Global ETD Search

61	The Simplified Human Intestinal Microbiota (SIHUMIx) Shows High Structural and Functional Resistance against Changing Transit Times in In Vitro Bioreactors Schäpe, Stephanie Serena, Krause, Jannike Lea, Engelmann, Beatrice, Fritz-Wallace, Katarina, Schattenberg, Florian, Liu, Zishu, Müller, Susann, Jehmlich, Nico, Rolle-Kampczyk, Ulrike, Herberth, Gunda, von Bergen, Martin 11 April 2023 (has links) Many functions in host–microbiota interactions are potentially influenced by intestinal transit times, but little is known about the effects of altered transition times on the composition and functionality of gut microbiota. To analyze these effects, we cultivated the model community SIHUMIx in bioreactors in order to determine the effects of varying transit times (TT) on the community structure and function. After five days of continuous cultivation, we investigated the influence of different medium TT of 12 h, 24 h, and 48 h. For profiling the microbial community, we applied flow cytometric fingerprinting and revealed changes in the community structure of SIHUMIx during the change of TT, which were not associated with changes in species abundances. For pinpointing metabolic alterations, we applied metaproteomics and metabolomics and found, along with shortening the TT, a slight decrease in glycan biosynthesis, carbohydrate, and amino acid metabolism and, furthermore, a reduction in butyrate, methyl butyrate, isobutyrate, valerate, and isovalerate concentrations. Specifically, B. thetaiotaomicron was identified to be affected in terms of butyrate metabolism. However, communities could recover to the original state afterward. This study shows that SIHUMIx showed high structural stability when TT changed—even four-fold. Resistance values remained high, which suggests that TTs did not interfere with the structure of the community to a certain degree. info:eu-repo/classification/ddc/570 ddc:570
62	Butyrate Permeation across the Isolated Ovine Reticulum Epithelium Rackwitz, Reiko, Dengler, Franziska, Gäbel, Gotthold 13 April 2023 (has links) We hypothesized that, due to the high pH of this compartment, the reticulum epithelium displays particular features in the transport of short-chain fatty acids (SCFA). Ovine reticulum epithelium was incubated in Ussing chambers using a bicarbonate-free buffer solution containing butyrate (20 mmol L−1). p-hydroxymercuribenzoic acid (pHMB), 5-(N-Ethyl-N-isopropyl)amiloride (EIPA), or ouabain were added to the buffer solution as inhibitors of monocarboxylate transporters, sodium-proton-exchangers, or the Na+/K+-ATPase, respectively. The short-circuit current (Isc) and transepithelial conductance (Gt) were monitored continuously while the flux rates of 14C-labelled butyrate were measured in the mucosal-to-serosal (Jmsbut) or serosal-to-mucosal direction (Jsmbut). Under control conditions, the mean values of Isc and Gt amounted to 2.54 ± 0.46 µEq cm−2 h−1 and 6.02 ± 3.3 mS cm−2, respectively. Jmsbut was 2.1 ± 1.01 µmol cm−2 h−1 on average and about twice as high as Jsmbut. Incubation with ouabain reduced Jmsbut, while Jsmbut was not affected. The serosal addition of EIPA did not affect Jmsbut but reduced Jsmbut by about 10%. The addition of pHMB to the mucosal or serosal solution reduced Jmsbut but had no effect on Jsmbut. Mucosally applied pHMB provoked a transient increase in the Isc. The serosal pHMB sharply reduced Isc. Our results demonstrate that butyrate can be effectively transported across the reticulum epithelium. The mechanisms involved in this absorption differ from those known from the rumen epithelium. info:eu-repo/classification/ddc/590 ddc:590
