Mouse Cyp2c expression and zonation structure in the liver begins in the early neonatal stage.

In the adult liver, drug-metabolizing enzymes such as cytochrome P450 (CYP) efficiently metabolize drugs by forming an expression pattern called "zonation" structure around the central veins (CV). However, most previous studies on CYPs have focused on the expression levels of CYP mRNA and proteins in the whole liver. In this study, we analyzed not only the expression levels of Cyp2c family mRNAs and proteins in mice during fetal liver development, but also the relationship with their localization. In the whole fetal liver, Cyp2c mRNA and protein were hardly expressed. On the other hand, zonation analysis results showed that only some cells around the CV of the fetal liver expressed Cyp2c. In addition, the protein expression level of Cyp2c in the whole liver during the neonatal period started from postnatal day (P) 7 in both males and females, while the zonation was weakly formed from P5. This study suggested that fetal liver cannot metabolize Cyp2c substrate drugs transferred from mother to fetus due to the low expression of Cyp2c and unformed zonation. The expression level of Cyp2c protein in neonates was lower than that in adult liver, and the zonation structure was not clear, suggesting that drug metabolism was not sufficient. Furthermore, this study revealed that the expression level of Cyp2c does not correlate with the formation of zonation structures, because Cyp2c expression is found in hepatocytes near the CV even in the fetal and neonatal stages, when Cyp2c protein expression is hardly detectable in the whole liver.

Maternal and Fetal Pharmacokinetic Analysis of Cannabidiol during Pregnancy in Mice.

Cannabidiol (CBD), a major component of cannabis, has various effects, such as antiemetic and anxiolytic activities, and has recently been marketed as a supplement. The number of people using CBD during pregnancy is increasing, and there are concerns about its effects on the fetus. In addition, the scientific evidence supporting the fetal safety of CBD use during pregnancy is insufficient. To investigate CBD transfer from the mother to the fetus, a single intravenous dose of CBD was administered to pregnant mice in this study, and fetal pharmacokinetics (distribution and elimination) was analyzed. The transfer of CBD from the maternal blood to the fetus was rapid, and the compound accumulated in the fetal brain, liver, and gastrointestinal tract. Conversely, little CBD was transferred from the mother to the amniotic fluid. We analyzed the pharmacokinetics of CBD using a two-compartment model and found that the maternal and fetal half-lives of CBD were approximately 5 and 2 hours, respectively. Furthermore, we performed a moment analysis of the pharmacokinetics of CBD, observing a mean residence time of less than 2 hours in both the mother and fetus. These results suggest that once-daily CBD intake during pregnancy is unlikely to result in CBD accumulation in the mother or fetus. SIGNIFICANCE STATEMENT: CBD is currently marketed as a supplement, and despite its increasing use during pregnancy, little information concerning its fetal effects has been reported. In the present study, CBD was administered to pregnant mice, and the pharmacokinetics in the fetus was investigated using a two-compartment model and moment analysis. The results of these analyses provide important information for estimating the risk to the fetus if CBD is mistakenly consumed during pregnancy.

Zonation of the drug-metabolizing enzyme cytochrome P450 3A in infant mice begins in pre-weaning period.

The drug-metabolizing enzyme CYP3A is a heterogeneous enzyme found in the liver that displays local characteristics referred to as "zonation." Zonation contributes to improved energy efficiency in metabolism. The objective of this study was to determine a scientific basis for the safety of fetuses and nursing infants in cases in which the use of pharmaceuticals by pregnant and nursing mothers is unavoidable. In addition, we analyzed CYP3A zonation in the liver using mice from the fetus stage to the nursing stage. The livers of mice ranging from day 13.5 of the fetal stage to day 7 of the nursing stage were resected and immunostained using rabbit anti-rat CYP3A2 Ab, which can detect CYP3A11, CYP3A13, CYP3A16, CYP3A25, CYP3A41 and CYP3A44. The results indicated that zonation did not begin in the fetus stage up to day 3 of the nursing stage, and began on day 7 of infancy. This study revealed that changes in the metabolic activity of CYP3A in the liver between the fetal and nursing stages are partly related to zonation. Further studies are needed to establish standards for the proper use of pharmaceuticals by pregnant and nursing mothers.

Relationship between low midazolam metabolism by cytochrome P450 3A in mice and the high incidence of birth defects.

