| 1 - 1 |
Special issue: Celebrating 50 years of oxygenases - Preface
Hayaishi O, Coon MJ, Estabrook RW, Que L, Yamamoto S |
| 2 - 6 |
An odyssey with oxygen
Hayaishi O |
| 7 - 11 |
Professor Howard Mason and oxygen activation
Waterman MR |
| 12 - 19 |
Biochemical and medical aspects of the indoleamine 2,3-dioxygenase-initiated L-tryptophan metabolism
Takikawa O |
| 20 - 24 |
Indoleamine 2,3 dioxygenase and regulation of T cell immunity
Mellor A |
| 25 - 33 |
Regulation of cyclooxygenase catalysis by hydroperoxides
Kulmacz RJ |
| 34 - 44 |
Structural and functional differences between cyclooxygenases: Fatty acid oxygenases with a critical role in cell signaling
Rouzer CA, Marnett LJ |
| 45 - 52 |
Cellular and molecular biology of prostacyclin synthase
Wu KK, Liou JY |
| 53 - 61 |
An intronic enhancer regulates cyclooxygenase-1 gene expression
DeLong CJ, Smith WL |
| 62 - 69 |
Cyclooxygenase variants: The role of alternative splicing
Roos KLT, Simmons DL |
| 70 - 76 |
Coupling between cyclooxygenases and terminal prostanoid synthases
Ueno N, Takegoshi Y, Kamei D, Kudo I, Murakami M |
| 77 - 81 |
Epileptogenesis in diacylglycerol kinase epsilon deficiency up-regulates COX-2 and tyrosine hydroxylase in hippocampus
Lukiw WJ, Cui JG, Musto AE, Musto BC, Bazan NG |
| 82 - 86 |
Localization of cyclooxygenases-1 and-2, and prostaglandin F synthase in human kidney and renal cell carcinoma
Sakurai M, Oishi K, Watanabe K |
| 87 - 92 |
A comprehensive model of positional and stereo control in lipoxygenases
Coffa G, Schneider C, Brash AR |
| 93 - 101 |
Structural biology of mammalian lipoxygenasese enzymatic consequences of targeted alterations of the protein structure
Kuhn H, Saam J, Eibach S, Holzhutter HG, Ivanov I, Walther M |
| 102 - 110 |
Regulation of 5-lipoxygenase enzyme activity
Radmark O, Samuelsson B |
| 111 - 116 |
Stress-induced nuclear export of 5-lipoxygenase
Hanaka H, Shimizu T, Izumi T |
| 117 - 121 |
Transcription factor Sp1 functions as an anchor protein in gene transcription of human 12(S)-lipoxygenase
Chang WC, Chen BK |
| 122 - 127 |
Arachidonate 12-lipoxygenases with reference to their selective inhibitors
Yamamoto S, Katsukawa M, Nakano A, Hiraki E, Nishimura K, Jisaka M, Yokota K, Ueda N |
| 128 - 135 |
Selective uptake and efflux of cholesteryl linoleate in LDL by macrophages expressing 12/15-lipoxygenase
Takahashi Y, Zhu H, Xu WP, Murakami T, Iwasaki T, Hattori H, Yoshimoto T |
| 136 - 143 |
Double dioxygenation by mouse 8S-lipoxygenase: Specific formation of a potent peroxisome proliferator-activated receptor alpha agonist
Jisaka M, Iwanaga C, Takahashi N, Goto T, Kawada T, Yamamoto T, Ikeda I, Nishimura K, Nagaya T, Fushiki T, Yokota K |
| 144 - 148 |
Synthesis of 8,9-leukotriene A(4) by murine 8-lipoxygenase
Kawajiri H, Piao YS, Takahashi Y, Murakami T, Hamanaka N, Yoshimoto T |
| 149 - 157 |
The contributions of aspirin and microbial oxygenase to the biosynthesis of anti-inflammatory resolvins: Novel oxygenase products from omega-3 polyunsaturated fatty acids
Arita M, Clish CB, Serhan CN |
| 158 - 160 |
PBT-3, a hepoxilin stable analog, causes long term inhibition of growth of K562 solid tumours in vivo
Li X, Qiao N, Reynaud D, Abdelhaleem M, Pace-Asciak CR |
