Mitochondrial dysfunction is the most fundamental mechanism of cell damage in cerebral hypoxia-ischemia and reperfusion. Mitochondrial respiratory chain (MRC) is increasingly recognized as a source for reactive oxygen species (ROS) in the postischemic tissue. Potentially, ROS originating in MRC can contribute to the reperfusion-driven oxidative stress, promoting mitochondrial membrane permeabilization. The loss of mitochondrial membranes integrity during reperfusion is considered as the major mechanism of secondary energy failure. This paper focuses on current data that support a pathogenic role of ROS originating from mitochondrial respiratory chain in the promotion of secondary energy failure and proposes potential therapeutic strategy against reperfusion-driven oxidative stress following hypoxia-ischemia-reperfusion injury of the developing brain. 1. Introduction Perinatal hypoxic-ischemic (HI) brain injury is one of the most common causes of severe neurological handicap in children. Estimated life-time costs to support children with cerebral palsy, a common outcome of HI brain injury in neonates, reached 11.5 billion dollars in 2003 [1]. Unfortunately, our understanding the mechanisms of the HI brain injury is not deep enough for the development of mechanism-targeted therapeutic interventions in this disease. Even therapeutic mechanisms of post-HI cerebral hypothermia (the only clinically proven neuroprotective strategy) are still not well defined which precludes an optimal use of this potentially powerful strategy. Physiologically, HI brain injury could be defined as an acute oxygen and nutrients deprivation to the brain caused by a collapse of cerebral circulation. Hypoxia-ischemia results in severe cellular bioenergetics failure, and if cerebral circulation is not restored, then the brain death is unpreventable. However, if the cerebral circulation is restored for example, as a result of successful resuscitation, then cerebral reperfusion ensures with a full or partial brain recovery. Unfortunately, the same reperfusion can also contribute to the propagation of brain injury initiated by the HI insult. This implies that HI brain injury as a disease, consists of two fundamental pathophysiological events: hypoxia-ischemia and reperfusion. During hypoxia-ischemia and reperfusion mitochondrial dysfunction plays a fundamental role in brain injury. It is now recognized that not only mitochondrial failure to generate ATP during ischemia, but the generation of oxidative radicals and the release of proapoptotic proteins during reperfusion contribute to the
References
[1]
“CDC Morbidity and Mortality Weekly Report,” 53, 57-59, 2004.
[2]
D. M. Ferriero, “Neonatal brain injury,” The New England Journal of Medicine, vol. 351, pp. 1985–1995, 2004.
[3]
S. Niermeyer, J. Kattwinkel, P. Van Reempts et al., “International guidelines for neonatal resuscitation: an excerpt from the guidelines 2000 for cardiopulmonary resuscitation and emergency cardiovascular care: international consensus on science. Contributors and reviewers for the neonatal resuscitation guidelines,” Pediatrics, vol. 106, no. 3, p. E29, 2000.
[4]
O. D. Saugstad, T. Rootwelt, and O. Aalen, “Resuscitation of asphyxiated newborn infants with room air or oxygen: an international controlled trial: the Resair 2 study,” Pediatrics, vol. 102, no. 1, article e1, 1998.
[5]
A. Tan, A. Schulze, C. P. O'Donnell, and P. G. Davis, “Air versus oxygen for resuscitation of infants at birth,” Cochrane Database of Systematic Reviews, no. 3, Article ID CD002273, 2005.
[6]
M. Vento and O. D. Saugstad, “Oxygen supplementation in the delivery room: updated information,” Journal of Pediatrics, vol. 158, supplement 2, pp. e5–e7, 2011.
[7]
M. Vento, M. Asensi, J. Sastre, A. Lloret, F. García-Sala, and J. Vi?a, “Oxidative stress in asphyxiated term infants resuscitated with 100% oxygen,” Journal of Pediatrics, vol. 142, no. 3, pp. 240–246, 2003.
