<i>N</i>-Oxide Reduction of Quinoxaline-1,4-Dioxides Catalyzed by Porcine Aldehyde Oxidase SsAOX1

Mu, Peiqiang; Zheng, Mingming; Xu, Min; Zheng, Yuanming; Tang, Xianqing; Wang, Yufan; Wu, Kaixin; Chen, Qingmei; Wang, Limin; Deng, Yiqun

doi:10.1124/dmd.113.055418

Cited by 20 publications

(13 citation statements)

References 39 publications

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“…N-oxide reduction is the predominant metabolic pathway of CYA in pigs (Liu et al, 2009). Xanthine oxidoreductase (XOR) and aldehyde oxidase (AO) are the key enzymes to catalyze the N-oxide reduction of quinoxaline 1,4-di-N-oxides (Liu et al, 2009;Zheng et al, 2011;Mu et al, 2014. Hence, the amount and activity of xanthine oxidoreductase and aldehyde oxidase in liver and intestine determine the rate of CYA metabolism.…”

Section: Parameter Sensitivitymentioning

confidence: 98%

Estimation of residue depletion of cyadox and its marker residue in edible tissues of pigs using physiologically based pharmacokinetic modelling

Huang

Lin

Zhou

et al. 2015

Food Additives & Contaminants: Part A

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Physiologically based pharmacokinetic (PBPK) models are powerful tools to predict tissue distribution and depletion of veterinary drugs in food animals. However, most models only simulate the pharmacokinetics of the parent drug without considering their metabolites. In this study, a PBPK model was developed to simultaneously describe the depletion in pigs of the food animal antimicrobial agent cyadox (CYA), and its marker residue 1,4-bisdesoxycyadox (BDCYA). The CYA and BDCYA sub-models included blood, liver, kidney, gastrointestinal tract, muscle, fat and other organ compartments. Extent of plasma-protein binding, renal clearance and tissue-plasma partition coefficients of BDCYA were measured experimentally. The model was calibrated with the reported pharmacokinetic and residue depletion data from pigs dosed by oral gavage with CYA for five consecutive days, and then extrapolated to exposure in feed for two months. The model was validated with 14 consecutive day feed administration data. This PBPK model accurately simulated CYA and BDCYA in four edible tissues at 24-120 h after both oral exposure and 2-month feed administration. There was only slight overestimation of CYA in muscle and BDCYA in kidney at earlier time points (6-12 h) when dosed in feed. Monte Carlo analysis revealed excellent agreement between the estimated concentration distributions and observed data. The present model could be used for tissue residue monitoring of CYA and BDCYA in food animals, and provides a foundation for developing PBPK models to predict residue depletion of both parent drugs and their metabolites in food animals.

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Section: Parameter Sensitivitymentioning

confidence: 98%

Estimation of residue depletion of cyadox and its marker residue in edible tissues of pigs using physiologically based pharmacokinetic modelling

Huang

Lin

Zhou

et al. 2015

Food Additives & Contaminants: Part A

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“…The origin of M2 should be defined first because the end-stage metabolite may be directly generated from the parent drug (Xie et al, 2013;Mu et al, 2014) or may undergo successive multistep metabolic pathways (Zhou et al, 2015). In this study, the major metabolic pathway of imrecoxib was characterized as M0 being successively oxidized to M1, to M-CHO, and ultimately to M2, because more M2 was observed in the M1 incubations relative to M0 incubations, and trapping experiments with methoxyamine provided further evidence.…”

Section: Discussionmentioning

confidence: 75%

Differences in the In Vivo and In Vitro Metabolism of Imrecoxib in Humans: Formation of the Rate-Limiting Aldehyde Intermediate

