Structural, Biochemical, and Phylogenetic Analysis of Bacterial and Fungal Carbohydrate Esterase Family 15 Glucuronoyl Esterases in the Rumen.

Glucuronoyl esterases (GEs) are carbohydrate active enzymes in carbohydrate esterase family 15 which are involved in the hydrolysis of lignin-carbohydrate complexes. They are encoded by a wide range of aerobic and anaerobic fungi and bacteria inhabiting diverse environments. The rumen microbiome is a complex microbial community with a wide array of enzymes that specialize in deconstructing plant cell wall carbohydrates. Enzymes from the rumen tend to show low similarity to homologues found in other environments, making the rumen microbiome a promising source for the discovery of novel enzymes. Using a combination of phylogenetic and structural analysis, we investigated the structure-function relationship of GEs from the rumen bacteria Fibrobacter succinogenes and Ruminococcus flavefaciens, and from the rumen fungus, Piromyces rhizinflata. All adopt a canonical α/ß hydrolase fold and possess a structurally conserved Ser-His-Glu/Asp catalytic triad. Structural variations in the enzymes are localized to loops surrounding the active site. Analysis of the active site structures in these enzymes emphasized the importance of structural plasticity in GEs with non-canonical active site conformations. We hypothesize that interkingdom HGT events may have contributed to the diversity of GEs in the rumen, and this is demonstrated by the phylogenetic and structural similarity observed between rumen bacterial and fungal GEs. This study advances our understanding of the structure-function relationship in glucuronoyl esterases and illuminates the evolutionary dynamics that contribute to enzyme diversity in the rumen microbiome.

Fibrobacter sp. HC4, a newly isolated strain, demonstrates a high cellulolytic activity as revealed by enzymatic measurements and in vitro assay.

Despite their low quantity and abundance, the cellulolytic bacteria that inhabit the equine large intestine are vital to their host, as they enable the crucial use of forage-based diets. Fibrobacter succinogenes is one of the most important intestinal cellulolytic bacteria. In this study, Fibrobacter sp. HC4, one cellulolytic strain newly isolated from the horse cecum, was characterized for its ability to utilize plant cell wall fibers. Fibrobacter sp. HC4 consumed only cellulose, cellobiose, and glucose and produced succinate and acetate in equal amounts. Among genes coding for CAZymes, 26% of the detected glycoside hydrolases (GHs) were involved in cellulolysis. These cellulases belong to the GH5, GH8, GH9, GH44, GH45, and GH51 families. Both carboxymethyl cellulase and xylanase activities of Fibrobacter sp. HC4 were detected using the Congo red method and were higher than those of F. succinogenes S85, the type strain. The in vitro addition of Fibrobacter sp. HC4 to a fecal microbial ecosystem of horses with large intestinal acidosis significantly enhanced fibrolytic activity as measured by the increase in gas and volatile fatty acids production during the first 48 h. According to this, the pH decreased and the disappearance of dry matter increased at a faster rate with Fibrobacter sp. HC4. Our data suggest a high specialization of the new strain in cellulose degradation. Such a strain could be of interest for future exploitation of its probiotic potential, which needs to be further determined by in vivo studies.IMPORTANCECellulose is the most abundant of plant cell wall fiber and can only be degraded by the large intestine microbiota, resulting in the production of volatile fatty acids that are essential for the host nutrition and health. Consequently, cellulolytic bacteria are of major importance to herbivores. However, these bacteria are challenged by various factors, such as high starch diets, which acidify the ecosystem and reduce their numbers and activity. This can lead to an imbalance in the gut microbiota and digestive problems such as colic, a major cause of mortality in horses. In this work, we characterized a newly isolated cellulolytic strain, Fibrobacter sp. HC4, from the equine intestinal microbiota. Due to its high cellulolytic capacity, reintroduction of this strain into an equine fecal ecosystem stimulates hay fermentation in vitro. Isolating and describing cellulolytic bacteria is a prerequisite for using them as probiotics to restore intestinal balance.

Outer membrane vesicles from Fibrobacter succinogenes S85 contain an array of carbohydrate-active enzymes with versatile polysaccharide-degrading capacity.

