Liver microsomal cytochrome P-450 and the oxidative metabolism of arachidonic acid.

Capdevila, Jorge H.; Chacos, N.; Werringloer, J.; Prough, Russell A.; Estabrook, Ronald W.

doi:10.1073/pnas.78.9.5362

Cited by 253 publications

(131 citation statements)

References 25 publications

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“…Although the liver is a well recognized site of P450 aa metabolism [21,42] and P450 aa metabolism was first identified in liver microsomes [43], effects of P450 aa metabolites in liver physiology and pathophysiology have not yet been delineated. Effects of EETs on liver cells or liver microsomes include increased intracellular Ca 2+ , vasopressin stimulated glycogenolysis, activation of phosphorylase and ADP ribosylation (reviewed in Spector and Norris [16]).…”

Section: Discussionmentioning

confidence: 99%

“…Although human CYP1A2 and avian CYP1A5 (more than other mammalian CYP1A2 enzymes [12,57]) have been demonstrated to have epoxygenase activities, and CYP1A induction was discovered to enhance aa epoxygenation early in the history of P450 mediated aa metabolism [43], attention to CYP1A epoxygenase activity has been eclipsed by interest in constitutive aa epoxygenases such as CYP2C and 2J, P450s, present in vascular endothelial and smooth muscle cells or heart [19]. Several factors should serve to increase attention to CYP1A2/1A5 mediated aa metabolism: (1) CYP1A2 is induced not only in liver, but in kidney, a well recognized site of action for P450-dependent aa metabolites [19,58], (2) CYP1A enzymes are induced not only by toxic chemicals but also by many aryl hydrocarbon receptor ligands such as tryptophan derivatives and other substances in food, as well as some endogenous CYP1A substrates, i.e.…”

Section: Discussionmentioning

confidence: 99%

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Mitochondrial P450-dependent arachidonic acid metabolism by TCDD-induced hepatic CYP1A5; conversion of EETs to DHETs by mitochondrial soluble epoxide hydrolase

Labitzke¹,

Diani-Moore²,

Rifkind³

2007

Archives of Biochemistry and Biophysics

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Several P450 enzymes localized in the endoplasmic reticulum and thought to be involved primarily in xenobiotic metabolism, including mouse and rat CYP1A1 and mouse CYP1A2, have also been found to translocate to mitochondria. We report here that the environmental toxin 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) induces enzymatically active CYP1A4/1A5, the avian orthologs of mammalian CYP1A1/1A2, in chick embryo liver mitochondria as well as in microsomes. P450 proteins and activity levels (CYP1A4-dependent 7-ethoxyresorufin-O-deethylase and CYP1A5-dependent arachidonic acid epoxygenation) in mitochondria were 23-40% of those in microsomes. DHET formation by mitochondria was twice that of microsomes and was attributable to a mitochondrial soluble epoxide hydrolase as confirmed by Western blotting with antiEPHX2, conversion by mitochondria of pure 11,12 and 14,15-EET to the corresponding DHETs and inhibition of DHET formation by the soluble epoxide hydrolase inhibitor, 12(-3-adamantan-1-yl-ureido)-dodecanoic acid (AUDA). TCDD also suppressed formation of mitochondrial and microsomal 20-HETE. The findings newly identify mitochondria as a site of P450-dependent arachidonic acid metabolism and as a potential target for TCDD effects. They also demonstrate that mitochondria contain soluble epoxide hydrolase and underscore a role for CYP1A in endobiotic metabolism.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Mitochondrial P450-dependent arachidonic acid metabolism by TCDD-induced hepatic CYP1A5; conversion of EETs to DHETs by mitochondrial soluble epoxide hydrolase

Labitzke¹,

Diani-Moore²,

Rifkind³

2007

Archives of Biochemistry and Biophysics

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“…The corresponding metabolites include a family of lipoxygenase-like HETEs, epoxyeicosatrienoic acids (EETs) and ω-HETEs which are formed by bis-allylic monoxygenation, olefin epoxydation and ω-hydroxylation respectively [85]. In addition, the CYP450 pathway gives rise to ROS termed HpETEs, although the EETs and ω-HETEs are the major products of the CYP450 pathway [86].…”

Section: Cyp450 Pathwaymentioning

confidence: 99%

Inhibition of arachidonic acid metabolism and its implication on cell proliferation and tumour-angiogenesis

Hyde

Missailidis

2009

International Immunopharmacology

142

101

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Lastly, the benefits of dietary omega-3 fatty acids and their mechanisms of action leading to reduced cancer risk and impeded cancer cell growth are mentioned. Finally, a proposal is put forward, suggesting a novel and integrated approach in viewing the molecular mechanisms and complex interactions responsible for the involvement of AA metabolites in carcinogenesis and the protective effects of omega-3 fatty acids in inflammation and tumour prevention.

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“…A high concentration of mitochondrial SOD ensures no significant O 2 .− accumulation beyond its initial site of production and allows for the generation of H 2 O 2 which has second messenger effects in the cytosol [31,[38][39][40]. The endoplasmic reticulum (ER) is another cellular source of ROS where resident cytochrome P-450 and b 5 family members oxidize unsaturated fatty acids and xenobiotics to generate O 2 .− and H 2 O 2 [41][42][43]. In addition, plasma membrane-associated oxidases such as NADPH oxidases generate ROS by oxidizing intracellular NADPH to reduce O 2 into O 2 .− in order to achieve localized microbicidal function in phagosomes [44][45][46][47].…”

Section: Types and Sources Of Cellular Rosmentioning

confidence: 99%

Reactive oxygen species and cellular oxygen sensing

Cash

Pan

Simon

2007

Free Radical Biology and Medicine

160

100

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Many organisms activate adaptive transcriptional programs to help them cope with decreased oxygen levels, or hypoxia, in their environment. These responses are triggered by various oxygen sensing systems in bacteria, yeast and metazoans. In metazoans, the hypoxia inducible factors (HIFs) mediate the adaptive transcriptional response to hypoxia by upregulating genes involved in maintaining bioenergetic homeostasis. The HIFs in turn are regulated by HIF-specific prolyl hydroxlase activity, which is sensitive to cellular oxygen levels and other factors such as tricarboxylic acid cycle metabolites and reactive oxygen species (ROS). Establishing a role for ROS in cellular oxygen sensing has been challenging since ROS are intrinsically unstable and difficult to measure. However, recent advances in fluorescence energy transfer resonance (FRET)-based methods for measuring ROS are alleviating some of the previous difficulties associated with dyes and luminescent chemicals. In addition, new genetic models have demonstrated that functional mitochondrial electron transport and associated ROS production during hypoxia are required for HIF stabilization in mammalian cells. Current efforts are directed at how ROS mediate prolyl hydroxylase activity and hypoxic HIF stabilization. Progress in understanding this process has been enhanced by the development of the FRET-based ROS probe, an vivo prolyl hydroxylase reporter and various genetic models harboring mutations in components of the mitochondrial electron transport chain.

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Liver microsomal cytochrome P-450 and the oxidative metabolism of arachidonic acid.

Cited by 253 publications

References 25 publications

Mitochondrial P450-dependent arachidonic acid metabolism by TCDD-induced hepatic CYP1A5; conversion of EETs to DHETs by mitochondrial soluble epoxide hydrolase

Mitochondrial P450-dependent arachidonic acid metabolism by TCDD-induced hepatic CYP1A5; conversion of EETs to DHETs by mitochondrial soluble epoxide hydrolase

Inhibition of arachidonic acid metabolism and its implication on cell proliferation and tumour-angiogenesis

Reactive oxygen species and cellular oxygen sensing

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