63	Environmentally Relevant Concentration of Bisphenol S Shows Slight Effects on SIHUMIx Schäpe, Stephanie Serena, Krause, Jannike Lea, Masanetz, Rebecca Katharina, Riesbeck, Sarah, Starke, Robert, Rolle-Kampczyk, Ulrike, Eberlein, Christian, Heipieper, Hermann-Josef, Herberth, Gunda, von Bergen, Martin, Jehmlich, Nico 20 April 2023 (has links) Bisphenol S (BPS) is an industrial chemical used in the process of polymerization of polycarbonate plastics and epoxy resins and thus can be found in various plastic products and thermal papers. The microbiota disrupting effect of BPS on the community structure of the microbiome has already been reported, but little is known on how BPS affects bacterial activity and function. To analyze these effects, we cultivated the simplified human intestinal microbiota (SIHUMIx) in bioreactors at a concentration of 45 µM BPS. By determining biomass, growth of SIHUMIx was followed but no differences during BPS exposure were observed. To validate if the membrane composition was affected, fatty acid methyl esters (FAMEs) profiles were compared. Changes in the individual membrane fatty acid composition could not been described; however, the saturation level of the membranes slightly increased during BPS exposure. By applying targeted metabolomics to quantify short-chain fatty acids (SCFA), it was shown that the activity of SIHUMIx was unaffected. Metaproteomics revealed temporal effect on the community structure and function, showing that BPS has minor effects on the structure or functionality of SIHUMIx. info:eu-repo/classification/ddc/570 ddc:570
64	Effets d’un régime hyperprotéique sur l’écosystème intestinal et d’un mélange d’acides aminés sur la cicatrisation de la muqueuse intestinale. / Effects of a high protein diet on intestinal ecosystem and of a amino acid mixture on intestinal mucosa healing. Liu, Xinxin 24 October 2013 (has links) Dans l'alimentation des pays industrialisés, l'apport en protéines est bien supérieur à l'apport nutritionnel conseillé (ANC). De plus, cet apport peut être encore supérieur lors de la consommation de régimes riches en protéines utilisés à des fins de perte de poids par des personnes obèses ou en surpoids. Cependant, les conséquences des régimes riches en protéines au niveau de l'écosystème du gros intestin sont encore très mal connues. Dans la première partie de cette thèse, nous avons étudié l'impact d'un régime hyperprotéique sur le microbiote, le contenu endoluminal du gros intestin et le métabolisme des colonocytes. Les rats ont consommé pendant 15 jours soit un régime hyperprotéique (53% de protéines) soit un régime normoprotéique (14% de protéines). Nous avons observé que le régime hyperprotéique réduit la quantité des groupes bactériens majeurs comme Clostridium coccoides et Clostridium leptum, ainsi que Faecalibacterium prausnitzii dans le microbiote du gros intestin avec conjointement des modifications sur sa biodiversité. En même temps, les quantités des produits finaux de la fermentation des acides aminés par le microbiote, les acides gras à chaîne courte (AGCC) et les acides gras à chaîne branchée sont fortement augmentées. Cependant, l'expression des transporteurs des acides monocarboxyliques et l'oxydation du butyrate par les colonocytes ne sont pas modifiés en lien avec des modifications mineures des concentrations en AGCC dues à une augmentation des contenus du gros intestin après l'ingestion du régime hyperprotéique. Il en résulte une augmentation de l'excrétion des AGCC dans les fèces. Ces phénomènes permettraient une homéostasie du métabolisme du butyrate dans les colonocytes, en lien avec le rôle crucial de cet AGCC sur l'épithélium du côlon. Dans la deuxième partie de cette thèse, nous avons testé l'effet d'un mélange d'acides aminés (Thr, Met et Glu) sur la cicatrisation de la muqueuse colique après une colite induite par le DSS (dextran sodium sulfate) ; un modèle d'étude des maladies inflammatoires intestinales souvent utilisé. Une optimisation de la cicatrisation de la muqueuse intestinale émerge comme une cible thérapeutique, dans la prise en charge de ces maladies. La colite a été induite chez le rat avec 5% (w/v) de DSS pendant 6 jours, puis, à l'arrêt du traitement DSS, les animaux ont soit reçu le mélange d'acides aminé soit l'Ala comme témoin iso-azoté, pendant 3, 7 et 10 jours. Nous avons observé que 10 jours de complément en mélange d'acides aminés améliorent la cicatrisation post-colite, avec des modifications sur le taux de synthèse protéique dans la muqueuse colique, sans toutefois modifier la résolution de l'inflammation. Nos résultats suggèrent que l'utilisation des mélanges d'acides aminés améliore la