Molecular cloning, expression, and characterization of a new endoglucanase gene fromFibrobacter succinogenes S85

Effect of Barium Addition on Hydrolytic Enzymatic Activities in Food Waste Degradation under Anaerobic Conditions

Enzymatic hydrolysis of complex components of residual materials, such as food waste, is a rate-limiting step that conditionates the production rate of biofuels. Research into the anaerobic degradation of cellulose and starch, which are abundant components in organic waste, could contribute to optimize biofuels production processes. In this work, a lab-scale anaerobic semi-continuous hydrolytic reactor was operated for 171 days using food waste as feedstock; the effect of Ba2+ dosage over the activity of five hydrolytic enzymes was also evaluated. No significant effects were observed on the global performance of the hydrolytic process during the steady-state of the operation of the reactor, nevertheless, it was detected that Ba2+ promoted β-amylases activity by 76%, inhibited endoglucanases and α-amylases activity by 39 and 20%, respectively, and had no effect on β-glucosidases and glucoamylases activity. The mechanisms that rule the observed enzymatic activity changes remain unknown; however, the discussion in this paper provides hypothetical explanations for further research.

Ruminococcus champanellensis sp. nov., a cellulose-degrading bacterium from human gut microbiota

A strictly anaerobic, cellulolytic strain, designated 18P13(T), was isolated from a human faecal sample. Cells were Gram-positive non-motile cocci. Strain 18P13(T) was able to degrade microcrystalline cellulose but the utilization of soluble sugars was restricted to cellobiose. Acetate and succinate were the major end products of cellulose and cellobiose fermentation. 16S rRNA gene sequence analysis revealed that the isolate belonged to the genus Ruminococcus of the family Ruminococcaceae. The closest phylogenetic relative was the ruminal cellulolytic strain Ruminococcus flavefaciens ATCC 19208(T) (<95% 16S rRNA gene sequence similarity). The DNA G+C content of strain 18P13(T) was 53.05±0.7 mol%. On the basis of phylogenetic analysis, and morphological and physiological data, strain 18P13(T) can be differentiated from other members of the genus Ruminococcus with validly published names. The name Ruminococcus champanellensis sp. nov. is proposed, with 18P13(T) (=DSM 18848(T)=JCM 17042(T)) as the type strain.

The cellulose-degrading microbial community of the human gut varies according to the presence or absence of methanogens

Cellulose-degrading microorganisms involved in the breakdown of plant cell wall material in the human gut remain rather unexplored despite their role in intestinal fermentation. Microcrystalline cellulose-degrading bacteria were previously identified in faeces of methane-excreting individuals, whereas these microorganisms were undetectable in faecal samples from non-methane excretors. This suggested that the structure and activity of the cellulose-degrading community differ in methane- and non-methane-excreting individuals. The purpose of this study was to characterize in depth this cellulose-degrading community in individuals of both CH(4) statuses using both culture-dependent and molecular methods. A new real-time PCR analysis was developed to enumerate microcrystalline cellulose-degrading ruminococci and used to confirm the predominance of these hydrolytic ruminococci in methane excretors. Culture-dependent methods using cell wall spinach (CWS) residue revealed the presence of CWS-degrading microorganisms in all individuals. Characterization of CWS-degrading isolates further showed that the main cellulose-degrading bacteria belong essentially to Bacteroidetes in non-methane-excreting subjects, while they are predominantly represented by Firmicutes in methane-excreting individuals. This taxonomic diversity was associated with functional diversity: the ability to degrade different types of cellulose and to produce H(2) from fermentation differed depending on the species. The structure of the cellulolytic community was shown to vary depending on the presence of methanogens in the human gut.

Bacteroides cellulosilyticus sp. nov., a cellulolytic bacterium from the human gut microbial community

A strictly anaerobic cellulolytic bacterium, strain CRE21(T), was isolated from a human faecal sample. Cells were Gram-negative non-motile rods that were about 1.7 microm in length and 0.9 microm in width. Strain CRE21(T) degraded different types of cellulose and was able to grow on a variety of carbohydrates. Cellulose and sugars were mainly converted to acetate, propionate and succinate. The G+C content of the DNA was 41.1 mol%. 16S rRNA gene sequence analysis revealed that the isolate belonged to the genus Bacteroides with highest sequence similarity to the type strain of Bacteroides intestinalis (98 %). DNA-DNA hybridization results revealed that strain CRE21(T) was distinct from B. intestinalis (40 % DNA-DNA relatedness). Strain CRE21(T) also showed several characteristics distinct from B. intestinalis. In particular, it exhibited different capacity to degrade polysaccharides such as cellulose. On the basis of phylogenetic analysis and the morphological, physiological and biochemical data presented in this study, strain CRE21(T) can be readily differentiated from recognized species of the genus Bacteroides. The name Bacteroides cellulosilyticus sp. nov. is proposed to accommodate this organism. The type strain is CRE21(T) (=DSM 14838(T)=CCUG 44979(T)).

