Colonic fermentation and markers of colorectal-cancer risk.
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The aim of this study was to determine the effect of soluble fiber on indexes of colon-cancer risk in postpolypectomy and nonpolyp patients. Forty-five postpolypectomy and 49 nonpolyp volunteers completed 2-wk metabolic studies where half of the group received oat-bran supplements and the other half took wheat-brain supplements. Colonic biopsies taken before and after the intervention showed no difference in the index of thymidine colonic-crypt-cell labeling, thymidine-labeling pattern, or nuclear aberrations. Nevertheless, fecal pH was significantly reduced by 0.23 +/- 0.07 pH units (P less than 0.002) as an index of increased colonic fermentation on oat bran. This was not associated with increased basal breath hydrogen concentrations; fecal butyrate concentrations were higher on wheat bran. We conclude that soluble fiber as oat brain appears to have no advantage over wheat bran in modifying putative risk factors for colonic cancer. (+info)
n-butyrate reduces the expression of beta-galactoside alpha 2,6-sialyltransferase in Hep G2 cells.
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n-Butyrate, a short chain fatty acid that is produced by colonic bacterial fermentation, is detectable in portal blood and induces differentiation in various human neoplastic cell lines. Earlier reports indicated approximately 20-fold induction in vitro by n-butyrate of the sialyltransferase that catalyzes terminal glycosylation of GM3 ganglioside in HeLa and colon cancer cells. We previously isolated a 1.3-kilobase cDNA for a human beta-galactoside alpha 2,6-sialyltransferase, for which N-linked glycoproteins are the acceptors. We report here that treatment of Hep G2 cells with 5 mM n-butyrate for 24 h reduced beta-galactoside alpha 2,6-sialyltransferase mRNA levels by approximately 90%. Reductions in mRNA level were followed by approximately 75 and approximately 90% reductions, respectively, in specific beta-galactoside alpha 2,6-sialyltransferase enzyme activity after treatment for 24 and 36 h with 5 mM n-butyrate. However, in contrast with earlier reports of enhanced ganglioside synthesis in response to n-butyrate treatment, incubation of Hep G2 cells with n-butyrate did not alter the ganglioside pattern as assessed by thin layer chromatography of lipids extracted from treated cells. Nuclear run-on reactions indicated that the rate of transcription of beta-galactoside, alpha 2,6-sialyltransferase was not altered by treatment with 5 mM n-butyrate for 24 h, but the effects of this treatment on cytoplasmic levels of beta-galactoside alpha 2,6-sialyltransferase mRNA were largely negated by co-treatment with actinomycin D or cycloheximide. Therefore, our results show that n-butyrate reduces expression of mature beta-galactoside alpha 2,6-sialyltransferase mRNA by post-transcriptional mechanisms. (+info)
Sodium butyrate inhibits myogenesis by interfering with the transcriptional activation function of MyoD and myogenin.
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Sodium butyrate reversibly inhibits muscle differentiation and blocks the expression of many muscle-specific genes in both proliferating myoblasts and differentiated myotubes. We investigated the role of the basic helix-loop-helix (bHLH) myogenic determinator proteins MyoD and myogenin in this inhibition. Our data suggest that both MyoD and myogenin are not able to function as transcriptional activators in the presence of butyrate, although both apparently retain the ability to bind DNA. Transcription of MyoD itself is extinguished in butyrate-treated myoblasts and myotubes, an effect that may be due to the inability of MyoD to autoactivate its own transcription. We present evidence that the HLH region of MyoD is essential for butyrate inhibition of MyoD. In contrast to MyoD and myogenin, butyrate does not inhibit the ubiquitous basic HLH protein E2-5 from functioning as a transcriptional activator. (+info)
Differential expression of S19 ribosomal protein, laminin-binding protein, and human lymphocyte antigen class I messenger RNAs associated with colon carcinoma progression and differentiation.
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Three complementary DNA encoding S19 ribosomal protein (S19), laminin-binding protein (LBP), and HLA class I (HLA-I) genes were isolated from a colon tumor-enriched subtraction library. To evaluate this mRNA expression, surgically removed colon tumors as well as matched normal tissue and human colon carcinoma cell lines showing various differentiation states, anchorage dependence, and proliferation states were examined by Northern blot analysis. The mRNA level of S19 mRNA (0.6 kilobase) was higher in primary colon carcinoma tissue than in matched normal colon tissue in 5 of 6 cases. In 2 of 4 cases, the expression of LBP mRNA (1.2 kilobases) was higher in carcinoma than in normal tissue. In 12 human colon cell lines, the level of LBP mRNA was higher in poorly differentiated cells. On the other hand, HLA-I mRNA (1.7 kilobases) was higher in well-differentiated cells. Although the S19 mRNA was expressed in both well- and poorly differentiated cells, a concomitant increase with tumor progression was observed in two pairs of cell lines derived from the same patients (SW480 and SW620; COLO201 and COLO205). Anchorage dependence of butyrate-treated HT29 colon carcinoma cells was correlated with lower levels of S19 and LBP mRNAs and higher levels of HLA-I mRNA expression compared with untreated cells. While the expression of S19 and LBP mRNAs was not changed due to cell growth states, HLA-I mRNA levels were found to be low in proliferating HT29 cells but highly induced in contact-inhibited cells. In summary, therefore, high expression of S19 and LBP combined with low expression of HLA-I were well correlated with colon carcinoma cells of higher malignant potential. (+info)
Vimentin expression as a late event in the in vitro differentiation of human promonocytic cells.
