The Synthesis of a New Class of Potential Inhibitors for Glycoside Hydrolases†

Some attempts toward the synthesis of novel inhibitors of glycosyl transferases are described. More successfully, the synthesis of an activated cyclopropacyclohexene and an amide and an amine of a cyclopropa‐fused pyranose are described. None of these three novel compounds proved to be a significant inhibitor of a retaining α‐glucosidase from barley.     

Substrate‐Guided Front‐Face Reaction Revealed by Combined Structural Snapshots and Metadynamics for the Polypeptide N‐Acetylgalactosaminyltransferase 2

The retaining glycosyltransferase GalNAc‐T2 is a member of a large family of human polypeptide GalNAc‐transferases that is responsible for the post‐translational modification of many cell‐surface proteins. By the use of combined structural and computational approaches, we provide the first set of structural snapshots of the enzyme during the catalytic cycle and combine these with quantum‐mechanics/molecular‐mechanics (QM/MM) metadynamics to unravel the catalytic mechanism of this retaining enzyme at the atomic‐electronic level of detail. Our study provides a detailed structural rationale for an ordered bi–bi kinetic mechanism and reveals critical aspects of substrate recognition, which dictate the specificity for acceptor Thr versus Ser residues and enforce a front‐face S_Ni‐type reaction in which the substrate N‐acetyl sugar substituent coordinates efficient glycosyl transfer.     

Directed evolution of new glycosynthases from Agrobacterium beta-glucosidase: a general screen to detect enzymes for oligosaccharide synthesis

BACKGROUND: Oligosaccharide synthesis is becoming increasingly important to industry as diverse therapeutic roles for these molecules are discovered. The chemical synthesis of oligosaccharides on an industrial scale is often prohibitively complex and costly. An alternative, that of enzymatic synthesis, is limited by the difficulty of obtaining an appropriate enzyme. A general screen for enzymes that catalyze the synthesis of the glycosidic bond would enable the identification and engineering of new or improved enzymes. RESULTS: Glycosynthases are nucleophile mutants of retaining glycosidases that efficiently catalyze the synthesis of the glycosidic linkage by condensing an activated glycosyl fluoride donor with a suitable acceptor sugar. A novel agar plate-based coupled-enzyme screen was developed (using a two-plasmid system) and used to select an improved glycosynthase from a library of mutants. CONCLUSIONS: Plate-based coupled-enzyme screens of this type are extremely valuable for identification of functional synthetic enzymes and can be applied to the evolution of a range of glycosyl transferases.     

The Biosynthesis of Cellulose

Abstract

Cellulose is one of the major commercial products of Sweden and constitutes the most abundant of the natural polymer systems. Thus, it is of interest to review the molecular design and architecture of cellulose with particular reference to the controls of its biosynthesis. The bioassembly process is highly ordered and structured, reflecting the intricate series of events which must occur to generate a thermodynamically metastable crystalline submicroscopic, ribbonlike structure. The plant cell wall is an extremely complex composite of many different polymers. Cellulose is the “reinforcing rod” component of the wall. True architectural design demands a polymer which can withstand great flexing and torsional strain. Using comparative Hydrophobic Cluster Analysis of a bacterial cellulose synthase and other glycosyl transferases, the multidomain architecture of glycosyl transferases has been analyzed. All polymerization reactions which are processive require at least three catalytic sites located on two different domains. In contrast, retaining reactions with glycosyl transferases require only a single domain and two sites. Cellulose synthase appears to have evolved a mechanism to simultaneously bind at least three UDP-glucoses and to polymerize, by double addition, two UDP-glucoses in such a manner that the 2-fold screw axis of the β-1,4-glucan chain is maintained. Thus, no primer is required as the glucose monomers are added two-by-two to the growing chain. At the next higher level of assembly, the catalytic sites simultaneously polymerize parallel glucan chain polymers in close proximity so that they will favorably associate to crystallize into the metastable cellulose I allomorph. Recent energy analysis suggests that the first stage of this association is the formation of a minisheet through van der Waals forces, followed by layering of these minisheets to form the crystalline microfibril. In native cellulose biogenesis, the microfibril shape and size appear to be determined by a multimeric enzyme complex (TC) which resides in the plasma membrane. This complex, known as a terminal complex, was discovered through electron microscopy of freeze fracture replicas. The entire complex moves in the plane of the fluid plasma membrane as the result of polymerization/crystallization reactions. The assembly stages for native cellulose I are coordinated on a spatial/temporal scale, and they are under the genetic control of the organism. This might lead one to conclude that cellulose I could only be assembled with Nature's indigenous machinery; however, this is not the case. Recently, in collaboration with Professor Kobayashi and his colleagues in Sendai and Tokyo, we have synthesized cellulose I abiotically under conditions very different from those in the living cell or from isolated cell components. Purification of an endoglucanase from Trichoderma which serves as the catalyst and the addition of β-cellobiosyl fluoride as the substrate in acetonitrile/acetate buffer has led to the assembly of synthetic cellulose I. Although natural and synthetic assembly pathways are very different, there are similar, underlying fundamental mechanisms common to both. These mechanisms will be discussed in relation to the more thermodynamically stable allomorph of cellulose (cellulose II) first demonstrated by Professor Rånby in 1952. The evolution of cellulose biosynthesis will be summarized in terms of the demands for maintaining optimal cellular environments to generate the complex macromolecular assemblies for cell wall biogenesis. Nature provides an exceptional model for cellulose biosynthesis that will lead us toward the biotechnological production of improved natural cellulose as well as synthetic cellulose and its derivatives.     