Fibrobacter succinogenes is an anaerobic bacterium naturally colonising the rumen and cecum of herbivores where it utilizes an enigmatic mechanism to deconstruct cellulose into cellobiose and glucose, which serve as carbon sources for growth. Here, we illustrate that outer membrane vesicles (OMVs) released by F. succinogenes are enriched with carbohydrate-active enzymes and that intact OMVs were able to depolymerize a broad range of linear and branched hemicelluloses and pectin, despite the inability of F. succinogenes to utilize non-cellulosic (pentose) sugars for growth. We hypothesize that the degradative versatility of F. succinogenes OMVs is used to prime hydrolysis by destabilising the tight networks of polysaccharides intertwining cellulose in the plant cell wall, thus increasing accessibility of the target substrate for the host cell. This is supported by observations that OMV-pretreatment of the natural complex substrate switchgrass increased the catalytic efficiency of a commercial cellulose-degrading enzyme cocktail by 2.4-fold. We also show that the OMVs contain a putative multiprotein complex, including the fibro-slime protein previously found to be important in binding to crystalline cellulose. We hypothesize that this complex has a function in plant cell wall degradation, either by catalysing polysaccharide degradation itself, or by targeting the vesicles to plant biomass.

Isolation and characterization of a novel glycosyl hydrolase family 74 (GH74) cellulase from the black goat rumen metagenomic library.

This study aimed to isolate and characterize a novel cellulolytic enzyme from black goat rumen by using a culture-independent approach. A metagenomic fosmid library was constructed from black goat rumen contents and screened for a novel cellulase. The KG37 gene encoding a protein of 858 amino acid residues (92.7 kDa) was isolated. The deduced protein contained a glycosyl hydrolase family 74 (GH74) domain and showed 77% sequence identity to two endo-1,4-ß-glucanases from Fibrobacter succinogenes. The novel GH74 cellulase gene was overexpressed in Escherichia coli, and its protein product was functionally characterized. The recombinant GH74 cellulase showed a broad substrate spectrum. The enzyme exhibited its optimum activity at pH 5.0 and temperature range of 20-50 °C. The enzyme was thermally stable at pH 5.0 and at a temperature of 20-40 °C. The novel GH74 cellulase can be practically exploited to convert lignocellulosic biomass to value-added products in various industrial applications in future.

Comprehensive detection of bacterial carbohydrate-active enzyme coding genes expressed in cow rumen.

To find the abundant and characteristic fibrolytic enzyme-coding gene expressed in fiber-associating microbiota, a metatranscriptomic data set was obtained from fiber-associating microbiota, and it was compared with that of rumen fluid-floating microbiota and two metagenomic data sets. Fibrolytic rumen bacteria associate with plant polysaccharide and hydrolyze it in the rumen. We obtained a metatranscriptomic assembly from fiber-associating microbiota in three ruminally fistulated Holstein cows fed timothy (Phleum pratense) hay. Each metatranscriptomic data set involved over a thousand of the glycoside hydrolase (GH) gene transcripts that accounted for about 1% of total protein coding gene transcripts. Three-quarters of the total GH gene transcripts were dominated by non-structural oligosaccharide-acting hydrolase gene transcripts. In the fiber-associating microbiota, endo-cellulase coding gene families, especially GHs 9 and 5, were abundantly detected, and GHs 9, 11, 30 and 43, carbohydrate esterase 8 and carbohydrate-binding module 6 were characteristically detected. Most fibrolytic gene transcripts assigned to Fibrobacter succinogenes were detected in fiber-associating sections, and GHs 45, 44, 74, 11, 30 and 16 were Fibrobacter-characteristically detected. The metatranscriptomic assembly highlighted the characteristic fibrolytic enzymes expressed in the fiber-associated rumen microbiota and offered access to the fibrolytic activities in each fibrolytic bacteria.

Designing novel cellulase systems through agent-based modeling and global sensitivity analysis.

