Chemical and Enzymatic Transformations of Nimesulide to GSH Conjugates through Reductive and Oxidative Mechanisms

Nimesulide (NIM) is a nonsteroidal anti-inflammatory drug, and clinical treatment with NIM has been associated with severe hepatotoxicity. The bioactivation of nitro-reduced NIM (NIM-NH₂), a major NIM metabolite, has been thought to be responsible for the hepatotoxicity of NIM. However, we found that NIM-NH₂ did not induce toxic effects in primary rat hepatocytes. This study aimed to investigate other bioactivation pathways of NIM and evaluate their association with hepatotoxicity. After incubating NIM with NADPH- and GSH-supplemented human or rat liver microsomes, we identified two types of GSH conjugates: one was derived from the attachment of GSH to NIM-NH₂ (NIM-NH₂-GSH) and the other one was derived from a quinone-imine intermediate (NIM-OH-GSH). NIM-NH₂-GSH was generated not only by the oxidative activation of NIM-NH₂ but also from the reductive activation of NIM. Both NADPH and GSH could act as reducing agents. Moreover, aldehyde oxidase also participated in the reductive activation of NIM. NIM-OH-GSH was generated mainly from NIM via epoxidation with CYP1A2 as the main catalyzing enzyme. NIM was toxic to both primary human and rat hepatocytes, with IC₅₀ values of 213 and 40 μM, respectively. Inhibition of the oxidative and reductive activation of NIM by the nonspecific CYP inhibitor 1-aminobenzotriazole and selective aldehyde oxidase inhibitor estradiol did not protect the cells from NIM-mediated toxicity. Moreover, pretreating cells with l-buthionine-sulfoximine (a GSH depletor) did not affect the cytotoxicity of NIM. These results suggested that oxidative and reductive activation of NIM did not cause the hepatotoxicity and that the parent drug concentration was associated with the cytotoxicity

Investigation of Isomeric Transformations of Chlorogenic Acid in Buffers and Biological Matrixes by Ultraperformance Liquid Chromatography Coupled with Hybrid Quadrupole/Ion Mobility/Orthogonal Acceleration Time-of-Flight Mass Spectrometry

Ultraperformance liquid chromatography coupled with hybrid quadrupole/ion mobility/orthogonal acceleration time-of-flight (oa-TOF) mass spectrometry (UPLC-IM-MS) was used to study the isomeric transformations of trans-5-caffeoylquinic acid, an extremely active compound present in multiple vegetables, fruits, and beverages. The UPLC/oa-TOF MS results proved that in phosphate buffer (pH 7.4), plasma, or urine sample, trans-5-caffeoylquinic acid first isomerizes to trans-4-caffeoylquinic acid and then to trans-3-caffeoylquinic acid by intramolecular acyl migration. When exposed to UV light, trans-3-, -4-, and -5-caffeoylquinic acids undergo cis/trans isomerization to form cis isomers. The isomerization was solely dependent on the pH of the matrix, as well as the incubation temperature, and was independent of metabolic enzymes. UPLC-IM-MS results revealed that a reversible cis/trans isomerization of caffeoylquinic acids could also be induced by the electric field in an electrospray source. Thus, understanding the possible role of electric field-induced isomerization of caffeoylquinic acids may help lessen the confusion between gas phase phenomena and liquid state chemistry when applying IM-MS analysis. The comprehensive understanding of caffeoylquinic acid isomerization transformations is crucial for the appropriate handling of samples and interpretation of experimental data

Metabolic map of the antiviral drug podophyllotoxin provides insights into hepatotoxicity

