Project description:Purpose: Next-generation sequencing (NGS) has been utilized for systems-based analysis of all liver samples. The goals of this study were to compare the hepatic transcriptome and PBDE metabolism between conventional (CV) and germ-free (GF) mice. Methods: Livers from vehicle (corn oil), BDE-47, or BDE-99 treated adult male CV and GF mice were used for RNA-Seq (biological replicates: n=3 for CV corn oil, n=4 for CV BDE-47, n=2 for CV BDE-99, n=3 for GF corn oil, n=3 for GF BDE-47, and n=3 for BDE-99) using a HiSeq 2000 sequencer. The sequence reads that passed quality filters were mapped to the mouse reference genome (mm10) using HISAT v 0.1.6 beta; transcript abundance and differential expression were determined using Cufflinks (CuffDiff) v 2.2.1. Results: Using an optimized data analysis workflow,RNA-Seq generated approximately 47 to 68 million reads per sample, among which approximately 40 to 60 million reads were uniquely mapped to the mouse reference genome (NCBI GRCm/38/mm10). And we identified 393 drug processing genes in the livers of WT and hCAR-TG with with HISAT workflow. RNA-seq data confirmed that among all the 393 DPGs with known important functions in xenobiotic biotransformation, 90 DPGs were not expressed in livers of any groups (threshold: average FPKM < 1 in all treatment groups); whereas a total of 303 genes were expressed in livers of at least one groups, among which 258 DPGs were differentially regulated by mCAR or hCAR activation in either Day 5 or Day 60 (FDR-BH<0.05), and 45 genes were stably expressed among all treatment groups. Conclusions: Our study has unveiled a novel interaction between gut microbiome and the hepatic biotransformation of PBDEs, demonstrating that germ-free conditions modified the hepatic oxidation of PBDEs as well as the expression of relevant drug-processing genes in liver.

Project description:Liver clock regulates transcription of hepatic genes in response to feeding. To explore the possibility that the microbiome influences this process, we measured the liver transcriptome in normal mice (Specific Pathogen Free or SPF mice) and compared it to the transcriptome in mice lacking microbiota (Germ Free or GF mice) at different time points over 24h. We used microarrays to detail the global programme of gene expression in liver of GF and SPF 10-12 weeks-old male C57Bl/6 male mice. There are 40 liver samples, each from an individual mouse. The samples are from germ free mice (GF) and specific pathogen free mice (SPF). Mice of both types were sacrificed at four time points: Zeitgeber Time 0, 6, 12, and 18. There are five replicates per condition.

Project description:Liver clock regulates transcription of hepatic genes in response to feeding. To explore the possibility that the microbiome influences this process, we measured the liver transcriptome in normal mice (Specific Pathogen Free or SPF mice) and compared it to the transcriptome in mice lacking microbiota (Germ Free or GF mice) at different time points over 24h. We used microarrays to detail the global programme of gene expression in liver of GF and SPF 10-12 weeks-old male C57Bl/6 male mice.

Project description:Deoxycholic acid (DCA) is a secondary bile acid produced by a small number of commensal species of bacteria present in the mammalian gut. Elevated DCA concentration correlates with disease states including colon cancer and cholesterol gallstones, but the associated mechanisms are not fully understood. Both primary and secondary bile acids are also capable of affecting gene expression through nuclear receptors such as FXR. To better understand the impact of a commensal-derived secondary bile acid on host metabolism we fed DCA to germ-free (GF) mice, which normally lack DCA, and compared the hepatic transcriptomes of bile acid fed GF mice to GF mice receiving a control diet, as well as to those of conventionally housed control animals. Interestingly, the feeding of DCA to GF mice, but not the feeding of cholic acid (CA) from which DCA is derived, results in an up-regulation of genes of cholesterol biosynthetic pathways. GF mice normally have elevated hepatic cholesterol compared to conventionally housed mice. Despite increase in the expression of cholesterol biosynthetic genes, the DCA fed GF mice showed a markedly decreased level of hepatic cholesterol equivalent to the hepatic cholesterol concentration of conventionally colonized animals. Total cholesterol in the serum was unaffected by DCA, but there was a decrease in the HDL lipoprotein fraction as well as an increase in the non-HDL lipoprotein fraction of the serum cholesterol. DCA, but not CA, is sufficient to modulate host lipoprotein metabolism. Taken together, these results suggests that a minor component of the gut microbiome has a significant impact on cholesterol homeostasis through secondary metabolism of bile acids and suggests a possible therapeutic intervention route through the microbial metabolic pathways. two mouse strains, three diets, one time point

Project description:This study aimed to quantify and compare the mRNA abundance of all major XPGs in liver and intestine between conventional (CV) and germ-free (GF) mice using RNA-Seq. The CV RNA-Seq data were previously uploaded to GEO database by the same research group (GSE79848). All CV and GF mice were age-matched, and were analyzed under the same conditions (diet, water, bedding, and animal facility).