[8]
J. D. Koch, D. K. Miles, J. A. Gilley, C. P. Yang, and S. G. Kernie, “Brief exposure to hyperoxia depletes the glial progenitor pool and impairs functional recovery after hypoxic-ischemic brain injury,” Journal of Cerebral Blood Flow and Metabolism, vol. 28, no. 7, pp. 1294–1306, 2008.
[9]
E. Haase, D. L. Bigam, Q. B. Nakonechny, L. D. Jewell, G. Korbutt, and P. Y. Cheung, “Resuscitation with 100% oxygen causes intestinal glutathione oxidation and reoxygenation injury in asphyxiated newborn piglets,” Annals of Surgery, vol. 240, no. 2, pp. 364–373, 2004.
[10]
B. H. Munkeby, W. B. B?rke, K. Bj?rnland et al., “Resuscitation with 100% O2 increases cerebral injury in hypoxemic piglets,” Pediatric Research, vol. 56, no. 5, pp. 783–790, 2004.
[11]
K. Van Meter, S. Sheps, F. Kriedt et al., “Hyperbaric oxygen improves rate of return of spontaneous circulation after prolonged normothermic porcine cardiopulmonary arrest,” Resuscitation, vol. 78, no. 2, pp. 200–214, 2008.
[12]
R. Linner, O. Werner, V. Perez-De-Sa, and D. Cunha-Goncalves, “Circulatory recovery is as fast with air ventilation as with 100% oxygen after asphyxia-induced cardiac arrest in piglets,” Pediatric Research, vol. 66, no. 4, pp. 391–394, 2009.
[13]
A. L. Solev?g, I. Dannevig, B. Nakstad, and O. D. Saugstad, “Resuscitation of severely asphyctic newborn pigs with cardiac arrest by using 21% or 100% oxygen,” Neonatology, vol. 98, no. 1, pp. 64–72, 2010.
[14]
D. Matsiukevich, T. M. Randis, I. Utkina-Sosunova, R. A. Polin, and V. S. Ten, “The state of systemic circulation, collapsed or preserved defines the need for hyperoxic or normoxic resuscitation in neonatal mice with hypoxia-ischemia,” Resuscitation, vol. 81, no. 2, pp. 224–229, 2010.
[15]
J. S. Ditelberg, R. A. Sheldon, C. J. Epstein, and D. M. Ferriero, “Brain injury after perinatal hypoxia-ischemia is exacerbated in copper/zinc superoxide dismutase transgenic mice,” Pediatric Research, vol. 39, no. 2, pp. 204–208, 1996.
[16]
R. A. Sheldon, S. Christen, and D. M. Ferriero, “Genetic and pharmacologic manipulation of oxidative stress after neonatal hypoxia-ischemia,” International Journal of Developmental Neuroscience, vol. 26, no. 1, pp. 87–92, 2008.
[17]
A. Y. Abramov, A. Scorziello, and M. R. Duchen, “Three distinct mechanisms generate oxygen free radicals in neurons and contribute to cell death during anoxia and reoxygenation,” Journal of Neuroscience, vol. 27, no. 5, pp. 1129–1138, 2007.
[18]
O. D. Saugstad and L. Gluck, “Plasma hypoxanthine levels in newborn infants: a specific indicator of hypoxia,” Journal of Perinatal Medicine, vol. 10, no. 6, pp. 266–272, 1982.
[19]
O. D. Saugstad, “Hypoxanthine as an indicator of hypoxia: its role in health and disease through free radical production,” Pediatric Research, vol. 23, no. 2, pp. 143–150, 1988.
[20]
Y. Feng, W. Shi, M. Huang, and M. H. LeBlanc, “Oxypurinol administration fails to prevent hypoxic-ischemic brain injury in neonatal rats,” Brain Research Bulletin, vol. 59, no. 6, pp. 453–457, 2003.
[21]
T. Chaudhari and W. McGuire, “Allopurinol for preventing mortality and morbidity in newborn infants with suspected hypoxic-ischaemic encephalopathy,” Cochrane Database of Systematic Reviews, no. 2, Article ID CD006817, 2008.
