Karen Bedard and Karl-Heinz Krause
Karen Bedard and Karl-Heinz Krause
Karen Bedard and Karl-Heinz Krause
Create successful ePaper yourself
Turn your PDF publications into a flip-book with our unique Google optimized e-Paper software.
962. Wyche KE, Wang SS, Griendling KK, Dikalov SI, Austin H,<br />
Rao S, Fink B, Harrison DG, Zafari AM. C242T CYBA polymorphism<br />
of the NADPH oxidase is associated with reduced respiratory<br />
burst in human neutrophils. Hypertension 43: 1246–1251,<br />
2004.<br />
963. Xiao L, Pimentel DR, Wang J, Singh K, Colucci WS, Sawyer<br />
DB. Role of reactive oxygen species <strong>and</strong> NAD(P)H oxidase in<br />
alpha(1)-adrenoceptor signaling in adult rat cardiac myocytes.<br />
Am J Physiol Cell Physiol 282: C926–C934, 2002.<br />
964. Yamagishi S, Nakamura K, Ueda S, Kato S, Imaizumi T. Pigment<br />
epithelium-derived factor (PEDF) blocks angiotensin II signaling<br />
in endothelial cells via suppression of NADPH oxidase: a<br />
novel anti-oxidative mechanism of PEDF. Cell Tissue Res 320:<br />
437–445, 2005.<br />
965. Yamashita T, Someya A, Hara E. Response of superoxide anion<br />
production by guinea pig eosinophils to various soluble stimuli:<br />
comparison to neutrophils. Arch Biochem Biophys 241: 447–452,<br />
1985.<br />
966. Yamasoba T, Nuttall AL, Harris C, Raphael Y, Miller JM. Role<br />
of glutathione in protection against noise-induced hearing loss.<br />
Brain Res 784: 82–90, 1998.<br />
967. Yan SR, Berton G. Regulation of Src family tyrosine kinase activities<br />
in adherent human neutrophils. Evidence that reactive oxygen<br />
intermediates produced by adherent neutrophils increase the activity<br />
of the p58c-fgr <strong>and</strong> p53/56lyn tyrosine kinases. J Biol Chem<br />
271: 23464–23471, 1996.<br />
968. Yang JQ, Li S, Domann FE, Buettner GR, Oberley LW. Superoxide<br />
generation in v-Ha-ras-transduced human keratinocyte Ha-<br />
CaT cells. Mol Carcinog 26: 180–188, 1999.<br />
969. Yang S, Madyastha P, Bingel S, Ries W, Key L. A new superoxide-generating<br />
oxidase in murine osteoclasts. J Biol Chem 276:<br />
5452–5458, 2001.<br />
970. Yang S, Madyastha P, Ries W, Key LL. Characterization of<br />
interferon gamma receptors on osteoclasts: effect of interferon<br />
gamma on osteoclastic superoxide generation. J Cell Biochem 84:<br />
645–654, 2002.<br />
971. Yang S, Ries WL, Key LL Jr. Nicotinamide adenine dinucleotide<br />
phosphate oxidase in the formation of superoxide in osteoclasts.<br />
Calcif Tissue Int 63: 346–350, 1998.<br />
972. Yang S, Ries WL, Key LL Jr. Superoxide generation in transformed<br />
B-lymphocytes from patients with severe, malignant osteopetrosis.<br />
Mol Cell Biochem 199: 15–24, 1999.<br />
973. Yang S, Zhang Y, Ries W, Key L. Expression of Nox4 in osteoclasts.<br />
J Cell Biochem 92: 238–248, 2004.<br />
974. Yang T, Zhang A, Honeggar M, Kohan DE, Mizel D, S<strong>and</strong>ers K,<br />
Hoidal JR, Briggs JP, Schnermann JB. Hypertonic induction of<br />
COX-2 in collecting duct cells by reactive oxygen species of mitochondrial<br />
origin. J Biol Chem 280: 34966–34973, 2005.<br />
975. Yasuhara R, Miyamoto Y, Akaike T, Akuta T, Nakamura M,<br />
Takami M, Morimura N, Yasu K, Kamijo R. Interleukin-1beta<br />
induces death in chondrocyte-like ATDC5 cells through mitochondrial<br />
dysfunction <strong>and</strong> energy depletion in a reactive nitrogen <strong>and</strong><br />
oxygen species-dependent manner. Biochem J 389: 315–323, 2005.<br />
976. Yi XY, Li VX, Zhang F, Yi F, Matson DR, Jiang MT, Li PL.<br />
Characteristics <strong>and</strong> actions of NAD(P)H oxidase on the sarcoplasmic<br />
reticulum of coronary artery smooth muscle. Am J Physiol<br />
Heart Circ Physiol 290: H1136–H1144, 2006.<br />
977. Yoshida LS, Nishida S, Shimoyama T, Kawahara T, Kondo-<br />
Teshima S, Rokutan K, Kobayashi T, Tsunawaki S. Superoxide<br />
generation by Nox1 in guinea pig gastric mucosal cells involves a<br />
component with p67(phox)-ability. Biol Pharm Bull 27: 147–155,<br />
2004.<br />
978. Yoshida M, Korfhagen TR, Whitsett JA. Surfactant protein D<br />
regulates NF-kappa B <strong>and</strong> matrix metalloproteinase production in<br />
