Your search keyword '"Joe Jongpyo Lim"' showing total 6 results

1. Deciphering the Zonal Distribution of Hepatic Drug Metabolizing Enzymes and Transporters in Mice by Single Cell Transcriptomics

Author

Joe Jongpyo Lim, Curtis Klaassen, and Julia Yue Cui

Published

2023

2. Assessing the Impact of Benzalkonium Chlorides on Gut Microbiome and Liver Metabolism

Author

Vanessa A. Lopez, Joe Jongpyo Lim, Ryan Seguin, Joseph L. Dempsey, Gabby C. Kunzman, Julia Yue Cui, and Libin Xu

Published

2023

3. Pregnane X Receptor and the Gut-Liver Axis: A Recent Update

Author

Moumita Dutta, Julia Yue Cui, and Joe Jongpyo Lim

Subjects

Male, Pharmacology, Receptors, Steroid, Pregnane X receptor, Pregnane X Receptor, Regulator, Receptors, Cytoplasmic and Nuclear, Pharmaceutical Science, Endogeny, Computational biology, Biology, digestive system, digestive system diseases, Gastrointestinal Microbiome, Xenobiotics, chemistry.chemical_compound, Tryptophan Metabolite, Liver, chemistry, Nuclear receptor, Humans, Female, Microbiome, Intestinal bacteria, Xenobiotic

Abstract

It is well-known that the pregnane X receptor (PXR)/Nr1i2 is a critical xenobiotic-sensing nuclear receptor enriched in liver and intestine and is responsible for drug-drug interactions, due to its versatile ligand binding domain (LBD) and target genes involved in xenobiotic biotransformation. PXR can be modulated by various xenobiotics including pharmaceuticals, nutraceuticals, dietary factors, and environmental chemicals. Microbial metabolites such as certain secondary bile acids (BAs) and the tryptophan metabolite indole-3-propionic acid (IPA) are endogenous PXR activators. Gut microbiome is increasingly recognized as an important regulator for host xenobiotic biotransformation and intermediary metabolism. PXR regulates and is regulated by the gut-liver axis. This review summarizes recent research advancements leveraging pharmaco- and toxico-metagenomic approaches that have redefined the previous understanding of PXR. Key topics covered in this review include: (1) genome-wide investigations on novel PXR-target genes, novel PXR-DNA interaction patterns, and novel PXR-targeted intestinal bacteria; (2) key PXR-modulating activators and suppressors of exogenous and endogenous sources; (3) novel bidirectional interactions between PXR and gut microbiome under physiologic, pathophysiological, pharmacological, and toxicological conditions; and (4) modifying factors of PXR-signaling including species and sex differences and time (age, critical windows of exposure, and circadian rhythm). The review also discusses critical knowledge gaps and important future research topics centering around PXR. SIGNIFICANCE STATEMENT: This review summarizes recent research advancements leveraging O'mics approaches that have redefined the previous understanding of the xenobiotic-sensing nuclear receptor pregnane X receptor (PXR). Key topics include: (1) genome-wide investigations on novel PXR-targeted host genes and intestinal bacteria as well as novel PXR-DNA interaction patterns; (2) key PXR modulators including microbial metabolites under physiological, pathophysiological, pharmacological, and toxicological conditions; and (3) modifying factors including species, sex, and time.

Published

2021

4. Perfluorinated Carboxylic Acids with Increasing Carbon Chain Lengths Upregulate Amino Acid Transporters and Modulate Compensatory Response of Xenobiotic Transporters in HepaRG Cells

Author

Julia Yue Cui, Youjun Suh, Joe Jongpyo Lim, and Elaine M. Faustman

Subjects

Pharmacology, chemistry.chemical_classification, Amino Acid Transport Systems, Carboxylic Acids, Pharmaceutical Science, Transporter, Carbon, Xenobiotics, Amino acid, Transcriptome, Thiazoles, chemistry.chemical_compound, Biotransformation, chemistry, Nuclear receptor, Biochemistry, Detoxification, Oximes, Protein biosynthesis, Humans, Dimethyl Sulfoxide, Environmental Pollutants, PPAR alpha, Amino Acids, Xenobiotic

Abstract

Perfluorinated carboxylic acids (PFCAs) are environmental pollutants for which human exposure has been documented. PFCAs at high doses were known regulate xenobiotic transporters partly through PPARα and CAR in rodents. Less is known regarding how various PFCAs at a lower concentration modulate transporters for endogenous substrates such as amino acids in human hepatocytes. Such studies are of particular importance because amino acids are involved in chemical detoxification and their transport system may serve as promising therapeutic targets for structurally similar xenobiotics. The focus of this study was to further elucidate how PFCAs modulate transporters involved in intermediary metabolism and xenobiotic biotransformation. We tested the hepatic transcriptomic response of HepaRG cells exposed to 45 mM PFOA, PFNA, or PFDA in triplicates for 24 h (vehicle: 0.1% DMSO), as well as the prototypical ligands for PPARα (WY-14643, 45 µM) and CAR (CITCO, 2 µM). PFCAs with increasing carbon chain lengths (C8-C10) regulated more liver genes, with amino acid metabolism and transport ranked among the top enriched pathways and PFDA ranked as the most potent PFCA tested. Genes encoding amino acid transporters, which are essential for protein synthesis, were novel inducible targets by all 3 PFCAs, suggesting a potentially protective mechanism to reduce further toxic insults. None of the transporter regulations appeared to be through PPARα or CAR but potential involvement of Nrf2 is noted for all 3 PFCAs. In conclusion, PFCAs with increasing carbon chain lengths up-regulate amino acid transporters and modulate xenobiotic transporters to limit further toxic exposures in HepaRG cells. Significance Statement Little is known regarding how various PFCAs modulate the transporters for endogenous substrates in human liver cells. Using HepaRG cells, this study is among the first to show that PFCAs with increasing carbon chain lengths up-regulate amino acid transporters, which are essential for protein synthesis, and modulate xenobiotic transporters to limit further toxic exposures at concentrations lower than what was used in literature.

