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.     

Genetic analysis of a locus on the Bacteroides ovatus chromosome which contains xylan utilization genes.

Bacteroides ovatus, a gram-negative obligate anaerobe found in the human colon, can utilize xylan as a sole source of carbohydrate. Previously, a 3.8-kbp segment of B. ovatus chromosomal DNA, which contained genes encoding a xylanase (xylI) and a bifunctional xylosidase-arabinosidase (xsa), was cloned, and expression of the two genes was studied in Escherichia coli (T. Whitehead and R. Hespell, J. Bacteriol. 172:2408-2412, 1990). In the present study, we have used segments of the cloned region to construct insertional disruptions in the B. ovatus chromosomal locus containing these two genes. Analysis of these insertional mutants demonstrated that (i) xylI and xsa are probably part of the same operon, with xylI upstream of xsa, (ii) the true B. ovatus promoter was not cloned on the 3.5-kbp DNA fragment which expressed xylanase and xylosidase in E. coli, (iii) there is at least one gene upstream of xylI which could encode an arabinosidase, and (iv) xylosidase rather than xylanase may be a rate-limiting step in xylan utilization. Insertional mutations in the xylI-xsa locus reduced the rate of growth on xylan, but the concentration of residual sugars at the end of growth was the same as that with the wild type. Thus, a slower rate of growth on xylan was not accompanied by less extensive digestion of xylan. Mutants in which xylI had been disrupted still expressed some xylanase activity. This second activity was associated with membranes and produced xylose from xylan, whereas the xylI gene product partitioned primarily with the soluble fraction and produced xylobiose from xylan.     

Genetic analysis of a locus on the Bacteroides ovatus chromosome which contains xylan utilization genes.

Bacteroides ovatus, a gram-negative obligate anaerobe found in the human colon, can utilize xylan as a sole source of carbohydrate. Previously, a 3.8-kbp segment of B. ovatus chromosomal DNA, which contained genes encoding a xylanase (xylI) and a bifunctional xylosidase-arabinosidase (xsa), was cloned, and expression of the two genes was studied in Escherichia coli (T. Whitehead and R. Hespell, J. Bacteriol. 172:2408-2412, 1990). In the present study, we have used segments of the cloned region to construct insertional disruptions in the B. ovatus chromosomal locus containing these two genes. Analysis of these insertional mutants demonstrated that (i) xylI and xsa are probably part of the same operon, with xylI upstream of xsa, (ii) the true B. ovatus promoter was not cloned on the 3.5-kbp DNA fragment which expressed xylanase and xylosidase in E. coli, (iii) there is at least one gene upstream of xylI which could encode an arabinosidase, and (iv) xylosidase rather than xylanase may be a rate-limiting step in xylan utilization. Insertional mutations in the xylI-xsa locus reduced the rate of growth on xylan, but the concentration of residual sugars at the end of growth was the same as that with the wild type. Thus, a slower rate of growth on xylan was not accompanied by less extensive digestion of xylan. Mutants in which xylI had been disrupted still expressed some xylanase activity. This second activity was associated with membranes and produced xylose from xylan, whereas the xylI gene product partitioned primarily with the soluble fraction and produced xylobiose from xylan.     

Comparison of proteins involved in chondroitin sulfate utilization by three colonic Bacteroides species

Three species of colonic bacteria can ferment the mucopolysaccharide chondroitin sulfate: Bacteroides ovatus, Bacteroides sp. strain 3452A (an unnamed DNA homology group), and B. thetaiotaomicron. Proteins associated with the utilization of chondroitin sulfate by B. thetaiotaomicron have been characterized previously. In this report we compare chondroitin lyases and chondroitin sulfate-associated outer membrane polypeptides of B. ovatus and Bacteroides sp. strain 3452A with those of B. thetaiotaomicron. All three species produce two soluble cell-associated chondroitin lyases, chondroitin lyase I and II. Purified enzymes from the three species have similar pH optima, Km values, and molecular weights. However, peptide mapping experiments show that the chondroitin lyases from B. ovatus and Bacteroides sp. strain 3452A are not identical to those of B. thetaiotaomicron. A cloned gene that codes for the chondroitin lyase II from B. thetaiotaomicron hybridized on a Southern blot with DNA from B. ovatus or Bacteroides sp. strain 3452A only when low-stringency conditions were used. Antibody to chondroitin lyase II from B. thetaiotaomicron did not cross-react with chondroitin lyase II from B. ovatus or Bacteroides sp. strain 3452A. Chondroitin lyase activity in all three species was inducible by chondroitin sulfate. B. ovatus and Bacteroides sp. strain 3452A, like B. thetaiotaomicron, have outer membrane polypeptides that appear to be regulated by chondroitin sulfate, but the chondroitin sulfate-associated outer membrane polypeptides differ in molecular weight. Despite these differences, the ability of intact bacteria to utilize chondroitin sulfate, as indicated by growth yields in carbohydrate-limited continuous culture and the rate at which the chondroitin lyases were induced, was the same for all three species.     