[22]
C. Doverhag, M. Keller, A. Karlsson et al., “Pharmacological and genetic inhibition of NADPH oxidase does not reduce brain damage in different models of perinatal brain injury in newborn mice,” Neurobiology of Disease, vol. 31, no. 1, pp. 133–144, 2008.
[23]
G. Loor, J. Kondapalli, H. Iwase et al., “Mitochondrial oxidant stress triggers cell death in simulated ischemia-reperfusion,” Biochimica et Biophysica Acta, vol. 1813, no. 7, pp. 1382–1394, 2011.
[24]
A. A. Starkov, C. Chinopoulos, and G. Fiskum, “Mitochondrial calcium and oxidative stress as mediators of ischemic brain injury,” Cell Calcium, vol. 36, no. 3-4, pp. 257–264, 2004.
[25]
G. Ambrosio, J. L. Zweier, C. Duilio et al., “Evidence that mitochondrial respiration is a source of potentially toxic oxygen free radicals in intact rabbit hearts subjected to ischemia and reflow,” Journal of Biological Chemistry, vol. 268, no. 25, pp. 18532–18541, 1993.
[26]
Q. Chen, S. Moghaddas, C. L. Hoppel, and E. J. Lesnefsky, “Ischemic defects in the electron transport chain increase the production of reactive oxygen species from isolated rat heart mitochondria,” American Journal of Physiology—Cell Physiology, vol. 294, no. 2, pp. C460–C466, 2008.
[27]
C. A. Piantadosi and J. Zhang, “Mitochondrial generation of reactive oxygen species after brain ischemia in the rat,” Stroke, vol. 27, no. 2, pp. 327–332, 1996.
[28]
M. G. Perrelli, P. Pagliaro, and C. Penna, “Ischemia/reperfusion injury and cardioprotective mechanisms: role of mitochondria and reactive oxygen species,” World Journal of Cardiology, vol. 3, no. 6, pp. 186–200, 2011.
[29]
M. Simerabet, E. Robin, I. Aristi et al., “Preconditioning by an in situ administration of hydrogen peroxide: involvement of reactive oxygen species and mitochondrial ATP-dependent potassium channel in a cerebral ischemia-reperfusion model,” Brain Research, vol. 1240, pp. 177–184, 2008.
[30]
M. V. Cohen, X. M. Yang, and J. M. Downey, “Acidosis, oxygen, and interference with mitochondrial permeability transition pore formation in the early minutes of reperfusion are critical to postconditioning's success,” Basic Research in Cardiology, vol. 103, no. 5, pp. 464–471, 2008.
[31]
V. S. Ten, J. Yao, V. Ratner et al., “Complement component C1q mediates mitochondria-driven oxidative stress in neonatal hypoxic-ischemic brain injury,” Journal of Neuroscience, vol. 30, no. 6, pp. 2077–2087, 2010.
[32]
Q. Chen, E. J. Vazquez, S. Moghaddas, C. L. Hoppel, and E. J. Lesnefsky, “Production of reactive oxygen species by mitochondria: central role of complex III,” Journal of Biological Chemistry, vol. 278, no. 38, pp. 36027–36031, 2003.
[33]
M. V. Skulachev, Y. N. Antonenko, V. N. Anisimov, et al., “Mitochondrial-targeted plastoquinone derivatives. Effect on senescence and acute age-related pathologies,” Current Drug Targets, vol. 12, no. 6, pp. 800–826, 2011.
[34]
H. H. Szeto, S. Liu, Y. Soong, et al., “Mitochondria-targeted peptide accelerates ATP recovery and reduces ischemic kidney injury,” Journal of the American Society of Nephrology, vol. 22, no. 6, pp. 1041–1052, 2011.
[35]
M. Rocha, A. Hernandez-Mijares, K. Garcia-Malpartida, C. Ba?uls, L. Bellod, and V. M. Victor, “Mitochondria-targeted antioxidant peptides,” Current Pharmaceutical Design, vol. 16, no. 28, pp. 3124–3131, 2010.