| 161 - 168 |
Hepoxilin A(3) synthase
Nigam S, Zafiriou MP |
| 169 - 174 |
alpha-Dioxygenases
Hamberg M, de Leon IP, Rodriguez MJ, Castresana C |
| 175 - 190 |
Rieske business: Structure-function of Rieske non-heme oxygenases
Ferraro DJ, Gakhar L, Ramaswamy S |
| 191 - 197 |
Kinetic and spectroscopic investigation of Co-II, Ni-II, and N-oxalylglycine inhibition of the Fe-II/alpha-ketoglutarate dioxygenase, TauD
Kalliri E, Grzyska PK, Hausinger RP |
| 198 - 205 |
Structure of catechol 1,2-dioxygenase from Pseudomonas arvilla
Earhart CA, Vetting MW, Gosu R, Michaud-Soret I, Que L, Ohlendorf DH |
| 206 - 214 |
Spectroscopic and computational studies of NTBC bound to the non-heme iron enzyme (4-hydroxyphenyl)pyruvate dioxygenase: Active site contributions to drug inhibition
Neidig ML, Decker A, Kavana M, Moran GR, Solomon EI |
| 215 - 222 |
Molecular basis for the substrate selectivity of bicyclic and monocyclic extradiol dioxygenases
Vaillancourt FH, Fortin PD, Labbe G, Drouin NM, Karim Z, Agar NYR, Eltis LD |
| 223 - 229 |
Single-turnover kinetics of 2,3-dihydroxybiphenyl 1,2-dioxygenase reacting with 3-formylcatechol
Ishida T, Senda T, Tanaka H, Yamamoto A, Horiike K |
| 230 - 239 |
Post-translational self-hydroxylation: A probe for oxygen activation mechanisms in non-heme iron enzymes
Farquhar ER, Koehntop KD, Emerson JP, Que L |
| 240 - 249 |
Oxygen-18 tracer studies of enzyme reactions with radical/cation diagnostic probes
Moe LA, Fox BG |
| 250 - 253 |
Role of molecular oxygen in the bioluminescence of the firefly squid, Watasenia scintillans
Tsuji FI |
| 254 - 261 |
Substrate radical intermediates in soluble methane monooxygenase
Liu AM, Jin Y, Zhang JY, Brazeau BJ, Lipscomb JD |
| 262 - 266 |
Reactions of the diiron(IV) intermediate Q in soluble methane monooxygenase with fluoromethanes
Beauvais LG, Lippard SJ |
| 267 - 270 |
Molecular genetics of tyrosine 3-monooxygenase and inherited diseases
Kobayashi K, Nagatsu T |
| 271 - 276 |
Regulatory mechanism of tyrosine hydroxylase activity
Fujisawa H, Okuno S |
| 277 - 284 |
Distinctive iron requirement of tryptophan 5-monooxygenase: TPH1 requires dissociable ferrous iron
Hasegawa H, Ichiyama A |
| 285 - 289 |
Early years of oxygenase research in Bethesda, Osaka, Urbana, and Kanazawa
Katagiri M |
| 290 - 298 |
Steroid hydroxylations: A paradigm for cytochrome P450 catalyzed mammalian monooxygenation reactions
Estabrook RW |
| 299 - 305 |
Phenotype-genotype variability in the human CYP3A locus as assessed by the probe drug quinine and analyses of variant CYP3A4 alleles
Rodriguez-Antona C, Sayi JG, Gustafsson LL, Bertilsson L, Ingelman-Sundberg M |
| 306 - 310 |
Genetic polymorphism of CYP2A6 as one of the potential determinants of tobacco-related cancer risk
Kamataki T, Fujieda M, Kiyotani K, Iwano S, Kunitoh H |
| 311 - 317 |
Molecular mechanisms of AhR functions in the regulation of cytochrome P450 genes
Fujii-Kuriyama Y, Mimura J |
| 318 - 324 |
Generation and characterization of a transgenic mouse model with hepatic expression of human CYP2A6
Zhang QY, Gu J, Su T, Cui H, Zhang XL, D'Agostino J, Zhuo XL, Yang WZ, Swiatek PJ, Ding XX |
| 325 - 330 |
Molecular identity and gene expression of aldosterone synthase cytochrome P450
