In Vitro Interactions of Dietary Fibre Enriched Food Ingredients with Primary and Secondary Bile Acids

Dietary fibres are reported to interact with bile acids, preventing their reabsorption and promoting their excretion into the colon. We used a method based on in vitro digestion, dialysis, and kinetic analysis to investigate how dietary fibre enriched food ingredients affect the release of primary and secondary bile acids as related to viscosity and adsorption. As the main bile acids abundant in humans interactions with glyco- and tauroconjugated cholic acid, chenodesoxycholic acid and desoxycholic acid were analysed. Viscous interactions were detected for apple, barley, citrus, lupin, pea, and potato derived ingredients, which slowed the bile acid release rate by up to 80%. Adsorptive interactions of up to 4.7 μmol/100 mg DM were significant in barley, oat, lupin, and maize preparations. As adsorption directly correlated to the hydrophobicity of the bile acids the hypothesis of a hydrophobic linkage between bile acids and dietary fibre is supported. Delayed diffusion in viscous fibre matrices was further associated with the micellar properties of the bile acids. As our results indicate changes in the bile acid pool size and composition due to interactions with dietary fibre rich ingredients, the presented method and results could add to recent fields of bile acid research.

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Retention of Primary Bile Acids by Lupin Cell Wall Polysaccharides Under In Vitro Digestion Conditions

Nutrients ◽

10.3390/nu11092117 ◽

2019 ◽

Vol 11 (9) ◽

pp. 2117 ◽

Cited By ~ 3

Author(s):

Naumann ◽

Schweiggert-Weisz ◽

Haller ◽

Eisner

Keyword(s):

Cell Wall ◽

Bile Acid ◽

Bile Acids ◽

Molecular Interactions ◽

Enterohepatic Circulation ◽

In Vitro Digestion ◽

Adsorptive Capacity ◽

Cell Wall Polysaccharides ◽

Dietary Fibres

Interference of dietary fibres with the enterohepatic circulation of bile acids is proposed as a mechanism for lowering cholesterol. We investigated how lupin hull and cotyledon dietary fibres interact with primary bile acids using an in vitro model under simulated upper gastrointestinal conditions. Cell wall polysaccharides were isolated and extracted to separate pectin-like, hemicellulosic, and lignocellulosic structures. Lupin hull consisted mainly of structural components rich in cellulose. The viscosity of the in vitro digesta of lupin hull was low, showing predominantly liquid-like viscoelastic properties. On the other hand, lupin cotyledon fibre retarded bile acid release due to increased viscosity of the in vitro digesta, which was linked with high contents of pectic polymers forming an entangled network. Molecular interactions with bile acids were not measured for the hull but for the cotyledon, as follows: A total of 1.29 µmol/100 mg DM of chenodesoxycholic acids were adsorbed. Molecular interactions of cholic and chenodesoxycholic acids were evident for lignin reference material but did not account for the adsorption of the lupin cotyledon. Furthermore, none of the isolated and fractionated cell wall materials showed a significant adsorptive capacity, thus disproving a major role of lupin cell wall polysaccharides in bile acid adsorption.

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Antibiotic-Induced Alterations of the Gut Microbiota Alter Secondary Bile Acid Production and Allow for Clostridium difficile Spore Germination and Outgrowth in the Large Intestine

mSphere ◽

10.1128/msphere.00045-15 ◽

2016 ◽

Vol 1 (1) ◽

Cited By ~ 154

Author(s):

Casey M. Theriot ◽

Alison A. Bowman ◽

Vincent B. Young

Keyword(s):

