Production of a halotolerant endo-1,4-ß-glucanase by a newly isolated Bacillus velezensis H1 on olive mill wastes without pretreatment: purification and characterization of the enzyme.

Facing the critical issue of high production costs for cellulase, numerous studies have focused on improving the efficiency of cellulase production by potential cellulolytic microorganisms using agricultural wastes as substrates, extremophilic cellulases, in particular, are crucial in the biorefinery process because they can maintain activity under harsh environmental conditions. This study aims to investigate the ability of a potential carboxymethylcellulose-hydrolyzing bacterial strain H1, isolated from an Algerian saline soil and identified as Bacillus velezensis, to use untreated olive mill wastes as a substrate for the production of an endo-1,4-ß-glucanase. The enzyme was purified 44.9 fold using only two steps: ultrafiltration concentration and ion exchange chromatography, with final recovery of 80%. Its molecular mass was estimated to be 26 kDa by SDS-PAGE. Enzyme identification by LC-MS analysis showed 40% identity with an endo-1,3-1,4-ß-glucanase of GH-16 family. The highest enzymatic activity was significantly measured on barley ß-glucan (604.5 U/mL) followed by lichenan and carboxymethylcellulose as substrates, confirming that the studied enzyme is an endo-1,4-ß-glucanase. Optimal enzymatic activity was at pH 6.0-6.5 and at 60-65 °C. It was fairly thermotolerant, retaining 76.9% of the activity at 70 °C, and halotolerant, retaining 70% of its activity in the presence of 4 M NaCl. The enzyme had a Vmax of 625 U/min/mL and a high affinity with barley ß-glucan resulting a Km of 0.69 mg/mL. It also showed a significant ability to release cello-oligosaccharides. Based on such data, the H1 endo-1,4-ß-glucanase may have significant commercial values for industry, argo-waste treatment, and other biotechnological applications.

Highlighting the factors governing transglycosylation in the GH5_5 endo-1,4-ß-glucanase RBcel1.

Transglycosylating glycoside hydrolases (GHs) offer great potential for the enzymatic synthesis of oligosaccharides. Although knowledge is progressing, there is no unique strategy to improve the transglycosylation yield. Obtaining efficient enzymatic tools for glycan synthesis with GHs remains dependent on an improved understanding of the molecular factors governing the balance between hydrolysis and transglycosylation. This enzymatic and structural study of RBcel1, a transglycosylase from the GH5_5 subfamily isolated from an uncultured bacterium, aims to unravel such factors. The size of the acceptor and donor sugars was found to be critical since transglycosylation is efficient with oligosaccharides at least the size of cellotetraose as the donor and cellotriose as the acceptor. The reaction pH is important in driving the balance between hydrolysis and transglycosylation: hydrolysis is favored at pH values below 8, while transglycosylation becomes the major reaction at basic pH. Solving the structures of two RBcel1 variants, RBcel1_E135Q and RBcel1_Y201F, in complex with ligands has brought to light some of the molecular factors behind transglycosylation. The structure of RBcel1_E135Q in complex with cellotriose allowed a +3 subsite to be defined, in accordance with the requirement for cellotriose as a transglycosylation acceptor. The structure of RBcel1_Y201F has been obtained with several transglycosylation intermediates, providing crystallographic evidence of transglycosylation. The catalytic cleft is filled with (i) donors ranging from cellotriose to cellohexaose in the negative subsites and (ii) cellobiose and cellotriose in the positive subsites. Such a structure is particularly relevant since it is the first structure of a GH5 enzyme in complex with transglycosylation products that has been obtained with neither of the catalytic glutamate residues modified.

Glycoside hydrolase family 5: structural snapshots highlighting the involvement of two conserved residues in catalysis.

The ability of retaining glycoside hydrolases (GHs) to transglycosylate is inherent to the double-displacement mechanism. Studying reaction intermediates, such as the glycosyl-enzyme intermediate (GEI) and the Michaelis complex, could provide valuable information to better understand the molecular factors governing the catalytic mechanism. Here, the GEI structure of RBcel1, an endo-1,4-ß-glucanase of the GH5 family endowed with transglycosylase activity, is reported. It is the first structure of a GH5 enzyme covalently bound to a natural oligosaccharide with the two catalytic glutamate residues present. The structure of the variant RBcel1_E135A in complex with cellotriose is also reported, allowing a description of the entire binding cleft of RBcel1. Taken together, the structures deliver different snapshots of the double-displacement mechanism. The structural analysis revealed a significant movement of the nucleophilic glutamate residue during the reaction. Enzymatic assays indicated that, as expected, the acid/base glutamate residue is crucial for the glycosylation step and partly contributes to deglycosylation. Moreover, a conserved tyrosine residue in the -1 subsite, Tyr201, plays a determinant role in both the glycosylation and deglycosylation steps, since the GEI was trapped in the RBcel1_Y201F variant. The approach used to obtain the GEI presented here could easily be transposed to other retaining GHs in clan GH-A.