Okamoto M, Nonaka Y, Takemori H, Doi J |
| 331 - 336 |
Structural diversity of human xenobiotic-metabolizing cytochrome P450 monooxygenases
Johnson EF, Stout CD |
| 337 - 345 |
Structural biology of heme monooxygenases
Poulos TL |
| 346 - 354 |
Thirty years of microbial P450 monooxygenase research: Peroxo-heme intermediates - The central bus station in heme oxygenase catalysis
Sligar SG, Makris TM, Denisov IG |
| 355 - 364 |
Freeze-quenched iron-oxo intermediates in cytochromes P450
Jung C, Schunemann V, Lendzian F |
| 365 - 371 |
Subzero-temperature stabilization and spectroscopic characterization of homogeneous oxyferrous complexes of the cytochrome P450BM3 (CYP102) oxygenase domain and holoenzyme
Perera R, Sono M, Raner GM, Dawson JH |
| 372 - 377 |
Reactivity of a new class of P450 enzyme models
Meyer D, Leifels T, Sbaragli L, Woggon WD |
| 378 - 385 |
Omega oxygenases: Nonheme-iron enzymes and P450 cytochromes
Coon MJ |
| 386 - 393 |
Roles of the threonine 407, aspartic acid 417, and threonine 419 residues in P4502B1 in metabolism
Sridar C, Harleton E, Hollenberg PF |
| 394 - 403 |
Highly reactive electrophilic oxidants in cytochrome P450 catalysis
Newcomb M, Chandrasena REP |
| 404 - 409 |
Heme-thiolate proteins
Omura T |
| 410 - 417 |
Preliminary assessment of the C13-side chain 2'-hydroxylase involved in Taxol biosynthesis
Long RM, Croteau R |
| 418 - 422 |
Sterol 14 alpha-demethylase, an abundant and essential mixed-function oxidase
Waterman MR, Lepesheva GI |
| 423 - 431 |
Renal localization, expression, and developmental regulation of P450 4F cytochromes in three substrains of spontaneously hypertensive rats
Kalsotra A, Cui XM, Anakk S, Hinojos CA, Doris PA, Strobel HW |
| 432 - 436 |
Protein oxidation by the cytochrome P450 mixed-function oxidation system
Stadtman ER, Arai H, Berlett BS |
| 437 - 445 |
Thermophilic cytochrome P450 enzymes
Nishida CR, de Montellano PRO |
| 446 - 449 |
Phosphorylation of cytochromes P450: First discovery of a posttranslational modification of a drug-metabolizing enzyme
Oesch-Bartlomowicz B, Oesch F |
| 450 - 455 |
First evidence that cytochrome P450 may catalyze both S-oxidation and epoxidation of thiophene derivatives
Dansette PM, Bertho G, Mansuy D |
| 456 - 464 |
Use of directed evolution of mammalian cytochromes P450 for investigating the molecular basis of enzyme function and generating novel biocatalysts
Kumar S, Halpert JR |
| 465 - 469 |
Function of human cytochrome P450s: Characterization of the orphans
Guengerich FP, Wu ZL, Bartleson CJ |
| 470 - 476 |
Electrochemistry of heme-thiolate proteins
Udit AK, Gray HB |
| 477 - 482 |
Active sites of two orthologous cytochromes P450 2E1: Differences revealed by spectroscopic methods
Anzenbacherova E, Hudecek J, Murgida D, Hildebrandt P, Marchal S, Lange R, Anzenbacher P |
| 483 - 490 |
Ascorbate stimulates monooxygenase-dependent steroidogenesis in adrenal zona glomerulosa
Mitani F, Ogishima T, Mukai K, Suematsu M |
| 491 - 498 |
The interaction domain of the redox protein adrenodoxin is mandatory for binding of the electron acceptor CYP11A1, but is not required for binding of the electron donor adrenodoxin reductase
Heinz A, Hannemann F, Muller JJ, Heinemann U, Bernhardt R |