[36]
K. Choi, J. Kim, G. W. Kim, and C. Choi, “Oxidative stress-induced necrotic cell death via mitochondira-dependent burst of reactive oxygen species,” Current Neurovascular Research, vol. 6, no. 4, pp. 213–222, 2009.
[37]
E. J. Lesnefsky, Q. Chen, S. Moghaddas, M. O. Hassan, B. Tandler, and C. L. Hoppel, “Blockade of electron transport during ischemia protects cardiac mitochondria,” Journal of Biological Chemistry, vol. 279, no. 46, pp. 47961–47967, 2004.
[38]
A. J. Tompkins, L. S. Burwell, S. B. Digerness, C. Zaragoza, W. L. Holman, and P. S. Brookes, “Mitochondrial dysfunction in cardiac ischemia-reperfusion injury: ROS from complex I, without inhibition,” Biochimica et Biophysica Acta, vol. 1762, no. 2, pp. 223–231, 2006.
[39]
A. A. Starkov, “The role of mitochondria in reactive oxygen species metabolism and signaling,” Annals of the New York Academy of Sciences, vol. 1147, pp. 37–52, 2008.
[40]
A. Y. Andreyev, Y. E. Kushnareva, and A. A. Starkov, “Mitochondrial metabolism of reactive oxygen species,” Biochemistry, vol. 70, no. 2, pp. 200–214, 2005.
[41]
A. A. Starkov, G. Fiskum, C. Chinopoulos et al., “Mitochondrial α-ketoglutarate dehydrogenase complex generates reactive oxygen species,” Journal of Neuroscience, vol. 24, no. 36, pp. 7779–7788, 2004.
[42]
L. Tretter and V. Adam-Vizi, “Generation of reactive oxygen species in the reaction catalyzed by α-ketoglutarate dehydrogenase,” Journal of Neuroscience, vol. 24, no. 36, pp. 7771–7778, 2004.
[43]
E. B. Tahara, F. D. T. Navarete, and A. J. Kowaltowski, “Tissue-, substrate-, and site-specific characteristics of mitochondrial reactive oxygen species generation,” Free Radical Biology and Medicine, vol. 46, no. 9, pp. 1283–1297, 2009.
[44]
A. Almeida, K. L. Allen, T. E. Bates, and J. B. Clark, “Effect of reperfusion following cerebral ischaemia on the activity of the mitochondrial respiratory chain in the gerbil brain,” Journal of Neurochemistry, vol. 65, no. 4, pp. 1698–1703, 1995.
[45]
K. L. Allen, A. Almeida, T. E. Bates, and J. B. Clark, “Changes of respiratory chain activity in mitochondrial and synaptosomal fractions isolated from the gerbil brain after graded ischaemia,” Journal of Neurochemistry, vol. 64, no. 5, pp. 2222–2229, 1995.
[46]
E. Gilland, M. Puka-Sundvall, L. Hillered, and H. Hagberg, “Mitochondrial function and energy metabolism after hypoxia-ischemia in the immature rat brain: involvement of NMDA-receptors,” Journal of Cerebral Blood Flow and Metabolism, vol. 18, no. 3, pp. 297–304, 1998.
[47]
N. R. Sims, “Selective impairment of respiration in mitochondria isolated from brain subregions following transient forebrain ischemia in the rat,” Journal of Neurochemistry, vol. 56, no. 6, pp. 1836–1844, 1991.
[48]
J. Folbergrova, B. Ljunggren, K. Norberg, and B. K. Siesjo, “Influence of complete ischemia on glycolytic metabolites, citric acid cycle intermediates, and associated amino acids in the rat cerebral cortex,” Brain Research, vol. 80, no. 2, pp. 265–279, 1974.
[49]
G. Benzi, E. Arrigoni, F. Marzatico, and R. F. Villa, “Influence of some biological pyrimidines on the succinate cycle during and after cerebral ischemia,” Biochemical Pharmacology, vol. 28, no. 17, pp. 2545–2550, 1979.
