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.     

Co-utilization of polymerized carbon sources by Bacteroides ovatus grown in a two-stage continuous culture system.

Bacteroides ovatus NCTC 11153 was grown in a two-stage continuous culture system at various growth rates (vessel 1, D = 0.06 to 0.19 h-1; vessel 2, D = 0.03 to 0.09 h-1) on media containing mixtures of starch and arabinogalactan as carbon sources. The cell-associated enzyme activities needed to hydrolyze both substrates (amylase, arabinogalactanase, alpha-glucosidase, beta-galactosidase, and alpha-arabinofuranosidase) were variously influenced by growth rate and polysaccharide availability but were detected under all growth conditions tested. Measurements of residual carbohydrate in spent culture media showed that both polysaccharides were co-utilized during growth under putative C-limited conditions. The arabinogalactan was partly depolymerized in N-limited chemostats, and significant amounts of arabinose- and galactose-containing oligosaccharides accumulated in the cultures, indicating that starch was being preferentially utilized. Acetate, propionate, and succinate were the major fermentation products formed by C-limited bacteria, but under N limitation, lactate was also produced. Molar ratios of succinate increased concomitantly with the dilution rate in C-limited chemostats, whereas molar ratios of propionate decreased. During N-limited growth, however, decarboxylation of succinate to propionate was relatively independent of growth rate. Cell viability was higher in C-limited cultures compared with those grown under N limitation and was greatest at high dilution rates, irrespective of nutrient limitation.     

Co-utilization of polymerized carbon sources by Bacteroides ovatus grown in a two-stage continuous culture system

Bacteroides ovatus NCTC 11153 was grown in a two-stage continuous culture system at various growth rates (vessel 1, D = 0.06 to 0.19 h-1; vessel 2, D = 0.03 to 0.09 h-1) on media containing mixtures of starch and arabinogalactan as carbon sources. The cell-associated enzyme activities needed to hydrolyze both substrates (amylase, arabinogalactanase, alpha-glucosidase, beta-galactosidase, and alpha-arabinofuranosidase) were variously influenced by growth rate and polysaccharide availability but were detected under all growth conditions tested. Measurements of residual carbohydrate in spent culture media showed that both polysaccharides were co-utilized during growth under putative C-limited conditions. The arabinogalactan was partly depolymerized in N-limited chemostats, and significant amounts of arabinose- and galactose-containing oligosaccharides accumulated in the cultures, indicating that starch was being preferentially utilized. Acetate, propionate, and succinate were the major fermentation products formed by C-limited bacteria, but under N limitation, lactate was also produced. Molar ratios of succinate increased concomitantly with the dilution rate in C-limited chemostats, whereas molar ratios of propionate decreased. During N-limited growth, however, decarboxylation of succinate to propionate was relatively independent of growth rate. Cell viability was higher in C-limited cultures compared with those grown under N limitation and was greatest at high dilution rates, irrespective of nutrient limitation.     

Utilization of starch and synthesis of a combined amylase/αα-glucosidase by the human colonic anaerobe Bacteroides ovatus

Bacteroides ovatus preferentially utilized starch and pectin when grown on a mixture of polysaccharides in batch culture, indicating that these carbohydrates are important substrates for the bacterium in the human large intestine. Further studies on starch breakdown showed that continuous cultures grew on the polysaccharide when it provided the sole carbohydrate source, to yield a single hydrolytic product at low dilution rates ( D = 0·04 h⁻¹), with an estimated molecular mass of 13 kDa. In contrast, two major types of oligomeric products were formed at higher dilution rates ( D = 0·44 h⁻¹), with approximate molecular weights of 11 and 140 kDa. Analysis of cell-associated starch-degrading enzymes produced by Bact. ovatus using ion exchange chromatography and HPLC gel-filtration showed that amylase and α-glucosidase activities eluted in the same fractions. The single peak containing amylase and α-glucosidase activities obtained by HPLC gel-filtration chromatography corresponded to a molecular mass of approximately 140 kDa, and activity staining of gels for α-glucosidase activity after polyacrylamide gel electrophoresis, in the presence of sodium dodecyl sulphate, gave an estimated molecular mass of 70 kDa, indicating this enzyme to be a dimer. After renaturation, the 70 kDa band was cut from the gels and solubilized. The extract hydrolysed gelatinized starch and p -nitrophenyl-α- D -glucopyranoside.     