Project description:Deoxycholic acid (DCA) is a secondary bile acid produced by a small number of commensal species of bacteria present in the mammalian gut. Elevated DCA concentration correlates with disease states including colon cancer and cholesterol gallstones, but the associated mechanisms are not fully understood. Both primary and secondary bile acids are also capable of affecting gene expression through nuclear receptors such as FXR. To better understand the impact of a commensal-derived secondary bile acid on host metabolism we fed DCA to germ-free (GF) mice, which normally lack DCA, and compared the hepatic transcriptomes of bile acid fed GF mice to GF mice receiving a control diet, as well as to those of conventionally housed control animals. Interestingly, the feeding of DCA to GF mice, but not the feeding of cholic acid (CA) from which DCA is derived, results in an up-regulation of genes of cholesterol biosynthetic pathways. GF mice normally have elevated hepatic cholesterol compared to conventionally housed mice. Despite increase in the expression of cholesterol biosynthetic genes, the DCA fed GF mice showed a markedly decreased level of hepatic cholesterol equivalent to the hepatic cholesterol concentration of conventionally colonized animals. Total cholesterol in the serum was unaffected by DCA, but there was a decrease in the HDL lipoprotein fraction as well as an increase in the non-HDL lipoprotein fraction of the serum cholesterol. DCA, but not CA, is sufficient to modulate host lipoprotein metabolism. Taken together, these results suggests that a minor component of the gut microbiome has a significant impact on cholesterol homeostasis through secondary metabolism of bile acids and suggests a possible therapeutic intervention route through the microbial metabolic pathways.

Project description:Knowing the gene expression profiles of drug-metabolizing enzymes and transporters throughout gestation is important for understanding the mechanisms of pregnancy-induced changes in drug pharmacokinetics. In this study, we compared gene expression of drug-metabolizing enzymes and transporters in the maternal liver, kidney, small intestine, and placenta of pregnant mice throughout gestation by microarray analysis. Specifically, we investigated cytochrome P450 (Cyp), UDP-glucuronosyltranserase (Ugt), and sulfotransferase (Sult), as well as ATP-binding cassette (Abc) and solute carrier (Slc) transporters. We found that relatively few Ugt and Sult genes were impacted by pregnancy in maternal tissues and placenta. Cyp1a2, most Cyp2 isoforms, Cyp3a11, and Cyp3a13 in the liver were down-regulated, with the greatest changes occurring on gestation days (gd) 15 and 19 compared to non-pregnant controls (gd 0). However, Cyp2d40, Cyp3a16, Cyp3a41a, Cyp3a41b, and Cyp3a44 in the liver were induced throughout pregnancy. Cyp expression in mid-gestation placenta (gd 10 and 15) was generally greater than that in term placenta (gd 19). There were also notable changes in Abc and Slc transporters. Abcc3 in the liver was down-regulated by 60%, and Abcb1a, Abcc4, and Slco4c1 in the kidney were down-regulated by 30-60% on gd 15 and 19 versus gd 0. Abcc5 in the placenta was induced 3-fold on gd 10 versus gd 15 and 19, whereas Slc22a3 expression in the placenta on gd 10 was 90% lower than that on gd 15 and 19. Overall, this study demonstrates important gestational age-dependent expression of drug-metabolizing enzymes and transporter genes, which may have mechanistic relevance to human pregnancy. Ninety pregnant mice at gestational days 0, 7.5, 10, 15, and 19 (n = 5-6 per gestational age) were used for the maternal liver, kidney, small intestine and placenta. The placentas were collected on gestational days 10, 15, and 19.