cicatrisation de la muqueuse colique après colite chimio-induite. / In industrialized countries, protein intake is largely higher than the recommended dietary allowance (RDA). Furthermore, high protein diets are used for their slimming effect by obese or overweight people. However, little is known regarding to the consequences of a high protein diet on the large intestinal ecosystem. We thus study the influence of a high protein diet on the microbiota, on the endoluminal composition of the large intestine and on the butyrate metabolism by isolated colonocytes. Rats received during 15 days either a high protein diet (53% of proteins) or a normo protein diet (14% of proteins). We observed that the quantity of major bacterial groups Clostridium coccoides and Clostridium leptum, but also Faecalibacterium prausnitzii was reduced in the microbiota of the large intestine together with modifications of its biodiversity. In the same time, the quantities of short-chain fatty acids (SCFA) and branched-chain fatty acids, final products of bacterial fermentation of amino acids, were increased. However, the expression of monocarboxylic acid transporters and butyrate oxidation in colonocytes remained unchanged, in association with minor changes of the SCFA concentrations due to marked increase of the weight of the large intestine content. We then observed an increase in the amount of SCFA in the feces. These phenomena would allow homeostatic metabolism of butyrate in colonocytes, in relationship with its crucial role on the colonic epitheliumIn. In the second part of this thesis, we have tested the effects of a mixture of amino acids (Thr, Met and Glu) on the colonic mucosa healing after colitis induced by DSS (dextran sodium sulphate); a model to study intestinal inflammatory bowel diseases largely used. Optimization of intestinal mucosa healing is more and more considered as a therapeutic goal. Colitis was induced in rats by 5% (w/v) DSS during 6 days, then at the end of the treatment with DSS, animals received either the amino acid mixture or Ala as iso-nitrogenous control, during 3, 7 or 10 days. We observed that 10 days amino acid mixture supplementation was able to improve the colonic mucosal healing, with modification of the protein synthesis rate, without however changes in the resolution of inflammation. Our results suggest that the supplementation with the amino acid mixture improve the mucosal healing after experimental colitis. Régime riche en protéines Microbiote Acides gras à chaîne courte Métabolisme des colonocytes Colite Cicatrisation de la muqueuse intestinale High protein diet Microbiota Short-Chain fatty acids Colonocyte metaboslim Colitis Intestinal mucosal healing 612.33
65	Effect of Bran Particle Size on Gut Microbiota Community Structure and Function Riya D Thakkar (6632180) 14 May 2019 (has links) With the advent of industrialization and food processing techniques the sizes of the cereal bran have been drastically reduced. In my thesis, I have tested the effect, if any, of wheat bran and maize bran particle size, in vitro, on the gut microbiota community structure by 16S rRNA sequencing and their function, by Short chain fatty acids (acetate, propionate, butyrate) production. In turn, we also linked the microbiota and SCFA differences to different chemical composition amongst variously sized fractions of wheat and maize bran. Food Sciences not elsewhere classified Cereal bran Maize bran Wheat bran Particle size 16s rRNA gut microbiota Short Chain Fatty Acids Acetate Propionate Butyrate In-vitro fermentation Upper gastrointestinal digestion