Experimental techniques allow engineering of biological systems to modify functionality; however, there still remains a need to develop tools to prioritize targets for modification. In this study, agent-based modeling (ABM) was used to build stochastic models of complexed and non-complexed cellulose hydrolysis, including enzymatic mechanisms for endoglucanase, exoglucanase, and ß-glucosidase activity. Modeling results were consistent with experimental observations of higher efficiency in complexed systems than non-complexed systems and established relationships between specific cellulolytic mechanisms and overall efficiency. Global sensitivity analysis (GSA) of model results identified key parameters for improving overall cellulose hydrolysis efficiency including: (1) the cellulase half-life, (2) the exoglucanase activity, and (3) the cellulase composition. Overall, the following parameters were found to significantly influence cellulose consumption in a consolidated bioprocess (CBP): (1) the glucose uptake rate of the culture, (2) the bacterial cell concentration, and (3) the nature of the cellulase enzyme system (complexed or non-complexed). Broadly, these results demonstrate the utility of combining modeling and sensitivity analysis to identify key parameters and/or targets for experimental improvement.

Engineering of dual-functional hybrid glucanases.

1,3-1,4-ß-D-Glucanase (lichenase) and 1,3-ß-D-glucanase (laminarinase) are fibrolytic enzymes which play an important role in the hydrolysis of polysaccharide components. Both of these glucanases have been employed in a number of industrial applications. This study aims to improve or combine the novel properties of both glucanases in an attempt to create desirable hybrid enzymes with economic benefits for industrial applications. A truncated and mutated 1,3-1,4-ß-D-glucanase gene (TFs(W203F)) from Fibrobacter succinogenes, and a 1,3-ß-D-glucanase gene (TmLam) from hyperthermophilic Thermotoga maritima were used as target enzymes. The substrate-binding domains (TmB1 and TmB2) and the catalytic domain (TmLam(CD)) of TmLam were ligated to the N- or C-terminus of TFsW203F to create four hybrid enzymes, TmB1-TFs(W203F), TFs(W203F)-TmB2, TmB1-TFs(W203F)-TmB2 and TFs(W203F)-TmLam(CD). The results obtained from kinetic studies show that increased specific activities and turnover rate for lichenan and laminarin were observed in TmB1-TFs(W203F)-TmB2 and TFs(W203F)-TmLam(CD), respectively. Furthermore, fluorescence and circular dichroism spectrometric analyses indicated that the hybrid TFs(W203F)-TmLam(CD) was structurally more stable than the parental TFs(W203F), which was attributed to an improved thermal tolerance of the hybrid enzyme. This study has been successful in creating bifunctional hybrid glucanases with dual substrate catalytic functions which warrant further evaluation of their possible use in industrial applications.

Screening of a xylanase clone from a fosmid library of rumen microbiota in Hu sheep.

The glycosyl hydrolase family 11, which is responsible for carbohydrate metabolism, was identified in the open reading frame (ORF) 6 of a xylanase positive clone from a fosmid library of rumen microbiota of Hu sheep. A BLASTP search of GenBank revealed that ORF6 encoded a 355-amino acid putative endoxylanase, having 61% similarity (e(-73)) to endo-1,4-ß-xylanase of Fibrobacter succinogenes S85 (YP_003250510.1). Predicted with the SWISS-MODEL, there were two separate ß-sandwich clusters linked with a high serine containing linker in ORF6. The N-terminal ß-sandwich is a novel endoxylanase of the glycosyl hydrolase family 11 with a specific activity of 1150.00 U/mg. The optimal pH and temperature for this enzyme were shown to be pH 5.0 and 50°C, respectively. The C-terminal helped increase the stability of the xylanase but decreased the activity to some degree. The C-terminal ß-sandwich could bind avicel, but no conserved domain could be found. It may be a novel carbohydrate-binding module.

Engineering Escherichia coli for succinate production from hemicellulose via consolidated bioprocessing.