Project description:Chronic renal failure (CRF) is associated with a decrease in drug metabolism. The present study investigated the repercussions of CRF on liver cytochrome P450 (CYPs), but the mechanisms have been little explored. On the other hand, the expression of several CYP genes exhibits circadian rhythm. Here we report that downregulation of hepatic CYP3A11 (the murine homolog to human CYP3A4; the most decrease in 5/6Nx using microarray analysis) by suppressing the expression of clock gene; D-site binding protein (DBP). In vivo experiments, the mRNA levels of hepatic CYP3A11 exhibit circadian rhythm regulated by DBP and E4BP4, and significantly decreased in 5/6Nx. Microarray analysis revealed that the general transcription factors of CYP3A11 did not changed. However, DBP were downregulated and several CYP genes controlled by DBP also significantly decreased in 5/6Nx. These downregulations were not observed in angiotensin II type 1alpha receptor (AT II R1a) deficient 5/6Nx because serum TGF-betaM-BM- was not upregulate. In vitro experiments, the RNA levels of CYP3A11 and DBP were downregulated in wild-type mouse hepatocytes incubated with serum from 5/6Nx, but did not changed in Id2 (-/-) hepatocytes. In fact, hepatic Id2 was upregulated and caused the downregulation of DBP in 5/6Nx. Hepatocyte treated with SD208 (TGF-beta receptor 1 selectivity inhibitor) recovered CYP3A11, DBP and Id2 to control levels. Furthermore, 5/6Nx treated with tranilast (inhibitor of TGF-beta production or isolation) or candesartan (ARBs) also recovered CYP3A11 levels. Our findings define that DBP has effects on downregulation of CYP3A11. In CRF conditions, TGF-beta is upregulated by angiotensin II receptor in renal and downregulates DBP and CYP3A11 levels mediated by Id2 in liver. Furthermore, downregulation of CYP3A11 can prevent by tranilast or candesartan. Differential gene expression between 5/6 nephrectomized and sham-operated mouse was measured on the liver.

Project description:Hepatic drug metabolism plays a key role in determining drug response and safety. Studies of drug metabolism generate valuable information about regulation of genes encoding drug-metabolizing enzymes and enzyme functions that are critical in developing dosing guideline. However, current knowledge is insufficient to support dosing guideline for pregnant women. Specifically, substrates of a major drug-metabolizing enzyme CYP2D6 show increased elimination during pregnancy, but the underlying mechanisms are completely unknown largely due to a lack of experimental models. Here, we introduce CYP2D6-humanized (Tg-CYP2D6) mice as an animal model where hepatic CYP2D6 expression is increased during pregnancy, recapitulating the clinically reported changes in CYP2D6-mediated drug metabolism. In these mice, pregnancy had minimal effects on the expression of hepatocyte nuclear factor (HNF) 4a, the transcription factor controlling basal CYP2D6 expression. Krüppel-like factor (KLF) 9 and small heterodimer partner (SHP) were found up- and down-regulated in Tg-CYP2D6 mouse livers during pregnancy, respectively. KLF9 enhanced HNF4a-mediated transactivation of the CYP2D6 promoter whereas SHP repressed it. Retinoic acid (RA), an endogenous compound that induces SHP, exhibited decreased hepatic levels during pregnancy. These results indicate that interplay among hepatic transcription factors HNF4a, SHP, and KLF9 underlies CYP2D6 induction during pregnancy, and that retinoic acid is a potential trigger. This is the first report on the mechanisms underlying CYP2D6 induction and illustrates the utility of humanized mice as an in vivo model to study altered drug disposition during pregnancy. Livers collected at pre-pregnancy, 21 days of pregnancy, and 7 days postpartum from CYP2D6-humanized mice.

Project description:Chronic renal failure (CRF) is associated with a decrease in drug metabolism. The present study investigated the repercussions of CRF on liver cytochrome P450 (CYPs), but the mechanisms have been little explored. On the other hand, the expression of several CYP genes exhibits circadian rhythm. Here we report that downregulation of hepatic CYP3A11 (the murine homolog to human CYP3A4; the most decrease in 5/6Nx using microarray analysis) by suppressing the expression of clock gene; D-site binding protein (DBP). In vivo experiments, the mRNA levels of hepatic CYP3A11 exhibit circadian rhythm regulated by DBP and E4BP4, and significantly decreased in 5/6Nx. Microarray analysis revealed that the general transcription factors of CYP3A11 did not changed. However, DBP were downregulated and several CYP genes controlled by DBP also significantly decreased in 5/6Nx. These downregulations were not observed in angiotensin II type 1alpha receptor (AT II R1a) deficient 5/6Nx because serum TGF-beta was not upregulate. In vitro experiments, the RNA levels of CYP3A11 and DBP were downregulated in wild-type mouse hepatocytes incubated with serum from 5/6Nx, but did not changed in Id2 (-/-) hepatocytes. In fact, hepatic Id2 was upregulated and caused the downregulation of DBP in 5/6Nx. Hepatocyte treated with SD208 (TGF-beta receptor 1 selectivity inhibitor) recovered CYP3A11, DBP and Id2 to control levels. Furthermore, 5/6Nx treated with tranilast (inhibitor of TGF-beta production or isolation) or candesartan (ARBs) also recovered CYP3A11 levels. Our findings define that DBP has effects on downregulation of CYP3A11. In CRF conditions, TGF-beta is upregulated by angiotensin II receptor in renal and downregulates DBP and CYP3A11 levels mediated by Id2 in liver. Furthermore, downregulation of CYP3A11 can prevent by tranilast or candesartan.