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In vitro fermentation of commercial α-gluco-oligosaccharide by faecal microbiota from lean and obese human subjects

Published online by Cambridge University Press:  02 November 2012

Shahrul R. Sarbini
Affiliation:
Department of Crop Science, Faculty of Agriculture and Food Science, Universiti Putra Malaysia, Jalan Nyabau, 97008 Bintulu, Sarawak, Malaysia
Sofia Kolida
Affiliation:
Department of Food and Nutritional Sciences, University of Reading, Whiteknights, PO Box 226, ReadingRG6 6AP, UK
Glenn R. Gibson
Affiliation:
Department of Food and Nutritional Sciences, University of Reading, Whiteknights, PO Box 226, ReadingRG6 6AP, UK
Robert A. Rastall*
Affiliation:
Department of Food and Nutritional Sciences, University of Reading, Whiteknights, PO Box 226, ReadingRG6 6AP, UK
*
*Corresponding author: Professor R. A. Rastall, fax +44 118 931 0080, email [email protected]
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Abstract

The fermentation selectivity of a commercial source of α-gluco-oligosaccharides (BioEcolians; Solabia) was investigated in vitro. Fermentation by faecal bacteria from four lean and four obese healthy adults was determined in anaerobic, pH-controlled faecal batch cultures. Inulin was used as a positive prebiotic control. Samples were obtained at 0, 10, 24 and 36 h for bacterial enumeration by fluorescent in situ hybridisation and SCFA analyses. Gas production during fermentation was investigated in non-pH-controlled batch cultures. α-Gluco-oligosaccharides significantly increased the Bifidobacterium sp. population compared with the control. Other bacterial groups enumerated were unaffected with the exception of an increase in the Bacteroides–Prevotella group and a decrease in Faecalibacterium prausnitzii on both α-gluco-oligosaccharides and inulin compared with baseline. An increase in acetate and propionate was seen on both substrates. The fermentation of α-gluco-oligosaccharides produced less total gas at a more gradual rate of production than inulin. Generally, substrates fermented with the obese microbiota produced similar results to the lean fermentation regarding bacteriology and metabolic activity. No significant difference at baseline (0 h) was detected between the lean and obese individuals in any of the faecal bacterial groups studied.

Type
Full Papers
Copyright
Copyright © The Authors 2012 

It is now well established that the composition of the colonic microbiota can be modified by the introduction of prebiotics to improve or maintain host health(Reference Gibson, Scott and Rastall1). The efficacy of a prebiotic can be evaluated by in vitro batch-culture fermentation systems which have been compared and validated against human and animal in vivo data(Reference Gibson and Fuller2). Batch-culture fermentation systems provide a simple, rapid and inexpensive method of evaluating the prebiotic potential of carbohydrates.

To date, the majority of studies on prebiotics have focused on inulin, fructo-oligosaccharides and galacto-oligosaccharides due to their selective fermentation by bifidobacteria and history of safe commercial use. Nevertheless, there are potential prebiotic oligosaccharides still under investigation, such as α-gluco-oligosaccharides. These gluco-oligosaccharides are selectively metabolised by Bifidobacterium, Lactobacillus and Bacteroides but are poorly metabolised by potentially pathogenic bacteria such as enterobacteria and Clostridium (Reference Chung and Day3). Even though they exhibit promising characteristics, the evidence is not sufficient to classify them as prebiotics presently(Reference Gibson4). All studies to date have been carried out by culture-dependent methods, which are not reliable for the analysis of complex bacterial samples. Therefore, further investigation using culture-independent (DNA-based) methods is needed to verify these initial findings.

The human gut microbiota is dominated by two major phyla, the Bacteroidetes and Firmicutes(Reference Eckburg, Bik and Bernstein5). A study has observed that genetically obese mice had a higher proportion of Firmicutes relative to Bacteroidetes compared with lean mice(Reference Ley, Bäckhed and Turnbaugh6). It is also thought that the gut microbiota of obese mice may be more efficient at salvaging energy from the diet than the microbiota of lean mice(Reference Turnbaugh, Ley and Mahowald7, Reference Bäckhed, Manchester and Semenkovich8). A further in vivo human study has suggested that obese individuals had a higher Firmicutes:Bacteroidetes ratio compared with lean ones(Reference Ley, Turnbaugh and Klein9). However, all the above-mentioned studies only determined changes in Bacteroidetes and Firmicutes, each containing various genera that have diverse metabolic capabilities. Identifying changes at the phylum rather than the genus level could be misleading. Some recent studies have failed to observe differences in Bacteroidetes between lean and obese individuals(Reference Collado, Isolauri and Laitinen10, Reference Duncan, Lobley and Holtrop11). Therefore, the role of the gut microbiota in obesity remains unclear. Some in vivo animal studies have demonstrated that the composition of the diet, not the obese state, resulted in changes of the gut microbiota(Reference Hildebrandt, Hoffmann and Sherrill-Mix12, Reference Murphy, Cotter and Healy13). This raises the possibility of developing prebiotics that influence the microbiota composition and could be consumed as part of a weight management diet.

The aim of the present study is to evaluate the fermentation selectivity of a commercial preparation of α-gluco-oligosaccharides (BioEcolians(14)) by the human faecal microbiota and to assess its prebiotic potential towards lean and obese adults.

Materials and methods

Materials

Unless stated otherwise, all reagents and chemicals used were purchased from Sigma Laboratories. α-Gluco-oligosaccharides were provided by Solabia (Pantin). Inulin Frutafit TEX (Sensus) with a degree of polymerisation (DP) >22 was used as a positive control.

Faecal inocula

Faecal samples were obtained from four lean human volunteers (BMI 19–23 kg/m2; age 30–36 years) and four obese human volunteers (BMI 35–40 kg/m2; age 30–36 years) who were free of known metabolic and gastrointestinal diseases (e.g. diabetes, ulcerative colitis, Crohn's disease, irritable bowel syndrome, peptic ulcers and cancer). The samples were collected on site, kept in an anaerobic cabinet (10 % H2, 10 % CO2 and 80 % N2) and used within a maximum of 15 min after collection. The samples were diluted 1:10 (w/w) in anaerobic PBS (0·1 mol/l, pH 7·4) and homogenised in a stomacher (Stomacher 400; Seward) for 2 min at normal speed.