[50]
V. A. Khazanov, A. N. Poborsky, and M. N. Kondrashova, “Air saturation of the medium reduces the rate of phosphorylating oxidation of succinate in isolated mitochondria,” FEBS Letters, vol. 314, no. 3, pp. 264–266, 1992.
[51]
A. N. Poborskii, “Effect of research conditions on succinate oxidation in brain mitochondria in circulatory hypoxia,” Patologicheskaia Fiziologiia i Eksperimental'naia Terapiia's, no. 1, pp. 10–12, 1997.
[52]
T. K?nig, D. G. Nicholls, and P. B. Garland, “The inhibition of pyruvate and Ls(+)-isocitrate oxidation by succinate oxidation in rat liver mitochondria,” Biochemical Journal, vol. 114, no. 3, pp. 589–596, 1969.
[53]
O. Pisarenko, I. Studneva, and V. Khlopkov, “Metabolism of the tricarboxylic acid cycle intermediates and related amino acids in ischemic guinea pig heart,” Biomedica Biochimica Acta, vol. 46, no. 8-9, pp. S568–S571, 1987.
[54]
K. Kato, T. Matsubara, and N. Sakamoto, “Correlation between myocardial blood flow and tissue succinate during acute ischemia,” Nagoya Journal of Medical Science, vol. 57, no. 1–4, pp. 43–50, 1994.
[55]
Z. V. Niatsetskaya, S. A. Sosunov, D. Matsiukevich et al., “The oxygen free radicals originating from mitochondrial complex I contribute to oxidative brain injury following hypoxia-ischemia in neonatal mice,” Journal of Neuroscience, vol. 32, no. 9, pp. 3235–3244, 2012.
[56]
F. Han, T. Da, N. A. Riobo, and L. B. Becker, “Early mitochondrial dysfunction in electron transfer activity and reactive oxygen species generation after cardiac arrest,” Critical Care Medicine, vol. 36, supplement 11, pp. S447–S453, 2008.
[57]
R. D. Guzy, M. M. Mack, and P. T. Schumacker, “Mitochondrial complex III is required for hypoxia-induced ROS production and gene transcription in yeast,” Antioxidants and Redox Signaling, vol. 9, no. 9, pp. 1317–1328, 2007.
[58]
I. Sipos, L. Tretter, and V. Adam-Vizi, “The production of reactive oxygen species in intact isolated nerve terminals is independent of the mitochondrial membrane potential,” Neurochemical Research, vol. 28, no. 10, pp. 1575–1581, 2003.
[59]
J. W. McDonald and M. V. Johnston, “Physiological and pathophysiological roles of excitatory amino acids during cental nervous system development,” Brain Research Reviews, vol. 15, no. 1, pp. 41–70, 1990.
[60]
S. L. Tahraoui, S. Marret, C. Bodénant et al., “Central role of microglia in neonatal excitotoxic lesions of the murine periventricular white matter,” Brain Pathology, vol. 11, no. 1, pp. 56–71, 2001.
[61]
A. A. Starkov, “The molecular identity of the mitochondrial Ca2+ sequestration system: minireview,” FEBS Journal, vol. 277, no. 18, pp. 3652–3663, 2010.
[62]
S. Matsumoto, H. Friberg, M. Ferrand-Drake, and T. Wieloch, “Blockade of the mitochondrial permeability transition pore diminishes infarct size in the rat after transient middle cerebral artery occlusion,” Journal of Cerebral Blood Flow and Metabolism, vol. 19, no. 7, pp. 736–741, 1999.
[63]
L. Khaspekov, H. Friberg, A. Halestrap, I. Viktorov, and T. Wieloch, “Cyclosporin A and its nonimmunosuppressive analogue N-Me-Val-4-cyclosporin A mitigate glucose/oxygen deprivation-induced damage to rat cultured hippocampal neurons,” European Journal of Neuroscience, vol. 11, no. 9, pp. 3194–3198, 1999.
[64]
A. W. C. Leung and A. P. Halestrap, “Recent progress in elucidating the molecular mechanism of the mitochondrial permeability transition pore,” Biochimica et Biophysica Acta, vol. 1777, no. 7-8, pp. 946–952, 2008.
