The aryl hydrocarbon receptor ligands 2,3,7,8-tetrachlorodibenzo-p-dioxin and 3-methylcholanthrene regulate distinct genetic networks.

The two estrogen receptor isoforms ERα and ERß mediate biological effects of estrogens, but are also targets for endocrine disruptive chemicals (EDCs), compounds that interfere with hormonal signaling. 3-Methylcholanthrene (3-MC) and dioxin (TCDD) are EDCs and prototypical aryl hydrocarbon receptor (AhR) agonists, and can inhibit ER signaling. However, in contrast to TCDD, 3-MC gives rise to metabolites with estrogenic properties. We compared gene expression profiles in HepG2 cells after exposure to 3-MC, TCDD, and the synthetic estrogen diethylstilbestrol (DES). Interestingly, we observed little overlap between the genetic networks activated by 3-MC and TCDD, two compounds sometimes considered as interchangeable AhR ligands. Like DES, 3-MC induced a number of ER-regulated genes and lead to recruitment of ERα to the promoters of such genes. Interestingly, in contrast to DES, the estrogenic effects exerted by 3-MC were exclusively observed in ERα, but not in ERß-expressing cells, suggesting ER isoform selectivity of 3-MC-derived metabolites.

A single dose of enterolactone activates estrogen signaling and regulates expression of circadian clock genes in mice.

Enterolactone (EL) is an enterolignan produced by gut microbiota from dietary plant lignans. Epidemiological and experimental studies suggest that EL and plant lignans may reduce the risk of breast and prostate cancer as well as cardiovascular disease. These effects are thought to at least in part involve modulation of estrogen receptor activity. Surprisingly little is known about the in vivo estrogenicity of EL. In the present study, we investigated the target tissues of EL, the genes affected by EL treatment, and the response kinetics. Following a single dose of EL, luciferase was significantly induced in reproductive and nonreproductive tissues of male and female 3xERE-luciferase mice, indicating estrogen-like activity. Microarray analysis revealed that EL regulated the expression of only 1% of 17ß-estradiol target genes in the uterus. The majority of these genes were traditional estrogen target genes, but also members of the circadian signaling pathway were affected. Kinetic analyses showed that EL undergoes rapid phase II metabolism and is efficiently excreted. In vivo imaging demonstrated that the estrogen response followed similar, fast kinetics. We conclude that EL activates estrogen signaling in both male and female mice and that the transient responses may be due to the fast metabolism of the compound. Lastly, EL may represent a link among diet, gut microbiota, and circadian signaling.

Solute carriers (SLC) in inflammatory bowel disease: a potential target of probiotics?

Transporter proteins of the solute carriers (SLCs) family play a role in epithelial permeability and barrier function in the intestine, and polymorphisms in SLC genes are associated with inflammatory bowel disease. Many SLCs also mediate the bioavailability of pharmaceutical compounds, and the modulation of such transport systems to increase drug efficacy is, therefore, of great interest. We have undertaken a large-scale project to evaluate whether bacteria can modulate the expression of SLCs in the intestine. Here we report the effect of VSL[sharp]3 (a high-potency probiotic preparation) on the expression of 3 large solute carrier families, SLC4, SLC21, and SLC22, which are involved in the transport of bicarbonates, organic anions and cations, and affect the bioavailability of several pharmaceutical compounds. Two groups of animals (VSL[sharp]3 and phosphate-buffered saline controls) were studied for SLC expression in the intestine by Real-Time PCR at the beginning (day 1) and at the end (day 20) of the treatment, and 7 days after the interruption of the treatment. An effect of VSL[sharp]3 administration was detected on the expression of 10% of the studied genes. This reached statistical significance (P=0.01) for the poorly characterized sodium-borate cotransporter SLC4A11, which showed a 5-times lower expression in VSL[sharp]3 than in control mice on day 1 of probiotic treatment. VSL[sharp]3-driven changes in the expression levels of SLC transporters might contribute to its reported effects on intestinal permeability. The elucidation of SLC4A11 function in the intestine will be the key to fully evaluate the relevance of specific findings.