Crystal structure determination of Pseudomonas stutzeri A1501 endoglucanase Cel5A: the search for a molecular basis for glycosynthesis in GH5_5 enzymes.

The discovery of new glycoside hydrolases that can be utilized in the chemoenzymatic synthesis of carbohydrates has emerged as a promising approach for various biotechnological processes. In this study, recombinant Ps_Cel5A from Pseudomonas stutzeri A1501, a novel member of the GH5_5 subfamily, was expressed, purified and crystallized. Preliminary experiments confirmed the ability of Ps_Cel5A to catalyze transglycosylation with cellotriose as a substrate. The crystal structure revealed several structural determinants in and around the positive subsites, providing a molecular basis for a better understanding of the mechanisms that promote and favour synthesis rather than hydrolysis. In the positive subsites, two nonconserved positively charged residues (Arg178 and Lys216) were found to interact with cellobiose. This adaptation has also been reported for transglycosylating ß-mannanases of the GH5_7 subfamily.

Antimicrobial properties of Pseudomonas strains producing the antibiotic mupirocin.

Mupirocin is a polyketide antibiotic with broad antibacterial activity. It was isolated and characterized about 40 years ago from Pseudomonas fluorescens NCIMB 10586. To study the phylogenetic distribution of mupirocin producing strains in the genus Pseudomonas a large collection of Pseudomonas strains of worldwide origin, consisting of 117 Pseudomonas type strains and 461 strains isolated from different biological origins, was screened by PCR for the mmpD gene of the mupirocin gene cluster. Five mmpD(+) strains from different geographic and biological origin were identified. They all produced mupirocin and were strongly antagonistic against Staphylococcus aureus. Phylogenetic analysis showed that mupirocin production is limited to a single species. Inactivation of mupirocin production leads to complete loss of in vitro antagonism against S. aureus, except on certain iron-reduced media where the siderophore pyoverdine is responsible for the in vitro antagonism of a mupirocin-negative mutant. In addition to mupirocin some of the strains produced lipopeptides of the massetolide group. These lipopeptides do not play a role in the observed in vitro antagonism of the mupirocin producing strains against S. aureus.

The proteome of Salmonella Typhimurium grown under in vivo-mimicking conditions.

To successfully infect a host, it is a prerequisite for enteric pathogens such as Salmonella enterica serovar Typhimurium to adapt to their environment, in casu the gastrointestinal tract. The adoption of an appropriate lifestyle is triggered by environmental signals such as the low oxygen availability and high osmolarity prevalent in the gut. In order to gain more insight in the changes that are induced when S. Typhimurium is adapting to these particular conditions, we used 2-D DIGE technology to investigate the combined effect of low oxygen tension and high osmolarity on the proteome of S. Typhimurium SL1344 compared to standard laboratory conditions. As a validation of the 2-D DIGE technique, preferential protein labeling by the Cy-dyes was assessed and proved to be negligible. The differentially expressed proteins identified reflect very well the applied culture conditions. Furthermore, reported transcriptional changes and observed changes at the translational level show overlap. Among the metabolic processes that are upregulated under in vivo-mimicking conditions are anaerobic fumarate respiration and the utilization of 1,2-propanediol. We also provide evidence that S. Typhimurium expresses an arginine deiminase pathway for the catabolism of L-arginine. The increased activity of this pathway was biochemically validated. Finally, also proteins involved in quorum sensing and virulence are differentially expressed under in vivo-mimicking conditions. These conditions offer possibilities as a simplified model system for the host environment given the high overlap of identifications in our study and reported genuine in vivo studies, respectively.

Purification of ArcR, an oxidation-sensitive regulatory protein from Bacillus licheniformis.

In Bacillus licheniformis, ArcR, a transcriptional activator of the Crp/Fnr family, is required for expression of the anaerobic pathway of arginine catabolism, the arginine deiminase pathway. The method described here allows the purification of milligram quantities of functional ArcR from a recombinant Escherichia coli strain. The solubility properties of ArcR were much exploited during the purification process. The protein appeared highly sensitive to oxidation. Oxidation-induced precipitation of the protein was attributed to the formation of intermolecular disulfide bridges. Alkylation of mutant proteins with single substitutions showed that both cysteine residues of the protein, C178 and C205, are involved in formation of the disulfide bridges. Substitution of both cysteines yielded a functional protein insensitive to oxidation and able to form a complex with its cognate target on the DNA.