Characterization of the xylan-degrading microbial community from human faeces

In humans, plant cell wall polysaccharides represent an important source of dietary fibres that are digested by gut microorganisms. Despite the extensive degradation of xylan in the colon, the population structure and the taxonomy of the predominant bacteria involved in degradation of this polysaccharide have not been extensively explored. The objective of our study was to characterize the xylanolytic microbial community from human faeces, using xylan from different botanic origins. The xylanolytic population was enumerated at high level in all faecal samples studied. The predominant xylanolytic organisms further isolated (20 strains) were assigned to Roseburia and Bacteroides species. Some Bacteroides isolates corresponded to the two newly described species Bacteroides intestinalis and Bacteroides dorei. Other isolates were closely related to Bacteroides sp. nov., a cellulolytic bacterium recently isolated from human faeces. The remaining Bacteroides strains could be considered to belong to a new species of this genus. Roseburia isolates could be assigned to the species Roseburia intestinalis. The xylanase activity of the Bacteroides and Roseburia isolates was found to be higher than that of other gut xylanolytic species previously identified. Our results provide new insights to the diversity and activity of the human gut xylanolytic community. Four new xylan-degrading Bacteroides species were identified and the xylanolytic capacity of R. intestinalis was further shown.

Xylanases and carboxymethylcellulases of the rumen protozoaPolyplastron multivesiculatum,Eudiplodinium maggiiandEntodiniumsp

Endoglucanase and xylanase activities of three rumen protozoa, Polyplastron multivesiculatum, Eudiplodinium maggii, and Entodinium sp. were compared qualitatively by zymograms and quantitatively by measuring specific activities against different polysaccharides. A set of carboxymethylcellulases and xylanases was produced by the large ciliates whereas no band of activity was observed for Entodinium sp. in zymograms. Specific activity of endoglucanases from P. multivesiculatum (1.3 micromol mg prot(-1) min(-1)) was twice that of E. maggii, whereas xylanase specific activity (4.5 micromol mg prot(-1) min(-1)) was only half. Very weak activities were observed for Entodinium sp. A new xylanase gene, xyn11D, from P. multivesiculatum was reported and its gene product compared to 33 other family 11 xylanases. Phylogenetic analysis showed that xylanase sequences from rumen protozoa are closely related to those of bacteria.

Reconstruction of the evolutionary history of the LexA-binding sequence

In recent years, the recognition sequence of the SOS repressor LexA protein has been identified for several bacterial clades, such as the Gram-positive, green non-sulfur bacteria and Cyanobacteria phyla, or the ‘Alphaproteobacteria’, ‘Deltaproteobacteria’ and ‘Gammaproteobacteria’ classes. Nevertheless, the evolutionary relationship among these sequences and the proteins that recognize them has not been analysed.Fibrobacter succinogenesis an anaerobic Gram-negative bacterium that branched from a common bacterial ancestor immediately before the Proteobacteria phylum. Taking advantage of its intermediate position in the phylogenetic tree, and in an effort to reconstruct the evolutionary history of LexA-binding sequences, theF. succinogenes lexAgene has been isolated and its product purified to identify its DNA recognition motif through electrophoretic mobility assays and footprinting experiments. After comparing the available LexA DNA-binding sequences with theF. succinogenesone, reported here, directed mutagenesis of theF. succinogenesLexA-binding sequence and phylogenetic analyses of LexA proteins have revealed the existence of two independent evolutionary lanes for the LexA recognition motif that emerged from the Gram-positive box: one generating the Cyanobacteria and ‘Alphaproteobacteria’ LexA-binding sequences, and the other giving rise to theF. succinogenesandMyxococcus xanthusones, in a transitional step towards the current ‘Gammaproteobacteria’ LexA box. The contrast between the results reported here and the phylogenetic data available in the literature suggests that, some time after its emergence as a distinct bacterial class, the ‘Alphaproteobacteria’ lost its vertically receivedlexAgene, but received later through lateral gene transfer a newlexAgene belonging to either a cyanobacterium or a bacterial species closely related to this phylum. This constitutes the first report based on experimental evidence of lateral gene transfer in the evolution of a gene governing such a complex regulatory network as the bacterial SOS system.

