Literature DB >> 21777669

Cross talk between mitochondria and NADPH oxidases.

Sergey Dikalov1.   

Abstract

Reactive oxygen species (ROS) play an important role in physiological and pathological processes. In recent years, a feed-forward regulation of the ROS sources has been reported. The interactions between the main cellular sources of ROS, such as mitochondria and NADPH oxidases, however, remain obscure. This work summarizes the latest findings on the role of cross talk between mitochondria and NADPH oxidases in pathophysiological processes. Mitochondria have the highest levels of antioxidants in the cell and play an important role in the maintenance of cellular redox status, thereby acting as an ROS and redox sink and limiting NADPH oxidase activity. Mitochondria, however, are not only a target for ROS produced by NADPH oxidase but also a significant source of ROS, which under certain conditions may stimulate NADPH oxidases. This cross talk between mitochondria and NADPH oxidases, therefore, may represent a feed-forward vicious cycle of ROS production, which can be pharmacologically targeted under conditions of oxidative stress. It has been demonstrated that mitochondria-targeted antioxidants break this vicious cycle, inhibiting ROS production by mitochondria and reducing NADPH oxidase activity. This may provide a novel strategy for treatment of many pathological conditions including aging, atherosclerosis, diabetes, hypertension, and degenerative neurological disorders in which mitochondrial oxidative stress seems to play a role. It is conceivable that the use of mitochondria-targeted treatments would be effective in these conditions.
Copyright © 2011 Elsevier Inc. All rights reserved.

Entities:  

Mesh:

Substances:

Year:  2011        PMID: 21777669      PMCID: PMC3163726          DOI: 10.1016/j.freeradbiomed.2011.06.033

Source DB:  PubMed          Journal:  Free Radic Biol Med        ISSN: 0891-5849            Impact factor:   7.376


  174 in total

1.  Redox regulation of the mitochondrial K(ATP) channel in cardioprotection.

Authors:  Bruno B Queliconi; Andrew P Wojtovich; Sergiy M Nadtochiy; Alicia J Kowaltowski; Paul S Brookes
Journal:  Biochim Biophys Acta       Date:  2010-11-20

2.  Therapeutic targeting of mitochondrial superoxide in hypertension.

Authors:  Anna E Dikalova; Alfiya T Bikineyeva; Klaudia Budzyn; Rafal R Nazarewicz; Louise McCann; William Lewis; David G Harrison; Sergey I Dikalov
Journal:  Circ Res       Date:  2010-05-06       Impact factor: 17.367

3.  Reactive oxygen and targeted antioxidant administration in endothelial cell mitochondria.

Authors:  Yunxia O'Malley; Brian D Fink; Nicolette C Ross; Thomas E Prisinzano; William I Sivitz
Journal:  J Biol Chem       Date:  2006-10-23       Impact factor: 5.157

4.  Increased sensitivity of mitochondrial respiration to inhibition by nitric oxide in cardiac hypertrophy.

Authors:  P S Brookes; J Zhang; L Dai; F Zhou; D A Parks; V M Darley-Usmar; P G Anderson
Journal:  J Mol Cell Cardiol       Date:  2001-01       Impact factor: 5.000

Review 5.  Mitochondrial free radical generation, oxidative stress, and aging.

Authors:  E Cadenas; K J Davies
Journal:  Free Radic Biol Med       Date:  2000-08       Impact factor: 7.376

6.  Overexpression of mitochondrial peroxiredoxin-3 prevents left ventricular remodeling and failure after myocardial infarction in mice.

Authors:  Shouji Matsushima; Tomomi Ide; Mayumi Yamato; Hidenori Matsusaka; Fumiyuki Hattori; Masaki Ikeuchi; Toru Kubota; Kenji Sunagawa; Yasuhiro Hasegawa; Tatsuya Kurihara; Shinzo Oikawa; Shintaro Kinugawa; Hiroyuki Tsutsui
Journal:  Circulation       Date:  2006-04-03       Impact factor: 29.690

Review 7.  Nox proteins in signal transduction.

Authors:  David I Brown; Kathy K Griendling
Journal:  Free Radic Biol Med       Date:  2009-07-21       Impact factor: 7.376

8.  Distinct roles of Nox1 and Nox4 in basal and angiotensin II-stimulated superoxide and hydrogen peroxide production.

Authors:  Sergey I Dikalov; Anna E Dikalova; Alfiya T Bikineyeva; Harald H H W Schmidt; David G Harrison; Kathy K Griendling
Journal:  Free Radic Biol Med       Date:  2008-08-16       Impact factor: 7.376

Review 9.  NADPH oxidases: functions and pathologies in the vasculature.