| 499 - 506 |
Role of cytochrome b(5) in catalysis by cytochrome P4502B4
Zhang HM, Myshkin E, Waskell L |
| 507 - 519 |
The journey from NADPH-cytochrome P450 oxidoreductase to nitric oxide synthases
Masters BSS |
| 520 - 528 |
Structure and function of NADPH-cytochrome P450 reductase and nitric oxide synthase reductase domain
Iyanagi T |
| 529 - 535 |
Hunting oxygen complexes of nitric oxide synthase at low temperature and high pressure
Marchal S, Gorren ACF, Andersson KK, Lange R |
| 536 - 542 |
Redox regulation of vascular prostanoid synthesis by the nitric oxide-superoxide system
Bachschmid M, Schildknecht S, Ullrich V |
| 543 - 549 |
Detection of nitrous oxide in the neuronal nitric oxide synthase reaction by gas chromatography-mass spectrometry
Ishimura Y, Gao YT, Panda SP, Roman LJ, Masters BSS, Weintraub ST |
| 550 - 557 |
Rho-kinase mediates spinal nitric oxide formation by prostaglandin E-2 via EP3 subtype
Matsumura S, Abe T, Mabuchi T, Katano T, Takagi K, Okuda-Ashitaka E, Tatsumi S, Nakai Y, Hidaka H, Suzuki M, Sasaki Y, Minami T, Ito S |
| 558 - 567 |
Heme oxygenase and heme degradation
Kikuchi G, Yoshida T, Noguchi M |
| 568 - 577 |
30 some years of heme oxygenase: From a "molecular wrecking ball" to a "mesmerizing" trigger of cellular events
Maines MD, Gibbs PEM |
| 578 - 583 |
A kinetic study of the mechanism of conversion of alpha-hydroxyheme to verdoheme while bound to heme oxygenase
Sakamoto H, Takahashi K, Higashimoto Y, Harada S, Palmer G, Noguchi M |
| 584 - 589 |
Evidence for the hydrophobic cavity of heme oxygenase-1 to be a CO-trapping site
Migita CT, Togashi S, Minakawa M, Zhang XH, Yoshida T |
| 590 - 598 |
Dynamics involved in catalysis by single-component and two-component flavin-dependent aromatic hydroxylases
Ballou DP, Entsch B, Cole LJ |
| 599 - 604 |
Some distinctions between flavin-containing and cytochrome P450 monooxygenases
Cashman JR |
| 605 - 609 |
A cytosolic cytochrome b(5)-like protein in yeast cell accelerating the electron transfer from NADPH to cytochrome c catalyzed by Old Yellow Enzyme
Nakagawa M, Yamano T, Kuroda K, Nonaka Y, Tojo H, Fujii S |
| 610 - 616 |
Regulation of hypoxia-inducible factor 1 by prolyl and asparaginyl hydroxylases
Hirota K, Semenza GL |
| 617 - 626 |
Signalling hypoxia by HIF hydroxylases
Schofield CJ, Ratcliffe PJ |
| 627 - 638 |
The von Hippel-Lindau protein, HIF hydroxylation, and oxygen sensing
Kaelin WG |
| 639 - 647 |
Dioxygenases as O-2-dependent regulators of the hypoxic response pathway
Dann CE, Bruick RK |
| 648 - 652 |
Hemeoxygenase-2 as an O-2 sensor in K+ channel-dependent chemotransduction
Kemp PJ |
| 653 - 659 |
Dynamic changes in expression of heme oxygenases in mouse heart and liver during hypoxia
Han F, Takeda K, Yokoyama S, Ueda H, Shinozawa Y, Furuyama K, Shibahara S |
| 660 - 667 |
Phosphorylation inhibits DNA-binding of alternatively spliced aryl hydrocarbon receptor nuclear translocator
Kewley RJ, Whitelaw ML |
| 668 - 676 |
Lipid peroxidation: Mechanisms, inhibition, and biological effects
Niki E, Yoshida Y, Saito Y, Noguchi N |
| 677 - 686 |
Molecular composition and regulation of the Nox family NAD(P)H oxidases
Sumimoto H, Miyano K, Takeya R |
