Sylvie Armand

The Active Site Topology of Aspergillus niger Endopolygalacturonase II as Studied by Site-directed Mutagenesis*

Strictly conserved charged residues among polygalacturonases (Asp-180, Asp-201, Asp-202, His-223, Arg-256, and Lys-258) were subjected to site-directed mutagenesis inAspergillus niger endopolygalacturonase II. Specific activity, product progression, and kinetic parameters (K m and V max) were determined on polygalacturonic acid for the purified mutated enzymes, and bond cleavage frequencies on oligogalacturonates were calculated. Depending on their specific activity, the mutated endopolygalacturonases II were grouped into three classes. The mutant enzymes displayed bond cleavage frequencies on penta- and/or hexagalacturonate different from the wild type endopolygalacturonase II. Based on the biochemical characterization of endopolygalacturonase II mutants together with the three-dimensional structure of the wild type enzyme, we suggest that the mutated residues are involved in either primarily substrate binding (Arg-256 and Lys-258) or maintaining the proper ionization state of a catalytic residue (His-223). The individual roles of Asp-180, Asp-201, and Asp-202 in catalysis are discussed. The active site topology is different from the one commonly found in inverting glycosyl hydrolases.

Plant chitinases use two different hydrolytic mechanisms

Bacterial, fungal, animal, and some plant chitinases form family 18 of glycosyl hydrolases. Most plant chitinases form the family 19. While some chitinases also have lysozyme activity, animal lysozymes belong to different families. For glycosyl hydrolases, two reaction mechanisms are possible, leading to either retention or inversion of the anomeric configuration. We analyzed by HPLC the stereochemical outcome of the hydrolysis catalyzed by cucumber and bean chitinases, belonging to families 18 and 19, respectively. Cucumber chitinase used the retaining mechanism as known for bacterial chitinases and hen egg white lysozyme for which the mechanism has been determined. In contrast, bean chitinase catalyzed the hydrolysis of chitooligosaccharides with overall inversion of anomeric configuration.

A Bifunctionalized Fluorogenic Tetrasaccharide as a Substrate to Study Cellulases

Cellulases are usually classified as endoglucanases and cellobiohydrolases, but the heterogeneity of cellulose, in terms of particle size and crystallinity, has always represented a problem for the biochemical characterization of the enzymes. The synthesis of a bifunctionalized tetrasaccharide substrate suitable for measuring cellulase activity by resonance energy transfer is described. The substrate, which carries a 5-(2-aminoethylamino)-1-naphthalenesulfonate group on the non-reducing end and an indolethyl group on the reducing end, was prepared from β-lactosyl fluoride and indolethyl β-cellobioside by a chemoenzymatic approach using the transglycosylating activity of endoglucanase I of Humicola insolens as the key step. The bifunctionalized substrate has been used for the determination of the catalytic constants of H. insolens endoglucanase I and cellobiohydrolases I and II; this substrate could be of general use to measure the kinetic constants of cellulases able to act on oligomers of degree of polymerization <5. The data also provide evidence that cellobiohydrolases I and II are able to degrade an oligosaccharide substrate carrying non-carbohydrate substituents at both ends.

Stereochemical course of the hydrolysis reaction catalyzed by chitinases Al and D from Bacillus circulans WL‐12

Chitinases A1 and D were purified from the periplasmic proteins produced by Escherichia coli HB101 harbouring recombinant plasmids carrying respectively the chiA and chiD genes of Bacillus circulans WL‐12. HPLC analysis indicated that during the hydrolysis of chitotriose, both chitinases initially produce N‐acetylglucosamine and only one anomer of chitobiose. 1H NMR spectroscopy of the hydrolysis of chitotetraitol showed that this anomer corresponds to β‐chitobiose, demonstrating that chitinases Al and D act by a molecular mechanism that retains the anomeric configuration. This mechanism is similar to that of lysozymes although both chitinases belong to a family of proteins sharing no demonstrable amino acid sequence similarity with lysozymes.