Influence of mucin on glycosidase, protease and arylamidase activities of human gut bacteria grown in a 3-stage continuous culture system

Human intestinal bacteria were grown in a 3-stage continuous culture system on a medium containing complex polysaccharides and proteins as carbon and nitrogen sources. Selected bacterial populations were enumerated and glycosidase, protease and arylamidase activities measured. Comparison of arylamidase and glycosidase activities in the multichamber system (MCS) and faeces showed that the predominant faecal enzymes were also produced by bacteria growing in the MCS. After 48 d operation, porcine gastric mucin (5.8 g/d) was independently fed to vessel 1. Elevated levels of volatile fatty acid (VFA) formation showed that the glycoprotein was actively fermented. The increase in carbohydrate availability as a result of breakdown of the mucin oligosaccharides stimulated bacterial growth and activities. The enzymological measurements showed that mucin increased production of both cell-bound and extracellular glycosidases, such as β-galactosidase, α-glucosidase and N-acetyl-β-glucosaminidase. Protease activities were profoundly influenced by mucin. These were largely cell-bound in non-mucin cultures but were predominantly extracellular and collagenolytic when mucin was present. Experiments with protease inhibitors showed that cysteine proteases were the major cell-bound and extracellular enzymes in both mucin and non-mucin cultures, but that serine and metalloproteases were also present. The effect of mucin on arylamidase formation was less marked, although there was increased production of these enzymes in vessels 1 and 2 of the MCS. These results suggest that host-produced substances such as mucin glycoprotein may play a role in modulating the growth and activity of bacteria growing in the human large intestine.     

Influence of mucin on glycosidase, protease and arylamidase activities of human gut bacteria grown in a 3-stage continuous culture system

Human intestinal bacteria were grown in a 3-stage continuous culture system on a medium containing complex polysaccharides and proteins as carbon and nitrogen sources. Selected bacterial populations were enumerated and glycosidase, protease and arylamidase activities measured. Comparison of arylamidase and glycosidase activities in the multichamber system (MCS) and faeces showed that the predominant faecal enzymes were also produced by bacteria growing in the MCS. After 48 d operation, porcine gastric mucin (5.8 g/d) was independently fed to vessel 1. Elevated levels of volatile fatty acid (VFA) formation showed that the glycoprotein was actively fermented. The increase in carbohydrate availability as a result of breakdown of the mucin oligosaccharides stimulated bacterial growth and activities. The enzymological measurements showed that mucin increased production of both cell-bound and extracellular glycosidases, such as beta-galactosidase, alpha-glucosidase and N-acetyl-beta-glucosaminidase. Protease activities were profoundly influenced by mucin. These were largely cell-bound in non-mucin cultures but were predominantly extracellular and collagenolytic when mucin was present. Experiments with protease inhibitors showed that cysteine proteases were the major cell-bound and extracellular enzymes in both mucin and non-mucin cultures, but that serine and metalloproteases were also present. The effect of mucin on arylamidase formation was less marked, although there was increased production of these enzymes in vessels 1 and 2 of the MCS. These results suggest that host-produced substances such as mucin glycoprotein may play a role in modulating the growth and activity of bacteria growing in the human large intestine.     

Factors affecting the formation of polysaccharide depolymerase and glycoside hydrolyase enzymes by Butyrivibrio fibrisolvens NCDO 2249

Specific activities of hemicellulose-degrading polysaccharide depolymerase and glycoside hydrolase enzymes were measured in batch and continuous cultures of Butyrivibrio fibrisolvens NCDO 2249 grown on cellobiose or a hemicellulosic carbohydrate. Enzyme activities were influenced by the growth substrate and by the rate and stage of growth of the micro-organism. In cellobiose batch cultures specific activities were maximal as the growth rate declined and in the initial stages of the stationary phase. The growth substrate did not affect the range of glycoside hydrolases formed, although specific activities were substrate-dependent, with activity increases (up to 200-fold) occurring in enzymes essential for effective substrate utilization. Appreciable xylanase activity was present only in xylan-grown cultures. The substrate effects were also evident in chemostat cultures. The activity response of the nine enzymes monitored to growth rate changes differed in that while the activity of some enzymes, including xylanase, declined at high dilution rates the activities of others were not growth rate-dependent and were maintained over the range of dilution rates examined. Exocellular activities were detected only in spent media from cultures grown with a polymeric (hemicellulosic) carbohydrate.     