Bile Acid ◽

Clostridium Difficile ◽

Gut Microbiota ◽

Bile Acids ◽

Large Intestine ◽

Spore Germination ◽

Secondary Bile Acid ◽

Content Type ◽

Secondary Bile Acids

ABSTRACT Antibiotics alter the gastrointestinal microbiota, allowing for Clostridium difficile infection, which is a significant public health problem. Changes in the structure of the gut microbiota alter the metabolome, specifically the production of secondary bile acids. Specific bile acids are able to initiate C. difficile spore germination and also inhibit C. difficile growth in vitro, although no study to date has defined physiologically relevant bile acids in the gastrointestinal tract. In this study, we define the bile acids C. difficile spores encounter in the small and large intestines before and after various antibiotic treatments. Antibiotics that alter the gut microbiota and deplete secondary bile acid production allow C. difficile colonization, representing a mechanism of colonization resistance. Multiple secondary bile acids in the large intestine were able to inhibit C. difficile spore germination and growth at physiological concentrations and represent new targets to combat C. difficile in the large intestine. It is hypothesized that the depletion of microbial members responsible for converting primary bile acids into secondary bile acids reduces resistance to Clostridium difficile colonization. To date, inhibition of C. difficile growth by secondary bile acids has only been shown in vitro. Using targeted bile acid metabolomics, we sought to define the physiologically relevant concentrations of primary and secondary bile acids present in the murine small and large intestinal tracts and how these impact C. difficile dynamics. We treated mice with a variety of antibiotics to create distinct microbial and metabolic (bile acid) environments and directly tested their ability to support or inhibit C. difficile spore germination and outgrowth ex vivo. Susceptibility to C. difficile in the large intestine was observed only after specific broad-spectrum antibiotic treatment (cefoperazone, clindamycin, and vancomycin) and was accompanied by a significant loss of secondary bile acids (deoxycholate, lithocholate, ursodeoxycholate, hyodeoxycholate, and ω-muricholate). These changes were correlated to the loss of specific microbiota community members, the Lachnospiraceae and Ruminococcaceae families. Additionally, physiological concentrations of secondary bile acids present during C. difficile resistance were able to inhibit spore germination and outgrowth in vitro. Interestingly, we observed that C. difficile spore germination and outgrowth were supported constantly in murine small intestinal content regardless of antibiotic perturbation, suggesting that targeting growth of C. difficile will prove most important for future therapeutics and that antibiotic-related changes are organ specific. Understanding how the gut microbiota regulates bile acids throughout the intestine will aid the development of future therapies for C. difficile infection and other metabolically relevant disorders such as obesity and diabetes. IMPORTANCE Antibiotics alter the gastrointestinal microbiota, allowing for Clostridium difficile infection, which is a significant public health problem. Changes in the structure of the gut microbiota alter the metabolome, specifically the production of secondary bile acids. Specific bile acids are able to initiate C. difficile spore germination and also inhibit C. difficile growth in vitro, although no study to date has defined physiologically relevant bile acids in the gastrointestinal tract. In this study, we define the bile acids C. difficile spores encounter in the small and large intestines before and after various antibiotic treatments. Antibiotics that alter the gut microbiota and deplete secondary bile acid production allow C. difficile colonization, representing a mechanism of colonization resistance. Multiple secondary bile acids in the large intestine were able to inhibit C. difficile spore germination and growth at physiological concentrations and represent new targets to combat C. difficile in the large intestine.

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Strain-dependent inhibition of Clostridioides difficile by commensal Clostridia encoding the bile acid inducible (bai) operon

10.1101/2020.01.22.916304 ◽

2020 ◽

Author(s):

A.D. Reed ◽

M.A. Nethery ◽

A. Stewart ◽

R. Barrangou ◽

C.M. Theriot

Keyword(s):

