Suchergebnisse

In the context of bioeconomy, the discovery and study of plant-cell wall degrading enzymes is particularly relevant for the use of lignocellulosic biomass for industrial purposes. In this respect, functional metagenomics has proven to be a powerful tool to discover new enzymes from a variety of microbial ecosystems, as exemplified by work performed on the gut of the termite Pseudacanthotermes militaris. This study provided a wealth of information and identified an interesting hypothetical xylan utilization system, encoding five glycoside hydrolases (GH) and one carbohydrate esterase (CE) annotated from bacteroidales. The Pseudacanthotermes militaris-derived putative XUS cluster contains a GH10 xylanase that displays a quite complex modular arrangement wherein the GH10 catalytic module contains two insertional carbohydrate binding modules (CBM). During the preliminary work, this modular enzyme, designated Pm25, was shown to be active on xylan, thus in the present research we set out to more thoroughly characterize its biochemical and catalytic properties.The role of the CBM was also investigated, quantifying protein-carbohydrate interactions and thus providing better insight into the specific role of the modules. Taken together, the results obtained provide insight into how Pm25 modularity translates into functional properties. In second part of our study, we set out investigate the function of Pm25 in the context of the XUS cluster. To achieve this we studied a xylan utilization system, which is constituted by another GH10, GH11, GH115 and GH43. The comparison of kinetic parameters and a detailed end product analysis by mass spectrometry showed that GH10 and GH11 outweigh over 20 fold Pm25 catalytic efficiency. In parallel, we developed the use of MicroScale Thermophoresis (MST) to quantify CBM-carbohydrates interactions, an interesting approach requiring smaller concentration of proteinsand ligands compared to other biophysical methods. Overall this study highlighted the important role of Pm25 homologs in the ...

The functional screening of a Pseudacanthotermes militaris termite gut metagenomic library revealed an array of xylan-degrading enzymes, including P. militaris 25 (Pm25), a multimodular glycoside hydrolase family 10 (GH10). Sequence analysis showed details of the unusual domain organization of this enzyme. It consists of one catalytic domain, which is intercalated by two carbohydrate binding modules (CBMs) from family 4. The genes upstream of the genes encoding Pm25 are susC-susD-unk, suggesting Pm25 is a Xyn10C-like enzyme belonging to a polysaccharide utilization locus. The majority of Xyn10C-like enzymes shared the same interrupted domain architecture and were vastly distributed in different xylan utilization loci found in gut Bacteroidetes, indicating the importance of this enzyme in glycan acquisition for gut microbiota. To understand its unusual multimodularity and the possible role of the CBMs, a detailed characterization of the full-length Pm25 and truncated variants was performed. Results revealed that the GH10 catalytic module is specific toward the hydrolysis of xylan. Ligand binding results indicate that the GH10 module and the CBMs act independently, whereas the tandem CBM4s act synergistically with each other and improve enzymatic activity when assayed on insoluble polysaccharides. In addition, we show that the UNK protein upstream of Pm25 is able to bind arabinoxylan. Altogether, these findings contribute to a better understanding of the potential role of Xyn10C-like proteins in xylan utilization systems of gut bacteria. IMPORTANCE Xylan is the major hemicellulosic polysaccharide in cereals and contributes to the recalcitrance of the plant cell wall toward degradation. Members of the Bacteroidetes, one of the main phyla in rumen and human gut microbiota, have been shown to encode polysaccharide utilization loci dedicated to the degradation of xylan. Here, we present the biochemical characterization of a xylanase encoded by a Bacteroidetes strain isolated from the termite gut metagenome. This ...