The production of plant cell wall polysaccharide-degrading enzymes by hemicellulolytic rumen bacterial isolates grown on a range of carbohydrate substrates

Several cultures of bacteria, isolated from the rumen, that were able to utilize plant cell wall structural polysaccharides were grown on a range of carbohydrate substrates and the activities of the principal polysaccharide-degrading enzymes determined. The esterase activity was also monitored. The extent of hemicellulose degradation and utilization by the isolates was comparable with that of the hemicellulolytic type strains. Enzyme activities in all of the cultures examined were affected by the carbon source in the growth medium. Many responses were strain specific, although growth on glucose (or cellobiose and maltose to a lesser extent) resulted in reduced activities in most of the organisms examined, whilst polysaccharidic substrates resulted in higher levels of the appropriate polysaccharidase. However, enzyme activity was detectable in some isolates after culture on mono- or disaccharides in the absence of the principal or related polysaccharide substrate.     

The effect of the carbohydrate growth substrate on the glycosidase activity of hemicellulose-degrading rumen bacterial isolates

Thirteen strains of hemicellulose-degrading bacteria isolated from the rumen were grown on ten different monosaccharide, disaccharide and hemicellulosic poly-saccharide substrates in vitro , and the range and specific activities of the glycosidase enzymes formed were determined. Alkaline phosphatase activities were also measured. The specific activities were affected by the carbohydrate source supplied in the growth medium and were usually reduced in glucose grown cells, and less frequently following growth on cellobiose; the responses to other substrates were both enzyme and organism dependent. In several of the strains examined many of the enzymes were found following growth on all of the substrates tested, although there were wide variations in the specific activities. The activities of several of the glycosidases were increased after growth on hemicellulosic polysaccharides.     

Hemicellulose-degrading Enzymes Synthesized by Rumen Bacteria

Over 100 bacterial cultures isolated from ovine rumen contents by enrichment techniques in polysaccharide-containing media were examined for the ability to degrade plant cell wall structural polysaccharides. Approximately two-thirds of the isolates retained were Gram negative and amongst the coccoid isolates diplococci predominated. Many of the rods examined were piliated and/or flagellated. Thirty of the more active xylan- and arabinan-degrading isolates were examined for both the production and activity of the principal polysaccharidase and glycosidase enzymes associated with plant cell wall polysaccharide hydrolysis, following culture in a hemicellulose containing growth medium. The wide range of glycosidase activities detected in these hemicellulolytic isolates was evidence for their rôle in the breakdown of dietary polysaccharides in the rumen.     

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.     

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.     

Production of cell-bound and vesicle-associated trypsin-like protease, alkaline phosphatase and N-acetyl-beta-glucosaminidase by Bacteroides gingivalis strain W50

Bacteroides gingivalis strain W50 was grown in batch and continuous culture on complex medium with haemin. In batch culture, cell-bound levels of trypsin-like protease (EC 3.4.21.4), alkaline phosphatase (EC 3.1.3.1) and N-acetyl-beta-glucosaminidase (EC 3.2.1.30) increased during the exponential phase of growth. These enzyme activities were also detected in extracellular vesicles and in extracellular soluble forms in the supernatant fluid, but in lower amounts per unit biomass compared to cell-bound levels. In continuous culture, at high relative growth rates (0.7-0.9 murel), the highest proportions of enzyme activities were cell-bound. In contrast, at low relative growth rates (0.1-0.2 murel), highest enzyme levels were detected in the extracellular vesicle fraction. Levels of extracellular soluble enzymes were always low compared to cell-bound or extracellular vesicle levels, but were highest at low relative growth rates. All three enzymes appeared to be relatively stable in their soluble forms. Vesicle production appeared to be associated with actively growing cells but was influenced by growth rate. The results are consistent with the hypothesis that cell-bound 'periplasmic' enzymes are encapsulated into vesicles which are subsequently released by the cells. Therefore, levels of total extracellular enzyme (extracellular vesicle plus extracellular soluble) may depend on the rate of vesicle formation superimposed on the rates of production of 'periplasmic' enzymes in the cell.     

锗对霍山石斛类原球茎悬浮培养细胞生长和多糖合成及氧化还原态的影响

为解决霍山石斛类原球茎液体培养细胞生长缓慢和代谢水平低下的问题,研究了不同浓度的锗(GeO2)对霍山石斛类原球茎增殖、多糖合成及碳氮利用的影响,分析了类原球茎细胞内还原糖、可溶性蛋白质含量、抗氧化酶活性以及细胞氧化还原态的变化。结果表明,适当浓度的二氧化锗(4.0mg/L)显著促进霍山石斛类原球茎的增殖和多糖的积累,最大细胞干重为32.6g/L,最大多糖产量为3.78g/L;显著提高胞内还原糖和可溶性蛋白质含量,超氧化物歧化酶和过氧化氢酶的活性明显升高,而过氧化物酶的活性则有所降低;氧化还原态分析发现,二氧化锗处理的细胞内还原型谷胱甘肽/氧化型谷胱甘肽的值明显提高,谷胱甘肽还原酶活性升高。添加适量的二氧化锗有利于细胞生长和多糖合成。     

Role of starch as a substrate for Bacteroides vulgatus growing in the human colon.