Bile Acid ◽

Bile Acids ◽

Culture System ◽

Dependent Manner ◽

Secondary Bile Acid ◽

Clostridioides Difficile ◽

The Relationship ◽

Strain Dependent ◽

Secondary Bile Acids

AbstractClostridioides difficile is one of the leading causes of antibiotic-associated diarrhea. Gut microbiota-derived secondary bile acids and commensal Clostridia that encode the bile acid inducible (bai) operon are associated with protection from C. difficile infection (CDI), although the mechanism is not known. In this study we hypothesized that commensal Clostridia are important for providing colonization resistance against C. difficile due to their ability to produce secondary bile acids, as well as potentially competing against C. difficile for similar nutrients. To test this hypothesis, we examined the ability of four commensal Clostridia encoding the bai operon (C. scindens VPI 12708, C. scindens ATCC 35704, C. hiranonis, and C. hylemonae) to convert CA to DCA in vitro, and if the amount of DCA produced was sufficient to inhibit growth of a clinically relevant C. difficile strain. We also investigated the competitive relationship between these commensals and C. difficile using an in vitro co-culture system. We found that inhibition of C. difficile growth by commensal Clostridia supplemented with CA was strain-dependent, correlated with the production of ∼2 mM DCA, and increased expression of bai operon genes. We also found that C. difficile was able to outcompete all four commensal Clostridia in an in vitro co-culture system. These studies are instrumental in understanding the relationship between commensal Clostridia and C. difficile in the gut, which is vital for designing targeted bacterial therapeutics. Future studies dissecting the regulation of the bai operon in vitro and in vivo and how this affects CDI will be important.ImportanceCommensal Clostridia encoding the bai operon such as C. scindens have been associated with protection against CDI, however the mechanism for this protection is unknown. Herein, we show four commensal Clostridia that encode the bai operon effect C. difficile growth in a strain-dependent manner, with and without the addition of cholate. Inhibition of C. difficile by commensals correlated with the efficient conversion of cholate to deoxycholate, a secondary bile acid that inhibits C. difficile germination, growth, and toxin production. Competition studies also revealed that C. difficile was able to outcompete the commensals in an in vitro co-culture system. These studies are instrumental in understanding the relationship between commensal Clostridia and C. difficile in the gut, which is vital for designing targeted bacterial therapeutics.

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In vitro digestion with bile acids enhances the bioaccessibility of kale polyphenols

Food & Function ◽

10.1039/c7fo01749a ◽

2018 ◽

Vol 9 (2) ◽

pp. 1235-1244 ◽

Cited By ~ 16

Author(s):

Isabelle Yang ◽

Guddarangavvanahally K. Jayaprakasha ◽

Bhimanagouda Patil

Keyword(s):

Bile Acid ◽

Bile Acids ◽

Brassica Oleracea ◽

Dietary Fiber ◽

In Vitro Digestion ◽

Health Promoting ◽

Bile Acid Binding

Kale (Brassica oleracea) polyphenols and dietary fiber have key roles in bile acid binding, and these bile acids enhanced significanlty higher (69.4%) bioaccessibility of certain health-promoting polyphenolics.

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Strain-Dependent Inhibition of Clostridioides difficile by Commensal Clostridia Carrying the Bile Acid-Inducible (bai) Operon

Journal of Bacteriology ◽

10.1128/jb.00039-20 ◽

2020 ◽

Vol 202 (11) ◽

Cited By ~ 2

Author(s):

A. D. Reed ◽

M. A. Nethery ◽

A. Stewart ◽

R. Barrangou ◽

C. M. Theriot

Keyword(s):

Bile Acid ◽

Bile Acids ◽

Dependent Manner ◽

Content Type ◽

Clostridioides Difficile ◽

Coculture System ◽

The Relationship ◽

Strain Dependent ◽

Secondary Bile Acids

ABSTRACT Clostridioides difficile is one of the leading causes of antibiotic-associated diarrhea. Gut microbiota-derived secondary bile acids and commensal Clostridia that carry the bile acid-inducible (bai) operon are associated with protection from C. difficile infection (CDI), although the mechanism is not known. In this study, we hypothesized that commensal Clostridia are important for providing colonization resistance against C. difficile due to their ability to produce secondary bile acids, as well as potentially competing against C. difficile for similar nutrients. To test this hypothesis, we examined the abilities of four commensal Clostridia carrying the bai operon (Clostridium scindens VPI 12708, C. scindens ATCC 35704, Clostridium hiranonis, and Clostridium hylemonae) to convert cholate (CA) to deoxycholate (DCA) in vitro, and we determined whether the amount of DCA produced was sufficient to inhibit the growth of a clinically relevant C. difficile strain. We also investigated the competitive relationships between these commensals and C. difficile using an in vitro coculture system. We found that inhibition of C. difficile growth by commensal Clostridia supplemented with CA was strain dependent, correlated with the production of ∼2 mM DCA, and increased the expression of bai operon genes. We also found that C. difficile was able to outcompete all four commensal Clostridia in an in vitro coculture system. These studies are instrumental in understanding the relationship between commensal Clostridia and C. difficile in the gut, which is vital for designing targeted bacterial therapeutics. Future studies dissecting the regulation of the bai operon in vitro and in vivo and how this affects CDI will be important. IMPORTANCE Commensal Clostridia carrying the bai operon, such as C. scindens, have been associated with protection against CDI; however, the mechanism for this protection is unknown. Herein, we show four commensal Clostridia that carry the bai operon and affect C. difficile growth in a strain-dependent manner, with and without the addition of cholate. Inhibition of C. difficile by commensals correlated with the efficient conversion of cholate to deoxycholate, a secondary bile acid that inhibits C. difficile germination, growth, and toxin production. Competition studies also revealed that C. difficile was able to outcompete the commensals in an in vitro coculture system. These studies are instrumental in understanding the relationship between commensal Clostridia and C. difficile in the gut, which is vital for designing targeted bacterial therapeutics.

