RESUMEN
Furan is a naturally forming compound found in heat-processed foods such as coffee, canned meats, and jarred baby food. It is concurrently found with analogues including 2-methylfuran (2-MF) and 3-methylfuran (3-MF), and toxicity studies demonstrate all are potent liver toxins. Toxicity studies found 3-MF is more toxic than either furan, or 2-MF. The present analysis assesses the transcriptional response in liver samples taken from male Fischer (F344) rats exposed to furan or 3-MF from 0 to 2.0 and 0-1.0 mg/kg bw/day, respectively, for 90 days. Transcriptional analyses found decreased liver function and fatty acid metabolism are common responses to both furan and 3-MF exposure. Furan liver injury promotes a ductular reaction through Hippo and TGFB signalling, which combined with increased immune response results in ameliorating perturbed bile acid homeostasis in treated rats. Failure to activate these pathways in 3-MF exposed rats and decreased p53 activity leads to cholestasis, and increased toxicity. Finally, BMD analysis indicate many of the most sensitive pathways affected by furan and 3-MF exposure relate to metabolism - malate dehydrogenase and glucose metabolism with BMDLs of 0.03 and 0.01 mg/kg bw/day for furan and 3-MF exposure, respectively, which agrees with BMDLs previously reported for apical and microarray data.
Asunto(s)
Furanos , Hígado , Ratas , Masculino , Animales , Ratas Endogámicas F344 , Furanos/análisis , Hígado/metabolismo , GenómicaRESUMEN
Ochratoxin A (OTA) is a mycotoxin produced by species of Penicillium and Aspergillus, and is found in many commodities including cereal grains, nuts, and coffee. OTA is a renal carcinogen and nephrotoxin at high concentrations, targeting the proximal tubules. This study uses transcriptomics and the previously reported apical data (Bondy et al., 2021) to infer mode-of-action of OTA toxicity in male and female rats exposed to low doses of OTA in utero and throughout development. Our findings support a male-specific activation of the innate and adaptive immune responses in F1 pups to OTA exposure. This was not found in the female F1 pups, and may be due to female-specific increased p38 activity and VDR signaling. Differentially expressed genes related to karyomegaly, MAPK activity, and immune activation appears to develop from in utero exposure to OTA whereas those related to decreased kidney and liver function, and changes to reproductive pathways occur in both rat generations. Together, these transcriptional results confirm that dietary exposure to OTA causes renal toxicity as well as alterations to hepatic and reproductive pathways in rats. In utero exposure of rats to OTA results in sex-specific alterations in immune response pathways, VDR signaling, and p38 activity.
Asunto(s)
Exposición Dietética , Ocratoxinas , Animales , Femenino , Genómica , Riñón/metabolismo , Masculino , Ocratoxinas/metabolismo , Ocratoxinas/toxicidad , Ratas , Ratas Endogámicas F344RESUMEN
Hexabromocyclododecane (HBCD) is a brominated flame retardant which was recommended by a UN expert body under the Stockholm Convention to be eliminated from the global marketplace in 2011; however, due to its ability to persist in the environment, undergo long-range transport and bioaccumulate, it remains a concern for human health. The commercial mix of HBCD (T-HBCD) consists of α-HBCD, ß-HBCD and γ-HBCD. Although the γ-HBCD (79%) isomer is the predominant isomer of T-HBCD, the most bioaccumulative isomer detected in mammals is the α-HBCD isomer. This study was undertaken to investigate three rat strains treated with commercial grade (technical) HBCD or HBCD enriched with the α isomer (A-HBCD) and to examine strain- and sex-related differences in response to exposure. Female Sprague Dawley (SD), Wistar (WI) and Fischer F344 (FI) rats were exposed for 28 days to either T-HBCD or A-HBCD in feed, at doses of 0, 250, 1250 and 5000â¯mg/kg diet. The FI rodent strain was found to be the most sensitive to effects of HBCD based on the greatest number of significantly affected endpoints which indicated that T-HBCD primarily affected liver and thyroid, resulting in multiple health effects. Consequently, male FI were included in the study and exposed to T- and A-HBCD. Histopathological data supports previously reported effects of HBCD on the thyroid and endocrine system although the effects in FI rats are significantly elevated compared to other strains. As with T-HBCD, liver and thyroid were found to be target organs of A-HBCD. Sex differences, specifically in tissue concentration levels, immune response parameters and in number and severity of thyroid and liver lesions, following exposure to either T- or A-HBCD were apparent, with treatment eliciting a greater response in males. Residue analysis revealed that α-HBCD is more bioaccumulative than γ-HBCD in all rodent strains, with levels of HBCD in animals treated with A-HBCD several fold higher for all tissues tested (7-11 fold at the highest dose). Thus, residue data supports the selective uptake (implies there are differences in bioavailability and/or bioaccumulation; is this the case or do certain isomers simply have a longer half-life) of specific isomers, with α-HBCDâ¯>â¯Î³-HBCD. Taken together, our study highlights the importance of selecting the most appropriate strain and of including both sexes in studies to ensure that sex-related differences in response to test chemical is taken into consideration. Moreover, ours is the first study to show the effects of a sub-acute exposure to a diet containing only HBCD enriched for the α isomer, which better represents the isomer ratios present in the biota due to bioaccumulation.