Karen Bedard and Karl-Heinz Krause
Karen Bedard and Karl-Heinz Krause
Karen Bedard and Karl-Heinz Krause
You also want an ePaper? Increase the reach of your titles
YUMPU automatically turns print PDFs into web optimized ePapers that Google loves.
304 KAREN BEDARD AND KARL-HEINZ KRAUSE<br />
612. Mishra M, Acharya UR. Protective action of vitamins on the<br />
spermatogenesis in lead-treated Swiss mice. J Trace Elem Med Biol<br />
18: 173–178, 2004.<br />
613. Mital S, Liao JK. Statins <strong>and</strong> the myocardium. Semin Vasc Med 4:<br />
377–384, 2004.<br />
614. Mitsushita J, Lambeth JD, Kamata T. The superoxide-generating<br />
oxidase Nox1 is functionally required for Ras oncogene transformation.<br />
Cancer Res 64: 3580–3585, 2004.<br />
615. Miyano K, Ueno N, Takeya R, Sumimoto H. Direct involvement<br />
of the small GTPase Rac in activation of the superoxide-producing<br />
NADPH oxidase Nox1. J Biol Chem. In press.<br />
616. Miyata K, Rahman M, Shokoji T, Nagai Y, Zhang GX, Sun GP,<br />
Kimura S, Yukimura T, Kiyomoto H, Kohno M, Abe Y, Nishiyama<br />
A. Aldosterone stimulates reactive oxygen species production<br />
through activation of NADPH oxidase in rat mesangial<br />
cells. J Am Soc Nephrol 16: 2906–2912, 2005.<br />
617. Mizukami Y, Matsubara F, Matsukawa S, Izumi R. Cytochemical<br />
localization of glutaraldehyde-resistant NAD(P)H-oxidase in<br />
rat hepatocytes. Histochemistry 79: 259–267, 1983.<br />
618. Mochizuki T, Furuta S, Mitsushita J, Shang WH, Ito M, Yokoo<br />
Y, Yamaura M, Ishizone S, Nakayama J, Konagai A, Hirose K,<br />
Kiyosawa K, Kamata T. Inhibition of NADPH oxidase 4 activates<br />
apoptosis via the AKT/apoptosis signal-regulating kinase 1 pathway<br />
in pancreatic cancer PANC-1 cells. Oncogene. In press.<br />
619. Moe KT, Aulia S, Jiang F, Chua YL, Koh TH, Wong MC,<br />
Dusting GJ. Differential upregulation of Nox homologues of<br />
NADPH oxidase by tumor necrosis factor-alpha in human aortic<br />
smooth muscle <strong>and</strong> embryonic kidney cells. J Cell Mol Med 10:<br />
231–239, 2006.<br />
620. Mohazzab KM, Kaminski PM, Wolin MS. NADH oxidoreductase<br />
is a major source of superoxide anion in bovine coronary artery<br />
endothelium. Am J Physiol Heart Circ Physiol 266: H2568–H2572,<br />
1994.<br />
621. Mohazzab KM, Wolin MS. Sites of superoxide anion production<br />
detected by lucigenin in calf pulmonary artery smooth muscle.<br />
Am J Physiol Lung Cell Mol Physiol 267: L815–L822, 1994.<br />
622. Mollnau H, Wendt M, Szocs K, Lassegue B, Schulz E, Oelze M,<br />
Li H, Bodenschatz M, August M, Kleschyov AL, Tsilimingas N,<br />
Walter U, Forstermann U, Meinertz T, Griendling K, Munzel<br />
T. Effects of angiotensin II infusion on the expression <strong>and</strong> function<br />
of NAD(P)H oxidase <strong>and</strong> components of nitric oxide/cGMP signaling.<br />
Circ Res 90: E58–65, 2002.<br />
623. Mor<strong>and</strong> S, Agn<strong>and</strong>ji D, Noel-Hudson MS, Nicolas V, Buisson<br />
S, Macon-Lemaitre L, Gnidehou S, Kaniewski J, Ohayon R,<br />
Virion A, Dupuy C. Targeting of the dual oxidase 2 N-terminal<br />
region to the plasma membrane. J Biol Chem 279: 30244–30251,<br />
2004.<br />
