrobacterium sp. Ki values are compared with those of previously prepared close relatives. Findings suggest dramatic effects exerted by the aglycon binding site on substrate/inhibitor binding.

Mechanism of Thermoanaerobacterium saccharolyticum beta-xylosidase: kinetic studies.

The catalytic mechanism of Thermoanaerobacterium saccharolyticum beta-xylosidase (XynB) from family 39 of glycoside hydrolases has been subjected to a detailed kinetic investigation using a range of substrates. The enzyme exhibits a bell-shaped pH dependence of k(cat)/K(m), reflecting apparent pK(a) values of 4.1 and 6.8. The k(cat) and k(cat)/K(m) values for a series of aryl xylosides have been measured and used to construct two Brønsted plots. The plot of log(k(cat)/K(m)) against the pK(a) of the leaving group reveals a significant correlation (beta(lg) = -0.97, r(2) = 0.94, n = 8), indicating that fission of the glycosidic bond is significantly advanced in the transition state leading to the formation of the xylosyl-enzyme intermediate. The large negative value of the slope indicates that there is relatively little proton donation to the glycosidic oxygen in the transition state. A biphasic, concave-downward plot of log(k(cat)) against pK(a) provides good evidence for a two-step double-displacement mechanism involving a glycosyl-enzyme intermediate. For activated leaving groups (pK(a) < 9), the breakdown of the xylosyl-enzyme intermediate is the rate-determining step, as indicated by the absence of any effect of the pK(a) of the leaving group on log(k(cat)) (beta(lg) approximately 0). However, a strong dependence of the first-order rate constant on the pK(a) value of relatively poor leaving groups (pK(a) > 9) suggests that the xylosylation step is rate-determining for these substrates. Support for the dexylosylation chemical step being rate-determining for activated substrates comes from nucleophilic competition experiments in which addition of dithiothreitol results in an increase in turnover rates. Normal secondary alpha-deuterium kinetic isotope effects ((alpha-D)(V) or (alpha-D)(V/K) = 1.08-1.10) for three different substrates of widely varying pK(a) value (5.15-9.95) have been measured and these reveal that the transition states leading to the formation and breakdown of the intermediate are similar and both steps involve rehybridization of C1 from sp(3) to sp(2). These results are consistent only with "exploded" transition states, in which the saccharide moiety bears considerable positive charge, and the intermediate is a covalent acylal-ester where C1 is sp(3) hybridized.

A case for reverse protonation: identification of Glu160 as an acid/base catalyst in Thermoanaerobacterium saccharolyticum beta-xylosidase and detailed kinetic analysis of a site-directed mutant.

The catalytic mechanism of the family 39 Thermoanaerobacterium saccharolyticum beta-xylosidase (XynB) involves a two-step double-displacement mechanism in which a covalent alpha-xylosyl-enzyme intermediate is formed with assistance from a general acid and then hydrolyzed with assistance from a general base. Incubation of recombinant XynB with the newly synthesized active site-directed inhibitor, N-bromoacetyl-beta-D-xylopyranosylamine, resulted in rapid, time-dependent inactivation of the enzyme (k(i)/K(i) = 4.3 x 10(-4) s(-1)mM(- 1)). Protection from inactivation using xylose or benzyl 1-thio-beta-xyloside suggested that the inactivation was active site-directed. Mass spectrometric analysis indicated that incubation of the enzyme with the inactivator resulted in the stoichiometric formation of a new enzyme species bearing the label. Comparative mapping of peptic digests of both the labeled and unlabeled enzyme by HPLC coupled to an electrospray ionization mass spectrometer permitted the identification of a labeled peptide. Sequencing of this peptide by tandem mass spectrometry identified Glu160 within the sequence (157)IWNEPNL(164) as the site of attachment of the N-acetyl-beta-D-xylopyranosylamine moiety. Kinetic analysis of the Glu160Ala mutant strongly suggests that this residue is involved in acid/base catalysis as follows. First, a significant difference in the dependence of k(cat)/K(m) on pH as compared to that seen for the wild-type enzyme was found, as expected for a residue that is involved in acid/base catalysis. The changes, however, were not as simple as those seen in other cases. Second, a dramatic decrease (up to 10(5)-fold) in the catalytic efficiency (k(cat)/K(m)) of the enzyme with a substrate requiring protonic assistance is observed upon such mutation. In contrast, the catalytic efficiency of the enzyme with substrates bearing a good leaving group, not requiring acid catalysis, is only moderately impaired relative to that of the wild-type enzyme (8-fold). Surprisingly, however, the glycosylation step was rate-limiting for all but the most reactive substrates. Last, the addition of azide as a competitive nucleophile resulted in the formation of a beta-xylosyl azide product and increased the k(cat) and K(m) values up to 8-fold while k(cat)/K(m) remained relatively unchanged. Such kinetic behavior is consistent with azide acting competitively with water as a nucleophile in the second step of the enzyme catalyzed reaction involving breakdown of the xylosyl-enzyme intermediate. Together, these results provide strong evidence for a role of Glu160 in acid/base catalysis but suggest that it may be partnered by a second carboxylic acid residue and that the enzyme may function through using acid catalysis involving reverse protonation of active site residues.