Fiber-degrading systems of different strains of the genus Fibrobacter

The S85 type strain of Fibrobacter succinogenes, a major ruminal fibrolytic species, was isolated 49 years ago from a bovine rumen and has been used since then as a model for extensive studies. To assess the validity of this model, we compared the cellulase- and xylanase-degrading activities of several other F. succinogenes strains originating from different ruminants, including recently isolated strains, and looked for the presence of 10 glycoside hydrolase genes previously identified in S85. The NR9 F. intestinalis type strain, representative of the second species of the genus, was also included in this study. DNA-DNA hybridization and 16S rRNA gene sequencing first classified the strains and provided the phylogenetic positions of isolates of both species. Cellulase and xylanase activity analyses revealed similar activity profiles for all F. succinogenes strains. However, the F(E) strain, phylogenetically close to S85, presented a poor xylanolytic system and weak specific activities. Furthermore, the HM2 strain, genetically distant from the other F. succinogenes isolates, displayed a larger cellulolytic profile on zymograms and higher cellulolytic specific activity. F. intestinalis NR9 presented a higher cellulolytic specific activity and a stronger extracellular xylanolytic activity. Almost all glycoside hydrolase genes studied were found in the F. succinogenes isolates by PCR, except in the HM2 strain, and few of them were detected in F. intestinalis NR9. As expected, the fibrolytic genes of strains of the genus Fibrobacter as well as the cellulase and xylanase activities are better conserved in closely related phylogenetic isolates.

Opportunities to improve fiber degradation in the rumen: microbiology, ecology, and genomics

The degradation of plant cell walls by ruminants is of major economic importance in the developed as well as developing world. Rumen fermentation is unique in that efficient plant cell wall degradation relies on the cooperation between microorganisms that produce fibrolytic enzymes and the host animal that provides an anaerobic fermentation chamber. Increasing the efficiency with which the rumen microbiota degrades fiber has been the subject of extensive research for at least the last 100 years. Fiber digestion in the rumen is not optimal, as is supported by the fact that fiber recovered from feces is fermentable. This view is confirmed by the knowledge that mechanical and chemical pretreatments improve fiber degradation, as well as more recent research, which has demonstrated increased fiber digestion by rumen microorganisms when plant lignin composition is modified by genetic manipulation. Rumen microbiologists have sought to improve fiber digestion by genetic and ecological manipulation of rumen fermentation. This has been difficult and a number of constraints have limited progress, including: (a) a lack of reliable transformation systems for major fibrolytic rumen bacteria, (b) a poor understanding of ecological factors that govern persistence of fibrolytic bacteria and fungi in the rumen, (c) a poor understanding of which glycolyl hydrolases need to be manipulated, and (d) a lack of knowledge of the functional genomic framework within which fiber degradation operates. In this review the major fibrolytic organisms are briefly discussed. A more extensive discussion of the enzymes involved in fiber degradation is included. We also discuss the use of plant genetic manipulation, application of free-living lignolytic fungi and the use of exogenous enzymes. Lastly, we will discuss how newer technologies such as genomic and metagenomic approaches can be used to improve our knowledge of the functional genomic framework of plant cell wall degradation in the rumen.

Endoglucanase activity and relative expression of glycoside hydrolase genes of Fibrobacter succinogenes S85 grown on different substrates

The endoglucanase activity of cells and extracellular culture fluid of Fibrobacter succinogenes S85 grown on glucose, cellobiose, soluble polysaccharides (beta-glucan, lichenan) and intact plant polysaccharides, was compared. The specific activity of cells grown on cellulose or forages was 6- to 20-fold higher than that of cells grown on soluble substrates, suggesting an induction of endoglucanases by the insoluble substrates. The ratios of cells to extracellular culture fluid endoglucanase activities measured in cultures grown on sugars or insoluble polysaccharides suggested that the endoglucanases induced by the insoluble polysaccharides remained attached to the cells. The mRNA of all the F. succinogenes glycoside hydrolase genes sequenced so far were then quantified in cells grown on glucose, cellobiose or cellulose. The results show that all these genes were transcribed in growing cells, and that they are all overexpressed in cultures grown on cellulose. Endoglucanase-encoding endB and endA(FS) genes, and xylanase-encoding xynC gene appeared the most expressed genes in growing cells. EGB and ENDA are thus likely to play a major role in cellulose degradation in F. succinogenes.

Characterisation of endoglucanases EGB and EGC from Fibrobacter succinogenes

The enzymatic properties of two endoglucanases from Fibrobacter succinogenes, EGB and EGC, were analysed. EGB and EGC were purified from recombinant Escherichia coli cultures expressing their gene. The failure of purification of EGB by classical techniques led us to produce antipeptide antibodies that allowed immunopurification of the protein from E. coli as well as its detection in F. succinogenes cultures. Synthetic peptides were selected from the predicted primary structure of EGB, linked to bovine serum albumin and used as immunogens to obtain specific antibodies. One of the polyclonal antipeptide antisera was used to purify EGB. EGC was purified by affinity chromatography with Ni-NTA resin. The endo mode of action of the two enzymes on carboxymethyl-cellulose was different. The values of K(m) and V(max) were respectively 13.6 mg/ml and 46 micromol/min mg protein for EGB, and 7 mg/ml and 110 micromol/min mg protein for EGC. The reactivity of the antipeptide and the anti-EGC sera with F. succinogenes proteins of molecular mass different from that of EGB and EGC produced in E. coli suggested post-translational modification of the two enzymes in F. succinogenes cultures. Expression of endB and endC genes in F. succinogenes was confirmed by RT-PCR.