624. Mor<strong>and</strong> S, Chaaraoui M, Kaniewski J, Deme D, Ohayon R,<br />
Noel-Hudson MS, Virion A, Dupuy C. Effect of iodide on nicotinamide<br />
adenine dinucleotide phosphate oxidase activity <strong>and</strong><br />
Duox2 protein expression in isolated porcine thyroid follicles.<br />
Endocrinology 144: 1241–1248, 2003.<br />
625. Mor<strong>and</strong> S, Dos Santos OF, Ohayon R, Kaniewski J, Noel-<br />
Hudson MS, Virion A, Dupuy C. Identification of a truncated dual<br />
oxidase 2 (DUOX2) messenger ribonucleic acid (mRNA) in two rat<br />
thyroid cell lines. Insulin <strong>and</strong> forskolin regulation of DUOX2 mRNA<br />
levels in FRTL-5 cells <strong>and</strong> porcine thyrocytes. Endocrinology 144:<br />
567–574, 2003.<br />
626. Morawietz H, Bornstein SR. Leptin, endothelin, NADPH oxidase,<br />
heart failure. Hypertension 47: e20–21, 2006.<br />
627. Morawietz H, Weber M, Rueckschloss U, Lauer N, Hacker A,<br />
Kojda G. Upregulation of vascular NAD(P)H oxidase subunit<br />
gp91phox <strong>and</strong> impairment of the nitric oxide signal transduction<br />
pathway in hypertension. Biochem Biophys Res Commun 285:<br />
1130–1135, 2001.<br />
628. Morazzani M, de Carvalho DD, Kovacic H, Smida-Rezgui S,<br />
Bri<strong>and</strong> C, Penel C. Monolayer versus aggregate balance in survival<br />
process for EGF-induced apoptosis in A431 carcinoma cells:<br />
implication of ROS-P38 MAPK-integrin alpha2beta1 pathway. Int J<br />
Cancer 110: 788–799, 2004.<br />
629. Moreno JC. Identification of novel genes involved in congenital<br />
hypothyroidism using serial analysis of gene expression. Horm Res<br />
60 Suppl 3: 96–102, 2003.<br />
Physiol Rev VOL 87 JANUARY 2007 www.prv.org<br />
630. Moreno JC, Bikker H, Kempers MJ, van Trotsenburg AS,<br />
Baas F, de Vijlder JJ, Vulsma T, Ris-Stalpers C. Inactivating<br />
mutations in the gene for thyroid oxidase 2 (THOX2) <strong>and</strong> congenital<br />
hypothyroidism. N Engl J Med 347: 95–102, 2002.<br />
631. Moreno MU, Jose GS, Fortuno A, Beloqui O, Diez J, Zalba G.<br />
The C242T CYBA polymorphism of NADPH oxidase is associated<br />
with essential hypertension. J Hypertens 24: 1299–1306, 2006.<br />
632. Moreno MU, San Jose G, Orbe J, Paramo JA, Beloqui O, Diez<br />
J, Zalba G. Preliminary characterisation of the promoter of the<br />
human p22(phox) gene: identification of a new polymorphism associated<br />
with hypertension. FEBS Lett 542: 27–31, 2003.<br />
633. Morgenstern DE, Gifford MA, Li LL, Doerschuk CM, Dinauer<br />
MC. Absence of respiratory burst in X-linked chronic granulomatous<br />
disease mice leads to abnormalities in both host defense <strong>and</strong><br />
inflammatory response to Aspergillus fumigatus. J Exp Med 185:<br />
207–218, 1997.<br />
634. Mosyagin I, Dettling M, Roots I, Mueller-Oerlinghausen B,<br />
Cascorbi I. Impact of myeloperoxidase <strong>and</strong> NADPH-oxidase polymorphisms<br />
in drug-induced agranulocytosis. J Clin Psychopharmacol<br />
24: 613–617, 2004.<br />
635. Moulton PJ, Hiran TS, Goldring MB, Hancock JT. Detection of<br />
protein <strong>and</strong> mRNA of various components of the NADPH oxidase<br />
