Ingénierie des glucane-saccharases de la famille 70 des glycoside-hydrolases pour la synthèse de nouveaux biopolymères

Les glucane-saccharases sont des transglucosidases de la famille 70 des glycoside-hydrolases. A partir de saccharose, ces enzymes catalysent la synthèse d alpha -glucanes, polymères de haute masse molaire formés d unités glucosyle. Elles sont aussi capables de synthétiser des oligosaccharides ou glucoconjugués par réaction de transglucosylation sur des accepteurs exogènes de natures variées. De par la diversité de leurs spécificités, tant au niveau des liaisons osidiques synthétisées [alpha (1->2) ; alpha (1->3) ; alpha (1->4) ou alpha (1->6)] que de l organisation de ces liaisons au sein des produits formés, ces biocatalyseurs peuvent être mis à profit pour produire des hydrates de carbones d'intérêt pour les secteurs de l'alimentation, de la santé et de l'environnement. L'objectif de ces travaux de thèse était de générer par ingénierie enzymatique de nouvelles glucane-saccharases capables de synthétiser des alpha -glucanes et des gluco-oligosaccharides de structures et propriétés innovantes, afin d élargir le panel d'applications de ces molécules. Sur le plan fondamental, l'enjeu était aussi d'améliorer la compréhension des relations entre structure et spécificité des glucane-saccharases. Pour atteindre nos objectifs, nous avons utilisé une stratégie d'ingénierie combinatoire de la dextrane-saccharase DSR-S de Leuconostoc mesenteroides NRRL B-512F, qui catalyse la synthèse d un dextrane formé à 95 % de liaisons alpha (1->6) et 5 % alpha (1->3). Le travail a tout d'abord consisté à développer une méthode de criblage multi-étapes et à haut-débit, pour isoler et trier les variants de spécificités de liaisons variées. La stratégie comprend une première étape de sélection in vivo sur milieu solide suivie d un criblage par RMN 1D 1H automatisé au format microplaque. Il s'agit de la première méthode de criblage à haut-débit de la spécificité de liaison des transglucosidases et glycosyltransferases. Cette stratégie a ensuite été appliquée au criblage de deux banques de variants de la DSR-S, totalisant plus de 36 000 clones obtenus par mutagénèse de saturation et recombinaison simultanée de 8 résidus du domaine catalytique. Au total, 82 mutants capables de synthétiser entre 2 et 8 fois plus de liaisons alpha (1->3) par rapport à l enzyme parentale ont été isolés. La caractérisation des propriétés catalytiques de sept mutants représentatifs de la diversité de spécificité générée a permis d identifier un nouveau motif peptidique 460DYVHT464 impliqué dans la spécificité de DSR-S. Enfin, la caractérisation de la structure et des propriétés rhéologiques et mécaniques des dextranes synthétisés par ces 7 mutants a mis en évidence les différences de taille et de conformation de ces macromolécules en solution et révélé l aptitude du polymère synthétisé par le variant H463R/T464V/S512T à former des films bio-sourcés innovants, dont les propriétés mécaniques sont remarquables en comparaison de celles d'autres biopolymères extraits de plantes ou produits par fermentationGlucansucrases are transglucosidases from glycoside hydrolase family 70. From sucrose, these enzymes catalyse the synthesis of alpha -glucans, high molecular weight polymers formed of glucosyl units. Glucansucrases are also able to synthesize oligosaccharides or glucoconjugates by transglucosylation reaction onto various exogenous acceptors. Due to the large specificity, in terms of osidic linkages synthesized [alpha (1->2); alpha (1->3); alpha (1->4) or alpha (1->6)] and their organization within the formed products, these biocatalysts can be used to produce carbohydrates of interest in food, health and environment fields. The aim of this research work was to generate, by enzyme engineering, new glucansucrases able to synthesize alpha -glucans and gluco-oligosaccharides with novel structures and properties, to enlarge applications of these molecules. At fundamental level, the work was to improve the understanding of the relationships between structure and specificity of glucansucrases. To reach our objectives, we used a combinatorial engineering strategy on the dextransucrase DSR-S of Leuconostoc mesenteroides NRRL B-512F, which catalyses the synthesis of a dextran formed by 95 % of alpha (1->6) and 5 % alpha (1->3) linkages. The work consisted first in the development of a multi-step high throughput screening methodology to sort out and isolate variants with altered linkage specificities. The strategy includes a first stage of in vivo selection on solid medium followed by an automated 1D 1H NMR-based screening using microplates. To date, this is the first high-throughput screening method for linkage specificity determination of transglucosidases and glycosyltransferases. This strategy was applied to the screening of two DSR-S variants libraries, totalizing more than 36,000 clones obtained by saturation mutagenesis and simultaneous recombination of 8 residues from the catalytic domain. Eighty two mutants able of synthesize 2 to 8 times more alpha (1->3) linkages compared to the parental enzyme were isolated. The characterization of the catalytic properties of 7 representative mutants enabled the identification of a new peptide motif 460DYVHT464, involved in DSR-S specificity. Finally, the characterization of structural, rheological and mechanical properties of dextrans synthetized by these 7 mutants highlighted the differences in size and conformation of these macromolecules in solution and revealed the capacity of the polymer synthesized by H463R/T464V/S512T variant to form biofilms, whose mechanical properties are remarkable in comparison to those of other biopolymers extracted from plants or produced by fermentation.TOULOUSE-INSA-Bib. electronique (315559905) / SudocSudocFranceF