Efficient chemoenzymatic synthesis of lipo-chitin oligosaccharides as plant growth promoters

Lipo-chitin oligosaccharides (Nod and Myc LCOs) are molecules involved in symbiotic phenomena in the plant kingdom. They play a major role in the process of atmospheric nitrogen fixation and mineral soil nutrients uptake both in legumes and in non-legumes, and are active at extremely low concentrations down to the nano- and even picomolar range. These compounds contain various substitutions along the oligosaccharide backbone of the molecule including an essential fatty acid on the non-reducing unit and are considered as environmentally-friendly fertilizers. Currently, chemical synthesis cannot produce precursors of Nod and Myc LCOs at a large scale and an in vitro chemoenzymatic pathway is presented here as a new and efficient method for preparing quantities of these high-value oligosaccharides. VC1280 (Vibrio cholerae) is a chitin deacetylase (CD) capable of regioselectively cleaving an acetate from the non-reducing penultimate N-acetyl-D-glucosaminyl (GlcNAc) unit of chitin oligosaccharides (COs). This provides a free amino group which can be further N-acylated with a fatty-acid chain to give analogues of LCOs. Alternatively, the non-reducing GlcNAc unit can be removed by β-N-acetylglucosaminidase treatment, followed by N-acylation to give natural LCOs. VC1280 CD was produced in the periplasm of E. coli. Under the conditions used, 120 mg of the pure enzyme was recovered from 1 L of culture medium. For the first time, in vitro production of a library of natural LCOs as well as their analogues has been carried out at a preparative scale from biosourced chitin oligosaccharides constituting an approach of major interest for sustainable agriculture.

A straightforward access to TMG-chitooligomycins and their evaluation as β-N-acetylhexosaminidase inhibitors

A chemo-biotechnological approach is reported for the synthesis of TMG-chitooligomycins, CO-n (NMe(3)). Their abilities to inhibit β-N-acetylhexosaminidases (HexNAcases), from Aspergillus oryzae (AoHex, fungi), Canavalia ensiformis (CeHex, plant) HexNAcases and a chitobiase from Serratia marcescens (SmCHB, bacteria) were studied and compared with their precursors CO-n (N). CO-n (NMe(3)) were revealed as potent inhibitors for AoHex and SmCHB with a proved chain length effect while CO-n (N) was a highly selective inhibitor of SmCHB. This route can be considered as the privileged way to produce easily and in large scale a wide range of size-defined chitooligosaccharide-based inhibitors to fine-tune the structure-activity relationships for inhibition of HexNAcases from various origins.

Oligosaccharide biosensor for direct monitoring of enzymatic activities using QCM-D

Enzymatic modification of saccharidic biomass is a subject of intensive research with potential applications in plant or human health, design of biomaterials and biofuel production. Bioengineering and metagenomics provide access to libraries of glycoside hydrolases but the biochemical characterization of these enzymes remains challenging, requiring fastidious colorimetric tests in discontinuous assays. Here, we describe a highly sensitive carbohydrate biosensor for the detection and characterization of glycoside hydrolases. Immobilization of oligosaccharides was achieved using copper-catalyzed azide-alkyne cycloaddition of maltoheptaose-modified probes onto self-assembled monolayers bearing azide reactive groups. This biosensor allowed detection of glycoside hydrolase activities at the picomolar level using quartz-crystal microbalance with dissipation monitoring (QCM-D). To our knowledge, this protocol provides the best performance to date for the detection of glycoside hydrolase activities. For each enzyme tested, we could determine the kinetic constant from the QCM-D data, and derive conclusions that correlated well with those of standard colorimetric tests. This opens the way to a new generation of rapid and direct tests characterizing functionally carbohydrate-active enzymes.

