The influence of acetoacetate and butyrate on calcium influx and ATP concentrations in HT-29 cells.

The effects of acetoacetate and butyrate on Ca(2+)-influx in HT-29 cells were unknown. Extracellular signals can be transferred to the intracellular environment of the cell via changes in the Ca(2+)-concentration. Extracellular Ca2+ may enter the cell via Ca(2+)-channels in the plasma membrane. Physiological processes occurring within the cell are dependent on Ca(2+)-concentration, including enzyme activity. Intracellular Ca(2+)-concentrations were measured using Fura-2/AM, a fluorescent intracellular Ca(2+)-probe. Ca(2+)-concentrations were measured immediately on application of the inducers to the cells, as well as after a 9 day incubation period. The effect of these inducers on the L-type voltage-operated Ca(2+)-channels were determined using the whole-cell patch-clamp technique. To validate these results for the intestinal epithelial model, membrane current studies were performed on HT-29 cells grown on a polycarbonate membrane. ATP concentrations were measured, and the theoretical effect of the inducers on PDE 4 activity was determined. It was found that both acetoacetate and butyrate blocked Ca(2+)-influx through the L-type voltage-operated Ca(2+)-channels, resulting in the initial low Ca(2+)-concentration (p < 0.05). The blockage effect is short-lived as after a 9 day incubation period in the presence of the inducers, Ca(2+)-concentrations were higher than that of the HT-29 control sample (p < 0.05). ATP concentrations of the cells were decreased in the presence of the inducers (p < 0.05), whilst it was suggested that no interaction between the catalytic site of PDE 4 and the inducers existed.

Cyclic dipeptides in the induction of maturation for cancer therapy.

Studies have suggested a possible form of therapy based on the use of maturation-inducing compounds to induce differentiation of neoplastic cells and stimulate faster recovery of the normal cell population. The study of the effects of nine cyclic dipeptides on biochemical markers of differentiation implicated their potential to induce differentiation. Studies were undertaken to determine the specificity of these agents for HT-29 cell cultures as well as the identification of the signal transduction pathways affected by these agents inducing the differential gene expression observed in the cells. The cyclic dipeptides studied showed a high degree of specificity, having no significant effect on Caco-2 cells (P > 0.05), representing the normal gastrointestinal mucosa. All inducers administered were shown to affect the total energy state of HT-29 cells, an effect which increased the probability of HT-29 cell differentiation. Results indicated that those agents which induced differential gene expression acted at different steps in the isolated signal transduction pathway. Cyclo(Trp-Trp) and cyclo(Phe-Pro) induced a high degree of acetylation of histones (P < 0.05), while the remaining cyclic dipeptides induced a high degree of phosphorylation of histones (P < 0.05) (cyclo(Trp-Trp) induced a moderate degree of histone phosphorylation). The results from histone phosphorylation and acetylation and cyclic AMP responsive element binding protein phosphorylation studies suggest that the cyclic dipeptides activate a chromatin switch, which leads to the increase in accessibility of lineage-specific genes for transcription.

The biological activity of selected cyclic dipeptides.

Cyclic dipeptides are widely used as models for larger peptides because of their simplicity and limited conformational freedom. Some cyclic dipeptides have been shown to be antiviral, antibiotic and anti-tumour. The aim of this study was to determine the biological activity of four cyclic dipeptides synthesized in this laboratory: cyclo(L-phenylalanyl-L-prolyl), cyclo(L-tyrosyl-L-prolyl), cyclo(L-tryptophanyl-L-prolyl) and cyclo(L-tryptophanyl-L-tryptophanyl). The enhancement or inhibition of calcium channels in ventricular myocytes from rats and delayed-rectifier potassium channels in ventricular myocytes from guinea-pigs were determined by use of the whole-cell patch-clamp technique. The induction of differentiation in HT-29 cells was assessed by assaying for an increase in the expression of alkaline phosphatase. Antibiotic properties against Escherichia coli, Pseudomonas aeruginosa, Klebsiella pneumoniae, Staphylococcus aureus, Bacillus subtilus and Streptococcus sp. were determined by use of the Kirby-Bauer disc-diffusion assay. Results from these assays indicate that the cyclic dipeptides have biological activity in both prokaryotes and eukaryotes. Three of the dipeptides block cation channels in ventricular myocytes and all increase the expression of alkaline phosphatase. All the dipeptides have concentration-dependent antibacterial properties. These results suggest that with increased solubility the cyclic dipeptides might have potential as muscle relaxants, anti-tumour compounds and antibiotics.

Energy state in HT-29 cells is linked to differentiation.

The relationship between the energy source used by HT-29 cells and their state of differentiation was determined. Short chain fatty acids and acetoacetate were applied to the cells for 9 d, after which the medium was replaced with conventional culture medium for a further 9 d so that the permanence of the changes could be assessed (18 d). Glucose utilization and lactic acid, acetoacetate, and beta-hydroxybutyrate production by the cells were determined. Differentiation was assessed by the presence of the enzymes sucrase-isomaltase and carbonic anhydrase 1, as well as morphological changes of the cells. By tracing carbon from acetate, propionate, and butyrate through the cells, it was found that the carbon from the short-chain fatty acids was fluxed into acetoacetate. Significant amounts of acetoacetate were released by the propionate-treated culture after 9 d and the acetate-, propionate-, valerate-, and caproate-treated cultures after 18 d. A significant positive correlation was found between acetoacetate synthesis and differentiation. Acetoacetate applied to HT-29 cells also induced their differentiation. The acetate-, butyrate-, valerate-, isovalerate-, and caproate-treated cells underwent terminal differentiation, while the propionate- and isocaproate-treated cultures underwent programming events. We, therefore, conclude that HT-29 cells utilize short chain fatty acids in preference to glucose, metabolize these to ketones, thereby raising the energy state and effecting the observed morphological and functional changes in the cells.