Biochemical characterization of a SusD-like protein involved in glucooligosaccharide utilization by a cow rumen uncultured Bacteroidales

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High-throughput functional metagenomics for the discovery of glycan metabolizing pathways

Glycans are widely distributed in nature. Produced by almost all organisms, they are involved in numerous cellular processes, such as energy supply and storage, cell structuration, protein maturation and signalling, and cell recognition. Glycans are thus key elements mediating the interactions between mammals, plants, bacteria, fungi and even viruses. They also represent a reliable source of carbon for microbes, which have developed complex strategies to face their structural diversity and to harvest them. However between 70 and 99% of these microorganisms are still uncultured, while they represent a goldmine for the discovery of new enzymes. In order to boost their identification and characterization, a functional metagenomic approach was developed, based on the design of various high-throughput, robust and sensitive screening strategies. The functional potential of Gbp of metagenomic DNA from various origins was explored, revealing dozens of novel enzyme families and functions. Integration of biochemical, structural, meta-omic and omic data allowed us to decipher, from the molecular to the ecosystemic scale, novel mechanisms of plant, microbial and mammal glycan metabolization. These new metabolic pathways involve batteries of glycoside-hydrolases, glycoside-phosphorylases and sugar transporters. These fascinating proteins appear as new targets to control host-microbe interactions. They also constitute very efficient biotechnological tools for biorefineries and synthetic biology

Investigating Host Microbiota Relationships Through Functional Metagenomics

The human Intestinal mucus is formed by glycoproteins, the O- and N-linked glycans which constitute a crucial source of carbon for commensal gut bacteria, especially when deprived of dietary glycans of plant origin. In recent years, a dozen carbohydrate-active enzymes from cultivated mucin degraders have been characterized. But yet, considering the fact that uncultured species predominate in the human gut microbiota, these biochemical data are far from exhaustive. In this study, we used functional metagenomics to identify new metabolic pathways in uncultured bacteria involved in harvesting mucin glycans. First, we performed a high-throughput screening of a fosmid metagenomic library constructed from the ileum mucosa microbiota using chromogenic substrates. The screening resulted in the isolation of 124 clones producing activities crucial in the degradation of human O- and N-glycans, namely sialidases, beta-D-N-acetyl-glucosaminidase, beta-D-N-acetyl-galactosaminidase, and/or beta-D-mannosidase. Thirteen of these clones were selected based on their diversified functional profiles and were further analyzed on a secondary screening. This step consisted of lectin binding assays to demonstrate the ability of the clones to degrade human intestinal mucus. In total, the structural modification of several mucin motifs, sialylated mucin ones in particular, was evidenced for nine clones. Sequencing their metagenomic loci highlighted complex catabolic pathways involving the complementary functions of glycan sensing, transport, hydrolysis, deacetylation, and deamination, which were sometimes associated with amino acid metabolism machinery. These loci are assigned to several Bacteroides and Feacalibacterium species highly prevalent and abundant in the gut microbiome and explain the metabolic flexibility of gut bacteria feeding both on dietary and human glycans