complex in an immortalized human chondrocyte line. Br J Rheumatol<br />
36: 522–529, 1997.<br />
636. Mueller CF, Laude K, McNally JS, Harrison DG. ATVB in focus:<br />
redox mechanisms in blood vessels. Arterioscler Thromb Vasc Biol<br />
25: 274–278, 2005.<br />
637. Munzel T, Daiber A, Mulsch A. Explaining the phenomenon of<br />
nitrate tolerance. Circ Res 97: 618–628, 2005.<br />
638. Munzel T, Hink U, Heitzer T, Meinertz T. Role for NADPH/<br />
NADH oxidase in the modulation of vascular tone. Ann NY Acad<br />
Sci 874: 386–400, 1999.<br />
639. Murillo I, Henderson LM. Expression of gp91phox/Nox2 in<br />
COS-7 cells: cellular localization of the protein <strong>and</strong> the detection of<br />
outward proton currents. Biochem J 385: 649–657, 2005.<br />
640. Murphy R, Decoursey TE. Charge compensation during the<br />
phagocyte respiratory burst. Biochim Biophys Acta. In press.<br />
641. Myatt L, Cui X. Oxidative stress in the placenta. Histochem Cell<br />
Biol 122: 369–382, 2004.<br />
642. Nakagami H, Jensen KS, Liao JK. A novel pleiotropic effect of<br />
statins: prevention of cardiac hypertrophy by cholesterol-independent<br />
mechanisms. Ann Med 35: 398–403, 2003.<br />
643. Nakagami H, Takemoto M, Liao JK. NADPH oxidase-derived<br />
superoxide anion mediates angiotensin II-induced cardiac hypertrophy.<br />
J Mol Cell Cardiol 35: 851–859, 2003.<br />
644. Nakamura M, Murakami M, Koga T, Tanaka Y, Minakami S.<br />
Monoclonal antibody 7D5 raised to cytochrome b558 of human<br />
neutrophils: immunocytochemical detection of the antigen in peripheral<br />
phagocytes of normal subjects, patients with chronic granulomatous<br />
disease, their carrier mothers. Blood 69: 1404–1408,<br />
1987.<br />
645. Nakamura Y, Makino R, Tanaka T, Ishimura Y, Ohtaki S.<br />
Mechanism of H 2O 2 production in porcine thyroid cells: evidence<br />
for intermediary formation of superoxide anion by NADPH-dependent<br />
H 2O 2-generating machinery. Biochemistry 30: 4880–4886,<br />
1991.<br />
646. Nakamura Y, Ohtaki S, Makino R, Tanaka T, Ishimura Y.<br />
Superoxide anion is the initial product in the hydrogen peroxide<br />
formation catalyzed by NADPH oxidase in porcine thyroid plasma<br />
membrane. J Biol Chem 264: 4759–4761, 1989.<br />
647. Nakano T, Matsunaga S, Nagata A, Maruyama T. NAD(P)H<br />
oxidase p22phox Gene C242T polymorphism <strong>and</strong> lipoprotein oxidation.<br />
Clin Chim Acta 335: 101–107, 2003.<br />
648. Nakayama M, Inoguchi T, Sonta T, Maeda Y, Sasaki S, Sawada<br />
F, Tsubouchi H, Sonoda N, Kobayashi K, Sumimoto H, Nawata<br />
H. Increased expression of NAD(P)H oxidase in islets of animal<br />
models of Type 2 diabetes <strong>and</strong> its improvement by an AT1 receptor<br />
antagonist. Biochem Biophys Res Commun 332: 927–933, 2005.<br />
649. Narayanan PK, Goodwin EH, Lehnert BE. Alpha particles initiate<br />
biological production of superoxide anions <strong>and</strong> hydrogen peroxide<br />
in human cells. Cancer Res 57: 3963–3971, 1997.<br />
650. Nardi M, Feinmark SJ, Hu L, Li Z, Karpatkin S. Complementindependent<br />
Ab-induced peroxide lysis of platelets requires 12-<br />
Downloaded from<br />
physrev.physiology.org<br />
on February 2, 2010