Effect of different carbohydrates on growth, polysaccharidase and glycosidase production by Bacteroides ovatus, in batch and continuous culture

Bacteroides ovatus was grown in batch culture on 12 different carbon sources (five polysaccharides, seven monosaccharides and disaccharides). Specific growth rates were determined for each substrate together with polysaccharidase and glycosidase activities. Growth rates on polymerized carbohydrates were as fast or faster than on corresponding simple sugars, demonstrating that the rate of polysaccharide depolymerization was not a factor limiting growth. Bacteroides ovatus synthesized a large range of polymer-degrading enzymes. These polysaccharidases and glycosidases were generally repressed during growth on simple sugars, but arabinose was required for optimal production of alpha-arabinofuranosidase. Polysaccharidase and glycosidase activities were measured in continuous cultures grown with either xylan or guar gum under putative carbon limitation. With the exception of beta-xylosidase, activities of the polymer-degrading enzymes were inversely related to growth rate. This correlated with polysaccharide utilization which was greatest at low dilution rates. These results show that Bact. ovatus is highly adapted for growth on polymerized carbohydrate in the human colon and confirm that the utilization of polysaccharides is partly regulated at the level of enzyme synthesis.     

Induction of insulin secretion in engineered liver cells by nitric oxide

Background  

Type 1 Diabetes Mellitus results from an autoimmune destruction of the pancreatic beta cells, which produce insulin. The lack of insulin leads to chronic hyperglycemia and secondary complications, such as cardiovascular disease. The currently approved clinical treatments for diabetes mellitus often fail to achieve sustained and optimal glycemic control. Therefore, there is a great interest in the development of surrogate beta cells as a treatment for type 1 diabetes. Normally, pancreatic beta cells produce and secrete insulin only in response to increased blood glucose levels. However in many cases, insulin secretion from non-beta cells engineered to produce insulin occurs in a glucose-independent manner. In the present study we engineered liver cells to produce and secrete insulin and insulin secretion can be stimulated via the nitric oxide pathway.     

Comparison of proteins involved in chondroitin sulfate utilization by three colonic Bacteroides species.

Three species of colonic bacteria can ferment the mucopolysaccharide chondroitin sulfate: Bacteroides ovatus, Bacteroides sp. strain 3452A (an unnamed DNA homology group), and B. thetaiotaomicron. Proteins associated with the utilization of chondroitin sulfate by B. thetaiotaomicron have been characterized previously. In this report we compare chondroitin lyases and chondroitin sulfate-associated outer membrane polypeptides of B. ovatus and Bacteroides sp. strain 3452A with those of B. thetaiotaomicron. All three species produce two soluble cell-associated chondroitin lyases, chondroitin lyase I and II. Purified enzymes from the three species have similar pH optima, Km values, and molecular weights. However, peptide mapping experiments show that the chondroitin lyases from B. ovatus and Bacteroides sp. strain 3452A are not identical to those of B. thetaiotaomicron. A cloned gene that codes for the chondroitin lyase II from B. thetaiotaomicron hybridized on a Southern blot with DNA from B. ovatus or Bacteroides sp. strain 3452A only when low-stringency conditions were used. Antibody to chondroitin lyase II from B. thetaiotaomicron did not cross-react with chondroitin lyase II from B. ovatus or Bacteroides sp. strain 3452A. Chondroitin lyase activity in all three species was inducible by chondroitin sulfate. B. ovatus and Bacteroides sp. strain 3452A, like B. thetaiotaomicron, have outer membrane polypeptides that appear to be regulated by chondroitin sulfate, but the chondroitin sulfate-associated outer membrane polypeptides differ in molecular weight. Despite these differences, the ability of intact bacteria to utilize chondroitin sulfate, as indicated by growth yields in carbohydrate-limited continuous culture and the rate at which the chondroitin lyases were induced, was the same for all three species.     