Podophyllotoxin (POD) is a natural compound with antiviral and anticancer activities. The purpose of the present study was to determine the metabolic map of POD in vitro and in vivo.Mouse and human liver microsomes were employed to identify POD metabolites in vitro and recombinant drug-metabolizing enzymes were used to identify the mono-oxygenase enzymes involved in POD metabolism. All in vitro incubation mixtures and bile samples from mice treated with POD were analysed with ultra-performance liquid chromatography coupled with electrospray ionization quadrupole time-of-flight mass spectrometry.A total of 38metabolites, including six phase-I metabolites and 32 phase-II metabolites, of POD were identified from bile and faeces samples after oral administration, and their structures were elucidated through interpreting MS/MS fragmentation patterns.Nine metabolites, including two phase-I metabolites, five glucuronide conjugates, and two GSH conjugates were detected in both human and mouse liver microsome incubation systems and the generation of all metabolites were NADPH-dependent. The main phase-I enzymes involved in metabolism of POD in vitro include CYP2C9, CYP2C19, CYP3A4, and CYP3A5.POD administration to mice caused hepatic and intestinal toxicity, and the cellular damage was exacerbated when 1-aminobenzotriazole, a broad-spectrum inhibitor of CYPs, was administered with POD, indicating that POD, but not its metabolites, induced hepatic and intestinal toxicities.This study elucidated the metabolic map and provides important reference basis for the safety evaluation and rational for the clinical application of POD. Podophyllotoxin (POD) is a natural compound with antiviral and anticancer activities. The purpose of the present study was to determine the metabolic map of POD in vitro and in vivo. Mouse and human liver microsomes were employed to identify POD metabolites in vitro and recombinant drug-metabolizing enzymes were used to identify the mono-oxygenase enzymes involved in POD metabolism. All in vitro incubation mixtures and bile samples from mice treated with POD were analysed with ultra-performance liquid chromatography coupled with electrospray ionization quadrupole time-of-flight mass spectrometry. A total of 38metabolites, including six phase-I metabolites and 32 phase-II metabolites, of POD were identified from bile and faeces samples after oral administration, and their structures were elucidated through interpreting MS/MS fragmentation patterns. Nine metabolites, including two phase-I metabolites, five glucuronide conjugates, and two GSH conjugates were detected in both human and mouse liver microsome incubation systems and the generation of all metabolites were NADPH-dependent. The main phase-I enzymes involved in metabolism of POD in vitro include CYP2C9, CYP2C19, CYP3A4, and CYP3A5. POD administration to mice caused hepatic and intestinal toxicity, and the cellular damage was exacerbated when 1-aminobenzotriazole, a broad-spectrum inhibitor of CYPs, was administered with POD, indicating that POD, but not its metabolites, induced hepatic and intestinal toxicities. This study elucidated the metabolic map and provides important reference basis for the safety evaluation and rational for the clinical application of POD.</p

Discovery of 9,11-Seco-Cholesterol Derivatives as Novel FXR Antagonists

The farnesoid X receptor (FXR) plays an important role in the regulation of bile acid, lipid, and glucose homeostasis. Recent findings have shown that the inhibition of FXR is beneficial to improvement of related metabolic diseases and cholestasis. In the present work, 9,11-seco-cholesterol derivatives were designed and synthesized by cleaving the C ring of cholesterol and were identified as novel structures of FXR antagonists. Compound 9a displayed the best FXR antagonistic activity at the cellular level (IC50 = 4.6 μM) and decreased the expression of the target genes of FXR in vivo

Metabolism and Bioactivation of Fluorochloridone, a Novel Selective Herbicide, in Vivo and in Vitro

Fluorochloridone (FLC) is a herbicide used worldwide that is thought to be safe. However, due to its potential genotoxicity, cytotoxicity, and even systematic toxicity, there are increasing concerns about human exposure to this compound. Thus, the metabolism and bioactivation of FLC was investigated. After oral administration to mice, 27 metabolites were identified by ultrahigh performance liquid chromatography-electrospray ionization-quadrupole time-of-flight-mass spectrometry and with further structural identification by nuclear magnetic resonance spectroscopy. Hydroxylation and oxidative dechlorination were the major phase I pathways, while glutathione (GSH) and <i>N</i>-acetylcysteine conjugations were two major phase II pathways, indicating the formation of a reactive intermediate. In vitro microsomal and cytosolic studies revealed that a GSH conjugate (M13) was the predominant metabolite of FLC formed through a nucleophilic S_N2 substitution of 3-Cl by GSH; this pathway is NADPH independent and accelerated by glutathione <i>S</i>-transferase (GST). Further, a kinetic study showed that M13 formation in both human liver microsomes and cytosols obeyed typical Michaelis–Menten kinetics. The maximum clearance (<i>V</i>_max/<i>K</i>_m) of GSH conjugation in human liver microsomes was approximately 5.5-fold higher than human liver cytosol, thus implying that microsomal GST was mainly responsible for M13 formation. These findings are important for understanding the potential hazard of human exposure to FLC

Discovery of Betulinic Acid Derivatives as Potent Intestinal Farnesoid X Receptor Antagonists to Ameliorate Nonalcoholic Steatohepatitis

