Handling Several Sugars at a Time: a Case Study of Xyloglucan Utilization by Ruminiclostridium cellulolyticum.

Xyloglucan utilization by Ruminiclostridium cellulolyticum was formerly shown to imply the uptake of large xylogluco-oligosaccharides, followed by cytosolic depolymerization into glucose, galactose, xylose, and cellobiose. This raises the question of how the anaerobic bacterium manages the simultaneous presence of multiple sugars. Using genetic and biochemical approaches targeting the corresponding metabolic pathways, we observed that, surprisingly, all sugars are catabolized, collectively, but glucose consumption is prioritized. Most selected enzymes display unusual features, especially the GTP-dependent hexokinase of glycolysis, which appeared reversible and crucial for xyloglucan utilization. In contrast, mutant strains lacking either galactokinase, cellobiose-phosphorylase, or xylulokinase still catabolize xyloglucan but display variably altered growth. Furthermore, the xylogluco-oligosaccharide depolymerization process appeared connected to the downstream pathways through an intricate network of competitive and noncompetitive inhibitions. Altogether, our data indicate that xyloglucan utilization by R. cellulolyticum relies on an energy-saving central carbon metabolism deviating from current bacterial models, which efficiently prevents carbon overflow. IMPORTANCE The study of the decomposition of recalcitrant plant biomass is of great interest as the limiting step of terrestrial carbon cycle and to produce plant-derived valuable chemicals and energy. While extracellular cellulose degradation and catabolism have been studied in detail, few publications describe the complete metabolism of hemicelluloses and, to date, the published models are limited to the extracellular degradation and sequential entry of simple sugars. Here, we describe how the model anaerobic bacterium Ruminiclostridium cellulolyticum deals with the synchronous intracellular release of glucose, galactose, xylose, and cellobiose upon cytosolic depolymerization of imported xyloglucan oligosaccharides. The described novel metabolic strategy involves the simultaneous activity of different metabolic pathways coupled to a network of inhibitions controlling the carbon flux and is distinct from the ubiquitously observed sequential uptake and metabolism of carbohydrates known as the diauxic shift. Our results highlight the diversity of cellular responses related to a complex environment.

A Novel Two-Component System, XygS/XygR, Positively Regulates Xyloglucan Degradation, Import, and Catabolism in Ruminiclostridium cellulolyticum.

Cellulolytic microorganisms play a key role in the global carbon cycle by decomposing structurally diverse plant biopolymers from dead plant matter. These microorganisms, in particular anaerobes such as Ruminiclostridium cellulolyticum that are capable of degrading and catabolizing several different polysaccharides, require a fine-tuned regulation of the biosynthesis of their polysaccharide-degrading enzymes. In this study, we present a bacterial regulatory system involved in the regulation of genes enabling the metabolism of the ubiquitous plant polysaccharide xyloglucan. The characterization of R. cellulolyticum knockout mutants suggests that the response regulator XygR and its cognate histidine kinase XygS are essential for growth on xyloglucan. Using in vitro and in vivo analyses, we show that XygR binds to the intergenic region and activates the expression of two polycistronic transcriptional units encoding an ABC transporter dedicated to the uptake of xyloglucan oligosaccharides and the two-component system itself together with three intracellular glycoside hydrolases responsible for the sequential intracellular degradation of the imported oligosaccharides into mono- and disaccharides. Interestingly, XygR also upregulates the expression of a distant gene coding for the most active extracellular cellulosomal xyloglucanase of R. cellulolyticum by binding to the upstream intergenic region.IMPORTANCERuminiclostridium cellulolyticum is a Gram-positive, mesophilic, anaerobic, cellulolytic, and hemicellulolytic bacterium. The last property qualifies this species as a model species for the study of hemicellulose degradation, import of degradation products, and overall regulation of these phenomena. In this study, we focus on the regulation of xyloglucan dextrin import and intracellular degradation and show that the two components of the two-component regulation system XygSR are essential for growth on xyloglucan and that the response regulator XygR regulates the transcription of genes involved in the extracellular degradation of the polysaccharide, the import of degradation products, and their intracellular degradation.

In vitro and in vivo exploration of the cellobiose and cellodextrin phosphorylases panel in Ruminiclostridium cellulolyticum: implication for cellulose catabolism.