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The administration of either 12-O-tetradecanoyl phorbol-13-acetate (TPA, 3 x 10(-8) M), sodium butyrate (SB, 10(-3) M), N6,2'-O-dibutyryladenosine-3':5'-cyclic monophosphate (dbcAMP, 10(-3) M), cytosine arabinoside (ara-C, 10(-7) M), amsacrine (mAMSA, 10(-7) M) or retinoic acid (RA, 10(-6) M) inhibits the growth activity of human promonocytic U-937 cells, by arresting them at G1 or at the G1/S border (SB, RA, ara-C), at G2 (mAMSA) or at G1 and G2 (dbcAMP). All these agents trigger cell differentiation, as proved by the increased expression of the maturation-associated CD11b and CD11c surface antigens, and induce the expression of the vimentin gene at both the protein and the mRNA levels. TPA, SB and dbcAMP behave as "early" inducers, in the sense that vimentin mRNA levels are rapidly increased (hour 6) upon drug administration. In contrast, mAMSA and RA behave as "late" inducers, since they do not increase vimentin mRNA levels until 48 to 72 hours, following the stimulation of surface antigen expression. The action of RA is characterized by an initial inhibition period, in which the basal level of vimentin mRNA is abolished (hour 24). Nevertheless, this RNA is later re-induced, to reach at 72 hours higher levels than in untreated cells. Moreover, RA is capable of delaying the early induction of vimentin expression caused by TPA and SB, without affecting the normal expression of differentiation markers. Taken together, these results strongly suggest that vimentin expression is not required at the initial stages of promonocytic cell differentiation, although it could play a role at an advanced stage. (+info)
Expression of tissue transglutaminase in Balb-C 3T3 fibroblasts: effects on cellular morphology and adhesion.
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Tissue transglutaminase is a cytosolic enzyme whose primary function is to catalyze the covalent cross-linking of proteins. To investigate the functions of this enzyme in physiological systems, we have established lines of Balb-C 3T3 fibroblasts stably transfected with a constitutive tissue transglutaminase expression plasmid. Several cell lines expressing high levels of catalytically active tissue transglutaminase have been isolated and characterized. Transglutaminase-transfected cells showed morphologic features quite distinct from their nontransfected counterparts. Many of the cells showed an extended and very flattened morphology that reflected increased adhesion of the cells to the substratum. Other cells, particularly those showing the highest levels of intracellular transglutaminase expression, showed extensive membrane blebbing and cellular fragmentation. The results of these experiments suggest that the induction and activation of tissue transglutaminase may contribute both to changes in cellular morphology and adhesiveness. (+info)
Effects of butyrate on cell cycle progression and polyploidization of various types of mammalian cells.
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We studied the effect of butyrate on cell cycle progression and polyploidization in three fibroblast (rat 3Y1, human IMR-90, and human embryo lung HEL) and two epithelial (human embryo kidney HEK and monkey kidney BSC-1) cells. In these cells, except for 3Y1, G1 arrest with butyrate was incomplete, and the production of tetraploid cells was detectable in the presence of butyrate. G2 arrest with butyrate was also incomplete in HEL and BSC-1 cells, and the number of HEL cells increased in the presence of butyrate. On the contrary, most BSC-1 cells that divided in the presence of butyrate were unstable and the number of attached cells decreased. These results indicate that the effect of butyrate on cell cycle progression varies with the cell type and that polyploidization can be induced by a single treatment with butyrate. (+info)
The effect of sodium butyrate on the growth characteristics of human cervix tumour cells.
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Sodium butyrate has been shown to affect cell proliferation, and, at concentrations above approximately 0.5 mM, to cause cell death in some tumour cell lines. When combined with cytotoxic drugs increase in chemosensitivity has been observed. We are presently carrying out a study of the combined effects of sodium butyrate and cytotoxic drugs on cultured cervix tumour cells. To provide a baseline for this study we have carried out a systematic investigation of the effects of sodium butyrate alone on the growth characteristics of cervix tumour cells cultured as multicell spheroids. This has shown that concentrations of n-butyrate of 0.005 mM to 0.50 mM decrease cell proliferation without inducing cell death, the effect increasing with increasing concentration. Butyrate concentrations greater than 0.50 mM cause cell death after a period of 5 to 15 days exposure, dependent on concentration. Concentrations of 0.010 mM and above cause fragmentation of, and increased cell shedding from, multicell spheroids, suggesting an effect on the cell surface. Concentrations of butyrate greater than 0.10 mM cause a considerable increase in the synthesis of cytokeratin, as shown by reaction with cytokeratin antibody. Correlated with this is a marked increase in cell size, concentrations of butyrate of 2.0 or 3.0 mM leading to an approximate doubling of cell diameter, followed by cell disintegration. The effects of butyrate less than 0.25 mM are readily reversible. At concentrations greater than 0.25 mM the effects are reversible up to a limit of about 7 to 20 days depending on concentration, even when cytokeratin synthesis has been induced. (+info)