Bacteroides vulgatus is the numerically predominant Bacteroides species in the human colonic microflora. Unlike other colonic Bacteroides species, B. vulgatus is not a versatile utilizer of polysaccharides. The only types of polysaccharide that support rapid growth and high growth yields by all strains are the starches amylose and amylopectin. Amylase and alpha-glucosidase activities are among the highest found in a bacterial fraction obtained from human feces. This observation raised the question of whether B. vulgatus was the source of the fecal enzymes. Both alpha-glucosidase and amylase were produced at 20- to 40-fold-higher levels when B. vulgatus was grown on maltose, amylose, or amylopectin than when B. vulgatus was grown on glucose or other monosaccharides. Both enzymes had the same pI (4.6 to 5.0) and undenatured molecular weight (150,000). The pIs and molecular weights of the B. vulgatus amylase and alpha-glucosidase were the same as those of the fecal enzymes. To determine whether the B. vulgatus alpha-glucosidase was identical to the fecal alpha-glucosidase, we partially purified the B. vulgatus enzyme and raised an antiserum against it. Using this antiserum, we showed that all strains of B. vulgatus produced the same enzyme. The antiserum did not detect the B. vulgatus alpha-glucosidase in the bacterial fraction from human feces, even when a partially purified preparation of the fecal enzyme was used. Thus the alpha-glucosidase activity in the bacterial fraction from human feces is not the B. vulgatus enzyme.     

Role of starch as a substrate for Bacteroides vulgatus growing in the human colon

Bacteroides vulgatus is the numerically predominant Bacteroides species in the human colonic microflora. Unlike other colonic Bacteroides species, B. vulgatus is not a versatile utilizer of polysaccharides. The only types of polysaccharide that support rapid growth and high growth yields by all strains are the starches amylose and amylopectin. Amylase and alpha-glucosidase activities are among the highest found in a bacterial fraction obtained from human feces. This observation raised the question of whether B. vulgatus was the source of the fecal enzymes. Both alpha-glucosidase and amylase were produced at 20- to 40-fold-higher levels when B. vulgatus was grown on maltose, amylose, or amylopectin than when B. vulgatus was grown on glucose or other monosaccharides. Both enzymes had the same pI (4.6 to 5.0) and undenatured molecular weight (150,000). The pIs and molecular weights of the B. vulgatus amylase and alpha-glucosidase were the same as those of the fecal enzymes. To determine whether the B. vulgatus alpha-glucosidase was identical to the fecal alpha-glucosidase, we partially purified the B. vulgatus enzyme and raised an antiserum against it. Using this antiserum, we showed that all strains of B. vulgatus produced the same enzyme. The antiserum did not detect the B. vulgatus alpha-glucosidase in the bacterial fraction from human feces, even when a partially purified preparation of the fecal enzyme was used. Thus the alpha-glucosidase activity in the bacterial fraction from human feces is not the B. vulgatus enzyme.     

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.     

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.     

Effects of auxin on wall polysaccharide composition and enzyme activity during extension-growth of Pellia (Bryophyta)

Auxin-induced changes in cell wall polysaccharide composition and enzyme activity of seta segments from the liverwort Pellia epiphylla (L.) Corda were studied using colorimetric, gas chromatographic, radioactive tracer, and viscometric techniques. Extension-growth of segments doubled in the presence of aqueous 10 μ M indole-3-acctic acid (IAA) ± 50 m M glucose. IAA-enhanced growth was accompanied by (1) enhanced synthesis of all wall polysaccharides but cellulose, (2) increase in the relative glucose content of neutral wall sugars, and (3) change in the activity of wall-bound glycosidase relative to controls, but no change in the activity of cellulase. Galactose and mannose (50 m M ) suppressed auxin enhancement of both growth and wall synthesis. These findings suggest that auxin-mediated extension-growth of Pellia setae is dependent upon the maintenance of non-cellulosic cell-wall synthesis.