BACKGROUND: In anaerobic cellulolytic micro-organisms, cellulolysis results in the action of several cellulases gathered in extracellular multi-enzyme complexes called cellulosomes. Their action releases cellobiose and longer cellodextrins which are imported and further degraded in the cytosol to fuel the cells. In Ruminiclostridium cellulolyticum, an anaerobic and cellulolytic mesophilic bacteria, three cellodextrin phosphorylases named CdpA, CdpB, and CdpC, were identified in addition to the cellobiose phosphorylase (CbpA) previously characterized. The present study aimed at characterizing them, exploring their implication during growth on cellulose to better understand the life-style of cellulolytic bacteria on such substrate. RESULTS: The three cellodextrin phosphorylases from R. cellulolyticum displayed marked different enzymatic characteristics. They are specific for cellodextrins of different lengths and present different k cat values. CdpC is the most active enzyme before CdpA, and CdpB is weakly active. Modeling studies revealed that a mutation of a conserved histidine residue in the phosphate ion-binding pocket in CdpB and CdpC might explain their activity-level differences. The genes encoding these enzymes are scattered over the chromosome of R. cellulolyticum and only the expression of the gene encoding the cellobiose phosphorylase and the gene cdpA is induced during cellulose growth. Characterization of four independent mutants constructed in R. cellulolyticum for each of the cellobiose and cellodextrin phosphorylases encoding genes indicated that only the cellobiose phosphorylase is essential for growth on cellulose. CONCLUSIONS: Unexpectedly, the cellobiose phosphorylase but not the cellodextrin phosphorylases is essential for the growth of the model bacterium on cellulose. This suggests that the bacterium adopts a "short" dextrin strategy to grow on cellulose, even though the use of long cellodextrins might be more energy-saving. Our results suggest marked differences in the cellulose catabolism developed among cellulolytic bacteria, which is a result that might impact the design of future engineered strains for biomass-to-biofuel conversion.

Versatile Vectors for Efficient Mutagenesis of Bradyrhizobium diazoefficiens and Other Alphaproteobacteria.

UNLABELLED: Analysis of bacterial gene function commonly relies on gene disruption or replacement followed by phenotypic characterization of the resulting mutant strains. Deletion or replacement of targeted regions is commonly achieved via two homologous recombination (HR) events between the bacterial genome and a nonreplicating plasmid carrying DNA fragments flanking the region to be deleted. The counterselection of clones that have integrated the entire plasmid in their genome via a single HR event is crucial in this procedure. Various genetic tools and well-established protocols are available for this type of mutagenesis in model bacteria; however, these methods are not always efficiently applicable in less established systems. Here we describe the construction and application of versatile plasmid vectors pREDSIX and pTETSIX for marker replacement and markerless mutagenesis, respectively. Apart from an array of restriction sites optimized for cloning of GC-rich DNA fragments, the vector backbone contains a constitutively expressed gene for mCherry, enabling the rapid identification of clones originating from single or double HR events by fluorescence-assisted cell sorting (FACS). In parallel, we constructed a series of plasmids from which gene cassettes providing resistance against gentamicin, kanamycin, hygromycin B, streptomycin and spectinomycin, or tetracycline were excised for use with pREDSIX-based marker replacement mutagenesis. In proof-of-concept mutagenesis experiments, we demonstrated the potential for the use of the developed tools for gene deletion mutagenesis in the nitrogen-fixing soybean symbiont Bradyrhizobium diazoefficiens(formerly Bradyrhizobium japonicum) and three additional members of the alphaproteobacteria. IMPORTANCE: Mutation and phenotypic analysis are essential to the study of gene function. Efficient mutagenesis protocols and tools are available for many bacterial species, including various model organisms; however, genetic analysis of less-well-characterized organisms is often impaired by the lack of efficient methods. Here we describe a set of novel genetic tools for facilitated mutagenesis of the nitrogen-fixing soybean symbiont Bradyrhizobium diazoefficiens and related alphaproteobacteria. We demonstrated their usefulness by generating several mutant strains lacking defined genes. Isolation of both antibiotic resistance gene-containing and markerless deletion mutants is greatly facilitated because undesired clones which contain the entire mutagenic plasmid integrated in the genome can be identified on the basis of their fluorescent phenotype derived from them Cherrygene carried by the vector backbone. The possibility to generate markerless mutants assists with the isolation of strains carrying multiple deletions, which can be crucial while studying functionally redundant genes.