66	Transport kurzkettiger Fettsäuren über die basolaterale Membran des ovinen Pansenepithels: Mechanismen und Regulation auf Genebene Dengler, Franziska 11 February 2015 (has links) (PDF) Einleitung: Kurzkettige Fettsäuren (SCFA) stellen das hauptsächliche Energiesubstrat für Wiederkäuer dar. In Anbetracht des - bedingt durch höhere Milch-, Mast und Reproduktionsleistung - steigenden Energiebedarfs von Hauswiederkäuern wie Milchkuh und Mastbulle ist es von zentraler Bedeutung, die Mechanismen zur Resorption dieser Energielieferanten bzw. Ansatzpunkte für die Beeinflussung dieser Transportprozesse genau zu kennen. Dieses Wissen kann möglicherweise dabei helfen, zukünftig die Energieaufnahme der Tiere zu unterstützen bzw. sogar effizienter zu gestalten. Ziele der Untersuchungen: Deshalb war es Ziel der vorliegenden Arbeit, die Mechanismen zur Resorption von SCFA zu charakterisieren, wobei der Schwerpunkt auf den Transport aus den Pansenepithelzellen ins Blut gelegt wurde, da hierzu im Gegensatz zu ihrer Aufnahme aus dem Pansenlumen in die Epithelzellen noch sehr wenig bekannt war. In einem zweiten Schritt sollte untersucht werden, inwiefern die nachgewiesenen Mechanismen einer Regulation unterliegen und über welche Signalwege diese vermittelt werden könnte. Materialien und Methoden: Zur Charakterisierung der beteiligten Resorptionsmechanismen wurden Epithelstücke aus dem ventralen Pansensack von Schafen in Ussing-Kammern eingespannt und mit Hilfe radioaktiv markierten Azetats, Butyrats und L-Laktats der Transport dieser Substrate unter verschiedenen Bedingungen sowie verschiedenen Hemmstoffeinflüssen untersucht. Zur Charakterisierung regulativer Einflüsse wurden die Epithelstücke über sechs bzw. 24 Stunden mit Butyrat inkubiert und anschließend RNA bzw. Totalprotein extrahiert. Hiermit konnten Veränderungen in mRNA- und Proteinexpression mittels quantitativer Echtzeit-PCR bzw. Western Blot nachgewiesen werden. Ergebnisse: Die Untersuchungen der vorliegenden Arbeit konnten zeigen, dass der Transport von SCFA über die basolaterale Membran des Pansenepithels hauptsächlich proteinvermittelt erfolgt. Eine signifikante Beteiligung lipophiler Diffusion, d.h. ein passiver Transport, kann weitgehend ausgeschlossen werden. Der aktive Transport wies eine bikarbonatabhängige und eine bikarbonatunabhängige Komponente auf. Der Einsatz von Hemmstoffen verschiedener Transportproteine ergab deutliche Hinweise darauf, dass der Monocarboxylattransporter (MCT) 1 eine Rolle beim bikarbonatgekoppelten Transport von Azetat bzw. allgemein unmetabolisierten SCFA spielt. Diese Hinweise wurden untersetzt durch die Beobachtung, dass MCT 1, aber auch der apikal bzw. intrazellulär lokalisierte MCT 4 durch langfristige Inkubation des Epithels mit Butyrat sowohl auf mRNA- als auch auf Proteinebene signifikant erhöht exprimiert wurden, was als Anpassungsreaktion an eine Substratakkumulation interpretiert werden kann. Außerdem wurde auch die mRNA-Expression des Putativen Anionentransporters (PAT) 1 durch Inkubation mit Butyrat erhöht, was für eine Beteiligung auch dieses Transportproteins am SCFA-Transport über das Pansenepithel spricht. Allerdings ist im Gegensatz zu MCT 1 die Lokalisation des PAT 1 in der basolateralen Membran noch fraglich. Die Expressionssteigerung von Zielgenen des Nukleären Faktors ĸB und des Peroxisomenproliferator-aktivierten Rezeptors α sowie des Hypoxie-induzierbaren Faktors selbst deuten weiterhin darauf hin, dass die Steigerung der Transportkapazitäten von MCT 1 und 4 und auch PAT 1 über diese Signalwege vermittelt wird. Schlussfolgerungen: Zusammenfassend konnte in dieser Arbeit erstmals der Transport von SCFA über die basolaterale Membran des Pansenepithels näher charakterisiert werden, sodass es nun möglich ist, zusammen mit den bereits vorliegenden Befunden für die apikale Membran ein komplettes Modell dafür zu erstellen. Auch wurden Erkenntnisse zu regulativen Einflüssen auf diesen Transport gewonnen, die es zukünftig ermöglichen könnten, die Resorption der SCFA aus dem Pansen nutritiv oder eventuell pharmakologisch zu beeinflussen. / Introduction: The main energy source for ruminants are short chain fatty acids (SCFA). Considering the ever increasing energy requirements of cattle due to increasing milk yield and meat production, it is crucial to identify the mechanisms for the resorption of these energy sources as well as possibilities to influence these transport mechanisms. This knowledge could help support the animals’ energy uptake or even making it more efficient. Aim: Thus, the aim of the present study was to characterise mechanisms for the resorption of SCFA focusing on their transport from the epithelial cells into the blood. In particular, since – compared