A xylanase produced by the rumen anaerobic protozoan Polyplastron multivesiculatum shows close sequence similarity to family 11 xylanases from gram-positive bacteria

We report for the first time the cloning and characterisation of a protozoal enzyme involved in plant cell wall polysaccharide degradation. A cDNA library was constructed from the ruminal protozoan Polyplastron multivesiculatum and a stable clone expressing xylanase activity was isolated. The encoded enzyme belongs to the glycoside hydrolase family 11, and phylogenetic analysis indicates a closer relationship with catalytic domains from Gram-positive bacteria than the other fibrolytic eukaryotes from the rumen, the anaerobic fungi.

13C and 1H nuclear magnetic resonance study of glycogen futile cycling in strains of the genus Fibrobacter

We investigated the carbon metabolism of three strains of Fibrobacter succinogenes and one strain of Fibrobacter intestinalis. The four strains produced the same amounts of the metabolites succinate, acetate, and formate in approximately the same ratio (3.7/1/0.3). The four strains similarly stored glycogen during all growth phases, and the glycogen-to-protein ratio was close to 0.6 during the exponential growth phase. 13C nuclear magnetic resonance (NMR) analysis of [1-13C]glucose utilization by resting cells of the four strains revealed a reversal of glycolysis at the triose phosphate level and the same metabolic pathways. Glycogen futile cycling was demonstrated by 13C NMR by following the simultaneous metabolism of labeled [13C]glycogen and exogenous unlabeled glucose. The isotopic dilutions of the CH2 of succinate and the CH3 of acetate when the resting cells were metabolizing [1-13C]glucose and unlabeled glycogen were precisely quantified by using 13C-filtered spin-echo difference 1H NMR spectroscopy. The measured isotopic dilutions were not the same for succinate and acetate; in the case of succinate, the dilutions reflected only the contribution of glycogen futile cycling, while in the case of acetate, another mechanism was also involved. Results obtained in complementary experiments are consistent with reversal of the succinate synthesis pathway. Our results indicated that for all of the strains, from 12 to 16% of the glucose entering the metabolic pathway originated from prestored glycogen. Although genetically diverse, the four Fibrobacter strains studied had very similar carbon metabolism characteristics.

Endoglucanase G from Fibrobacter succinogenes S85 belongs to a class of enzymes characterized by a basic C-terminal domain

A 3.6-kb fragment of the Fibrobacter succinogenes S85 DNA was sequenced and found to contain two open reading frames (ORFs) on the same strand separated by 242 nucleotide bases. The translated protein from ORF1 had a predicted mass of 52.3 kDa. In a region of 320 amino acid overlap, it shares a 35% identity with the b-chain of the glutamate synthase of Escherichia coli. The ORF2 protein encodes a 519 residue protein designated CelG. It consists of an ORF of 1557 bp, encoding a polypeptide of 54.5 kDa. The N-terminal region, which contains the catalytic domain, is linked to a C-terminal basic domain, which has a predicted isoelectric point of 10.8. The catalytic domain in endoglucanase G (CelG) is homologous to the family 5 (A) cellulases. The enzyme has an apparent mass of 55 kDa, a pH optimum of 5.5, and temperature optimum of 25 degrees C. It had a specific activity of 16.5 mumols x min(-1) x mg-1 on barley b-glucan and produced a mixture of cellooligosaccharides from the hydrolysis of acid swollen cellulose and cellooligosaccharides. Antiserum raised against the purified form of CelG in E. coli failed to react with proteins from the native organism when grown on either glucose or crystalline cellulose, but reverse transcription and polymerase chain reaction techniques using RNA from the native organism demonstrated that the celG gene was expressed constitutively. Its distribution amongst subspecies of Fibrobacter was restricted to F. succinogenes S85.

Gene sequence and analysis of protein domains of EGB, a novel family E endoglucanase from Fibrobacter succinogenes S85

The endoglucanase gene (endB) of Fibrobacter succinogenes S85 encodes a protein of 555 amino acids (EGB) with a M(r) of 62,500. EGB shows homology with cellulases belonging to family E. Residues involved in the catalytic activity of CelD from Clostridium thermocellum are also found in EGB. Structure predictions suggest that EGB, like CelD, comprises a large alpha-helical catalytic domain plus a beta-strand domain of unknown function located in the N-terminal part of the protein. Construction of a phylogenetic tree of family E catalytic domains revealed that EGB is closest to a cellodextrinase from Butyrivibrio fibrisolvens.