THE NOX FAMILY OF ROS-GENERATING NADPH OXIDASES 313<br />
Physiol Rev VOL 87 JANUARY 2007 www.prv.org<br />
alveolar macrophages via oxidant-sensitive pathways. J Immunol<br />
166: 7514–7519, 2001.<br />
979. Yu D, Imajoh-Ohmi S, Akagawa K, Kanegasaki S. Suppression<br />
of superoxide-generating ability during differentiation of monocytes<br />
to dendritic cells. J Biochem 119: 23–28, 1996.<br />
980. Yu JH, Lim JW, Kim KH, Morio T, Kim H. NADPH oxidase <strong>and</strong><br />
apoptosis in cerulein-stimulated pancreatic acinar AR42J cells.<br />
Free Radical Biol Med 39: 590–602, 2005.<br />
981. Zalba G, Jose GS, Moreno MU, Fortuno A, Diez J. NADPH<br />
oxidase-mediated oxidative stress: genetic studies of the p22(phox)<br />
gene in hypertension. Antioxid Redox Signal 7: 1327–1336, 2005.<br />
982. Zalba G, San Jose G, Moreno MU, Fortuno MA, Fortuno A,<br />
Beaumont FJ, Diez J. Oxidative stress in arterial hypertension:<br />
role of NAD(P)H oxidase. Hypertension 38: 1395–1399, 2001.<br />
983. Zekry D, Epperson TK, <strong>Krause</strong> KH. A role for NOX NADPH<br />
oxidases in Alzheimer’s disease <strong>and</strong> other types of dementia?<br />
IUBMB Life 55: 307–313, 2003.<br />
984. Zhan CD, Sindhu RK, Vaziri ND. Up-regulation of kidney<br />
NAD(P)H oxidase <strong>and</strong> calcineurin in SHR: reversal by lifelong<br />
antioxidant supplementation. Kidney Int 65: 219–227, 2004.<br />
985. Zhang W, Wang T, Qin L, Gao HM, Wilson B, Ali SF, Hong JS,<br />
Liu B. Neuroprotective effect of dextromethorphan in the MPTP<br />
Parkinson’s disease model: role of NADPH oxidase. FASEB J 18:<br />
589–591, 2004.<br />
986. Zhang X, Shan P, Sasidhar M, Chupp GL, Flavell RA, Choi AM,<br />
Lee PJ. Reactive oxygen species <strong>and</strong> extracellular signal-regulated<br />
kinase 1/2 mitogen-activated protein kinase mediate hyperoxiainduced<br />
cell death in lung epithelium. Am J Respir Cell Mol Biol 28:<br />
305–315, 2003.<br />
987. Zhao X, Xu B, Bhattacharjee A, Oldfield CM, Wientjes FB,<br />
Feldman GM, Cathcart MK. Protein kinase Cdelta regulates<br />
p67phox phosphorylation in human monocytes. J Leukoc Biol 77:<br />
414–420, 2005.<br />
988. Zhao Y, Chaiswing L, Bakthavatchalu V, Oberley TD, St Clair<br />
DK. Ras mutation promotes p53 activation <strong>and</strong> apoptosis of skin<br />
keratinocytes. Carcinogenesis. In press.<br />
989. Zhou C, Ziegler C, Birder LA, Stewart AF, Levitan ES. Angiotensin<br />
II <strong>and</strong> stretch activate NADPH oxidase to destabilize cardiac<br />
Kv4.3 channel mRNA. Circ Res. In press.<br />
990. Zhu QS, Xia L, Mills GB, Lowell CA, Touw IP, Corey SJ.<br />
G-CSF induced reactive oxygen species involves Lyn-PI3-kinase-<br />
Akt <strong>and</strong> contributes to myeloid cell growth. Blood 107: 1847–<br />
1856, 2006.<br />
991. Zhukov A Ingelman-Sundberg M. Relationship between cytochrome<br />
P450 catalytic cycling <strong>and</strong> stability: fast degradation of<br />
ethanol-inducible cytochrome P450 2E1 (CYP2E1) in hepatoma<br />
cells is abolished by inactivation of its electron donor NADPHcytochrome<br />
P450 reductase. Biochem J 340: 453–458, 1999.<br />
992. Zimmerman MC, Dunlay RP, Lazartigues E, Zhang Y, Sharma<br />
RV, Engelhardt JF, Davisson RL. Requirement for Rac1-dependent<br />
NADPH oxidase in the cardiovascular <strong>and</strong> dipsogenic actions<br />
of angiotensin II in the brain. Circ Res 95: 532–539, 2004.<br />
993. Zimmerman MC, Lazartigues E, Lang JA, Sinnayah P, Ahmad<br />
IM, Spitz DR, Davisson RL. Superoxide mediates the actions of<br />
angiotensin II in the central nervous system. Circ Res 91: 1038–<br />
1045, 2002.<br />
994. Zimmerman MC, Sharma RV, Davisson RL. Superoxide mediates<br />
angiotensin II-induced influx of extracellular calcium in neural<br />
cells. Hypertension 45: 717–723, 2005.<br />
995. Zuo L, Pasniciuc S, Wright VP, Merola AJ, Clanton TL. Sources<br />
for superoxide release: lessons from blockade of electron transport,<br />
NADPH oxidase, <strong>and</strong> anion channels in diaphragm. Antioxid<br />
Redox Signal 5: 667–675, 2003.<br />
Downloaded from<br />
physrev.physiology.org<br />
on February 2, 2010