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Delivery of Phenolic Compounds, Peptides and β-Glucan to the Gastrointestinal Tract by Incorporating Dietary Fibre-Rich Mushrooms into Sorghum Biscuits

Foods ◽

10.3390/foods10081812 ◽

2021 ◽

Vol 10 (8) ◽

pp. 1812

Author(s):

Juncai Tu ◽

Margaret Anne Brennan ◽

Gang Wu ◽

Weidong Bai ◽

Ping Cheng ◽

...

Keyword(s):

Phenolic Compounds ◽

Dietary Fibre ◽

Lentinula Edodes ◽

Phenolic Content ◽

Antioxidant Activities ◽

In Vitro Digestion ◽

Total Phenolic ◽

Soluble Peptide ◽

Insoluble Dietary Fibre

Sorghum biscuits were enriched with mushroom powders (Lentinula edodes, Auricularia auricula and Tremella fuciformis) at 5%, 10% and 15% substitution levels. An in vitro gastrointestinal digestion was used to evaluate the effect of this enrichment on the phenolic content and soluble peptide content as well as antioxidant activities of the gastric or intestinal supernatants (bio-accessible fractions), and the remaining portions of phenolic compounds, antioxidants and β-glucan in the undigested residue (non-digestible fraction). The phenolic content of the gastric and intestinal supernatants obtained from digested mushroom-enriched biscuits was found to be higher than that of control biscuit, and the phenolic content was positively correlated to the antioxidant activities in each fraction (p < 0.001). L. edodes and T. fuciformis enrichment increased the soluble protein content (small peptide) of sorghum biscuits after in vitro digestion. All mushroom enrichment increased the total phenolic content and β-glucan content of the undigested residue and they were positively correlated (p < 0.001). The insoluble dietary fibre of biscuits was positively correlated with β-glucan content (p < 0.001) of undigested residue. These findings suggested that enriching food with mushroom derived dietary fibre increases the bioavailability of the non-digestible β-glucan and phenolic compounds.

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The Effects of Sulfated Secondary Bile Acids on Intestinal Barrier Function and Immune Response in an Inflammatory in vitro Human Intestinal Model

SSRN Electronic Journal ◽

10.2139/ssrn.3940829 ◽

2021 ◽

Author(s):

Benthe van der Lugt ◽

Maartje C.P. Vos ◽

Mechteld Grootte Bromhaar ◽

Noortje Ijssennagger ◽

Frank Vrieling ◽

...

Keyword(s):

Immune Response ◽

Bile Acids ◽

Barrier Function ◽

Intestinal Barrier ◽

Intestinal Barrier Function ◽

Secondary Bile Acids

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Recent advances in understanding bile acid homeostasis

F1000Research ◽

10.12688/f1000research.12449.1 ◽

2017 ◽

Vol 6 ◽

pp. 2029 ◽

Cited By ~ 52

Author(s):

John YL Chiang

Keyword(s):

Bile Acid ◽

Bile Acids ◽

Acid Synthesis ◽

Bile Acid Synthesis ◽

Farnesoid X Receptor ◽

Recent Advances ◽

Bile Acid Pool Size ◽

Bile Acid Receptor ◽

Acid Toxicity ◽

G Protein Coupled

Bile acids are derived from cholesterol to facilitate intestinal nutrient absorption and biliary secretion of cholesterol. Recent studies have identified bile acids as signaling molecules that activate nuclear farnesoid X receptor (FXR) and membrane G protein-coupled bile acid receptor-1 (Gpbar-1, also known as TGR5) to maintain metabolic homeostasis and protect liver and other tissues and cells from bile acid toxicity. Bile acid homeostasis is regulated by a complex mechanism of feedback and feedforward regulation that is not completely understood. This review will cover recent advances in bile acid signaling and emerging concepts about the classic and alternative bile acid synthesis pathway, bile acid composition and bile acid pool size, and intestinal bile acid signaling and gut microbiome in regulation of bile acid homeostasis.