[65]
F. Di Lisa, N. Kaludercic, A. Carpi, R. Menabò, and M. Giorgio, “Mitochondrial pathways for ROS formation and myocardial injury: the relevance of p66Shc and monoamine oxidase,” Basic Research in Cardiology, vol. 104, no. 2, pp. 131–139, 2009.
[66]
J. J. Lemasters, T. P. Theruvath, Z. Zhong, and A. L. Nieminen, “Mitochondrial calcium and the permeability transition in cell death,” Biochimica et Biophysica Acta, vol. 1787, no. 11, pp. 1395–1401, 2009.
[67]
E. Basso, L. Fante, J. Fowlkes, V. Petronilli, M. A. Forte, and P. Bernardi, “Properties of the permeability transition pore in mitochondria devoid of cyclophilin D,” Journal of Biological Chemistry, vol. 280, no. 19, pp. 18558–18561, 2005.
[68]
J. S. Kim, Y. Jin, and J. J. Lemasters, “Reactive oxygen species, but not Ca2+ overloading, trigger pH- and mitochondrial permeability transition-dependent death of adult rat myocytes after ischemia-reperfusion,” American Journal of Physiology—Heart and Circulatory Physiology, vol. 290, no. 5, pp. H2024–H2034, 2006.
[69]
H. L. Liang, F. Sedlic, Z. Bosnjak, and V. Nilakantan, “SOD1 and MitoTEMPO partially prevent mitochondrial permeability transition pore opening, necrosis, and mitochondrial apoptosis after ATP depletion recovery,” Free Radical Biology and Medicine, vol. 49, no. 10, pp. 1550–1560, 2010.
[70]
M. Puka-Sundvall, C. Wallin, E. Gilland et al., “Impairment of mitochondrial respiration after cerebral hypoxia-ischemia in immature rats: relationship to activation of caspase-3 and neuronal injury,” Developmental Brain Research, vol. 125, no. 1-2, pp. 43–50, 2000.
[71]
C. S. Caspersen, A. Sosunov, I. Utkina-Sosunova, V. I. Ratner, A. A. Starkov, and V. S. Ten, “An isolation method for assessment of brain mitochondria function in neonatal mice with hypoxic-ischemic brain injury,” Developmental Neuroscience, vol. 30, no. 5, pp. 319–324, 2008.
[72]
A. Vinogradov, A. Scarpa, and B. Chance, “Calcium and pyridine nucleotide interaction in mitochondrial membranes,” Archives of Biochemistry and Biophysics, vol. 152, no. 2, pp. 646–654, 1972.
[73]
C. P. Baines, R. A. Kaiser, N. H. Purcell et al., “Loss of cyclophilin D reveals a critical role for mitochondrial permeability transition in cell death,” Nature, vol. 434, no. 7033, pp. 658–662, 2005.
[74]
T. Nakagawa, S. Shimizu, T. Watanabe et al., “Cyclophilin D-dependent mitochondrial permeability transition regulates some necrotic but not apoptotic cell death,” Nature, vol. 434, no. 7033, pp. 652–658, 2005.
[75]
M. Puka-Sundvall, B. Gajkowska, M. Cholewinski, K. Blomgren, J. W. Lazarewicz, and H. Hagberg, “Subcellular distribution of calcium and ultrastructural changes after cerebral hypoxia-ischemia in immature rats,” Developmental Brain Research, vol. 125, no. 1-2, pp. 31–41, 2000.
[76]
X. Wang, Y. Carlsson, E. Basso et al., “Developmental shift of cyclophilin D contribution to hypoxic-ischemic brain injury,” Journal of Neuroscience, vol. 29, no. 8, pp. 2588–2596, 2009.
[77]
M. Puka-Sundvall, E. Gilland, and H. Hagberg, “Cerebral hypoxia-ischemia in immature rats: involvement of mitochondrial permeability transition?” Developmental Neuroscience, vol. 23, no. 3, pp. 192–197, 2001.