Structural Snapshots of α‐1,3‐Galactosyltransferase with Native Substrates: Insight into the Catalytic Mechanism of Retaining Glycosyltransferases

Glycosyltransferases (GTs) are a key family of enzymes that catalyze the synthesis of glycosidic bonds in all living organisms. The reaction involves the transfer of a glycosyl moiety and can proceed with retention or inversion of the anomeric configuration. To date, the catalytic mechanism of retaining GTs is a topic of great controversy, particularly for those enzymes containing a putative nucleophilic residue in the active site, for which the occurrence of a double‐displacement mechanism has been suggested. We report native ternary complexes of the retaining glycosyltransferase α‐1,3‐galactosyltransferase (α3GalT) from Bos taurus , which contains such a nucleophile in the active site, in a productive mode for catalysis in the presence of its sugar donor UDP‐Gal, the acceptor substrate lactose, and the divalent cation cofactor. This new experimental evidence supports the occurrence of a front‐side substrate‐assisted S_Ni‐type reaction for α3GalT, and suggests a conserved common catalytic mechanism among retaining GTs.     

Formation of Orthoesters of Oleanolic Acid During Königs-Knorr Glycosidations

Summary.  The formation of orthoesters during K?nigs-Knorr reactions is described. Diphenylmethyl oleanolate reacts with 1 → 4 linked disaccharide donors to orthoesters instead of the expected glycosides. The reaction with acetobromoglucose gave a mixture of orthoester and glycoside. The influence of the structure of the glycosyl donors and of the reaction conditions on the formation of orthoesters is discussed. Received February 12, 2001. Accepted February 22, 2001     

Reconstitution and characterization of a new desosaminyl transferase, EryCIII, from the erythromycin biosynthetic pathway

EryCIII converts alpha-mycarosyl erythronolide B into erythromycin D using TDP-d-desosamine as the glycosyl donor. We report the heterologous expression, purification, in vitro reconstitution, and preliminary characterization of EryCIII. Coexpression of EryCIII with the GroEL/ES chaperone complex was found to enhance greatly the expression of soluble EryCIII protein. The enzyme was found to be highly active with a kcat greater than 100 min-1. EryCIII was quite selective for the natural nucleotide sugar donor and macrolide acceptor substrates, unlike several other antibiotic glycosyl transferases with broad specificity such as desVII, oleG2, and UrdGT2. Within detectable limits, neither 6-deoxyerythronolide B nor 10-deoxymethynolide were found to be glycosylated by EryCIII. Furthermore, TDP-d-mycaminose, which only differs from TDP-d-desosamine at the C4 position, could not be transferred to alphaMEB. These studies lay the groundwork for detailed structural and mechanistic analysis of an important member of the desosaminyl transferase family of enzymes.     

Thioglycosynthases: double mutant glycosidases that serve as scaffolds for thioglycoside synthesis

A double mutant, retaining glycosidase that lacks both the catalytic nucleophile and the catalytic acid/base residues efficiently catalyzes thioglycoside formation from a glycosyl fluoride donor and thiosugar acceptors.     

保留型与反转型β-木糖苷酶活性位点的分子动力学模拟

Xylans are important as potential renewable energy sources. In recent years, there has therefore been interest in improving their degradation efficiencies. β-Xylosidases are key enzymes for xylan degradation; these enzymes are classified, based on their hydrolysis mechanisms, as retaining or inverting enzymes. Although much research has been devoted to understanding retaining and inverting mechanisms, little is known about their differences in solution. We used molecular dynamics (MD) simulations with explicit solvent representation to study the dynamic behaviors of the active-sites of four typical β-xylosidases by analyzing the distances between two catalytic amino acids and the pK_a values of proton-donor amino acids. The results show that the distance between the catalytic amino acids with inverting enzymes is about 0.8-1.0 nm, which is greater than that for retaining enzymes, i.e., 0.5-0.6 nm. This is consistent with previous results based on the crystal structures of glycosidases. We found that the pK_a of the retaining proton donors are modulated by interactions with neighboring amino acids, enabling switching between low and high values. Such a pK_a switch is needed for the double-displacement mechanism of retaining enzymes. In contrast, inverting proton donors, modulated by interactions with neighboring glutamic acids, have only high pK_a values. This may be important in proton capture from the solvent by donors, and may facilitate the single-displacement mechanism of inverting enzymes. This study provides new insights into the hydrolysis mechanisms of β-xylosidases, and will therefore be useful in improving the efficiency and applications of β-xylosidases.     

Retaining60Co2+ ions from residual water on zeolites

The ion exchange between⁶⁰Co²⁺ ions contained in residual radioactive water and zeolites of the NaA, NaX and CaA types was studied. The more advanced retaining of⁶⁰Co²⁺ ions occurs for the NaA zeolite with the higher exchange capacity, as compared to NaX. With the CaA zeolite, a very weak ion exchange with⁶⁰Co²⁺ ions was observed.