Arthur N. Mayeno scite author profile

Cytochromes P450 (CYPs) are a superfamily of enzymes that metabolize the majority of xenobiotics in humans. This review presents a structure-based outline of CYP-catalyzed biotransformations of selected substrates, representing diverse structural classes of chemicals, ranging from drugs to toxicants. Data are presented in a tabular format for easy reference, with visual representations of all substrates and sites-of-attack. The major metabolites, isozymes responsible, chemical classification, and other information related to the biotransformation are provided. Pharmacophores proposed for the major CYP isozymes are discussed. This visual combination of substrates and biotransformation sites can serve as a useful reference for researchers.

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Computational Toxicology of Chloroform: Reverse Dosimetry Using Bayesian Inference, Markov Chain Monte Carlo Simulation, and Human Biomonitoring Data

Lyons

Yang²,

Mayeno³

et al. 2008

Environ Health Perspect

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BackgroundOne problem of interpreting population-based biomonitoring data is the reconstruction of corresponding external exposure in cases where no such data are available.ObjectivesWe demonstrate the use of a computational framework that integrates physiologically based pharmacokinetic (PBPK) modeling, Bayesian inference, and Markov chain Monte Carlo simulation to obtain a population estimate of environmental chloroform source concentrations consistent with human biomonitoring data. The biomonitoring data consist of chloroform blood concentrations measured as part of the Third National Health and Nutrition Examination Survey (NHANES III), and for which no corresponding exposure data were collected.MethodsWe used a combined PBPK and shower exposure model to consider several routes and sources of exposure: ingestion of tap water, inhalation of ambient household air, and inhalation and dermal absorption while showering. We determined posterior distributions for chloroform concentration in tap water and ambient household air using U.S. Environmental Protection Agency Total Exposure Assessment Methodology (TEAM) data as prior distributions for the Bayesian analysis.ResultsPosterior distributions for exposure indicate that 95% of the population represented by the NHANES III data had likely chloroform exposures ≤ 67 μg/L in tap water and ≤ 0.02 μg/L in ambient household air.ConclusionsOur results demonstrate the application of computer simulation to aid in the interpretation of human biomonitoring data in the context of the exposure–health evaluation–risk assessment continuum. These results should be considered as a demonstration of the method and can be improved with the addition of more detailed data.

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Granule-associated flavin adenine dinucleotide (FAD) is responsible for eosinophil autofluorescence

Mayeno

Hamann

Gleich

1992

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Unstained human eosinophils exhibit marked autofluorescence in comparison to other leukocytes due to a granule-associated fluorescent substance. Fluorescence spectroscopy of granule extracts reveals excitation maxima at approximately 380 and approximately 450 nm with a single emission at approximately 520, characteristic of flavins. The fluorescent material from eosinophil granule extracts was characterized by fluorescence, high-performance liquid chromatographic, and enzymatic analyses. First, acidification to pH 2.6 resulted in increased fluorescence, indicative of flavin adenine dinucleotide (FAD). Second, because flavin mononucleotide (FMN) and riboflavin cannot be distinguished by acidification, high-performance liquid chromatography was performed and revealed a predominance of FAD and smaller amounts (< 15%) of both FMN and riboflavin. Third, the presence of FAD was clearly demonstrated by reconstitution of the activity of D-amino acid oxidase, a FAD-dependent enzyme, when granule extracts were added to the apoenzyme. Thus, we have identified FAD as the predominant fluorophore in eosinophil granules. The small amounts of FMN and riboflavin detected may result from the hydrolysis of FAD under the acidic conditions of granule extraction. Because fluorescent material is deposited onto target cells by eosinophils, it is possible that granule-associated flavoproteins may act as a source of hydrogen peroxide and/or superoxide, which, in conjunction with eosinophil peroxidase, could yield potent cytotoxic agents.

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Eosinophils Preferentially Use Bromide to Generate Halogenating Agents

Mayeno

Curran

Roberts

et al. 1989

Journal of Biological Chemistry

137

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Arthur N. Mayeno

An Investigation of the Cause of the Eosinophilia–Myalgia Syndrome Associated with Tryptophan Use

Cytochromes P450: A Structure-Based Summary of Biotransformations Using Representative Substrates

Computational Toxicology of Chloroform: Reverse Dosimetry Using Bayesian Inference, Markov Chain Monte Carlo Simulation, and Human Biomonitoring Data

Granule-associated flavin adenine dinucleotide (FAD) is responsible for eosinophil autofluorescence

Eosinophils Preferentially Use Bromide to Generate Halogenating Agents

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