Identification of Novel Metabolites of Colchicine in Rat Bile Facilitated by Enhanced Online Radiometric Detection

Xu, Lin; Adams, Bruce R.; Jeliazkova-Mecheva, Valentina V.; Trimble, Laird A.; Kwei, Gloria Y.; Harsch, Andreas

doi:10.1124/dmd.107.019463

Cited by 16 publications

(10 citation statements)

References 33 publications

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“…Retention times and mass spectral data of these compounds were consistent with synthesized reference compounds, i.e., a cysteinylglycine-BDA-GSH conjugate d (m/z 532), a cysteinyl-BDA-GSH conjugate e (m/z 475), and a GSH-BDA-glycine conjugate f (m/z 429). The structure of f is further supported by the characteristic neutral loss of 129, resulting from cleavage of the ␥-glutamyl-cysteinyl-isopeptide bond within a GSH residue and loss of 273 (GSH cleavage at the SCH 2 group) (Xu et al, 2008), which indicate that GSH is linked to the pyrrole ring by its thiol group and not by an amino group. The amount of metabolite f was below the limit of detection in bile samples from [3,4-13 C]furantreated rats.…”

Section: Identification Of Biliary Furan Metabolitesmentioning

confidence: 72%

Hepatobiliary Toxicity of Furan: Identification of Furan Metabolites in Bile of Male F344/N Rats

Hamberger

Kellert²,

Schauer³

et al. 2010

Drug Metab Dispos

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ABSTRACT:Furan, which occurs in a wide variety of heat-treated foods, is a potent hepatotoxicant and liver carcinogen in rodents. In a 2-year bioassay, furan caused hepatocellular adenomas and carcinomas in mice and rats but also high incidences of bile duct tumors in rats. Furan is bioactivated by cytochrome P450 enzymes to cis-2-butene-1,4-dial, an ␣,␤-unsaturated dialdehyde, which readily reacts with tissue nucleophiles. The objective of this study was to structurally characterize furan metabolites excreted with bile to better understand the potential role of reactive furan intermediates in the biliary toxicity of furan. Bile duct-cannulated F344/N rats (n ‫؍‬ 3) were administered a single oral dose of 5 mg/kg b.wt. The main metabolite was a cyclic monoglutathione conjugate of cis-2-butene-1,4-dial, which was previously detected in urine of furan-treated rats. Furthermore, a N-acetylcysteine-N-acetyllysine conjugate, previously observed in rat urine, and a cysteinylglycine-glutathione conjugate were identified as major metabolites. These data suggest that degraded protein adducts are in vivo metabolites of furan, consistent with the hypothesis that cytotoxicity mediated through binding of cis-2-butene-1,4-dial to critical target proteins is likely to play a key role in furan toxicity and carcinogenicity.

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Section: Identification Of Biliary Furan Metabolitesmentioning

confidence: 72%

Hepatobiliary Toxicity of Furan: Identification of Furan Metabolites in Bile of Male F344/N Rats

Hamberger

Kellert²,

Schauer³

et al. 2010

Drug Metab Dispos

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“…O ‐demethylation is a major pathway for COL metabolism in which P450 3A plays a critical role in the process. O ‐ glucuronidated metabolites, O ‐sulfation conjugates, and glutathione conjugates derived from demethylated COL were detected in rat bile . In our early work, we detected several cysteine conjugates derived from demethylated COL in COL‐exposed microsomal protein samples after proteolytic digestion.…”

Section: Introductionmentioning

confidence: 84%

Studies on hepatotoxicity and toxicokinetics of colchicine

Guo

Chen

et al. 2019

J Biochem & Molecular Tox

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Colchicine (COL) is an alkaloid existing in plants of Liliaceous colchicum. It has widely been used in the treatments of many diseases, such as gout, Familial Mediterranean Fever, and tumor. However, the adverse effects of COL are an obstacle to its safe use. The present studies explored the role of metabolic demethylation in the development of COL‐induced hepatotoxicity. We found that inhibition of CYP3A increased the susceptibility of mice to COL hepatotoxicity, and induction of CYP3A decreased the susceptibility of animals to the hepatotoxicity. The toxicokinetic study demonstrated that pretreatment with ketoconazole caused elevated area under the concentration‐time curve of COL. Three demethylation metabolites of COL were found to be less hepatotoxic than the parent compound. It appears that the formation of electrophilic demethylation metabolites was not involved in the development of COL‐induced liver injury.

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“…As discussed above, the planar structure of tropolone ring C and the hydrophobic methoxyl at C-10 greatly impacted COL analogues' activities by affecting their interaction with the relevant protein. Herein, a total of 13 COL analogues (19)(20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31) were involved in molecular docking analysis to understand better how the modification on ring C would affect ZO-1-related intestinal injury toxicity of COL. Chemically, these ligands with a type II structure, as shown in Figure 1, were all obtained from chemical modification at C-10.…”

Section: Effect Of Modification On Ring Cmentioning

confidence: 99%

A New Insight into Toxicity of Colchicine Analogues by Molecular Docking Analysis Based on Intestinal Tight Junction Protein ZO-1

Liu

Gao

et al. 2022

Molecules

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Colchicine (COL) is a well-known plant alkaloid long used for medical purposes due to the selective anti-inflammatory effect on acute gouty arthritis. It is also a kind of mitosis toxin with strong inhibitory effects of cell division and is therefore being applied to the treatment of various cancers. However, this product shows a variety of adverse effects that are significantly correlated with the dosage and have attracted much attention. For the first time, the present work obtained a new insight into the gastrointestinal toxicity of colchicine analogues by molecular docking analysis, which was based on the 3D structure of intestinal tight junction protein ZO-1 and the ligand library containing dozens of small-molecule compounds with the basic skeleton of COL and its metabolites. The binding energy and mode of protein–ligand interaction were investigated to better understand the structure–toxicity relationships of COL analogues and the mechanism of action as well. Cluster analysis clearly demonstrated the strong correlation between the binding energy and toxicity of ligand molecules. The interaction mode further revealed that the hydrogen bonding (via the C-7 amide or C-9 carbonyl group) and hydrophobic effect (at ring A or C) were both responsible for ZO-1-related gastrointestinal toxicity of COL analogues, while metabolic transformation via phase I and/or phase II reaction would significantly attenuate the gastrointestinal toxicity of colchicine, indicating an effective detoxication pathway through metabolism.

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Identification of Novel Metabolites of Colchicine in Rat Bile Facilitated by Enhanced Online Radiometric Detection

Cited by 16 publications

References 33 publications

Hepatobiliary Toxicity of Furan: Identification of Furan Metabolites in Bile of Male F344/N Rats

Hepatobiliary Toxicity of Furan: Identification of Furan Metabolites in Bile of Male F344/N Rats

Studies on hepatotoxicity and toxicokinetics of colchicine

A New Insight into Toxicity of Colchicine Analogues by Molecular Docking Analysis Based on Intestinal Tight Junction Protein ZO-1

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