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Formation and biological targets of botanical o-quinones

The formation of o-quinones from direct 2-electron oxidation of catechols and/or two successive one electron oxidations could explain the cytotoxic/genotoxic and/or chemopreventive effects of several phenolic botanical extracts. For example, poison ivy contains urushiol, an oily mixture, which is ox...

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Published in:	Food and chemical toxicology 2018-10, Vol.120, p.700-707
Main Authors:	Bolton, Judy L., Dunlap, Tareisha L., Dietz, Birgit M.
Format:	Article
Language:	English
Subjects:	Activation, Metabolic Alkylation Bioactivation Botanicals Carcinogen Chemoprevention DNA - chemistry Glutathione - chemistry Hydroxylation Oxidation-Reduction P450 Plants - chemistry Proteins - chemistry Quinones Quinones - chemical synthesis Quinones - chemistry Quinones - pharmacology
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description	The formation of o-quinones from direct 2-electron oxidation of catechols and/or two successive one electron oxidations could explain the cytotoxic/genotoxic and/or chemopreventive effects of several phenolic botanical extracts. For example, poison ivy contains urushiol, an oily mixture, which is oxidized to various o-quinones likely resulting in skin toxicity through oxidative stress and alkylation mechanisms resulting in immune responses. Green tea contains catechins which are directly oxidized to o-quinones by various oxidative enzymes. Alternatively, phenolic botanicals could be o-hydroxylated by P450 to form catechols in vivo which are oxidized to o-quinones. Examples include, resveratrol which is oxidized to piceatannol and further oxidized to the o-quinone. Finally, botanical o-quinones can be formed by O-dealkylation of O-alkoxy groups or methylenedioxy rings resulting in catechols which are further oxidized to o-quinones. Examples include safrole, eugenol, podophyllotoxin and etoposide, as well as methysticin. Once formed these o-quinones have a variety of biological targets in vivo resulting in various biological effects ranging from chemoprevention -> no effect -> toxicity. This U-shaped biological effect curve has been described for a number of reactive intermediates including o-quinones. The current review summarizes the latest data on the formation and biological targets of botanical o-quinones. [Display omitted] •o-Quinone formation could explain numerous biological effects of phenolic botanical compounds.•o-Quinones are alkylating agents and redox active compounds that can alkylate/oxidize key proteins, GSH, and/or DNA.•Three major mechanisms for o-quinone formation are presented.•Several botanicals form o-quinones through these mechanisms explaining the biological effects of the parent compounds.
doi_str_mv	10.1016/j.fct.2018.07.050
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This U-shaped biological effect curve has been described for a number of reactive intermediates including o-quinones. The current review summarizes the latest data on the formation and biological targets of botanical o-quinones. [Display omitted] •o-Quinone formation could explain numerous biological effects of phenolic botanical compounds.•o-Quinones are alkylating agents and redox active compounds that can alkylate/oxidize key proteins, GSH, and/or DNA.•Three major mechanisms for o-quinone formation are presented.•Several botanicals form o-quinones through these mechanisms explaining the biological effects of the parent compounds.</description><identifier>ISSN: 0278-6915</identifier><identifier>EISSN: 1873-6351</identifier><identifier>DOI: 10.1016/j.fct.2018.07.050</identifier><identifier>PMID: 30063944</identifier><language>eng</language><publisher>England: Elsevier Ltd</publisher><subject>Activation, Metabolic ; Alkylation ; Bioactivation ; Botanicals ; Carcinogen ; Chemoprevention ; DNA - chemistry ; Glutathione - chemistry ; Hydroxylation ; Oxidation-Reduction ; P450 ; Plants - chemistry ; Proteins - chemistry ; Quinones ; Quinones - chemical synthesis ; Quinones - chemistry ; Quinones - pharmacology</subject><ispartof>Food and chemical toxicology, 2018-10, Vol.120, p.700-707</ispartof><rights>2018 The Authors</rights><rights>Copyright © 2018 The Authors. 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subjects	Activation, Metabolic Alkylation Bioactivation Botanicals Carcinogen Chemoprevention DNA - chemistry Glutathione - chemistry Hydroxylation Oxidation-Reduction P450 Plants - chemistry Proteins - chemistry Quinones Quinones - chemical synthesis Quinones - chemistry Quinones - pharmacology
title	Formation and biological targets of botanical o-quinones
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