Farnesoid X receptor (FXR) has emerged as a promising therapeutic target for nonalcoholic steatohepatitis (NASH) because of its tightly interwoven relationship with bile acid homeostasis, inflammation, fibrosis, and glucose and lipid metabolism. Evidence showed that intestinal FXR antagonism exhibited remarkable metabolic improvements in mice. Herein, we developed a series of betulinic acid derivatives as potent intestinal FXR antagonists, and F6 was identified as the most potent one with an IC50 at 2.1 μM. F6 selectively inhibited intestinal FXR signaling and ameliorated the hepatic steatosis, inflammation, and fibrosis in Gubra-amylin NASH (GAN) and high-fat with methionine and choline deficiency (HFMCD) diet-induced NASH models. The beneficial effects were achieved by direct antagonism of intestinal FXR and feedback activation of hepatic FXR, thereby decreasing ceramides and repressing inflammasome activation in the liver. Collectively, our work substantially supports F6 as a promising drug candidate against NASH and demonstrates that antagonism of intestinal FXR signaling is a practical strategy for treating metabolic diseases

Discovery of Betulinic Acid Derivatives as Potent Intestinal Farnesoid X Receptor Antagonists to Ameliorate Nonalcoholic Steatohepatitis

Farnesoid X receptor (FXR) has emerged as a promising therapeutic target for nonalcoholic steatohepatitis (NASH) because of its tightly interwoven relationship with bile acid homeostasis, inflammation, fibrosis, and glucose and lipid metabolism. Evidence showed that intestinal FXR antagonism exhibited remarkable metabolic improvements in mice. Herein, we developed a series of betulinic acid derivatives as potent intestinal FXR antagonists, and F6 was identified as the most potent one with an IC50 at 2.1 μM. F6 selectively inhibited intestinal FXR signaling and ameliorated the hepatic steatosis, inflammation, and fibrosis in Gubra-amylin NASH (GAN) and high-fat with methionine and choline deficiency (HFMCD) diet-induced NASH models. The beneficial effects were achieved by direct antagonism of intestinal FXR and feedback activation of hepatic FXR, thereby decreasing ceramides and repressing inflammasome activation in the liver. Collectively, our work substantially supports F6 as a promising drug candidate against NASH and demonstrates that antagonism of intestinal FXR signaling is a practical strategy for treating metabolic diseases

Discovery of Betulinic Acid Derivatives as Potent Intestinal Farnesoid X Receptor Antagonists to Ameliorate Nonalcoholic Steatohepatitis

Farnesoid X receptor (FXR) has emerged as a promising therapeutic target for nonalcoholic steatohepatitis (NASH) because of its tightly interwoven relationship with bile acid homeostasis, inflammation, fibrosis, and glucose and lipid metabolism. Evidence showed that intestinal FXR antagonism exhibited remarkable metabolic improvements in mice. Herein, we developed a series of betulinic acid derivatives as potent intestinal FXR antagonists, and F6 was identified as the most potent one with an IC50 at 2.1 μM. F6 selectively inhibited intestinal FXR signaling and ameliorated the hepatic steatosis, inflammation, and fibrosis in Gubra-amylin NASH (GAN) and high-fat with methionine and choline deficiency (HFMCD) diet-induced NASH models. The beneficial effects were achieved by direct antagonism of intestinal FXR and feedback activation of hepatic FXR, thereby decreasing ceramides and repressing inflammasome activation in the liver. Collectively, our work substantially supports F6 as a promising drug candidate against NASH and demonstrates that antagonism of intestinal FXR signaling is a practical strategy for treating metabolic diseases

Additional file 2 of Limosilactobacillus reuteri and caffeoylquinic acid synergistically promote adipose browning and ameliorate obesity-associated disorders

Additional file 2: Supplemental table 1. Sequences of primers used for quantitative real-time PCR

Additional file 1 of Limosilactobacillus reuteri and caffeoylquinic acid synergistically promote adipose browning and ameliorate obesity-associated disorders

Additional file 1: Figure S1. CQA reverses lipid dysregulation upon HFD. Figure S2. The microbial metabolic behaviors of CQA. Figure S3. Gut microbiota play a key role in the anti-obesity effects of CQA. Figure S4. Comparison of the biochemical indices between non-responder and responder after chronic CQA treatment. Figure S5. L. reuteri is susceptible to bacitracin and resistant to vancomycin. Figure S6. Intervention of mice with microbial communities lacking or including L. reuteri influences the anti-obesity phenotypes of CQA. Figure S7. Long-term colonization of L. reuteri does not improve the metabolic dysfunctions in DIO mice. Figure S8. L. reuteri improves metabolic control in DIO mice treated with CQA. Figure S9. SCFAs profiling in DIO mice. Figure S10. Monocarboxylate transporter is involved in propionate-induced energy expenditure