Investigating host-microbiome interactions by droplet based microfluidics

Funder: Royal Society Newton fellowshipFunder: CAPES Scholarship - BrazilAbstract: Background: Despite the importance of the mucosal interface between microbiota and the host in gut homeostasis, little is known about the mechanisms of bacterial gut colonization, involving foraging for glycans produced by epithelial cells. The slow pace of progress toward understanding the underlying molecular mechanisms is largely due to the lack of efficient discovery tools, especially those targeting the uncultured fraction of the microbiota. Results: Here, we introduce an ultra-high-throughput metagenomic approach based on droplet microfluidics, to screen fosmid libraries. Thousands of bacterial genomes can be covered in 1 h of work, with less than ten micrograms of substrate. Applied to the screening of the mucosal microbiota for β-N-acetylgalactosaminidase activity, this approach allowed the identification of pathways involved in the degradation of human gangliosides and milk oligosaccharides, the structural homologs of intestinal mucin glycans. These pathways, whose prevalence is associated with inflammatory bowel diseases, could be the result of horizontal gene transfers with Bacteroides species. Such pathways represent novel targets to study the microbiota-host interactions in the context of inflammatory bowel diseases, in which the integrity of the mucosal barrier is impaired. Conclusion: By compartmentalizing experiments inside microfluidic droplets, this method speeds up and miniaturizes by several orders of magnitude the screening process compared to conventional approaches, to capture entire metabolic pathways from metagenomic libraries. The method is compatible with all types of (meta)genomic libraries, and employs a commercially available flow cytometer instead of a custom-made sorting system to detect intracellular or extracellular enzyme activities. This versatile and generic workflow will accelerate experimental exploration campaigns in functional metagenomics and holobiomics studies, to further decipher host-microbiota relationships. BEyZgKg3YsWtKJ_ei8gXkiVideo Abstrac

A catalog of microbial genes from the bovine rumen unveils a specialized and diverse biomass-degrading environment

Background The rumen microbiota provides essential services to its host and, through its role in ruminant production, contributes to human nutrition and food security. A thorough knowledge of the genetic potential of rumen microbes will provide opportunities for improving the sustainability of ruminant production systems. The availability of gene reference catalogs from gut microbiomes has advanced the understanding of the role of the microbiota in health and disease in humans and other mammals. In this work, we established a catalog of reference prokaryote genes from the bovine rumen. Results Using deep metagenome sequencing we identified 13,825,880 non-redundant prokaryote genes from the bovine rumen. Compared to human, pig, and mouse gut metagenome catalogs, the rumen is larger and richer in functions and microbial species associated with the degradation of plant cell wall material and production of methane. Genes encoding enzymes catalyzing the breakdown of plant polysaccharides showed a particularly high richness that is otherwise impossible to infer from available genomes or shallow metagenomics sequencing. The catalog expands the dataset of carbohydrate-degrading enzymes described in the rumen. Using an independent dataset from a group of 77 cattle fed 4 common dietary regimes, we found that only <0.1% of genes were shared by all animals, which contrast with a large overlap for functions, i.e., 63% for KEGG functions. Different diets induced differences in the relative abundance rather than the presence or absence of genes, which explains the great adaptability of cattle to rapidly adjust to dietary changes. Conclusions These data bring new insights into functions, carbohydrate-degrading enzymes, and microbes of the rumen to complement the available information on microbial genomes. The catalog is a significant biological resource enabling deeper understanding of phenotypes and biological processes and will be expanded as new data are made available.info:eu-repo/semantics/publishedVersio

Discovery of new protein families and functions: new challenges in functional metagenomics for biotechnologies and microbial ecology