Effect of different carbohydrates on growth, polysaccharidase and glycosidase production by Bacteroides ovatus, in batch and continuous culture

Bacteroides ovatus was grown in batch culture on 12 different carbon sources (five polysaccharides, seven monosaccharides and disaccharides). Specific growth rates were determined for each substrate together with polysaccharidase and glycosidase activities. Growth rates on polymerized carbohydrates were as fast or faster than on corresponding simple sugars, demonstrating that the rate of polysaccharide depolymerization was not a factor limiting growth. Bacteroides ovatus synthesized a large range of polymer-degrading enzymes. These polysaccharidases and glycosidases were generally repressed during growth on simple sugars, but arabinose was required for optimal production of α-arabinofuranosidase. Polysaccharidase and glycosidase activities were measured in continuous cultures grown with either xylan or guar gum under putative carbon limitation. With the exception of β-xylosidase, activities of the polymer-degrading enzymes were inversely related to growth rate. This correlated with polysaccharide utilization which was greatest at low dilution rates. These results show that Bact. ovatus is highly adapted for growth on polymerized carbohydrate in the human colon and confirm that the utilization of polysaccharides is partly regulated at the level of enzyme synthesis. and accepted 8 June 1989     

Studies on mixed populations of human intestinal bacteria grown in single-stage and multistage continuous culture systems.

Mixed intestinal bacteria were grown for 336 h in two identical single-stage chemostats at low growth rates in a carbohydrate-limited medium. Complex bacterial populations were maintained and anaerobes always outnumbered aerobes. The predominant organisms belonged to the genera Bacteroides, Bifidobacterium, Lactobacillus, Clostridium, Eubacterium, Propionbacterium, Peptococcus, and Peptostreptococcus. Bacteroides species predominated in both fermentors, particularly B. ovatus and B. thetaiotaomicron. A high degree of reproducibility of bacteriological and fermentation product data was obtained in these experiments. When gut contents were inoculated into a five-stage continuous culture system (retention time of 79 or 38 h) containing soya bran, the medium flow rate had little quantitative effect on the formation of acidic fermentation products; however, more oxidized fermentation acids were produced at the higher retention time. Diverse bacterial populations were maintained in every vessel at each flow rate. Bacteroides fragilis group organisms, especially B. ovatus, were numerically the most important. The viability of bacteria decreased through the system, especially at a retention time of 79 h, when the bacteria were growing under severely nutrient-limited conditions.     

Evaluation of the RAPID ID 32A system for the identification of Bacteroides fragilis and related organisms

S.A. JENKINS, D.B. DRUCKER, M.G.L. KEANEY AND L.A. GANGULI. 1991. This study evaluated the ability of a rapid identification system for anaerobic bacteria. ATB 32A, now renamed RAPID ID 32A (API-bioMérieux UK Ltd., Basingstoke), to identify accurately 74 strains of the 'B. fragilis group'. ATB 32A identified correctly 78.4% of strains to species level, without supplemental tests. The percentage of strains identified to species level rose to 94.6% when a supplementary test (advised by bioMérieux) for catalase production was used to differentiate between Bacteroides ovatus and Bacteroides uniformis. RAPID ID 32A is a rapid, accurate method for the identification of members of the 'B. fragilis group' isolated within a routine clinical laboratory.     

Use of randomly cloned DNA fragments for identification of Bacteroides thetaiotaomicron.

Randomly cloned fragments of DNA from Bacteroides thetaiotaomicron were used as hybridization probes for differentiation of B. thetaiotaomicron from closely related Bacteroides species. HindIII digestion fragments of DNA from B. thetaiotaomicron (type strain) were inserted into plasmid pBR322 and labeled with [alpha-32P]dCTP by nick translation. These labeled plasmids were screened for hybridization to HindIII digests of chromosomal DNA from type strains of the following human colonic Bacteroides species: B. thetaiotaomicron, Bacteroides ovatus, reference strain 3452-A (formerly part of B. distasonis), Bacteroides uniformis, Bacteroides fragilis, Bacteroides vulgatus, Bacteroides distasonis, Bacteroides eggerthii, and reference strain B5-21 (formerly B. fragilis subsp. a). Two of the five cloned fragments hybridized only to DNA from B. thetaiotaomicron. Each of these two fragments hybridized to the same DNA restriction fragment in five strains of B. thetaiotaomicron other than the strain from which the DNA was cloned. One of the cloned fragments (pBT2) was further tested for specificity by determining its ability to hybridize to DNA from 65 additional strains of colonic Bacteroides.     

