A Mechanism by which Ergosterol Inhibits the Promotion of Bladder Carcinogenesis in Rats.

We previously showed that ergosterol has an inhibitory effect on bladder carcinogenesis. In this study, we aimed to elucidate the molecular mechanism by which ergosterol inhibits bladder carcinogenesis using a rat model of N-butyl-N-(4-hydroxybutyl)nitrosamine-induced bladder cancer. The messenger ribonucleic acid (mRNA) expression level of the cell cycle-related gene cyclin D1 and inflammation-related gene cyclooxygenase-2 in bladder epithelial cells was significantly increased in the carcinogenesis group compared with the control group. In contrast, in ergosterol-treated rats, these increases were significantly suppressed. Ergosterol did not affect the plasma testosterone concentration or the binding of dihydrotestosterone to androgen receptor (AR). The mRNA expression levels of 5α-reductase type 2 and AR were higher in the carcinogenesis group than in the control group but were significantly decreased by ergosterol administration. These results suggest that ergosterol inhibits bladder carcinogenesis by modulating various aspects of the cell cycle, inflammation-related signaling, and androgen signaling. Future clinical application of the preventive effect of ergosterol on bladder carcinogenesis is expected.

Inhibitory effect of ergosterol on bladder carcinogenesis is due to androgen signaling inhibition by brassicasterol, a metabolite of ergosterol.

We previously revealed that Choreito, a traditional Kampo medicine, strongly inhibits bladder carcinogenesis promotion. We have also shown that Polyporus sclerotium, which is one of the crude drugs in Choreito, has the strongest bladder carcinogenesis inhibitory effect and that the ergosterol contained in Polyporus sclerotium is the main active component. In this study, we analyzed the mechanism by which ergosterol inhibits bladder carcinogenesis. Rats were given an N-butyl-N-(4-hydroxybutyl) nitrosamine (BHBN) solution ad libitum, and then a promoter [saccharin sodium (SS), DL-tryptophan, or BHBN] was administered together with ergosterol or its metabolite, brassicasterol. The bladders were removed from rats, and the inhibitory effect on carcinogenesis promotion was evaluated by an agglutination assay with concanavalin A (Con A). Although the oral administration of ergosterol inhibited the promotion of bladder carcinogenesis with SS, the intraperitoneal administration of brassicasterol showed a stronger effect. The effect of brassicasterol on carcinogenesis promotion was observed regardless of the type of promoter. Administration of testosterone to castrated rats increased the number of cell aggregates caused by Con A. In contrast, intraperitoneal administration of brassicasterol to castrated rats treated with testosterone significantly decreased the number of cell aggregates, confirming the inhibition of bladder carcinogenesis promotion. The inhibitory effect of ergosterol on bladder carcinogenesis is due to brassicasterol, a metabolite of ergosterol. The action of brassicasterol via androgen signaling may play a role in the inhibitory effect on bladder carcinogenesis promotion.

Effects of menthol on the pharmacokinetics of triazolam and phenytoin.

We have previously shown that menthol attenuates the anticoagulant effect of warfarin by increasing the expression levels of CYP3A and CYP2C in the liver. This study evaluated the effects of menthol on the pharmacokinetics of the CYP3A substrate triazolam and the CYP2C substrate phenytoin. Menthol was orally administered to mice for 7 d. Twenty-four hours after the administration of menthol, triazolam was orally administered, and the plasma concentration was measured. In addition, the CYP3A metabolic activity for triazolam and the CYP3A expression level in the liver were determined. The effects of menthol on the pharmacokinetics of phenytoin were assessed in the same manner. In the menthol-treated group, the area under the blood concentration-time curve (AUC) of triazolam was lower and its clearance was higher compared with the control group. The CYP3A metabolic activity and CYP3A expression level in the liver were significantly increased in the menthol-treated group compared with the control group. Similarly, the AUC of phenytoin was lower and the hepatic CYP2C expression level was higher in the menthol-treated group. Thus, menthol lowered the plasma concentrations of triazolam and phenytoin when concurrently administered. These effects may be attributed to an increased metabolic activity for these drugs due to the increased expression of CYP3A and CYP2C in the liver.

Menthol reduces the anticoagulant effect of warfarin by inducing cytochrome P450 2C expression.

Recently, it was reported that the anticoagulant effect of warfarin was reduced when patients receiving warfarin also took menthol. The purpose of this study is to reveal the mechanism of this reduced anticoagulant effect of warfarin from the pharmacokinetic point of view. Warfarin was orally administered to mice 24h after the administration of menthol for 2 days, and the plasma warfarin concentration was measured. In the menthol administration group, the area under the blood concentration time curve of warfarin was decreased by approximately 25%, while total clearance was increased to 1.3-fold compared to the control group. The hepatic cytochrome P450 (CYP) 2C protein expression level in the menthol administration group was significantly increased compared to that in the control group. An increase in the nuclear translocation of constitutive androstane receptor (CAR) was also observed. The addition of menthol to human hepatic cells, HepaRG cells, caused an increase in the mRNA expression level of CYP2C9. The results of this study revealed that menthol causes an increase in CYP2C expression levels in the liver, which leads to an enhancement of warfarin metabolism, resulting in a decreased anticoagulant effect of warfarin. It was also suggested that menthol acted directly on the liver and increased the expression level of CYP2C by enhancing the nuclear translocation of CAR.

Inhibition of aquaporin-3 water channel in the colon induces diarrhea.

Aquaporin (AQP) 3, which is predominantly expressed in the colon, is considered to play an important role in regulating the fecal water content in the colon. In this study, the role of AQP3 in the colon was examined using HgCl(2) and CuSO(4), which are known to inhibit AQP3 function. The fecal water content was measured up to 1 h after the rectal administration of HgCl(2) or CuSO(4) to rats. The results showed that the fecal water content in the HgCl(2) administration group increased significantly to approximately 4 times that in the control group, and severe diarrhea was observed. However, no changes were observed in the mRNA expression level of the osmoregulatory genes (sodium myo-inositol transporter and taurine transporter) and the level and distribution of AQP3 protein expression, as determined 1 h after the administration of HgCl(2). Comparable results were observed in the CuSO(4) administration group. The results of this study indicated that the inhibition of AQP3 function in the colon caused diarrhea. Therefore, it has been revealed that the fecal water content in the colon is controlled by the transport of water from the luminal side to the vascular side, which is mediated by AQP3. Our findings suggest that a drug that modulates the function or expression of AQP3 in the colon may represent a new target for the development of laxatives.