The rapid expansion of new sequencing technologies has enabled large-scale functional exploration of numerous microbial ecosystems, by establishing catalogs of functional genes and by comparing their prevalence in various microbiota. However, sequence similarity does not necessarily reflect functional conservation, since just a few modifications in a gene sequence can have a strong impact on the activity and the specificity of the corresponding enzyme or the recognition for a sensor. Similarly, some microorganisms harbor certain identified functions yet do not have the expected related genes in their genome. Finally, there are simply too many protein families whose function is not yet known, even though they are highly abundant in certain ecosystems. In this context, the discovery of new protein functions, using either sequence-based or activity-based approaches, is of crucial importance for the discovery of new enzymes and for improving the quality of annotation in public databases. This paper lists and explores the latest advances in this field, along with the challenges to be addressed, particularly where microfluidic technologies are concerned

Self-association and crystallization of amylose

International audienceAmylose, the linear constituent of starch, consists of a(1,4)-linked glucose monomers. Although weakly involved in the crystalline structure of starch, it can be recrystallized in a variety of allomorphic types, including those encountered in native starch (A- and B-types). Amylose can either be extracted from starch or produced in vitro by enzymatic synthesis using amylosucrase or phosphorylase. Recrystallization and self-association of amylose in aqueous solutions have been widely studied to understand both the crystallization of starch during biosynthesis and the structural changes that occur during starch processing. Depending on the chain length, concentration, and temperature, gels, spherulites, or lamellar crystals can be formed withA or B allomorphic type. Other ligand-dependent allomorphs (the various V-types) are obtained when amylose is complexed with molecules such as alcohols, lipids, or flavours. Amylose also self-associates into networks, spherulites, or axialites during in-vitro enzymatic synthesis by amylosucrase. When a highly branched acceptor like glycogen is used, dendritic nanoparticles are formed by elongation of the external chains. The recrystallization of amylose extracted from starch and the self-association of amylose during its in-vitro synthesis are described. The amylose properties are discussed in terms of polymer behaviour and model systems to investigate the structure and formation of starch granules

Metagenomics for the discovery of pollutant degrading enzymes

Organic pollutants, including xenobiotics, are often persistent and toxic organic compounds resulting from human activities and released in large amounts into terrestrial, fluvial and marine environments. However, some microbial species which are naturally exposed to these compounds in their own habitat are capable of degrading a large range of pollutants, especially poly-aromatic, halogenated and polyester molecules. These microbes constitute a huge reservoir of enzymes for the diagnosis of pollution and for bioremediation. Most are found in highly complex ecosystems like soils, activated sludge, compost or polluted water, and more than 99% have never been cultured. Meta-omic approaches are thus well suited to retrieve biocatalysts from these environmental samples. In this review, we report the latest advances in functional metagenomics aimed at the discovery of enzymes capable of acting on different kinds of polluting molecules. (C) 2015 Published by Elsevier Inc

Identification of Glycoside Transporters From the Human Gut Microbiome

International audienceTransport is a crucial step in the metabolism of glycosides by bacteria, which is itself key for microbiota function and equilibrium. However, most transport proteins are function-unknown or only predicted, limiting our understanding of how bacteria utilize glycosides. Here, we present an activity-based screening method to identify functional glycoside transporters from microbiomes. The method is based on the co-expression in Escherichia coli of genes encoding transporters and carbohydrate-active enzymes (CAZymes) from metagenomic polysaccharide utilization loci (PULs) cloned in fosmids. To establish the proof of concept of the methodology, we used two different metagenomic libraries derived from human gut microbiota to select 18 E. coli clones whose metagenomic sequence contained at least one putative glycoside transporter and one functional CAZyme, identified by screening for various glycoside-hydrolase activities. Growth tests were performed on plant-derived glycosides, which are the target substrates of the CAZymes identified in each PUL. This led to the identification of 10 clones that are able to utilize oligosaccharides as sole carbon sources, thanks to the production of transporters from the PTS, ABC, MFS, and SusCD families. Six of the 10 hit clones contain only one transporter, providing direct experimental evidence that these transporters are functional. In the six cases where two transporters are present in the sequence of a clone, the transporters' function can be predicted from the flanking CAZymes or from similarity with transporters characterized previously, which facilitates further functional characterization. The results expand the understanding of how glycosides are selectively metabolized by bacteria and offers a new approach to screening for glycoside-transporter specificity toward oligosaccharides with defined structures