In vitro fermentations

Sterile stirred batch-culture fermentation systems (50 ml working volume) were set up, and aseptically filled with 45 ml sterile, pre-reduced, basal medium (peptone water 2 g/l (Oxoid), yeast extract 2 g/l (Oxoid), NaCl 0·1 g/l, K2HPO4 0·04 g/l, KH2PO4 0·04 g/l, MgSO4.7H2O 0·01 g/l, CaCl2.6H2O 0·01 g/l, NaHCO3 2 g/l, Tween-80 2 ml (BDH), haemin 0·05 g/l, vitamin K1 10 μl, cysteine.HCl 0·5 g/l, bile salts 0·5 g/l, pH 7·0) and gassed overnight with O2-free N2 (15 ml/min). The carbohydrate substrates were added to the respective fermentation vessels just before the addition of the faecal slurry. Concentration of the test substrates was 1 % (w/v) in 50 ml culture fluid (0·5 g). The temperature was kept at 37°C and the pH was controlled between 6·7 and 6·9 using an automated pH controller (Fermac 260; Electrolab). Each vessel was inoculated with 5 ml of fresh faecal slurry (1:10, w/w). The batch cultures were run over a period of 36 h and 5 ml samples were obtained from each vessel at 0, 10, 24 and 36 h for fluorescent in situ hybridisation(Reference Jeanes, Haynes and Wilham15) and SCFA analysis. Finally, eight replicate batch culture fermentations were set up, each inoculated with one of eight different human faecal inocula (four lean and four obese).

Bacterial enumeration

Synthetic oligonucleotide probes targeting specific regions of the 16S ribosomal RNA molecule, labelled with the fluorescent dye Cy3, were utilised for the enumeration of bacterial groups: Chis150(Reference Franks, Harmsen and Raangs16), Lab158(Reference Harmsen, Elfferich and Schut17), Erec482(Reference Franks, Harmsen and Raangs16), Prop853(Reference Walker, Duncan and McWilliam Leitch18), Fpra655(Reference Hold, Schwiertz and Aminov19), Rbro730/Rfla729(Reference Harmsen, Raangs and He20), Bac303(Reference Manz, Amann and Ludwig21), Bif164(Reference Langendijk, Schut and Jansen22) and Ato291(Reference Harmsen, Wildeboer-Veloo and Grijpstra23) (Table 1). Samples (375 μl) obtained from each vessel at each sampling time were fixed for 4 h (4°C) in 1125 μl (4 %, w/v) paraformaldehyde. Fixed cells were centrifuged at 13 000 g for 5 min and washed twice in 1 ml filtered sterilised PBS. The washed cells were resuspended in 150 μl filtered PBS and stored in 150 μl ethanol (99 %) at − 20°C for at least 1 h before further processing. Samples (10 μl) were diluted in a suitable volume of PBS in order to obtain 20–100 fluorescent cells in each field of view and 20 μl of the above solution were added to each well of a six-well polytetrafluoroethylene/poly-l-lysine-coated slide (Tekdon, Inc.). The samples were dried for 15 min in a drying chamber (46°C). They were then dehydrated, using an alcohol series (50, 80 and 96 % (v/v) ethanol) for 3 min in each solution. Slides were returned in the drying oven for 2 min to evaporate excess ethanol before adding the hybridisation mixture. The hybridisation mixture (50 μl consisting of 5 μl probe and 45 μl hybridisation buffer) was added to each well and left to hybridise for 4 h in a microarray hybridisation incubator (Grant-Boekel). After hybridisation, slides were washed in 50 ml washing buffer for 15 min. They were then dipped in cold water for a few seconds and dried with compressed air. Thereafter, 5 μl of polyvinyl alcohol mounting medium with 1,4-diazabicyclo(2,2,2)octane were added onto each well and a cover slip was placed on each slide (20 mm, thickness no. 1; VWR). The slides were examined under an epifluorescence microscope (Eclipse 400; Nikon) using the Fluor 100 lens. For each well, fifteen different fields of view were enumerated.

Table 1 16S ribosomal RNA oligonucleotide probes used in the present study

Organic acid analyses

Analysis was performed using an ion-exclusion HPLC system (LaChrom Merck Hitachi) equipped with a pump (L-7100), an RI detector (L-7490) and an autosampler (L-7200). Data were collected using Jones Chromatography Limited for Windows 2.0 software. The column used was an ion-exclusion Rezex ROA-Organic Acid H+(8 %) (300 × 7·80 mm; Phenomenex). Guard columns were SecurityGuard™ Carbo-H+4 × 3·0 mm cartridges (Phenomenex). The eluent used was 0·0025 mm-H2SO4 in HPLC-grade water.

Samples (1 ml) from each fermentation time point were centrifuged at 13 000 g for 10 min. Supernatants were filtered through a 0·22 μm filter unit (Millipore) and 20 μl were injected into the HPLC, operating at a flow rate of 0·5 ml/min with a heated column at 84·2°C. The sample run-time was 35 min. Sample quantification was carried out using calibration curves for lactate, acetate, propionate and butyrate at concentrations of 12·5, 25, 50, 75 and 100 mm.

Rate of gas production

Sterile glass Balch tubes (18 × 150 mm; Bellco) containing 13·5 ml pre-reduced basal medium (peptone water 2 g/l (Oxoid), yeast extract 2 g/l (Oxoid), NaCl 0·1 g/l, K2HPO4 0·04 g/l, KH2PO4 0·04 g/l, MgSO4.7H2O 0·01 g/l, CaCl2.6H2O 0·01 g/l, NaHCO3 2 g/l, Tween-80 2 ml, haemin 0·05 g/l, vitamin K1 10 μl, cysteine.HCl 0·5 g/l, bile salts 0·5 g/l, pH 7·0) were placed in the anaerobic cabinet and kept overnight. Substrates (1:10, w/v) were added to the fermentation tubes just before the addition of the faecal inocula (1:10, w/v). The tubes were then sealed with a gas-impermeable butyl rubber septum (Bellco) and aluminium crimp (Sigma-Aldrich). The tubes were incubated at 37°C with constant agitation. The volume of gas generated by faecal bacteria from each substrate was measured every 3 h up to 36 h fermentation by inserting a sterile needle (BD, 23G X 1 inch) attached to a transducer (Gems Sensors) into the butyl rubber septum of each tube. The pressure build-up in the headspace was measured in pounds per square inch. After each measurement, the headspace of each tube was allowed to equilibrate with the atmosphere. The gas production experiments were performed in four replicates for each substrate. Quantification of gas volume (ml) was carried out using calibration curves of air pressure (pounds per square inch) by injecting known volumes of air into the culture tubes (0·5–7 ml).

