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Docosahexaenoic acid and butyrate synergistically modulate intracellular calcium compartmentalization to induce colonocyte apoptosisKolar, Satya Sree N. 15 May 2009 (has links)
Docosahexaenoic acid (DHA, 22:6n-3) from fish oil, and butyrate, a short-chain
fatty acid fiber-fermentation product, protect against colon tumorigenesis in part by
coordinately inducing apoptosis. We have demonstrated that the combination of these
two bioactive compounds demonstrates an enhanced ability to induce colonocyte
apoptosis by potentiating mitochondrial lipid oxidation. In order to explore the potential
involvement of intracellular Ca2+ in the pro-apoptotic effect of DHA and butyrate, young
adult mouse colonocytes (YAMC) and human colonocytes (HCT-116: p53+/+ and p53-
/-) were treated with DHA or linoleic acid (LA) for 72 h ± butyrate for the final 6, 12 or
24 h. Cytosolic and mitochondrial Ca2+ levels were measured using Fluo-4 and Rhod-2.
In addition, IP3 pool, store-operated channel (SOC)-mediated changes and apoptosis
were measured. DHA did not alter basal Ca2+ or apoptosis following 6 h butyrate cotreatment.
In contrast, at 12 and 24 h, DHA and butyrate treated cultures exhibited a
decrease in cytosolic Ca2+ and enhanced apoptosis compared to LA and butyrate. DHA
and butyrate also increased the mitochondrial-to-cytosolic Ca2+ ratio at 6, 12 and 24 h. The accumulation of mitochondrial Ca2+ preceded the onset of apoptosis which increased
only following 12 h of butyrate co-treatment. RU-360, a mitochondrial uniporter
inhibitor, abrogated mitochondrial Ca2+ accumulation and also partially blocked
apoptosis in DHA and butyrate co-treated cells. p53+/+ and p53-/- cells demonstrated
similar data with respect to all parameters.
Additionally, mitochondrial Ca2+ measurements were also made in rat primarycolonocyte-
culture. Rats were fed semipurified diets containing either fish oil (a source
of DHA) or corn oil (a source of LA), and colonic crypts were incubated in butyrate exvivo
and mitochondrial Ca2+ was quantified. Crypts from rats fed fish oil incubated in
butyrate exhibited an increase in the mitochondrial-to-cytosolic Ca2+ ratio compared to
fish oil only.
In summary, our results indicate for the first time that the combination of DHA
and butyrate, compared to butyrate alone, further enhances apoptosis by additionally
recruiting a p53-independent Ca2+-mediated intrinsic mitochondrial pathway. These data
explain in part why fermentable fiber when combined with fish oil exhibits an enhanced
ability to induce apoptosis and protect against colon tumorigenesis.
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The Influence of Dietary Iron and Tocopherols on Oxidative Stress and Ras-p21 Levels in the ColonStone, William L., Papas, Andreas M., LeClair, Irene O., Qui, Min, Ponder, Terry 01 December 2002 (has links)
The purpose of this investigation was to determine how dietary levels of α-tocopherol, γ-tocopherol and iron influence oxidative stress and ras-p21 levels in the colon. Rats were fed diets deficient in tocopherols (-E) or supplemented with either 0.156 mmol of α-tocopherol (AE)/kg diet or 0.156 mmol of γ-tocopherol (GE)/kg of diet. Half the rats in each of these three groups received dietary iron at a level of 35 mg/kg diet and the other half at eight times this level (280 mg/kg diet). Rats fed the AE diets had higher levels of Vitamin E in feces, colonocytes, plasma and liver than did rats fed the GE diets. Dietary iron levels did not influence tocopherol levels in plasma, liver or feces. For colonocytes, high dietary iron decreased tocopherol levels. The ratio of γ-tocopherol (in the GE groups) to α-tocopherol (in the AE groups) was 0.13 for plasma, 0.11 for liver, 0.28 for colonocytes and 0.51 for feces. The plasma ratio is not, therefore, predictive of the ratio in colonocytes and feces. High levels of dietary iron increased levels of fecal lipid hydroperoxides. Moreover, rats fed the GE diets had lower levels of fecal lipid hydroperoxides than rats fed the AE diets. The levels of ras-p21 were significantly lower in rats fed the GE diets compared with rats fed the AE diets. The γ-tocopherol may, therefore, play a significant role in preventing colon cancer. High levels of dietary iron were found to promote oxidative stress in feces and colonocytes.
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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.
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