We examined the effects of gut microbial catabolites of tryptophan on the aryl hydrocarbon receptor (AhR). Using a reporter gene assay, we show that all studied catabolites are low-potency agonists of human AhR. The efficacy of catabolites differed substantially, comprising agonists with no or low (i3-propionate, i3-acetate, i3-lactate, i3-aldehyde), medium (i3-ethanol, i3-acrylate, skatole, tryptamine), and high (indole, i3-acetamide, i3-pyruvate) efficacies. We displayed ligand-selective antagonist activities by i3-pyruvate, i3-aldehyde, indole, skatole, and tryptamine. Ligand binding assay identified low affinity (skatole, i3-pyruvate, and i3-acetamide) and very low affinity (i3-acrylate, i3-ethanol, indole) ligands of the murine AhR. Indole, skatole, tryptamine, i3-pyruvate, i3-acrylate, and i3-acetamide induced CYP1A1 mRNA in intestinal LS180 and HT-29 cells, but not in the AhR-knockout HT-29 variant. We observed a similar CYP1A1 induction pattern in primary human hepatocytes. The most AhR-active catabolites (indole, skatole, tryptamine, i3-pyruvate, i3-acrylate, i3-acetamide) elicited nuclear translocation of the AhR, followed by a formation of AhR-ARNT heterodimer and enhanced binding of the AhR to the CYP1A1 gene promoter. Collectively, we comprehensively characterized the interactions of gut microbial tryptophan catabolites with the AhR, which may expand the current understanding of their potential roles in intestinal health and disease.
Activation of pregnane X receptor (PXR) by clinical compounds during multidrug chemotherapy results in upregulation of the expression of PXR target genes, including cytochrome p450 3A4 (CYP3A4) and multidrug resistance protein 1 (MDR1), leading to chemoresistance. It is possible to overcome the PXR‐mediated chemoresistance by downregulating the upregulated PXR target genes by inhibiting the activated PXR. However, a selective and less‐toxic PXR antagonist has yet to be developed. In this regard, a clinical anticancer drug, with selective PXR antagonistic activity at its less‐toxic concentrations, would be beneficial. We sought to determine whether belinostat, a clinically‐used histone deacetylase inhibitor, inhibits the PXR target gene expression at its clinically relevant plasma concentrations (< ~100 μM) in human hepatocytes (primary hepatocytes & hepatocells) and intestinal cells (LS174T colon cancer cells). Rifampicin, an agonist of human PXR, was used to activate PXR. Cell viability and CYQUANT cell proliferation assays were performed to determine cytotoxicity and cell proliferation, respectively. Quantitative RT‐PCR assays were conducted to study the gene expression. CYP3A4 p450‐Glo and Rhodamine‐123 intracellular accumulation assays were performed to determine the function of CYP3A4 and MDR1, respectively. Belinostat, at its unbound therapeutic plasma concentrations (< ~5 μM) did not affect the viability of LS174T cells and the hepatocytes. Belinostat (1 & 3 μM) not only inhibited rifampicin‐induced gene expression of CYP3A4 and MDR1, but also attenuated rifampicin‐induced activity of CYP3A4 and MDR1. However, belinostat alone did not affect CYP3A4 or MDR1 gene expression. These results suggest that belinostat does not affect the basal expression of PXR target genes but downregulates the upregulated PXR target genes by inhibiting the ligand‐activated PXR. Notably, belinostat, at its PXR inhibiting concentrations, decreased rifampicin‐induced proliferation of LS174T cells, suggesting that belinostat suppresses PXR‐mediated proliferation of the cancer cells. Interestingly, belinostat failed to inhibit rodent PXR agonist pregnenolone‐16 alpha‐carbonitrile (PCN)‐induced expression of CYP3A1 (the rat analog of human CYP3A4) in rat primary hepatocytes, suggesting that belinostat exhibits species‐specific inhibition of PXR at unbound plasma therapeutic concentrations. Taken together, these results are consistent with the conclusion that belinostat, at its less‐toxic and clinically relevant unbound plasma concentrations, inhibits the ligand‐activated human PXR target gene expression. Future studies will determine the mechanisms of belinostat inhibition of PXR, and belinostat sensitization of the cancer cells to chemotherapy drugs with PXR agonistic activity. Support or Funding Information The authors would like to thank Drs. Coleman, Schwartz, and Tao for sharing their research facilities. This work was supported by the Auburn University Research Initiative in Cancer Grant, Animal Health and Disease Research Grant...
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