Statistical analyses

Statistical analysis was performed using SPSS for Windows (version 16.0; SPSS, Inc.). One-way ANOVA and post hoc Tukey's tests were used to determine the significant difference of substrate used on bacterial group population, SCFA production and gas production. Principal component analysis was performed using XLSTAT-Pro software (Addinsoft) in accordance with Pearson's correlation test to identify correlated variables among the target bacterial groups at baseline (0 h) in the lean and obese faecal microbiota populations. Differences were deemed significant when P< 0·05.

Results

Bacterial enumeration

The average bacterial concentrations of the test substrates fermented by the lean and obese human faecal slurries are shown in Table 2. There was a significant increase in the Bif164 populations in the lean fermentations following the response to α-gluco-oligosaccharides at all time points compared with 0 h. Furthermore, the Bif164 populations at 36 h fermentation were significantly higher in α-gluco-oligosaccharides compared with inulin (P< 0·05). Other members of the actinobacteria group, i.e. Ato291, on α-gluco-oligosaccharides were significantly lesser in comparison with inulin at 36 h. There were significant increases in the Bac303 group on both α-gluco-oligosaccharides and inulin at 24 and 36 h, respectively. A significant decrease in Fpra655 was observed with both test substrates (P< 0·01) at all time points. No significant changes were detected in the other bacterial populations. Also, there were no significant changes in the total cell count (enumerated by 4′,6-diamidino-2-phenylindole stain) on both substrates of the lean fermentation.

Table 2 Bacterial populations (log10 cells/ml batch culture fluid) in pH-controlled batch cultures at 0, 10, 24 and 36 h inoculated with the lean and obese faecal microbiota (Mean values and standard deviations, n 4)

Chis150, Clostridium histolyticum; Lab158, Lactobacillus/Enterococcus; Erec482, Eubacterium rectale/Clostridium coccoides; Prop853, Clostridium cluster IX; Fpra655, Faecalibacterium prausnitzii; Rbro730/Rfla729, Ruminococcus bromii/Ruminococcus flavefaciens; Bac303, Bacteroides/Prevotella; Bif164, Bifidobacterium spp.; Ato291, Atopobium cluster; DAPI, 4′,6-diamidino-2-phenylindole.

Mean value was significantly different from that at 0 h: * P< 0·05, ** P< 0·01.

a,b Mean values with unlike superscript letters were significantly higher/lower in comparison with inulin and the lean human faecal fermentation values of the same sampling hour (P< 0·05).

Analyses of the obese faecal microbiota composition at baseline (0 h) did not reveal any significant differences in the specific bacterial groups between the obese and lean human faecal microbiota. The total cell counts were higher in the obese human faecal samples compared with lean faecal samples (P< 0·05). However, a considerably higher percentage of the baseline microbiota was accounted for in the lean cultures compared with the obese cultures by the probe set used. The principal component analysis results for all parameters related to gut bacteria and the distribution of the faecal microbiota from all donors at baseline (0 h) are shown in Fig. 1. The first and second principal components were responsible for 63 % of the total variance. The projection of the parameters in the plane by these principal components did not separate the lean and obese faecal microbiota and no clustering was observed, indicating no significant differences among the faecal inocula in accordance with Pearson's correlation test (P>0·05).

Fig. 1 Principal component analysis score plot of the faecal microbiota groups at baseline (0 h) for the lean (L, n 4) and obese (O, n 4) donors enumerated using fluorescent in situ hybridisation (Chis150, Clostridium histolyticum; Lab158, Lactobacillus/Enterococcus; Erec482, Eubacterium rectale/Clostridium coccoides; Prop853, Clostridium cluster IX; Fpra655, Faecalibacterium prausnitzii; Rbro730/Rfla729, Ruminococcus bromii/Ruminococcus flavefaciens; Bac303, Bacteroides/Prevotella; Bif164, Bifidobacterium spp.; Ato291, Atopobium cluster). The plot shows no clustering, indicating no significant differences between the L and O donors according to Pearson's correlation test (P>0·05).

There was a significant increase of Bif164 in response to α-gluco-oligosaccharides tested at all time points from 0 h, which was similar to the lean fermentation. Also, the Bif164 populations at 36 h with α-gluco-oligosaccharides were significantly higher compared with inulin fermentation (P< 0·05). Generally, substrates fermented with the obese microbiota produced similar results to the lean fermentation, i.e. increasing Bac303 populations and decreasing Fpra655 populations. However, during the obese slurry fermentation, the populations of Lab158 increased with both substrates, which was not the case in the lean fermentation (P< 0·05).

The percentages of the major bacterial phyla in the fermentation using the lean and obese persons' inocula are shown in Table 3, where the total bacterial number of Chis150, Lab158, Erec482, Prop853, Fpra655 and Rbro730/Rfla729 represents Firmicutes; Bac303 represents Bacteroidetes; Bif164 and Ato291 represent Actinobacteria. The starting bacterial populations in both lean and obese faecal slurries (0 h) demonstrate that Firmicutes was the predominant group followed by Bacteroidetes and then Actinobacteria. No significant difference was detected in all major bacterial phyla (P>0·05) between the lean and obese faecal fermentations.

Table 3 Percentage of the major bacterial phyla in pH-controlled batch cultures of the lean and obese human faecal fermentations at 0, 10, 24 and 36 h*

* No significant difference was detected in all major bacterial phyla (P>0·05) between the lean and obese faecal fermentations.

Organic acid analyses

Table 4 shows organic acid (OA) concentrations in the lean and obese faecal cultures. Generally, fermentation of the lean faecal microbiota of both substrates produced all OA except butyrate. Lactate significantly increased early in the α-gluco-oligosaccharide fermentation (10 h) but later diminished. Total OA concentrations significantly increased on both test substrates after 10 h of fermentation (P< 0·01). In addition, total OA concentrations with α-gluco-oligosaccharides at 36 h were significantly higher compared with inulin. Acetate was the most prevalent SCFA on both test substrates accounting for >50 % of the total OA produced followed by propionate and butyrate. Significant increases in acetate were found with both test substrates. The highest acetate concentration was observed following α-gluco-oligosaccharide fermentation at 36 h, which was significantly higher than inulin. Significant increases in propionate were found with both substrates, with α-gluco-oligosaccharides giving higher propionate levels. There is no significant difference in the acetate:propionate ratio observed in the fermentation of α-gluco-oligosaccharide compared with inulin.