The use of midazolam in early stages of pregnancy has resulted in a high incidence of birth defects; however, the underlying reason is unknown. We investigated expression changes of the CYP3A molecular species and focused on its midazolam metabolizing activity from the foetal period to adulthood. CYP3A16 was the only CYP3A species found to be expressed in the liver during the foetal period. However, CYP3A11 is upregulated in adult mice, but has been found to be downregulated during the foetal period and to gradually increase after birth. When CYP3A16 expression was induced in a microsomal fraction of cells used to study midazolam metabolism by CYP3A16, its activity was suppressed. These results showed that the capacity to metabolize midazolam in the liver during the foetal period is very low, which could hence result in a high incidence of birth defects associated with the use of midazolam during early stages of pregnancy.

Analysis of CYP2R1 and CYP26A1 Expression Patterns in Regeneration in Mice with Liver Injury.

Cytochrome P450 enzymes (CYPs) are involved in the metabolism of various substances in the liver and small intestine and show markedly higher expression levels in the liver compared to other organs. The liver exhibits a remarkable capacity to regenerate. After excision of 70% of the liver, the organ can regenerate to its original size in approximately 1 week. Unlike the normal liver, in the injured liver, hepatic stem cells known as oval cells are considered to play an important role in regeneration. However, the role of CYPs in liver regeneration remains unclear. In the present study, we investigated the role of CYPs in the regeneration of injured liver. Liver injury was induced by 4-week repeated doses of 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) in the diet. Next, both DDC-fed mice and control diet (containing no DDC)-fed mice were subjected to 70% hepatectomy, and the hepatic gene expression patterns measured during regeneration were analyzed. Mice with DDC-induced liver injury expressed the oval cell markers cytokeratin 19 (CK19) and epithelial cell adhesion molecule (EpCAM), and partial hepatectomy increased the expression levels of CYP2R1 and CYP26A1 as well as the hepatoblast marker alpha-fetoprotein (AFP) in these mice. The results of this study suggest that CYP2R1 and CYP26A1 are important in the differentiation of oval cells into hepatoblast-like cells in the injured liver.

Role of the Drug-Metabolizing Enzyme CYP during Mouse Liver Development.

The drug-metabolizing enzyme CYP is mainly involved in the metabolism of various substances in the liver, such as drugs, endogenous substances, and carcinogens. Recent reports have also revealed that CYP1B1 plays a major role in the developmental process. Because the level of CYP expression is markedly high in the liver, we hypothesize that CYP plays a role in the developmental process of the liver. To verify this hypothesis, we analyzed the expression patterns of various CYP molecular species and their functions during the differentiation of embryonic stem cells (ES cells) into hepatocytes and the developmental process in mice. The results demonstrated that CYP2R1 and CYP26A1 are expressed at an earlier stage of the differentiation of ES cells into hepatocytes than hepatoblast-specific markers. Additionally, during the development of the mouse liver, CYP2R1 and CYP26A1 were mostly up-regulated during the stage when hepatoblasts appeared. In addition, when CYP2R1 and CYP26A1 expressions were forced in ES cells and liver of adult mice, they differentiated into hepatoblast marker positive cells. These results suggest that CYP2R1 and CYP26A1 may play a major role in hepatoblast cell differentiation during the development of the liver.

Mechanism for Increased Expression of UGT2B in the Liver of Mice with Neuropathic Pain.

Approximately 30% of patients with cancer pain experience concurrent neuropathic pain. Since these patients are not sufficiently responsive to morphine, the development of an effective method of pain relief is urgently needed. Decreased function of the µ opioid receptor, which binds to the active metabolite of morphine M-6-G in the brain, has been proposed as a mechanism for morphine resistance. Previously, we pharmacokinetically examined morphine resistance in mice with neuropathic pain, and demonstrated that the brain morphine concentration was decreased, expression level of P-glycoprotein (P-gp) in the small intestine was increased, and expression level and activity of uridine diphosphate glucuronosyltransferase (UGT)2B in the liver were increased. In order to clarify the mechanism of the increased expression of UGT2B, we examined the phase of neuropathic pain during which UGT2B expression in the liver begins to increase, and whether this increased expression is nuclear receptor-mediated. The results of this study revealed that the increased expression of UGT2B in the liver occurred during the maintenance phase of neuropathic pain, suggesting that it may be caused by transcriptional regulation which was not accompanied by increased nuclear import of pregnane X receptor (PXR).