CGTase‐Catalysed cis‐Glucosylation of L‐Rhamnosides for the Preparation of Shigella flexneri 2a and 3a Haptens

We report the enzymatic synthesis of α‐D‐glucopyranosyl‐(1→4)‐α‐L‐rhamnopyranoside and α‐D‐glucopyranosyl‐(1→3)‐α‐L‐rhamnopyranoside by using a wild‐type transglucosidase in combination with glucoamylase and glucose oxidase. It was shown that Bacillus circulans 251 cyclodextrin glucanotransferase (CGTase, EC 2.1.4.19) can efficiently couple an α‐L‐rhamnosyl acceptor to a maltodextrin molecule with an α‐(1→4) linkage, albeit in mixture with the α‐(1→3) regioisomer, thus giving two glucosylated acceptors in a single reaction. Optimisation of the CGTase coupling reaction with β‐cyclodextrin as the donor substrate and methyl or allyl α‐L‐rhamnopyranoside as acceptors resulted in good conversion yields (42–70 %) with adjustable glycosylation regioselectivity. Moreover, the efficient chemical conversion of the products of CGTase‐mediated cis‐glucosylation into protected building blocks (previously used in the synthesis of O‐antigen fragments of several Shigella flexneri serotypes) was substantiated. These novel chemoenzymatic strategies towards useful, convenient intermediates in the synthesis of S. flexneri serotypes 2a and 3a oligosaccharides might find applications in developments towards synthetic carbohydrate‐based vaccine candidates against bacillary dysentery.

High yield production of Rhizobium NodB chitin deacetylase and its use for in vitro synthesis of lipo-chitinoligosaccharide precursors

Lipo-chitinoligosaccharides (LCOs) are key molecules for the establishment of plant-microorganisms symbiosis. Interactions of leguminous crops with nitrogen-fixing rhizobial bacteria involve Nod factors, while Myc-LCOs improve the association of most plants with arbuscular mycorrhizal fungi. Both Nod factors and Myc-LCOs are composed of a chitinoligosaccharide fatty acylated at the non-reducing end accompanied with various substituting groups. One straightforward way to access LCOs is starting from chitin hydrolysate, an abundant polysaccharide found in crustacean shells, followed by regioselective enzymatic cleavage of an acetyl group from the non-reducing end of chitin tetra- or pentaose, and subsequent chemical introduction of N-acyl group. In the present work, we describe the in vitro synthesis of LCO precursors on preparative scale. To this end, Sinorhizobium meliloti chitin deacetylase NodB was produced in high yield in E. coli as a thioredoxin fusion protein. The recombinant enzyme was expressed in soluble and catalytically active form and used as an efficient biocatalyst for N-deacetylation of chitin tetra- and pentaose.

Chemoenzymatic Syntheses of Sialylated Oligosaccharides Containing C5-Modified Neuraminic Acids for Dual Inhibition of Hemagglutinins and Neuraminidases.

A fast chemoenzymatic synthesis of sialylated oligosaccharides containing C5-modified neuraminic acids is reported. Analogues of GM3 and GM2 ganglioside saccharidic portions where the acetyl group of NeuNAc has been replaced by a phenylacetyl (PhAc) or a propanoyl (Prop) moiety have been efficiently prepared with metabolically engineered E. coli bacteria. GM3 analogues were either obtained by chemoselective modification of biosynthetic N-acetyl-sialyllactoside (GM3 NAc) or by direct bacterial synthesis using C5-modified neuraminic acid precursors. The latter strategy proved to be very versatile as it led to an efficient synthesis of GM2 analogues. These glycomimetics were assessed against hemagglutinins and sialidases. In particular, the GM3 NPhAc displayed a binding affinity for Maackia amurensis agglutinin (MAA) similar to that of GM3 NAc, while being resistant to hydrolysis by Vibrio cholerae (VC) neuraminidase. A preliminary study with influenza viruses also confirmed a selective inhibition of N1 neuraminidase by GM3 NPhAc, suggesting potential developments for the detection of flu viruses and for fighting them.