Characteristics of Bacteroides isolates from the cecum of conventional mice.

Bacteroides isolates from the cecum of conventional mice were characterized and grouped according to their ability to ferment or hydrolyze carbohydrates and other compounds believed to be present in the intestinal ecosystem. The isolates were divided into 11 groups on the basis of the fermentation of glucose, cellobiose, gum arabic and xylan (hemicelluloses), N-acetylglucosamine, and dextrin; the hydrolysis of starch and casein (proteolysis); and the production of indole. Stock cultures of B. fragilis, B. distasonis, B. ovatus, B. vulgatus, and B. ruminicola were characterized in the same way. The strains isolated most frequently from the mouse cecum resembled B. fragilis (except that arabinose was fermented) and B. thetaiotaomicron.     

Escherichia coli binary culture engineered for direct fermentation of hemicellulose to a biofuel

Metabolic engineering has created several Escherichia coli biocatalysts for production of biofuels and other useful molecules. However, the inability of these biocatalysts to directly use polymeric substrates necessitates costly pretreatment and enzymatic hydrolysis prior to fermentation. Consolidated bioprocessing has the potential to simplify the process by combining enzyme production, hydrolysis, and fermentation into a single step but requires a fermenting organism to multitask by producing both necessary enzymes and target molecules. We demonstrate here a binary strategy for consolidated bioprocessing of xylan, a complex substrate requiring six hemicellulases for complete hydrolysis. An integrated modular approach was used to design the two strains to function cooperatively in the process of transforming xylan into ethanol. The first strain was engineered to coexpress two hemicellulases. Recombinant enzymes were secreted to the growth medium by a method of lpp deletion with over 90% efficiency. Secreted enzymes hydrolyzed xylan into xylooligosaccharides, which were taken in by the second strain, designed to use the xylooligosaccharides for ethanol production. Cocultivation of the two strains converted xylan hemicellulose to ethanol with a yield about 55% of the theoretical value. Inclusion of other three hemicellulases improved the ethanol yield to 70%. Analysis of the culture broth showed that xylooligosaccharides with four or more xylose units were not utilized, suggesting that improving the use of higher xyloogligomers should be the focus in future efforts. This is the first demonstration of an engineered binary culture for consolidated bioprocessing of xylan. The modular design should allow the strategy to be adopted for a broad range of biofuel and biorefinery products.     

Properties of Bacteroides fragilis antigens with specificity B

Five different serologically active preparations were extracted from Bacteroides ovatus ATCC 8483 strain. These substances and sixteen preparations of culture supernatants all giving a positive reaction with antiserum of serotype B were used as inhibitors in haemagglutination inhibition test. The results showed that substances obtained from the culture supernatants differ from endotoxin of Bacteroides ovatus ATCC 8483 serotype B.     

Optimization of five environmental factors to increase beta‐propeller phytase production in Pichia pastoris and impact on the physiological response of the host

Recently, we engineered Pichia pastoris Mut^s strains to produce several beta‐propeller phytases, one from Bacillus subtilis and the others designed by a structure‐guided consensus approach. Furthermore, we demonstrated the ability of P. pastoris to produce and secrete these phytases in an active form in shake‐flask cultures. In the present work, we used a design of experiments strategy (Simplex optimization method) to optimize five environmental factors that define the culture conditions in the induction step to increase beta‐propeller phytase production in P. pastoris bioreactor cultures. With the optimization process, up to 347,682 U (82,814 U/L or 6.4 g/L culture medium) of phytase at 68 h of induction was achieved. In addition, the impact of the optimization process on the physiological response of the host was evaluated. The results indicate that the increase in extracellular phytase production through the optimization process was correlated with an increase in metabolic activity of P. pastoris, shown by an increase in oxygen demand and methanol consumption, that increase the specific growth rate. The increase in extracellular phytase production also occurred with a decrease in extracellular protease activity. Moreover, the optimized culture conditions increased the recombinant protein secretion by up to 88%, along with the extracellular phytase production efficiency per cell. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:1377–1385, 2013     

Secretion of Insulinotropic Proteins by Commensal Bacteria: Rewiring the Gut To Treat Diabetes

Here, we show that commensal bacteria can stimulate intestinal epithelial cells to secrete insulin in response to glucose. Commensal strains were engineered to secrete the insulinotropic proteins GLP-1 and PDX-1. Epithelia stimulated by engineered strains and glucose secreted up to 1 ng ml⁻¹ of insulin with no significant background secretion.     