Table 4 SCFA and lactic acid concentrations (mm) in pH-controlled batch cultures at 0, 10, 24 and 36 h inoculated with the lean and obese faecal microbiota (Mean values and standard deviations, n 4)

Mean value was significantly different from that at 0 h: * P< 0·05, ** P< 0·01.

a,b Mean values with unlike superscript letters were significantly higher/lower in comparison with inulin and the lean human faecal fermentation values of the same sampling hour (P< 0·05).

Substrates fermented with the obese microbiota exhibited similar OA patterns to the lean fermentation, i.e. a significantly higher total OA concentration with α-gluco-oligosaccharides compared with inulin at 36 h. However, for α-gluco-oligosaccharides, the acetate:propionate ratio in the obese faecal fermentation was significantly lower than that in the lean faecal fermentation.

Gas production

The total gas production after 36 h in the lean and obese fermentations is shown in Fig. 2. No significant differences were observed in the total gas produced between the lean and obese fermentations. Fig. 3 shows the gas production patterns in the lean faecal fermentation. Fermentation of α-gluco-oligosaccharides produced gas which peaked at 3 h. Meanwhile, fermentation of inulin produced the highest amount of gas at 6 h. α-Gluco-oligosaccharides produced a slower rate of gas combined with lower total gas production compared with inulin (P< 0·05). This indicates that α-gluco-oligosaccharides were fermented more slowly to produce a more gradual build-up of gas compared with inulin. Fig. 4 shows the gas production patterns in the obese faecal fermentation. Fermentation of α-gluco-oligosaccharides produced gas which peaked at the same time with inulin at 3 h. However, thereafter, the gas production rate of α-gluco-oligosaccharide was slower than that of inulin. The fermentation of α-gluco-oligosaccharides with the obese faecal inocula was significantly faster than that with the lean faecal inocula (P< 0·05). However, no significant difference on the gas production rate of inulin was observed between the lean and obese faecal fermentations (P>0·05).

Fig. 2 Total gas production (ml) from 36 h non-pH-controlled batch culture fermentation inoculated with lean () and obese (■) faecal microbiota (n 4). Values are means, with standard deviations represented by vertical bars. a,b,cMean values with unlike letters were significantly different among the treatments (P< 0·05), with ‘a’ being the least amount of total gas and ‘c’ being the highest amount of total gas.

Fig. 3 Gas production pattern expressed in ml/h from non-pH-controlled batch culture (n 4) inoculated with lean faecal microbiota. Values are means, with standard deviations represented by vertical bars. a,b,cMean values with unlike letters were significantly different among the treatments (P< 0·05), with ‘a’ being the slowest gas rate and ‘c’ being the fastest gas rate. ▲, α-Gluco-oligosaccharides; ■, inulin; ◆, no substrate.

Fig. 4 Gas production pattern expressed in ml/h from non-pH-controlled batch culture (n 4) inoculated with obese faecal microbiota. Values are means, with standard deviations represented by vertical bars. a,b,cMean values with unlike letters were significantly different among the treatments (P< 0·05), with ‘a’ being the slowest gas rate and ‘c’ being the fastest gas rate. ▲, α-Gluco-oligosaccharides; ■, inulin; ◆, no substrate.

Discussion

This is the first study to evaluate commercial α-gluco-oligosaccharides (BioEcolians) in a mixed human faecal culture system using modern DNA-based microbiological methods. α-Gluco-oligosaccharides gave rise to significant increases in Bifidobacterium populations when compared with inulin. This may be related to the difference in the molecular weight of the substrates tested. α-Gluco-oligosaccharides used in the present study have a DP of 5–6(Reference Cote and Rastall24). Our current understanding of prebiotic substances is that low-molecular-weight oligosaccharides are more selectively fermented by bifidobacteria and lactobacilli than high-molecular-weight carbohydrates(Reference Gibson4). A study has demonstrated that lower-DP oligodextrans produced by controlled enzymatic hydrolysis resulted in higher fermentation selectivity for bifidobacteria, compared with the parent dextran molecule and other oligodextran fractions with a higher average DP(Reference Olano-Martin, Mountzouris and Gibson25), with a DP of 3 giving higher prebiotic activity than a DP of 2(Reference Kaneko, Kohmoto and Kikuchi26). This may be due to the fact that the low molecular mass means more non-reducing ends per unit mass, which are susceptible to attack by various exo-acting α- and β-glucosidases produced by colonic bacteria such as Bifidobacterium spp.(Reference van den Broek, Hinz and Beldman27). Little is known about the biochemical characteristics of α-glucosidase enzymes from bifidobacteria, although it is a common activity observed among this genus(Reference Rada, Vlková and Nevoral28).

We previously demonstrated that an increase in α-1,2 branching of dextrans did not lead to higher selectivity for bifidobacteria. However, branching may decrease the gastrointestinal digestibility of the 1 kDa dextrans as assessed by the higher total dietary fibre content of branched 1 kDa dextrans than linear 1 kDa dextrans(Reference Sarbini, Kolida and Naeye29). A study has found that α-1,2- and α-1,6-linked disaccharides were selective for Bifidobacterium spp. using in vitro faecal cultures(Reference Sanz, Gibson and Rastall30). These observations are consistent with α-gluco-oligosaccharides used in the present study, which consist of a linear α-1,6 glucan backbone with α-1,2 and α-1,3 branching(14).

An in vivo animal study has demonstrated that gluco-oligosaccharides fed to gnotobiotic rats (inoculated with human faecal microbiota) did not influence major bacterial populations (including bifidobacteria) as opposed to rats fed fructo-oligosaccharides(Reference Djouzi and Andrieux31). However, this study used culture-based techniques to enumerate bacterial populations disregarding the non-cultivable species. Nevertheless, gluco-oligosaccharides increased β-galactosidase and α-glucosidase activities and decreased β-glucuronidase, which could be considered beneficial for the host. β-Glucuronidase is involved in the generation of toxic and carcinogenic metabolites(Reference Rowland32), whereas β-galactosidase and α-glucosidase activities can improve carbohydrate fermentation to SCFA(Reference Macfarlane, Cummings, Phillips, Pemberton and Shorter33). A study has shown that α-glucosidase from Bifidobacterium breve UCC2003 belongs to a subgroup of the glycosyl hydrolase family 13, the α-1,6-glucosidases (EC 3.2.1.10), which exhibits hydrolytic activity towards α-1,6-linked carbohydrates such as panose, isomaltose and isomaltotriose(Reference Pokusaeva, O'Connell-Motherway and Zomer34). It has also been demonstrated, in non-pH-controlled fermentations, that α-1,2- and α-1,6-linked disaccharides were selective for Bifidobacterium spp.(Reference Sanz, Côté and Gibson35). The decrease in Faecalibacterium prausnitzii was seen in all fermentations using faecal inocula from lean and obese donors. Another study has demonstrated that a clinical improvement of Crohn's disease was correlated with a significant decrease in F. prausnitzii (Reference Jia, Whitehead and Griffiths36).