Hou

Zhou

et al. 2018

Drug Metab Dispos

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Imrecoxib is a typical cyclooxygenase-2 inhibitor and the benzylic carbon motif is its major site of oxidative metabolism, producing a hydroxymethyl metabolite (M1) and a carboxylic acid metabolite (M2). The plasma exposure of M2 is four times higher than those of both M0 and M1 in humans. However, this metabolite is rarely formed in in vitro experiments. Therefore, this study aims to investigate the formation mechanism of M2 and to further elucidate the reason for the discrepancy between in vitro and in vivo metabolic data. By employing human hepatocytes, human liver microsomes (HLMs), human liver cytosols (HLCs), recombinant enzymes, and selective enzyme inhibitors, the metabolic map of imrecoxib was elaborated as follows: the parent drug was initially hydroxylated to form M1 in HLMs, mainly mediated by CYP3A4 and CYP2D6, and to subsequently form aldehyde imrecoxib (M-CHO) in HLMs and HLCs. The latter process is the rate-limiting step in generating the end-product M2. In further M-CHO metabolism, two opposite reactions (namely, rapid oxidation catalyzed by CYP3A4, CYP2D6, and cytosolic aldehyde oxidase to form M2 versus reduction to regenerate M1 mediated by NADPH-dependent reductases in HLMs and HLCs, such as cytochrome P450 reductase) led to marked underestimation of the M2 amount in static in vitro incubations. The findings provided a possible explanation for the difference between in vitro and in vivo metabolism of imrecoxib, suggesting that the effect of competitive reduction on the static oxidation metabolism in in vitro metabolic experiments should be considered.

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“…AO, acridine orange; cCBR1, chicken carbonyl reductase 1; porcine carbonyl reductase 1; SsAOX1, porcine aldehyde oxidase. Cited from (Chen et al, 2013;Huang et al, 2015bHuang et al, , 2015cLi et al, 2014aLi et al, , 2014bLiu et al, 2008Liu et al, , 2009Liu et al, , 2010aLiu et al, , 2010bLiu et al, , 2010cLiu et al, , 2011aLiu et al, , 2011bLiu & Sun, 2013;Mu et al, 2014;Tang et al, 2012;Wang et al, 2016b;Yang et al, 2013a;Zheng et al, 2011). marked as less genotoxicity than other kinds Wang et al, , 2011b.…”

Section: Resultsmentioning

confidence: 97%

“…The porcine aldehyde oxidase SsAOX1 mainly catalyzed the N!O reduction of QdNOs at the N1 position. SsAOX1 could catalyze QCT, MEQ and CYA to 1-deoxy QCT, 1-deoxy MEQ and 1-deoxy CYA, respectively (Mu et al, 2014).…”

Section: Metabolizing Enzymesmentioning

confidence: 99%

The critical role of oxidative stress in the toxicity and metabolism of quinoxaline 1,4-di-N-oxides in vitro and in vivo

Wang

Martínez

Cheng

et al. 2016

Drug Metabolism Reviews

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Quinoxaline 1,4-dioxide derivatives (QdNOs) have been widely used as growth promoters and antibacterial agents. Carbadox (CBX), olaquindox (OLA), quinocetone (QCT), cyadox (CYA) and mequindox (MEQ) are the classical members of QdNOs. Some members of QdNOs are known to cause a variety of toxic effects. To date, however, almost no review has addressed the toxicity and metabolism of QdNOs in relation to oxidative stress. This review focused on the research progress associated with oxidative stress as a plausible mechanism for QdNO-induced toxicity and metabolism. The present review documented that the studies were performed over the past 10 years to interpret the generation of reactive oxygen species (ROS) and oxidative stress as the results of QdNO treatment and have correlated them with various types of QdNO toxicity, suggesting that oxidative stress plays critical roles in their toxicities. The major metabolic pathways of QdNOs are N→O group reduction and hydroxylation. Xanthine oxidoreductase (XOR), aldehyde oxidase (SsAOX1), carbonyl reductase (CBR1) and cytochrome P450 (CYP) enzymes were involved in the QdNOs metabolism. Further understanding the role of oxidative stress in QdNOs-induced toxicity will throw new light onto the use of antioxidants and scavengers of ROS as well as onto the blind spots of metabolism and the metabolizing enzymes of QdNOs. The present review might contribute to revealing the QdNOs toxicity, protecting against oxidative damage and helping to improve the rational use of concurrent drugs, while developing novel QdNO compounds with more efficient potentials and less toxic effects.

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N-Oxide Reduction of Quinoxaline-1,4-Dioxides Catalyzed by Porcine Aldehyde Oxidase SsAOX1

Cited by 20 publications

References 39 publications

Estimation of residue depletion of cyadox and its marker residue in edible tissues of pigs using physiologically based pharmacokinetic modelling

Estimation of residue depletion of cyadox and its marker residue in edible tissues of pigs using physiologically based pharmacokinetic modelling

Differences in the In Vivo and In Vitro Metabolism of Imrecoxib in Humans: Formation of the Rate-Limiting Aldehyde Intermediate

The critical role of oxidative stress in the toxicity and metabolism of quinoxaline 1,4-di-N-oxides in vitro and in vivo

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