Screening for the presence of the insertion sequence IS1 in the genus Bacteroides

Abstract A specific DNA probe, containing a conserved region of the insertion sequence IS1, was hybridised to dot blots of total genomic DNA from 2 oral and 5 intestinal Bacteroides spp. Using Escherichia coli K12 as a positive control and Pseudomonas aeruginosa as a negative control, DNA homologous to the probe could not be detected in Bacteroides corporis, Bacteroides intermedius, Bacteroides ovatus, Bacteroides vulgatus, Bacteroides thetaiotaomicron or 2 strains of Bacteroides fragilis . The total DNA included plasmid DNA of 30.2, 42.7 and 42.7 MDa from B. fragilis, B. intermedius and B. corporis , respectively.
IS1 is commonly found in members of the Enterobacteriaceae, and it was concluded that the 2 groups of bacteria are not closely related.     

Esterase activities in Butyrivibrio fibrisolvens strains

Thirty strains of Butyrivibrio fibrisolvens isolated in diverse geographical locations were examined for esterase activity by using naphthyl esters of acetate, butyrate, caprylate, laurate, and palmitate. All strains possessed some esterase activity, and high levels of activity were observed with strains 49, H17c, S2, AcTF2, and LM8/1B. Esterase activity also was detected in other ruminal bacteria (Bacteroides ruminicola, Selenomonas ruminantium, Ruminobacter amylophilus, and Streptococcus bovis). For all B. fibrisolvens strains tested, naphthyl fatty acid esterase activity paralleled culture growth and was predominantly cell associated. With strains 49, CF4c, and S2, the activity was retained by protoplasts made from whole cells. Esterase activity was detected with all strains when grown on glucose, and some strains showed higher activity levels when grown on other substrates (larchwood xylan or citrus pectin). When nitrophenyl esters of fatty acids were used to measure esterase activity, generally four- to sevenfold-higher activity levels were detected, and with a number of strains substantial levels were found in the culture fluid. Cultures of these strains (H17c, NOR37, D1, and D30g) contained xylanase and acetyl xylan esterase activities, neither of which was associated to any great extent with the cells. Acetyl xylan esterase has not been previously detected in ruminal bacteria and may be important to overall digestion of forage by these organisms.     

Hydrolysis of dietary flavonoid glycosides by strains of intestinal Bacteroides from humans.

Rutin and quercitrin are hydrolysed to quercetin, and robinin is hydrolysed to kaempferol, by faecal flora from healthy subjects. The enzymes required for these hydrolyses, namely alpha-rhamnosidase and beta-galactosidase, were produced by some strains of Bacteroides distasonis; other strains, however, synthesized beta-glucosidase. The last-named enzyme was also elaborated by Bacteroides uniformis and Bacteroides ovatus. All the enzymes were produced constitutively. A cell-free extract of B. distasonis containing beta-glucosidase displayed an enzymic activity of 1 mumol/10 min per 10 mg of protein.     

Effects of methanol on the growth of gastrointestinal anaerobes

The effects of methanol on the growth of representative, predominant, anaerobic gut bacteria were studied. Growth yields and rates were determined in a base medium to which methanol was added to produce media with methanol concentrations varying, in twofold steps, over a concentration range of 0.01 to 25%, by volume. The growth of many of the organisms was completely inhibited by a methanol concentration equal to, or less than, 6.2%. Isolates representing cellulolytic species were completely inhibited at a methanol concentration of 3.1%, and inhibitory effects on the yield of some cellulolytic isolates were found at a methanol concentration as small as 0.01%. Although most of the organisms studied were inhibited at relatively small methanol concentrations, isolates of Selenomonas ruminantium, Bacteroides ovatus, and Fusobacterium necrophorum were relatively methanol resistant. A methanol concentration of 12.5% was required to completely inhibit S. ruminantium. Substantial growth of B. ovatus was obtained in media containing 12.5% methanol, and for F. necrophorum, substantial growth occurred in media containing 25% methanol. The yields of F. necrophorum strain B85 and S. ruminantium strain PC18 were enhanced by relatively small methanol concentrations and reduced with further methanol concentration increase Anaerobic, nonsporing gut bacteria exhibit a diversity of responses to methanol.