A preliminary human study has suggested differences between lean and obese human gut microbiota based on sequencing 16S ribosomal RNA genes from stool samples(Reference Ley, Turnbaugh and Klein9). However, through the present findings, we did not see any significant difference in the major colonic bacterial groups (except for Lab158) between lean and obese, either on the baseline or subsequent fermentation. In addition, the fermentation of α-gluco-oligosaccharides significantly increased Bif164 and Bac303, and decreased Fpra655 in the obese faecal fermentation. This was similar to the lean faecal fermentation, which may suggest that the changes appear to be mainly in response to the substrates. Obesity is thought to be associated with low-grade systemic inflammation(Reference Bastard, Maachi and Lagathu37Reference Fogarty, Glancy and Jones41). High numbers of bifidobacteria may decrease endotoxaemia and pro-inflammatory cytokines, further improving glucose tolerance and glucose-induced insulin secretion(Reference Cani, Neyrinck and Fava42).

Some studies have observed altered proportions of Firmicutes and Bacteroidetes in obese compared with lean mice(Reference Ley, Bäckhed and Turnbaugh6, Reference Turnbaugh, Ley and Mahowald7, Reference Bäckhed, Ding and Wang43). It has also been reported that Firmicutes concentrations were higher in the faeces of obese than lean human subjects(Reference Turnbaugh, Ley and Mahowald7, Reference Turnbaugh, Hamady and Yatsunenko44). However, we observed here that the number of Bacteroidetes, Firmicutes and Actinobacteria in baseline faecal samples from obese donors was similar to those from lean donors. Nevertheless, it has to be noted that the present study only involved four donors that could possibly limit the statistical significance of this particular observation.

Fermentation of α-gluco-oligosaccharides induced the production of lactate early in the fermentation, which later declined. This is likely to be due to lactate conversion into SCFA by cross-feeding of other bacteria. The significantly higher concentration of acetate observed on α-gluco-oligosaccharides compared with inulin at 36 h is probably due to a higher population of Bifidobacterium (Reference Falony, Lazidou and Verschaeren45). There was also an increase in propionate concentration on both substrates in accordance with a significant increase in the BacteroidesPrevotella group, as these are known to be propionate producers. It has been postulated that propionate may have anti-obesity properties through the reduction of fatty acid levels in plasma(Reference Al-Lahham, Peppelenbosch and Roelofsen46). High plasma fatty acids are known to cause inflammation, leading to insulin resistance(Reference Kennedy, Martinez and Chuang47). These beneficial effects are usually linked with a reduction in body weight and have been demonstrated to increase satiety(Reference Ruijschop, Boelrijk and te Giffel48). Acetate may act as a precursor for cholesterol synthesis, whereas propionate may inhibit this process. Therefore, a low acetate:propionate ratio may be of interest in regulating serum cholesterol levels(Reference Chen, Anderson and Jennings49). In the present in vitro study, the fermentation of α-gluco-oligosaccharides produced a significantly lower acetate:propionate ratio in the obese faecal fermentation than in the lean faecal fermentation. Therefore, it is suggested to some extent that this type of α-gluco-oligosaccharides may demonstrate an anti-obesity effect through its propionate production especially when used in obese people. However, this has to be demonstrated in vivo.

Known producers of propionate include Bacteroides spp. and Clostridium. An example is Bacteroides fragilis that is prevalent in the human gut microbial community, which produces substantial amounts of propionate from succinate and fumarate(Reference Macy, Ljungdahl and Gottschalk50). Species within the Clostridium histolyticum group can also produce propionate, for example Clostridium homopropionicum (Reference Salminen, Bouley and Boutron-Ruault51, Reference Zigová, SturdIk and Vandák52). Clostridial cluster IX contains known propionate producers(Reference Zigová, SturdIk and Vandák52) and species within it (e.g. Succiniclasticum ruminis and Succinispira mobilis) have been reported to convert succinate into propionate(Reference Janssen and O'Farrell53, Reference Van Gylswyk54). Through the present study, we only observed significant increases in Bacteroides Prevotella populations but not in the Clostridium group, i.e. C. histolyticum and Clostridium cluster IX. Therefore, we suggest that propionate may have been produced by the Bacteroides Prevotella group. In addition, a previous study has shown that Bacteroides thetaiotaomicron is highly efficient in utilising α-1,2 and α-1,6 glycosidic linkages that occur in α-gluco-oligosaccharides(Reference Djouzi, Andrieux and Pelenc55).

There is no significant increase in butyrate in the fermentation of both substrates. This may be due to the decrease in the population of major butyrate producers such as F. prausnitzii, Clostridium coccoidesEubacterium rectale and Ruminococcus groups. An in vitro study has demonstrated that fermentation of α-gluco-oligosaccharides resulted in a lower concentration of butyrate compared with fructo-oligosaccharides(Reference Flickinger, Wolf and Garleb56), which is in agreement with the present findings. In addition, an in vitro study has shown that α-gluco-oligosaccharide fermentation resulted in significantly lower butyrate concentration compared with short-, medium- and long-chain fructo-oligosaccharides(Reference Smiricky-Tjardes, Flickinger and Grieshop57).

Gas production in the large intestine is part of the normal digestive function caused by fermentation of carbohydrate by the gut microbiota. These gases are inevitable fermentation products but are also the main reported disincentive to consumption of prebiotics. Undesirable symptoms relating to gas production in the gut have been widely reported in human prebiotic feeding studies(Reference Hartemink, Rombouts and Hartemink58). Gastrointestinal discomfort usually occurs with high carbohydrate intakes (more than 20 g/d)(Reference Kolida and Gibson59). Although it is known that prebiotic target bacteria, i.e. bifidobacteria, do not produce gas, they do produce lactate which can be utilised by gas-producing bacteria such as Clostridium spp., sulphate-reducing bacteria and Bacteroides (Reference Bernalier, Dore, Durand, Gibson and Roberfroid60, Reference Falony, Calmeyn and Leroy61). Clostridial clusters IV and XIVa, which are also butyrate producers, have been shown to produce gases, mainly CO2 and H2(Reference Duncan, Louis and Flint62, Reference Duncan, Hold and Harmsen63). Fermentation of α-gluco-oligosaccharides resulted in lower quantities of gas, and this was produced more gradually than the fermentation of inulin with both lean and obese faecal slurries. This is in accordance with a previous study which demonstrated that fermentation of gluco-oligosaccharides produced significantly lower amounts of total gas than fructo-oligosaccharides(Reference Djouzi and Andrieux31).