Published

2021

5. Neonatal Exposure to BPA, BDE-99, and PCB Produces Persistent Changes in Hepatic Transcriptome Associated With Gut Dysbiosis in Adult Mouse Livers

Author

Joe Jongpyo Lim, Haiwei Gu, Moumita Dutta, Terrance J. Kavanagh, James W. MacDonald, Theo K. Bammler, Joseph L. Dempsey, Cheryl L. Walker, Hans-Joachim Lehmler, Julia Yue Cui, and Sridhar Mani

Subjects

Adult, Male, Physiology, Biology, Toxicology, Transcriptome, Mice, Polybrominated diphenyl ethers, Halogenated Diphenyl Ethers, medicine, Animals, Humans, Epigenetics, Microbiome, medicine.disease, biology.organism_classification, Polychlorinated Biphenyls, Environmental Toxicology, Mice, Inbred C57BL, Liver, Dysbiosis, Environmental Pollutants, Female, Liver cancer, Toxicogenomics, Akkermansia muciniphila

Abstract

Recent evidence suggests that complex diseases can result from early life exposure to environmental toxicants. Polybrominated diphenyl ethers (PBDEs), and polychlorinated biphenyls (PCBs) are persistent organic pollutants (POPs) and remain a continuing risk to human health despite being banned from production. Developmental BPA exposure mediated-adult onset of liver cancer via epigenetic reprogramming mechanisms has been identified. Here, we investigated whether the gut microbiome and liver can be persistently reprogrammed following neonatal exposure to POPs, and the associations between microbial biomarkers and disease-prone changes in the hepatic transcriptome in adulthood, compared with BPA. C57BL/6 male and female mouse pups were orally administered vehicle, BPA, BDE-99 (a breast milk-enriched PBDE congener), or the Fox River PCB mixture (PCBs), once daily for three consecutive days (postnatal days [PND] 2–4). Tissues were collected at PND5 and PND60. Among the three chemicals investigated, early life exposure to BDE-99 produced the most prominent developmental reprogramming of the gut-liver axis, including hepatic inflammatory and cancer-prone signatures. In adulthood, neonatal BDE-99 exposure resulted in a persistent increase in Akkermansia muciniphila throughout the intestine, accompanied by increased hepatic levels of acetate and succinate, the known products of A. muciniphila. In males, this was positively associated with permissive epigenetic marks H3K4me1 and H3K27, which were enriched in loci near liver cancer-related genes that were dysregulated following neonatal exposure to BDE-99. Our findings provide novel insights that early life exposure to POPs can have a life-long impact on disease risk, which may partly be regulated by the gut microbiome.

Published

2021

6. Gut Microbiome Critically Impacts PCB-induced Changes in Metabolic Fingerprints and the Hepatic Transcriptome in Mice

Author

Xueshu Li, Dongfang Wang, Julia Yue Cui, Joe Jongpyo Lim, Haiwei Gu, and Hans-Joachim Lehmler

Subjects

0301 basic medicine, 010501 environmental sciences, Gut flora, Toxicology, 01 natural sciences, Transcriptome, Mice, 03 medical and health sciences, chemistry.chemical_compound, Metabolomics, Constitutive androstane receptor, Animals, Microbiome, 0105 earth and related environmental sciences, Pregnane X receptor, biology, food and beverages, Aryl hydrocarbon receptor, biology.organism_classification, Polychlorinated Biphenyls, Environmental Toxicology, Gastrointestinal Microbiome, Cell biology, 030104 developmental biology, Liver, chemistry, biology.protein, Female, Xenobiotic

Abstract

Polychlorinated biphenyls (PCBs) are ubiquitously detected and have been linked to metabolic diseases. Gut microbiome is recognized as a critical regulator of disease susceptibility; however, little is known how PCBs and gut microbiome interact to modulate hepatic xenobiotic and intermediary metabolism. We hypothesized the gut microbiome regulates PCB-mediated changes in the metabolic fingerprints and hepatic transcriptome. Ninety-day-old female conventional and germ-free mice were orally exposed to the Fox River Mixture (synthetic PCB mixture, 6 or 30 mg/kg) or corn oil (vehicle control, 10 ml/kg), once daily for 3 consecutive days. RNA-seq was conducted in liver, and endogenous metabolites were measured in liver and serum by LC-MS. Prototypical target genes of aryl hydrocarbon receptor, pregnane X receptor, and constitutive androstane receptor were more readily upregulated by PCBs in conventional conditions, indicating PCBs, to the hepatic transcriptome, act partly through the gut microbiome. In a gut microbiome-dependent manner, xenobiotic, and steroid metabolism pathways were upregulated, whereas response to misfolded proteins-related pathways was downregulated by PCBs. At the high PCB dose, NADP, and arginine appear to interact with drug-metabolizing enzymes (ie, Cyp1–3 family), which are highly correlated with Ruminiclostridium and Roseburia, providing a novel explanation of gut-liver interaction from PCB-exposure. Utilizing the Library of Integrated Network-based Cellular Signatures L1000 database, therapeutics targeting anti-inflammatory and endoplasmic reticulum stress pathways are predicted to be remedies that can mitigate PCB toxicity. Our findings demonstrate that habitation of the gut microbiota drives PCB-mediated hepatic responses. Our study adds knowledge of physiological response differences from PCB exposure and considerations for further investigations for gut microbiome-dependent therapeutics.

Published

2020