BACKGROUND: The recalcitrant nature of hemicellulosic materials and the high cost in depolymerization are the primary obstacles preventing the use of xylan as feedstock for fuel and chemical production. Consolidated bioprocessing, incorporating enzyme-generating, biomass-degrading and bioproduct-producing capabilities into a single microorganism, could potentially avoid the cost of the dedicated enzyme generation in the process of xylan utilization. In this study, we engineered Escherichia coli strains capable of exporting three hemicellulases to the broth for the succinate production directly from beechwood xylan. RESULTS: Xylanases were extracellular environment-directed by fusing with OsmY. Subsequently, twelve variant OsmY fused endoxylanase-xylosidase combinations were characterized and tested. The combination of XynC-A from Fibrobacter succinogenes S85 and XyloA from Fusarium graminearum which appeared to have optimal enzymatic properties was identified as the best choice for xylan hydrolysis (0.18 ± 0.01 g/l protein in the broth with endoxylanase activity of 12.14 ± 0.34 U/mg protein and xylosidase activity of 92 ± 3 mU/mg protein at 8 h after induction). Further improvements of hemicellulases secretion were investigated by lpp deletion, dsbA overexpression and expression level optimization. With co-expression of α-arabinofuranosidase, the engineered E. coli could hydrolyze beechwood xylan to pentose monosaccharides. The hemicellulolytic capacity was further integrated with a succinate-producing strain to demonstrate the production of succinate directly from xylan without externally supplied hydrolases and any other organic nutrient. The resulting E. coli Z6373 was able to produce 0.37 g/g succinate from xylan anaerobically equivalent to 76% of that from xylan acid hydrolysates. CONCLUSIONS: This report represents a promising step towards the goal of hemicellulosic chemical production. This engineered E. coli expressing and secreting three hemicellulases demonstrated a considerable succinate production on the released monosaccharides from xylan. The ability to use lower-cost crude feedstock will make biological succinate production more economically attractive.

Rational design to improve thermostability and specific activity of the truncated Fibrobacter succinogenes 1,3-1,4-ß-D-glucanase.

1,3-1,4-ß-D-Glucanase has been widely used as a feed additive to help non-ruminant animals digest plant fibers, with potential in increasing nutrition turnover rate and reducing sanitary problems. Engineering of enzymes for better thermostability is of great importance because it not only can broaden their industrial applications, but also facilitate exploring the mechanism of enzyme stability from structural point of view. To obtain enzyme with higher thermostability and specific activity, structure-based rational design was carried out in this study. Eleven mutants of Fibrobacter succinogenes 1,3-1,4-ß-D-glucanase were constructed in attempt to improve the enzyme properties. In particular, the crude proteins expressed in Pichia pastoris were examined firstly to ensure that the protein productions meet the need for industrial fermentation. The crude protein of V18Y mutant showed a 2 °C increment of Tm and W203Y showed ∼30% increment of the specific activity. To further investigate the structure-function relationship, some mutants were expressed and purified from P. pastoris and Escherichia coli. Notably, the specific activity of purified W203Y which was expressed in E. coli was 63% higher than the wild-type protein. The double mutant V18Y/W203Y showed the same increments of Tm and specific activity as the single mutants did. When expressed and purified from E. coli, V18Y/W203Y showed similar pattern of thermostability increment and 75% higher specific activity. Furthermore, the apo-form and substrate complex structures of V18Y/W203Y were solved by X-ray crystallography. Analyzing protein structure of V18Y/W203Y helps elucidate how the mutations could enhance the protein stability and enzyme activity.

The complete genome sequence of Fibrobacter succinogenes S85 reveals a cellulolytic and metabolic specialist.

Fibrobacter succinogenes is an important member of the rumen microbial community that converts plant biomass into nutrients usable by its host. This bacterium, which is also one of only two cultivated species in its phylum, is an efficient and prolific degrader of cellulose. Specifically, it has a particularly high activity against crystalline cellulose that requires close physical contact with this substrate. However, unlike other known cellulolytic microbes, it does not degrade cellulose using a cellulosome or by producing high extracellular titers of cellulase enzymes. To better understand the biology of F. succinogenes, we sequenced the genome of the type strain S85 to completion. A total of 3,085 open reading frames were predicted from its 3.84 Mbp genome. Analysis of sequences predicted to encode for carbohydrate-degrading enzymes revealed an unusually high number of genes that were classified into 49 different families of glycoside hydrolases, carbohydrate binding modules (CBMs), carbohydrate esterases, and polysaccharide lyases. Of the 31 identified cellulases, none contain CBMs in families 1, 2, and 3, typically associated with crystalline cellulose degradation. Polysaccharide hydrolysis and utilization assays showed that F. succinogenes was able to hydrolyze a number of polysaccharides, but could only utilize the hydrolytic products of cellulose. This suggests that F. succinogenes uses its array of hemicellulose-degrading enzymes to remove hemicelluloses to gain access to cellulose. This is reflected in its genome, as F. succinogenes lacks many of the genes necessary to transport and metabolize the hydrolytic products of non-cellulose polysaccharides. The F. succinogenes genome reveals a bacterium that specializes in cellulose as its sole energy source, and provides insight into a novel strategy for cellulose degradation.