The in vitro study described here suggested that α-gluco-oligosaccharides (BioEcolians; Solabia) have bifidogenic activity. This, in combination with the fact that glycosidic linkages present results in a very high resistance to hydrolysis by digestive enzymes in both humans and animals(Reference Valette, Pelenc and Djouzi64), makes this type of α-glucan an interesting candidate prebiotic and is worthy of further in vivo evaluation. Also, we suggested that the substrate (or diet) but probably not the individual's obese condition can influence the microbiota composition. However, further in vivo work is needed to ultimately confirm this.

Acknowledgements

The present study was carried out with the financial support from the Department of Food and Nutritional Sciences, University of Reading. The Sarawak Foundation and Universiti Putra Malaysia of the Malaysian government funded a scholarship for S. R. S. The authors' responsibilities were as follows: S. R. S. carried out the study, collected and interpreted the data and wrote the manuscript; S. K. and R. A. R. designed the study, interpreted the data and edited the manuscript; G. R. G. designed the study and edited the manuscript. All authors read and approved the findings of the study. None of the authors had any conflict of interest.

References

1Gibson, GR, Scott, KP, Rastall, RA, et al. (2010) Dietary prebiotics: current status and new definition. Food Sci Technol Bull: Funct Foods 7, 119.Google Scholar
2Gibson, GR & Fuller, R (2000) Aspects of in vitro and in vivo research approaches directed toward identifying probiotics and prebiotics for human use. J Nutr 130, 391.CrossRefGoogle ScholarPubMed
3Chung, CH & Day, DF (2002) Glucooligosaccharides from Leuconostoc mesenteroides B-742 (ATCC 13146): a potential prebiotic. J Indus Microbiol Biotechnol 29, 196199.Google Scholar
4Gibson, GR (2004) Fibre and effects on probiotics (the prebiotic concept). Clin Nutr Suppl 1, 2531.CrossRefGoogle Scholar
5Eckburg, PB, Bik, EM, Bernstein, CN, et al. (2005) Diversity of the human intestinal microbial flora. Science 308, 16351638.Google Scholar
6Ley, RE, Bäckhed, F, Turnbaugh, P, et al. (2005) Obesity alters gut microbial ecology. Proc Natl Acad Sci U S A 102, 1107011075.Google Scholar
7Turnbaugh, PJ, Ley, RE, Mahowald, MA, et al. (2006) An obesity-associated gut microbiome with increased capacity for energy harvest. Nature 444, 10271131.Google Scholar
8Bäckhed, F, Manchester, JK, Semenkovich, CF, et al. (2007) Mechanisms underlying the resistance to diet-induced obesity in germ-free mice. Proc Natl Acad Sci U S A 104, 979984.Google Scholar
9Ley, RE, Turnbaugh, PJ, Klein, S, et al. (2006) Microbial ecology: human gut microbes associated with obesity. Nature 444, 10221023.Google Scholar
10Collado, MC, Isolauri, E, Laitinen, K, et al. (2008) Distinct composition of gut microbiota during pregnancy in overweight and normal-weight women. Am J Clin Nutr 88, 894899.Google Scholar
11Duncan, SH, Lobley, GE, Holtrop, G, et al. (2008) Human colonic microbiota associated with diet, obesity and weight loss. Int J Obes 32, 17201724.Google Scholar
12Hildebrandt, MA, Hoffmann, C, Sherrill-Mix, SA, et al. (2009) High-fat diet determines the composition of the murine gut microbiome independently of obesity. Gastroenterology 137, 171624e2.Google Scholar
13Murphy, EF, Cotter, PD, Healy, S, et al. (2010) Composition and energy harvesting capacity of the gut microbiota: relationship to diet, obesity and time in mouse models. Gut 59, 16351642.CrossRefGoogle ScholarPubMed
15Jeanes, A, Haynes, WC, Wilham, CA, et al. (1954) Characterization and classification of dextrans from ninety-six strains of bacteria. J Am Chem Soc 76, 50415052.CrossRefGoogle Scholar
16Franks, AH, Harmsen, HJM, Raangs, GC, et al. (1998) Variations of bacterial populations in human feces measured by fluorescent in situ hybridization with group-specific 16s rRNA-targeted oligonucleotide probes. Appl Environ Microbiol 64, 33363345.CrossRefGoogle ScholarPubMed
17Harmsen, HJM, Elfferich, P, Schut, F, et al. (1999) A 16s rRNA-targeted probe for detection of lactobacilli and enterococci in faecal samples by fluorescent in situ hybridization. Microb Ecol Health Dis 11, 312.Google Scholar
18Walker, AW, Duncan, SH, McWilliam Leitch, EC, et al. (2005) pH and peptide supply can radically alter bacterial populations and short-chain fatty acid ratios within microbial communities from the human colon. Appl Environ Microbiol 71, 36923700.Google Scholar
19Hold, GL, Schwiertz, A, Aminov, RI, et al. (2003) Oligonucleotide probes that detect quantitatively significant groups of butyrate-producing bacteria in human feces. Appl Environ Microbiol 69, 43204324.Google Scholar
20Harmsen, HJM, Raangs, GC, He, T, et al. (2002) Extensive set of 16s rRNA-based probes for detection of bacteria in human feces. Appl Environ Microbiol 68, 29822990.Google Scholar
21Manz, W, Amann, R, Ludwig, W, et al. (1996) Application of a suite of 16s rRNA-specific oligonucleotide probes designed to investigate bacteria of the phylum cytophaga–flavobacter–bacteroides in the natural environment. Microbiology 142, 10971106.Google Scholar
22Langendijk, P, Schut, F, Jansen, G, et al. (1995) Quantitative fluorescence in situ hybridization of Bifidobacterium spp. with genus-specific 16s rRNA-targeted probes and its application in fecal samples. Appl Environ Microbiol 61, 30693075.Google Scholar
23Harmsen, HJM, Wildeboer-Veloo, ACM, Grijpstra, J, et al. (2000) Development of 16s rRNA-based probes for the Coriobacterium group and the Atopobium cluster and their application for enumeration of Coriobacteriaceae in human feces from volunteers of different age groups. Appl Environ Microbiol 66, 45234527.Google Scholar
24Cote, GL (2007) Flavorings and other value-added products from sucrose. In Novel Enzyme Technology for Food Applications, pp. 243269 [Rastall, RA, editor]. Boca Raton, FL: CRC Press.Google Scholar
25Olano-Martin, E, Mountzouris, KC, Gibson, GR, et al. (2000) In vitro fermentability of dextran, oligodextran and maltodextrin by human gut bacteria. Br J Nutr 83, 247255.Google Scholar
26Kaneko, T, Kohmoto, T, Kikuchi, H, et al. (1994) Effects of isomaltooligosaccharides with different degrees of polymerization on human fecal bifidobacteria. Biosci Biotechnol Biochem 58, 22882290.CrossRefGoogle Scholar
27van den Broek, LAM, Hinz, SWA, Beldman, G, et al. (2008) Bifidobacterium carbohydrases – their role in breakdown and synthesis of (potential) prebiotics. Mol Nutr Food Res 52, 146163.Google Scholar
28Rada, V, Vlková, E, Nevoral, J, et al. (2006) Comparison of bacterial flora and enzymatic activity in faeces of infants and calves. FEMS Microbiol Lett 258, 2528.Google Scholar
29Sarbini, SR, Kolida, S, Naeye, T, et al. (2011) In vitro fermentation of linear and alpha-1,2-branched dextrans by the human fecal microbiota. Appl Environ Microbiol 77, 53075315.Google Scholar