to the research findings on the uptake of SCFA from ruminal lumen into the cells – so far only very little was known regarding this side of the epithelium. In a second step, the study aimed to elucidate whether the mechanisms observed are subject to regulatory processes and which signalling pathways are involved. Materials and methods: To characterise the transport mechanisms involved, epithelial pieces from the ventral sac of ovine rumen were mounted in Ussing chambers. Using radioactively labelled acetate, butyrate and L-lactate, the transport of these substrates was investigated under different conditions and by applying different inhibitors for potential SCFA transport proteins. To characterise regulatory influences, epithelial pieces were incubated with butyrate for six and 24 hours, respectively. Subsequently, total RNA and protein were extracted to detect changes in mRNA and protein expression using quantitative real time PCR and western blot, respectively. Results: The present study could show that transport of SCFA across the basolateral membrane of rumen epithelium is mainly realised by protein-mediated mechanisms. A significant participation of lipophilic diffusion, i.e. a passive transport, can almost entirely be excluded. The active transport could be divided into a bicarbonate-dependent and a bicarbonate-independent part. The experiments with inhibitors of different transport proteins showed clear evidence of an involvement of monocarboxylate transporter (MCT) 1 in the bicarbonate-dependent transport of acetate and non-metabolised SCFA in general. This evidence was supported by the finding that the expression of MCT 1 but also of the apically and intracellularly localised MCT 4 was increased significantly on both mRNA- and protein-level after long-term incubation of the epithelium with butyrate. This can be interpreted as an adaptation to a substrate accumulation. Additionally, butyrate incubation led to an increased mRNA expression of putative anion transporter (PAT) 1, which makes an involvement of this transport protein in SCFA transport across ruminal epithelium likely as well. However, in contrast to MCT 1 the localisation of PAT 1 in the basolateral membrane is still questionable. The increased expression of target genes of nuclear factor ĸB and peroxisome-proliferator activated receptor α as well as of hypoxia inducible factor strongly point to an involvement of these pathways in the increased expression of MCT 1 and 4 as well as PAT 1. Conclusions: In summary, this study could characterise the transport of SCFA across the basolateral membrane of ruminal epithelium in detail for the first time. This enables us to draw a complete model of ruminal SCFA transport. Also, evidence for regulatory influence on this transport processes was found, perhaps making it possible to influence resorption of SCFA from rumen by nutritive or pharmacological means in the future. Kurzkettige Fettsäuren Monocarbolyttransporter mRNA-Expression Pansenepithel Putativer Anionentransporter Proteinexpression Ussing-Kammer short chain fatty acids monocarboxylate transporter mRNA-expression rumen epithelium putative anion transporter protein expression Ussing chamber ddc:571 ddc:636.089
67	Development of a GC Method for the Quantification of Short Chain Carboxylic Acids in Aqueous Solution Åkervall, Anton January 2020 (has links) Petroleum powered vehicles emit volatile organic compounds (VOCs) through combustion that contributes to the pollution of the environment. A technique in the 1970s was developed to decrease these emissions, especially for nitrogen oxides (NOx) and sulphuric oxides (SOx) which is called exhaust gas recirculation (EGR). The technique works by recirculating a portion of the combusted gas back into the engine, this limits the NOx and SOx emissions because of lower temperatures and less available oxygen. The problems that follow these effects is the formation and condensation of acids that corrode the material of the EGR system, which are created by many different reactions. It is of importance to understand how the compounds in the EGR system behaves through analysis of authentic and simulated