[78]
J. H. Hwang, J. H. Lee, K. H. Lee et al., “Cyclosporine A attenuates hypoxic-ischemic brain injury in newborn rats,” Brain Research, vol. 1359, pp. 208–215, 2010.
[79]
P. L. Leger, D. De Paulis, S. Branco et al., “Evaluation of cyclosporine A in a stroke model in the immature rat brain,” Experimental Neurology, vol. 230, no. 1, pp. 58–66, 2011.
[80]
X. D. Liu, G. Y. Pan, L. Xie et al., “Cyclosporin A enhanced protection of nimodipine against brain damage induced by hypoxia-ischemia in mice and rats,” Acta Pharmacologica Sinica, vol. 23, no. 3, pp. 225–229, 2002.
[81]
I. Marzo, C. Brenner, N. Zamzami et al., “Bax and adenine nucleotide translocator cooperate in the mitochondrial control of apoptosis,” Science, vol. 281, no. 5385, pp. 2027–2031, 1998.
[82]
R. Eskes, B. Antonsson, A. Osen-Sand et al., “Bax-induced cytochrome C release from mitochondria is independent of the permeability transition pore but highly dependent on Mg2+ ions,” Journal of Cell Biology, vol. 143, no. 1, pp. 217–224, 1998.
[83]
W. Korytowski, L. V. Basova, A. Pilat, R. M. Kernstock, and A. W. Girotti, “Permeabilization of the mitochondrial outer membrane by Bax/truncated Bid (tBid) proteins as sensitized by cardiolipin hydroperoxide translocation: mechanistic implications for the intrinsic pathway of oxidative apoptosis,” The Journal of Biological Chemistry, vol. 286, no. 30, pp. 26334–26343, 2011.
[84]
E. Jacotot, P. Costantini, E. Laboureau, N. Zamzami, S. A. Susin, and G. Kroemer, “Mitochondrial membrane permeabilization during the apoptotic process,” Annals of the New York Academy of Sciences, vol. 887, pp. 18–30, 1999.
[85]
H. Hagberg, C. Mallard, C. I. Rousset Catherine, and X. Wang, “Apoptotic mechanisms in the immature brain: involvement of mitochondria,” Journal of Child Neurology, vol. 24, no. 9, pp. 1141–1146, 2009.
[86]
X. Wang, W. Han, X. Du et al., “Neuroprotective effect of Bax-inhibiting peptide on neonatal brain injury,” Stroke, vol. 41, no. 9, pp. 2050–2055, 2010.
[87]
P. Pasdois, J. E. Parker, E. J. Griffiths, and A. P. Halestrap, “The role of oxidized cytochrome c in regulating mitochondrial reactive oxygen species production and its perturbation in ischaemia,” Biochemical Journal, vol. 436, no. 2, pp. 493–505, 2011.
[88]
L. Vela, M. Contel, L. Palomera, G. Azaceta, and I. Marzo, “Iminophosphorane-organogold (III) complexes induce cell death through mitochondrial ROS production,” Journal of Inorganic Biochemistry, vol. 105, no. 10, pp. 1306–1313, 2011.
[89]
E. R. Hahm, M. B. Moura, E. E. Kelley, B. Van Houten, S. Shiva, and S. V. Singh, “Withaferin a-induced apoptosis in human breast cancer cells is mediated by reactive oxygen species,” PLoS One, vol. 6, no. 8, article e23354, 2011.
[90]
Q. Ma, H. Fang, W. Shang, et al., “Superoxide flashes: early mitochondrial signals for oxidative stress-induced apoptosis,” The Journal of Biological Chemistry, vol. 286, no. 31, pp. 27573–27581, 2011.
[91]
M. Narita, S. Shimizu, T. Ito et al., “Bax interacts with the permeability transition pore to induce permeability transition and cytochrome c release in isolated mitochondria,” Proceedings of the National Academy of Sciences of the United States of America, vol. 95, no. 25, pp. 14681–14686, 1998.