Structural basis for the inhibition of 1,3-1,4-ß-D-glucanase by noncompetitive calcium ion and competitive Tris inhibitors.

In this paper, we determine the mutant W203F structure of TFsß-glucanase, which contains aromatic residue Trp203 at the active site of the enzyme. Residue Trp203 is stacked with the glucose product of cellotriose. Further analysis reveals that two extra calcium ions and a Tris molecule bind to the mutant structure. A Tris molecule, bound to the catalytic residues of Glu56 and Glu60, was found at the position normally taken by substrate binding at the -1 subsite. In addition, a second Ca(2+) ion was found near the residues Phe152 and Glu154 on the protein's surface, and a third one near the active site residue Asp202. Kinetic experiments reveal that both Tris and imidazole are competitive inhibitors, while calcium is a noncompetitive inhibitor for TFsß-glucanase. The two types of enzymatic inhibition are first-time descriptions for the glycosyl hydrolase family 16.

Display of Fibrobacter succinogenes ß-glucanase on the cell surface of Lactobacillus reuteri.

The aim of this study was to display a rumen bacterial ß-glucanase on the cell surface of a probiotic Lactobacillus reuteri strain. The ß-glucan degrading ability and the adhesion capability of the genetically modified strain were evaluated. The ß-glucanase (Glu) from Fibrobacter succinogenes was fused to the C-terminus of collagen-binding protein (Cnb) from L. reuteri and then expressed by L. reuteri Pg4 as a recombinant Cnb-Glu-His(6) fusion protein. Confocal immunofluorescence microscopy and flow cytometric analysis of the transformed strain L. reuteri pNZ-cnb/glu demonstrated that Cnb-Glu-His(6) fusion protein was displayed on its cell surface. In addition, L. reuteri pNZ-cnb/glu acquired the capacity to break down barley ß-glucan and showed higher adhesion capability, in comparison with the parental strain L. reuteri Pg4. To the best of the authors' knowledge, this is the first report of successful display of fibrolytic enzymes on the cell surface of intestinal lactobacilli.

Functional annotation of Fibrobacter succinogenes S85 carbohydrate active enzymes.

Fibrobacter succinogenes is a cellulolytic bacterium that degrades plant cell wall biomass in ruminant animals and is among the most rapidly fibrolytic of all mesophilic bacteria. The complete genome sequence of Fisuc was completed by the DOE Joint Genome Institute in late 2009. Using new expression tools developed at Lucigen and C5-6 Technologies and a multi-substrate screen, 5,760 random shotgun expression clones were screened for biomass-degrading enzymes, representing 2× genome expression coverage. From the screen, 169 positive hits were recorded and 33 were unambiguously identified by sequence analysis of the inserts as belonging to CAZy family genes. Eliminating duplicates, 24 unique CAZy genes were found by functional screening. Several previously uncharacterized enzymes were discovered using this approach and a number of potentially mis-annotated enzymes were functionally characterized. To complement this approach, a high-throughput system was developed to clone and express all the annotated glycosyl hydrolases and carbohydrate esterases in the genome. Using this method, six previously described and five novel CAZy enzymes were cloned, expressed, and purified in milligram quantities.

Domain analysis of a modular alpha-L-Arabinofuranosidase with a unique carbohydrate binding strategy from the fiber-degrading bacterium Fibrobacter succinogenes S85.