condensates, which is why a quantitative method for these compounds are of interest. The aim of the project was to develop a simple quantitative analysis method for formic acid, acetic acid, and lactic acid in aqueous solution, which was done at Gränges Sweden AB. The technique used for detection and quantification was gas chromatography (GC) coupled to a flame ionization detector (FID) and a water compatible polyethylene glycol (PEG) column. Fractional factorial design (FFD) was used for determination of adequate operating parameters of the GC method and the sample preparation. Sample preparation only required filtration and pH adjustment prior to direct aqueous injection (DAI) to the chromatographic instrument. Detection of the analytes was very difficult because of non-compatibility with the FID, and quantification of asymmetric peak shapes made this problem worse, omitting lactic acid from further analysis. Limit of detection (LOD) and limit of quantification (LOQ) was 490 and 1640 ppm for formic acid and 120 and 400 ppm for acetic acid, with an injection volume of 0.3 μL and split ratio 10:1. Limits were too high for every EGR sample leaving no peaks detected for the sample preparation used. Further development should be done with complementary techniques and sample reprocessing in order to quantify the compounds. DAI-GC-FID Direct Aqueous Injection Gas Chromatography Flame Ionization Detector SCFA Short Chain Fatty Acids Formic Acid Acetic Acid Lactic Acid EGR Exhaust Gas Recirculation CAC Charged Air Cooler FFD Fractional Factorial Design Analytical Chemistry Analytisk kemi
68	Consequences of Dietary Fibers and their Proportion on the Fermentation of Dietary Protein by Human Gut Microbiota Rachel M. Jackson (5930684) 05 December 2019 In the human gut, bacterial fermentation of dietary fibers and proteins produces metabolites, primarily as short-chain fatty acids (SCFA), that are highly beneficial for host health. However, unlike dietary fiber, bacterial fermentation of protein additionally generates potentially toxic substances such as ammonia, hydrogen sulfide, amines, and indoles. It is believed that most gut bacteria favor utilization of dietary fiber over that of protein for energy. Therefore, when fermentable dietary fiber is readily available to colonic bacteria, protein fermentation, and its subsequent potentially toxic metabolites, remains relatively low. Dietary intake primarily determines the quantity of dietary fiber and protein substrate available to the gut microbiota and the resulting profile of metabolites produced. Increased protein consumption is associated with deleterious health outcomes such as higher risk of colorectal cancer and type II diabetes. Conversely, diets following US dietary recommendations are high in fiber, which promote a healthy microbiome and are protective against disease. Diets following the recommendation are also moderate in protein intake so that, ultimately, far more fiber than protein is available for colonic bacterial fermentation. On the contrary, dietary fiber intake is chronically low in a standard Western diet, while protein consumption is above dietary recommendations, which results in nearly equal amounts of dietary fiber and protein available for gut microbial fermentation. Furthermore, the popularity of high-protein diets for athletes, as well as that of high-protein low-carbohydrate diets for weight loss, may flip fiber and protein substrate proportions upside down, resulting in more protein than fiber available in the gut for fermentation. The objective of this study was to elucidate how substrate ratios in protein-fiber mixtures affect protein fermentation and metabolites, as well as examine the degree to which fiber source may influence these outcomes. Each dietary fiber source [fructooligosaccharides (FOS), apple pectin (Pectin), a wheat bran and raw potato starch mixture (WB+PS), and an even mixture of the three aforementioned fibers (Even Mix)] and protein were combined in three ratios and provided as substrate for in vitro fecal fermentation to understand how low, medium, and high fiber inclusion levels influence fermentation outcomes. They