Authors:  Bernard Lassègue; Kathy K Griendling
Journal:  Arterioscler Thromb Vasc Biol       Date:  2009-11-12       Impact factor: 8.311

10.  Expression of NAD(P)H oxidase subunits and their contribution to cardiovascular damage in aldosterone/salt-induced hypertensive rat.

Authors:  Young Mee Park; Bong Hee Lim; Rhian M Touyz; Jeong Bae Park
Journal:  J Korean Med Sci       Date:  2008-12-24       Impact factor: 2.153
View more
  311 in total

1.  Transcriptional and phenotypic changes in aorta and aortic valve with aging and MnSOD deficiency in mice.

Authors:  Carolyn M Roos; Michael Hagler; Bin Zhang; Elise A Oehler; Arman Arghami; Jordan D Miller
Journal:  Am J Physiol Heart Circ Physiol       Date:  2013-08-30       Impact factor: 4.733

Review 2.  Reactive oxygen species in inflammation and tissue injury.

Authors:  Manish Mittal; Mohammad Rizwan Siddiqui; Khiem Tran; Sekhar P Reddy; Asrar B Malik
Journal:  Antioxid Redox Signal       Date:  2013-10-22       Impact factor: 8.401

Review 3.  Reduction-oxidation (redox) system in radiation-induced normal tissue injury: molecular mechanisms and implications in radiation therapeutics.

Authors:  R Yahyapour; E Motevaseli; A Rezaeyan; H Abdollahi; B Farhood; M Cheki; S Rezapoor; D Shabeeb; A E Musa; M Najafi; V Villa
Journal:  Clin Transl Oncol       Date:  2018-01-09       Impact factor: 3.405

4.  Combined incubation of colon carcinoma cells with phorbol ester and mitochondrial uncoupling agents results in synergic elevated reactive oxygen species levels and increased γ-glutamyltransferase expression.

Authors:  Seila Pandur; Chandra Ravuri; Ugo Moens; Nils-Erik Huseby
Journal:  Mol Cell Biochem       Date:  2013-11-27       Impact factor: 3.396

5.  LOX-1, mtDNA damage, and NLRP3 inflammasome activation in macrophages: implications in atherogenesis.

Authors:  Zufeng Ding; Shijie Liu; Xianwei Wang; Yao Dai; Magomed Khaidakov; Xiaoyan Deng; Yubo Fan; David Xiang; Jawahar L Mehta
Journal:  Cardiovasc Res       Date:  2014-04-28       Impact factor: 10.787

6.  Diazoxide pretreatment prevents Aβ1-42 induced oxidative stress in cholinergic neurons via alleviating NOX2 expression.

Authors:  Qingxi Fu; Naiyong Gao; Jixu Yu; Guozhao Ma; Yifeng Du; Fumin Wang; Quanping Su; Fengyuan Che
Journal:  Neurochem Res       Date:  2014-04-27       Impact factor: 3.996

Review 7.  Cardiac dysfunction and oxidative stress in the metabolic syndrome: an update on antioxidant therapies.

Authors:  Olesya Ilkun; Sihem Boudina
Journal:  Curr Pharm Des       Date:  2013       Impact factor: 3.116

Review 8.  NADPH oxidases as a source of oxidative stress and molecular target in ischemia/reperfusion injury.

Authors:  Pamela W M Kleikers; K Wingler; J J R Hermans; I Diebold; S Altenhöfer; K A Radermacher; B Janssen; A Görlach; H H H W Schmidt
Journal:  J Mol Med (Berl)       Date:  2012-10-23       Impact factor: 4.599

Review 9.  Role of mitochondrial oxidative stress in hypertension.

Authors:  Sergey I Dikalov; Zoltan Ungvari
Journal:  Am J Physiol Heart Circ Physiol       Date:  2013-09-16       Impact factor: 4.733

Review 10.  Molecular and Supramolecular Structure of the Mitochondrial Oxidative Phosphorylation System: Implications for Pathology.

Authors:  Salvatore Nesci; Fabiana Trombetti; Alessandra Pagliarani; Vittoria Ventrella; Cristina Algieri; Gaia Tioli; Giorgio Lenaz
Journal:  Life (Basel)       Date:  2021-03-15
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.