Family 43 glycoside hydrolases (GH43s) are known to exhibit various activities involved in hemicellulose hydrolysis. Thus, these enzymes contribute to efficient plant cell wall degradation, a topic of much interest for biofuel production. In this study, we characterized a unique GH43 protein from Fibrobacter succinogenes S85. The recombinant protein showed α-l-arabinofuranosidase activity, specifically with arabinoxylan. The enzyme is, therefore, an arabinoxylan arabinofuranohydrolase (AXH). The F. succinogenes AXH (FSUAXH1) is a modular protein that is composed of a signal peptide, a GH43 catalytic module, a unique ß-sandwich module (XX domain), a family 6 carbohydrate-binding module (CBM6), and F. succinogenes-specific paralogous module 1 (FPm-1). Truncational analysis and site-directed mutagenesis of the protein revealed that the GH43 domain/XX domain constitute a new form of carbohydrate-binding module and that residue Y484 in the XX domain is essential for binding to arabinoxylan, although protein structural analyses may be required to confirm some of the observations. Kinetic studies demonstrated that the Y484A mutation leads to a higher k(cat) for a truncated derivative of FSUAXH1 composed of only the GH43 catalytic module and the XX domain. However, an increase in the K(m) for arabinoxylan led to a 3-fold decrease in catalytic efficiency. Based on the knowledge that most XX domains are found only in GH43 proteins, the evolutionary relationships within the GH43 family were investigated. These analyses showed that in GH43 members with a XX domain, the two modules have coevolved and that the length of a loop within the XX domain may serve as an important determinant of substrate specificity.

Structural and catalytic roles of amino acid residues located at substrate-binding pocket in Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase.

We created 12 mutant enzymes (E11L, F40I, Y42L, N44L, N44Q, E47I, L62G, K64A, K64M, R137M, R137Q, and N139A) from the truncated Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase (TF-glucanase). The enzymes were used to investigate the structural and catalytic roles of specific amino acid residues located at the catalytic pocket and having direct interactions with glucose subsites of the product beta-1,3-1,4-cellotriose (CLTR). Fluorescence spectrometry showed no discernible changes in secondary structures among purified TF-glucanase and the mutants. Kinetic analyses showed E11L, F40I, Y42L, R137M, and R137Q with a >10-fold decrease of specific activity (11.2- to 67.4-fold), and E11L, N44Q, E47I, K64M, R137M, R137Q, and N139A with a 2.17- to 4.3-fold increase of K(m) value when compared with TF-glucanase. Notably, E11L, R137Q, R137M, F40I, and N139A showed the most significant decrease in catalytic efficiency relative to TF-glucanase, by 2155-, 84.9-, 48.5-, 41.1-, and 19.1-fold, respectively; the five mutants showed the greatest changes in comparative energy DeltaDeltaG(b), with values of 1.94 to 4.92 kcal/mol. Combined with results from kinetic and structure modeling analyses of all mutant enzymes and X-ray crystallography of F40I, we elucidate that Glu11, Phe40, Arg137, and Asn139 play a crucial role in the catalysis of TF-glucanase owing to their local and direct interaction through hydrogen bonds or van der Waals stacking interaction by aromatic rings onto the glucose subsites -3, -2, and -1 of CLTR/substrate. The overall globular structures in the wild-type and mutant F40I enzymes do not differ.

Biochemical and domain analyses of FSUAxe6B, a modular acetyl xylan esterase, identify a unique carbohydrate binding module in Fibrobacter succinogenes S85.

Acetyl xylan esterase (EC 3.1.1.72) is a member of a set of enzymes required to depolymerize hemicellulose, especially xylan that is composed of a main chain of beta-1,4-linked xylopyranoside residues decorated with acetyl side groups. Fibrobacter succinogenes S85 Axe6B (FSUAxe6B) is an acetyl xylan esterase encoded in the genome of this rumen bacterium. The enzyme is a modular protein comprised of an esterase domain, a carbohydrate-binding module, and a region of unknown function. Sequences that are homologous to the region of unknown function are paralogously distributed, thus far, only in F. succinogenes. Therefore, the sequences were designated Fibrobacter succinogenes-specific paralogous module 1 (FPm-1). The FPm-1s are associated with at least 24 polypeptides in the genome of F. succinogenes S85. A bioinformatics search showed that most of the FPm-1-appended polypeptides are putative carbohydrate-active enzymes, suggesting a potential role in carbohydrate metabolism. Truncational analysis of FSUAxe6B, together with catalytic and substrate binding studies, has allowed us to delineate the functional modules in the polypeptide. The N-terminal half of FSUAxe6B harbors the activity that cleaves side chain acetyl groups from xylan-like substrates, and the binding of insoluble xylan was determined to originate from FPm-1. Site-directed mutagenesis studies of highly conserved active-site residues in the esterase domain suggested that the esterase activity is derived from a tetrad composed of Ser(44), His(273), Glu(194), and Asp(270), with both Glu(194) and Asp(270) functioning as helper acids, instead of a single carboxylate residue proposed to initiate catalysis.