were compared to 100% protein and fiber (each different fiber) controls. Branched-chain fatty acids (BCFAs), metabolites produced exclusively from protein fermentation, were used as a measure of protein fermentation; the data were normalized based on the initial quantity of protein within the substrate. In protein-fiber substrate mixtures, only FOS and Even Mix inhibited BCFAs (mM/g protein basis) and only when they made up at least half of the substrate. Unexpectedly, the rate of protein fermentation was increased when the protein-fiber substrate contained 25% WB+PS fiber, possibly due to the starch component of the fiber. There was evidence that when pH drops during fermentation, as was the case for protein-FOS mixtures, it played a significant role in suppressing protein fermentation. Ammonia production was not largely affected by increasing the proportion of dietary fiber. A significant reduction did not occur until FOS made up at least 50% of the protein-fiber substrate; for Pectin, WB+PS, and Even Mix fibers, 75% inclusion was required for a significant decrease in ammonia. Interestingly, protein was butyrogenic. Protein as the sole substrate produced more butyrate than either Pectin or Even Mix as the sole substrates, and in fact, addition of Pectin to protein significantly reduced butyrate concentrations. However, the possible benefits of butyrate produced via protein fermentation needs to be tempered by the production of potentially toxic compounds and the association between protein fermentation and colorectal cancer. Overall, the thesis findings showed protein fermentation to be relatively stable and not easily influenced by increasing the availability of dietary fiber, and no clear evidence of microbial preference for carbohydrates over protein was found. Microbiology Food Sciences not elsewhere classified Fermentation microbiome dietary fiber dietary protein gut health metabolites gut bacteria butyrate short chain fatty acids branched chain fatty acids ammonia fermentation large intestine colon protein fermentation
69	Fabrication of Model Plant Cell Wall Materials to Probe Gut Microbiota Use of Dietary Fiber Nuseybe Bulut (5930564) 31 January 2022 (has links) The cell wall provides a complex and rigid structure to the plant for support, protection from environmental factors, and transport. It is mainly composed of polysaccharides, proteins, and lignin. Arabinoxylan (AX), pectin (P), and cellulose (C) are the main components of cereal cell walls and are particularly concentrated in the bran portion of the grain. Cereal arabinoxylans create networks in plant cell walls in which other cell wall polysaccharides are imbedded forming complex matrices. These networks give an insolubility profile to plant cell wall. A previous study in our lab showed that soluble crosslinked arabinoxylan with relatively high residual ferulic acid from corn bran provided advantageous <i>in vitro </i>human fecal fermentation products and promoted butyrogenic gut bacteria. In the present work, arabinoxylan was isolated from corn bran with a mild sodium hydroxide concentration to keep most of its ferulic acid content. Highly ferulated corn bran arabinoxylan was crosslinked to create an insoluble network to mimic the cereal grain cell wall matrices. Firstly, arabinoxylan film (Cax-F), pectin film (P-F), the film produced by embedding pectin into arabinoxylan networks (CaxP-F), and cellulose embedding arabinoxylan matrices (CaxC-F), and embedding the mixture of cellulose and pectin into arabinoxylan networks (CaxCP-F) were fabricated into simulated plant cell wall materials. Water solubility of films in terms of monosaccharide content was examined and revealed that Cax-F was insoluble, and P-F was partially insoluble, and nanosized pectin and cellulose were partially entrapped inside the crosslinked-arabinoxylan matrices. In a further study, these films were used in an <i>in vitro </i>human fecal fermentation assay to understand how gut microbiota access and utilize the different simulated plant cell walls to highlight the role of each plant cell wall component during colonic fermentation. <i>In vitro </i>fecal