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Water-Dispersible Phytosterol Nanoparticles: Preparation, Characterization, and in vitro Digestion

Frontiers in Nutrition ◽

10.3389/fnut.2021.793009 ◽

2022 ◽

Vol 8 ◽

Author(s):

Ao Li ◽

Aixia Zhu ◽

Di Kong ◽

Chunwei Wang ◽

Shiping Liu ◽

...

Keyword(s):

Particle Size ◽

Soybean Lecithin ◽

Average Particle Size ◽

Soy Protein Isolate ◽

In Vitro Digestion ◽

Bimodal Distribution ◽

Average Particle ◽

Food Ingredients ◽

The Impact

For improving solubility and bioaccessibility of phytosterols (PS), phytosterol nanoparticles (PNPs) were prepared by emulsification–evaporation combined high-pressure homogenization method. The organic phase was formed with the dissolved PS and soybean lecithin (SL) in anhydrous ethanol, then mixed with soy protein isolate (SPI) solution, and homogenized into nanoparticles, followed by the evaporation of ethanol. The optimum fabrication conditions were determined as PS (1%, w/v): SL of 1:4, SPI content of 0.75% (w/v), and ethanol volume of 16 ml. PNPs were characterized to have average particle size 93.35 nm, polydispersity index (PDI) 0.179, zeta potential −29.3 mV, and encapsulation efficiency (EE) 97.3%. The impact of temperature, pH, and ionic strength on the stability of fabricated PNPs was determined. After 3-h in vitro digestion, the bioaccessibility of PS in nanoparticles reached 70.8%, significantly higher than the 18.2% of raw PS. Upon freeze-drying, the particle size of PNPs increased to 199.1 nm, resulting in a bimodal distribution. The solubility of PS in water could reach up to 2.122 mg/ml, ~155 times higher than that of raw PS. Therefore, this study contributes to the development of functional PS-food ingredients.

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Disease-Associated Gut Microbiota Reduces the Profile of Secondary Bile Acids in Pediatric Nonalcoholic Fatty Liver Disease

Frontiers in Cellular and Infection Microbiology ◽

10.3389/fcimb.2021.698852 ◽

2021 ◽

Vol 11 ◽

Author(s):

Jiake Yu ◽

Hu Zhang ◽

Liya Chen ◽

Yufei Ruan ◽

Yiping Chen ◽

...

Keyword(s):

Liver Disease ◽

Bile Acid ◽

Gut Microbiota ◽

Fatty Liver ◽

Nonalcoholic Fatty Liver Disease ◽

Bile Acids ◽

Fatty Liver Disease ◽

Healthy Children ◽

Nonalcoholic Fatty Liver ◽

Secondary Bile Acids

Children with nonalcoholic fatty liver disease (NAFLD) display an altered gut microbiota compared with healthy children. However, little is known about the fecal bile acid profiles and their association with gut microbiota dysbiosis in pediatric NAFLD. A total of 68 children were enrolled in this study, including 32 NAFLD patients and 36 healthy children. Fecal samples were collected and analyzed by metagenomic sequencing to determine the changes in the gut microbiota of children with NAFLD, and an ultra-performance liquid chromatography coupled to tandem mass spectrometry (UPLC-MS/MS) system was used to quantify the concentrations of primary and secondary bile acids. The associations between the gut microbiota and concentrations of primary and secondary bile acids in the fecal samples were then analyzed. We found that children with NAFLD exhibited reduced levels of secondary bile acids and alterations in bile acid biotransforming-related bacteria in the feces. Notably, the decrease in Eubacterium and Ruminococcaceae bacteria, which express bile salt hydrolase and 7α-dehydroxylase, was significantly positively correlated with the level of fecal lithocholic acid (LCA). However, the level of fecal LCA was negatively associated with the abundance of the potential pathogen Escherichia coli that was enriched in children with NAFLD. Pediatric NAFLD is characterized by an altered profile of gut microbiota and fecal bile acids. This study demonstrates that the disease-associated gut microbiota is linked with decreased concentrations of secondary bile acids in the feces. The disease-associated gut microbiota likely inhibits the conversion of primary to secondary bile acids.

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