30Sanz, ML, Gibson, GR & Rastall, RA (2005) Influence of disaccharide structure on prebiotic selectivity in vitro. J Agric Food Chem 53, 51925199.Google Scholar
31Djouzi, Z & Andrieux, C (1997) Compared effects of three oligosaccharides on metabolism of intestinal microflora in rats inoculated with human faecal flora. Br J Nutr 78, 313324.Google Scholar
32Rowland, IR (1988) Factors affecting metabolic activity of the intestinal microflora. Drug Metab Rev 19, 243261.Google Scholar
33Macfarlane, GT & Cummings, JH (1991) The colonic flora, fermentation and large bowel digestive function. In The Large Intestine: Physiology, Pathophysiology and Disease, pp. 5192 [Phillips, SF, Pemberton, JH and Shorter, RG, editors]. New York: Raven Press.Google Scholar
34Pokusaeva, K, O'Connell-Motherway, M, Zomer, A, et al. (2009) Characterization of two novel α-glucosidases from Bifidobacterium breve UCC2003. Appl Environ Microbiol 75, 11351143.CrossRefGoogle ScholarPubMed
35Sanz, ML, Côté, GL, Gibson, GR, et al. (2006) Influence of glycosidic linkages and molecular weight on the fermentation of maltose-based oligosaccharides by human gut bacteria. J Agric Food Chem 54, 97799784.Google Scholar
36Jia, W, Whitehead, RN, Griffiths, L, et al. (2010) Is the abundance of Faecalibacterium prausnitzii relevant to Crohn's disease? FEMS Microbiol Lett 310, 138144.CrossRefGoogle ScholarPubMed
37Bastard, J-P, Maachi, M, Lagathu, C, et al. (2006) Recent advances in the relationship between obesity, inflammation, and insulin resistance. Eur Cytokine Netw 17, 412.Google Scholar
38Hotamisligil, GS (2006) Inflammation and metabolic disorders. Nature 444, 860867.Google Scholar
39Sbarbati, A, Osculati, F, Silvagni, D, et al. (2006) Obesity and inflammation: evidence for an elementary lesion. Pediatrics 117, 220223.CrossRefGoogle ScholarPubMed
40Scanlan, PD, Shanahan, F, O'Mahony, C, et al. (2006) Culture-independent analyses of temporal variation of the dominant fecal microbiota and targeted bacterial subgroups in Crohn's disease. J Clin Microbiol 44, 39803988.CrossRefGoogle ScholarPubMed
41Fogarty, AW, Glancy, C, Jones, S, et al. (2008) A prospective study of weight change and systemic inflammation over 9 y. Am J Clin Nutr 87, 3035.Google Scholar
42Cani, PD, Neyrinck, AM, Fava, F, et al. (2007) Selective increases of bifidobacteria in gut microflora improve high-fat-diet-induced diabetes in mice through a mechanism associated with endotoxaemia. Diabetologia 50, 23742383.Google Scholar
43Bäckhed, F, Ding, H, Wang, T, et al. (2004) The gut microbiota as an environmental factor that regulates fat storage. Proc Natl Acad Sci U S A 101, 1571815723.CrossRefGoogle ScholarPubMed
44Turnbaugh, PJ, Hamady, M, Yatsunenko, T, et al. (2009) A core gut microbiome in obese and lean twins. Nature 457, 480484.Google Scholar
45Falony, G, Lazidou, K, Verschaeren, A, et al. (2009) In vitro kinetic analysis of fermentation of prebiotic inulin-type fructans by Bifidobacterium species reveals four different phenotypes. Appl Environ Microbiol 75, 454461.Google Scholar
46Al-Lahham, SaH, Peppelenbosch, MP, Roelofsen, H, et al. (2010) Biological effects of propionic acid in humans; metabolism, potential applications and underlying mechanisms. Biochim Biophys Acta – Mol Cell Biol Lip 1801, 11751183.Google Scholar
47Kennedy, A, Martinez, K, Chuang, C-C, et al. (2009) Saturated fatty acid-mediated inflammation and insulin resistance in adipose tissue: mechanisms of action and implications. J Nutr 139, 14.Google Scholar
48Ruijschop, RMAJ, Boelrijk, AEM & te Giffel, MC (2008) Satiety effects of a dairy beverage fermented with propionic acid bacteria. Int Dairy J 18, 945950.Google Scholar
49Chen, W, Anderson, J & Jennings, D (1984) Propionate may mediate the hypo-cholesterolemic effects of certain soluble plant fibers in cholesterol-fed rats. Proc Soc Exp Biol Med 175, 215218.Google Scholar
50Macy, JM, Ljungdahl, LG & Gottschalk, G (1978) Pathway of succinate and propionate formation in Bacteroides fragilis. J Bacteriol 134, 8491.Google Scholar
51Salminen, S, Bouley, C, Boutron-Ruault, MC, et al. (1998) Functional food science and gastrointestinal physiology and function. Br J Nutr 80, 147171.Google Scholar
52Zigová, J, SturdIk, E, Vandák, D, et al. (1999) Butyric acid production by Clostridium butyricum with integrated extraction and pertraction. Proc Biochem 34, 835843.Google Scholar
53Janssen, PH & O'Farrell, KA (1999) Succinispira mobilis gen. Nov., sp. Nov., a succinate-decarboxylating anaerobic bacterium. Int J Syst Evol Microbiol 49, 10091013.Google Scholar
54Van Gylswyk, NO (1995) Succiniclasticum ruminis gen. Nov., sp. Nov., a ruminal bacterium converting succinate to propionate as the sole energy-yielding mechanism. Int J Syst Bacteriol 45, 297300.Google Scholar
55Djouzi, Z, Andrieux, C, Pelenc, V, et al. (1995) Degradation and fermentation of α-gluco-oligosaccharides by bacterial strains from human colon: in vitro and in vivo studies in gnotobiotic rats. J Appl Microbiol 79, 117127.Google Scholar
56Flickinger, EA, Wolf, BW, Garleb, KA, et al. (2000) Glucose-based oligosaccharides exhibit different in vitro fermentation patterns and affect in vivo apparent nutrient digestibility and microbial populations in dogs. J Nutr 130, 12671273.Google Scholar
57Smiricky-Tjardes, MR, Flickinger, EA, Grieshop, CM, et al. (2003) In vitro fermentation characteristics of selected oligosaccharides by swine fecal microflora. J Anim Sci 81, 25052514.Google Scholar
58Hartemink, R & Rombouts, FM (1997) Gas formation from oligosaccharides by the intestinal microflora. In Non-digestible Oligosaccharides: Healthy Food for the Colon? Proceedings of the International Symposium, pp. 5766 [Hartemink, R, editor]. Wageningen: Wageningen Graduate School VLAG.Google Scholar
59Kolida, S & Gibson, GR (2007) Prebiotic capacity of inulin-type fructans. J Nutr 137, 2503S2506S.Google Scholar
60Bernalier, A, Dore, J & Durand, M (1999) Biochemistry of fermentation. In Colonic Microbiota, Nutrition and Health, pp. 3753 [Gibson, GR and Roberfroid, MB, editors]. Dordrecht: Kluwer Academic Publishers.Google Scholar
61Falony, G, Calmeyn, T, Leroy, F, et al. (2009) Coculture fermentations of Bifidobacterium species and Bacteroides thetaiotaomicron reveal a mechanistic insight into the prebiotic effect of inulin-type fructans. Appl Environ Microbiol 75, 23122319.Google Scholar
62Duncan, SH, Louis, P & Flint, HJ (2004) Lactate-utilizing bacteria, isolated from human feces that produce butyrate as a major fermentation product. Appl Environ Microbiol 70, 58105817.Google Scholar
63Duncan, SH, Hold, GL, Harmsen, H, et al. (2002) Growth requirements and fermentation products of Fusobacterium prausnitzii, and a proposal to reclassify it as Faecalibacterium prausnitzii gen. Nov., comb. Nov. Int J Syst Evol Microbiol 52, 21412146.Google Scholar
64Valette, P, Pelenc, V, Djouzi, Z, et al. (1993) Bioavailability of new synthesised glucooligosaccharides in the intestinal tract of gnotobiotic rats. J Sci Food Agric 62, 121127.Google Scholar
Figure 0