samples, obtained from three healthy donors were used to ferment the films (Cax-F, P-F, CaxP-F, CaxC-F, and CaxCP-F) and controls (free form of cell wall components -Cax, P and C). The fabricated films that were compositionally similar to cell walls were fermented more slowly than the free polysaccharides (Cax and P). Besides, CaxP-F produced the highest short chain fatty acids (SCFA) amount among the films after 24 hour <i>in vitro </i>fecal fermentation. Regarding specific SCFA, butyrate molar ratio of all films was significantly higher than the free, soluble Cax and P. 16S rRNA gene sequencing explained the differences of the butyrate proportion derived from specific butyrogenic bacteria. Particularly, some bacteria, especially in a butyrogenic genera from Clostridium cluster XIVa, were increased in arabinoxylan films forms compared to the native free arabinoxylan polysaccharide. However, no changes were observed between P and P-F in terms of both end products (SCFA) and microbiota compositions. Moreover, CaxP-F promoted the butyrogenic bacteria in fecal samples compared with pectin alone, arabinoxylan alone, and the arabinoxylan film. Differences in matrix insolubility of the film, which was high for the covalently linked arabinoxylan films, but low for the non-covalent ionic-linked pectin film, appears to play an important role in targeting Clostridial bacterial groups. Overall, the cell wall-like films were useful to understand which bacteria degrade them related to their physical form and location of the fiber polymers. This study showed how fabricated model plant cell wall films influence specificity and competitiveness of some gut bacteria and suggest that fabricated materials using natural fibers might be used for targeted support of certain gut bacteria and bacterial groups. Food Sciences not elsewhere classified Cereal Plant Cell Wall Cereal cell wall Arabinoxylan crosslinking arabinoxylan Cellulose Pectin Casting Film In-Vitro fermentation Short chain fatty acids (SCFAs) Acetate Butyrate Propionate 16S rRNA gene sequences Gut Microbiota
70	Intestinal Microbiome, Fecal Fermentation Profile, and Health Indices in HIV Infected Men versus Non-Infected Controls Andreae, Mary, Andreae, Mary C, Mrs 01 December 2023 (has links) (PDF) Many HIV-positive (HIV+) males on Highly Active Anti-Retroviral Therapy (HAART) experience metabolic abnormalities, including Non-Alcoholic Fatty Liver Disease (NAFLD) and lipodystrophy. The intestinal microbiota and short chain fatty acids (SCFA), participate in bidirectional communication with their host. Dysbiosis in HIV+ males on HAART demonstrate a Prevotella-rich enterotype shaped by multiple factors including, medications, adiposity, diet, intestinal permeability, and lifestyle; our objective was to investigate these factors. 19 HIV+ and 21 HIV- males were enrolled. BMI and hip-to-waist ratio (H:W) were obtained, and FibroScan for liver health. Intestinal permeability markers Claudin-21, flagellin, and intestinal fatty acid binding protein (IFABP) in serum via enzyme-linked immunoassay (ELISA). Stool was collected for 16s rRNA sequencing, SCFAs (gas chromatography), and proximate analyses (PA). PA analyses: Bomb calorimetry (kcal), soxhlet for lipids, kjeldhal for protein, and fiber. Dietary intake by food frequency questionnaires (FFQ). HIV+ males had significantly higher H:W and hepatic steatosis (pPrevotella and Lachnospiraceae compared to HIV- males. Additionally, HIV+ males had significantly higher central obesity and hepatic steatosis. In a retrospective analysis, all HIV+ men were men that have sex with men (MSM). These findings support differences in intestinal microbiome and SCFAs, and measures of altered lipid metabolism between HIV+ and HIV- males. These findings lay the framework for investigations into intestinal microbiome, SCFAs and metabolism in HIV+ MSM. HIV microbiome short chain fatty acids proximate analysis NAFLD Biochemistry Cardiovascular Diseases Dietetics and Clinical Nutrition Digestive System Diseases Immune System Diseases Immunology of Infectious Disease Other Microbiology Virus Diseases

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