Structural and catalytic roles of residues located in beta13 strand and the following beta-turn loop in Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase.

BACKGROUND: Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase (Fsbeta-glucanase) is the only naturally occurring circularly permuted beta-glucanase among bacterial glucanases with reverse protein domains. We characterized the functional and structural significance of residues 200-209 located in the domain B of Fsbeta-glucanase, corresponding to the major surface loop in the domain A region of Bacillus licheniformis glucanase. METHODS: Rational design approaches including site-directed mutagenesis, initial-rate kinetics, and structural modeling analysis were used in this study. RESULTS: Our kinetic data showed that D202N and D206N exhibited a 1.8- and 1.5-fold increase but G207N, G207-, F205L, N208G and T204F showed a 7.0- to 2.2-fold decrease, in catalytic efficiency (k(cat)/K(M)) compared to the wild-type enzyme. The comparative energy DeltaDeltaG(b) value in individual mutant enzymes was well correlated to their catalytic efficiency. D206R mutant enzyme exhibited the highest relative activity at 50 degrees C over 10 min, whereas K200F was the most heat-sensitive enzyme. CONCLUSIONS: This study demonstrates that Phe205, Gly207, and Asn208 in the Type II turn of the connecting loop may play a role in the catalytic function of Fsbeta-glucanase. GENERAL SIGNIFICANCE: Residues 200-209 in Fsbeta-glucanase resided at the similar structural topology to that of Bacillus enzyme were found to play some similar catalytic function in glucanase.

Development of a RT-qPCR method for the quantification of Fibrobacter succinogenes S85 glycoside hydrolase transcripts in the rumen content of gnotobiotic and conventional sheep.

An improved RNA isolation method based on the acid guanidinium-phenol-chloroform (AGPC) procedure using saline precipitation but no column purification was evaluated for quantifying microbial gene expression using reverse transcription quantitative PCR (RT-qPCR) in rumen contents. The method provided good RNA integrity and quantity extracts. The transcript levels of eight glycoside hydrolase (GH) genes of the major rumen fibrolytic bacterium Fibrobacter succinogenes were quantified in the complex microbiota of a conventional sheep and in a gnotobiotic lamb harboring a microflora containing F. succinogenes S85 as the sole cellulolytic microorganism. This study validated the improved RNA isolation method, RT-qPCR conditions to quantify GH transcripts using either the F. succinogenes S85 tuf gene or the 16S rRNA-encoding gene (rrs) as the reference gene, and demonstrated the need to work with good quality RNAs. Transcripts from all the selected genes cel3, endA(FS), celF and endB endoglucanase genes, cedA cellodextrinase gene, mlg lichenase gene, and xynC and xynD xylanase genes of F. succinogenes S85 were detected and quantified at varying levels in the rumen content of the two animal models. This study opens new perspectives in studying microbial gene expression in the rumen of both conventional and gnotobiotic sheep.

Isolation and identification of cellulose-binding proteins from sheep rumen contents.

To extend our understanding of the mechanisms of plant cell wall degradation in the rumen, cellulose-binding proteins (CBPs) from the contents of a sheep rumen were directly isolated and identified using a metaproteomics approach. The rumen CBPs were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and some CBPs revealed endoglucanase activities toward carboxymethyl cellulose. Using mass spectrometry analyses, four CBPs were identified and annotated as known proteins from the predominant rumen cellulolytic bacterium Fibrobacter succinogenes: tetratricopeptide repeat domain protein, OmpA family protein, fibro-slime domain protein, and cellulose-binding endoglucanase F (EGF). Another CBP was identified as the cellulosomal glycosyl hydrolase family 6 exoglucanase, Cel6A, of Piromyces equi. F. succinogenes cells expressing EGF were found to be major members of the bacterial community on the surface or at the inner surface of hay stems by immunohistochemical analyses using anti-EGF antibody. The finding that four of the five CBPs isolated and identified from sheep rumen contents were from F. succinogenes indicates that F. succinogenes is significantly involved in cellulose degradation in the rumen.