Table 1 16S ribosomal RNA oligonucleotide probes used in the present study

Figure 1

Table 2 Bacterial populations (log10 cells/ml batch culture fluid) in pH-controlled batch cultures at 0, 10, 24 and 36 h inoculated with the lean and obese faecal microbiota (Mean values and standard deviations, n 4)

Figure 2

Fig. 1 Principal component analysis score plot of the faecal microbiota groups at baseline (0 h) for the lean (L, n 4) and obese (O, n 4) donors enumerated using fluorescent in situ hybridisation (Chis150, Clostridium histolyticum; Lab158, Lactobacillus/Enterococcus; Erec482, Eubacterium rectale/Clostridium coccoides; Prop853, Clostridium cluster IX; Fpra655, Faecalibacterium prausnitzii; Rbro730/Rfla729, Ruminococcus bromii/Ruminococcus flavefaciens; Bac303, Bacteroides/Prevotella; Bif164, Bifidobacterium spp.; Ato291, Atopobium cluster). The plot shows no clustering, indicating no significant differences between the L and O donors according to Pearson's correlation test (P>0·05).

Figure 3

Table 3 Percentage of the major bacterial phyla in pH-controlled batch cultures of the lean and obese human faecal fermentations at 0, 10, 24 and 36 h*

Figure 4

Table 4 SCFA and lactic acid concentrations (mm) in pH-controlled batch cultures at 0, 10, 24 and 36 h inoculated with the lean and obese faecal microbiota (Mean values and standard deviations, n 4)

Figure 5

Fig. 2 Total gas production (ml) from 36 h non-pH-controlled batch culture fermentation inoculated with lean () and obese (■) faecal microbiota (n 4). Values are means, with standard deviations represented by vertical bars. a,b,cMean values with unlike letters were significantly different among the treatments (P< 0·05), with ‘a’ being the least amount of total gas and ‘c’ being the highest amount of total gas.

Figure 6

Fig. 3 Gas production pattern expressed in ml/h from non-pH-controlled batch culture (n 4) inoculated with lean faecal microbiota. Values are means, with standard deviations represented by vertical bars. a,b,cMean values with unlike letters were significantly different among the treatments (P< 0·05), with ‘a’ being the slowest gas rate and ‘c’ being the fastest gas rate. ▲, α-Gluco-oligosaccharides; ■, inulin; ◆, no substrate.

Figure 7

Fig. 4 Gas production pattern expressed in ml/h from non-pH-controlled batch culture (n 4) inoculated with obese faecal microbiota. Values are means, with standard deviations represented by vertical bars. a,b,cMean values with unlike letters were significantly different among the treatments (P< 0·05), with ‘a’ being the slowest gas rate and ‘c’ being the fastest gas rate. ▲, α-Gluco-oligosaccharides; ■, inulin; ◆, no substrate.