Regulation of hydrogen peroxide production by brain mitochondria by calcium and Bax

Abnormal accumulation of Ca2+ and exposure to pro‐apoptotic proteins, such as Bax, is believed to stimulate mitochondrial generation of reactive oxygen species (ROS) and contribute to neural cell death during acute ischemic and traumatic brain injury, and in neurodegenerative diseases, e.g. Parkinson's disease. However, the mechanism by which Ca2+ or apoptotic proteins stimulate mitochondrial ROS production is unclear. We used a sensitive fluorescent probe to compare the effects of Ca2+ on H2O2 emission by isolated rat brain mitochondria in the presence of physiological concentrations of ATP and Mg2+ and different respiratory substrates. In the absence of respiratory chain inhibitors, Ca2+ suppressed H2O2 generation and reduced the membrane potential of mitochondria oxidizing succinate, or glutamate plus malate. In the presence of the respiratory chain Complex I inhibitor rotenone, accumulation of Ca2+ stimulated H2O2 production by mitochondria oxidizing succinate, and this stimulation was associated with release of mitochondrial cytochrome c. In the presence of glutamate plus malate, or succinate, cytochrome c release and H2O2 formation were stimulated by human recombinant full‐length Bax in the presence of a BH3 cell death domain peptide. These results indicate that in the presence of ATP and Mg2+, Ca2+ accumulation either inhibits or stimulates mitochondrial H2O2 production, depending on the respiratory substrate and the effect of Ca2+ on the mitochondrial membrane potential. Bax plus a BH3 domain peptide stimulate H2O2 production by brain mitochondria due to release of cytochrome c and this stimulation is insensitive to changes in membrane potential.

[1]  A. Lehninger,et al.  Inhibition of oxidative phosphorylation in ascites tumor mitochondria and cells by intramitochondrial Ca2+. , 1980, The Journal of biological chemistry.

[2]  I. Reynolds,et al.  DeltaPsi(m)-Dependent and -independent production of reactive oxygen species by rat brain mitochondria. , 2001, Journal of neurochemistry.

[3]  M. Beal,et al.  Mitochondria in Neurodegeneration: Bioenergetic Function in Cell Life and Death , 1999, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[4]  J. Turrens Superoxide Production by the Mitochondrial Respiratory Chain , 1997, Bioscience reports.

[5]  R. Haugland,et al.  A stable nonfluorescent derivative of resorufin for the fluorometric determination of trace hydrogen peroxide: applications in detecting the activity of phagocyte NADPH oxidase and other oxidases. , 1997, Analytical biochemistry.

[6]  B. Chance,et al.  Partial resolution of the enzymes catalyzing oxidative phosphorylation. XV. Reverse electron transfer in the flavin-cytochrome beta region of the respiratory chain of beef heart submitochondrial particles. , 1967, The Journal of biological chemistry.

[7]  INTERNATIONAL SOCIETY FOR NEUROCHEMISTRY , 1976 .

[8]  J. Dykens Isolated Cerebral and Cerebellar Mitochondria Produce Free Radicals when Exposed to Elevated Ca2+ and Na+: Implications for Neurodegeneration , 1994, Journal of neurochemistry.

[9]  Anibal E. Vercesi,et al.  The Thiol-specific Antioxidant Enzyme Prevents Mitochondrial Permeability Transition , 1998, The Journal of Biological Chemistry.

[10]  G. Fiskum,et al.  Calcium induced release of mitochondrial cytochrome c by different mechanisms selective for brain versus liver , 1999, Cell Death and Differentiation.

[11]  V. Mildažienė,et al.  Dependence of H2O2 Formation by Rat Heart Mitochondria on Substrate Availability and Donor Age , 1997, Journal of bioenergetics and biomembranes.

[12]  G. Fiskum,et al.  Cytochrome c release from brain mitochondria is independent of the mitochondrial permeability transition , 1998, FEBS letters.

[13]  V. Skulachev,et al.  The antioxidant functions of cytochrome c , 1999, FEBS letters.

[14]  M. Dossena,et al.  Relationships between γ‐aminobutyrate and succinate cycles during and after cerebral ischemia , 1982 .

[15]  E. Wang,et al.  Bcl-2 potentiates the maximal calcium uptake capacity of neural cell mitochondria. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[16]  A. Vercesi,et al.  Ca(2+)-induced mitochondrial membrane permeabilization: role of coenzyme Q redox state. , 1995, The American journal of physiology.

[17]  S. Grimm,et al.  The permeability transition pore signals apoptosis by directing Bax translocation and multimerization , 2002, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[18]  A. J. Hulbert,et al.  Characteristics of mitochondrial proton leak and control of oxidative phosphorylation in the major oxygen-consuming tissues of the rat. , 1994, Biochimica et biophysica acta.

[19]  A. Vercesi,et al.  Opening of the mitochondrial permeability transition pore by uncoupling or inorganic phosphate in the presence of Ca2+ is dependent on mitochondrial‐generated reactive oxygen species , 1996, FEBS letters.

[20]  Gary Fiskum,et al.  Generation of reactive oxygen species by the mitochondrial electron transport chain , 2002, Journal of neurochemistry.

[21]  G. Fiskum,et al.  BH3 death domain peptide induces cell type-selective mitochondrial outer membrane permeability. , 2001, The Journal of biological chemistry.

[22]  N. Sims Rapid Isolation of Metabolically Active Mitochondria from Rat Brain and Subregions Using Percoll Density Gradient Centrifugation , 1990, Journal of neurochemistry.

[23]  S. Korsmeyer,et al.  Bax ablation prevents dopaminergic neurodegeneration in the 1-methyl- 4-phenyl-1,2,3,6-tetrahydropyridine mouse model of Parkinson's disease , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[24]  G. Fiskum Mitochondrial participation in ischemic and traumatic neural cell death. , 2000, Journal of neurotrauma.

[25]  S. Budd,et al.  Mitochondria and neuronal survival. , 2000, Physiological reviews.

[26]  R. Weindruch,et al.  Caloric restriction prevents age-associated accrual of oxidative damage to mouse skeletal muscle mitochondria. , 1998, Free radical biology & medicine.

[27]  A. Azzariti,et al.  Cytochrome c Is Released from Mitochondria in a Reactive Oxygen Species (ROS)-dependent Fashion and Can Operate as a ROS Scavenger and as a Respiratory Substrate in Cerebellar Neurons Undergoing Excitotoxic Death* , 2000, The Journal of Biological Chemistry.

[28]  Ian J. Reynolds,et al.  ΔΨm‐Dependent and ‐independent production of reactive oxygen species by rat brain mitochondria , 2001 .

[29]  N. Plesnila,et al.  BID mediates neuronal cell death after oxygen/ glucose deprivation and focal cerebral ischemia , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[30]  G Fiskum,et al.  Mitochondria in Neurodegeneration: Acute Ischemia and Chronic Neurodegenerative Diseases , 1999, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[31]  A. Fabi,et al.  Ischemic injury to rat forebrain mitochondria and cellular calcium homeostasis. , 1992, Biochimica et biophysica acta.

[32]  A. Vercesi,et al.  Oxidative stress in Ca2+‐induced membrane permeability transition in brain mitochondria , 2001, Journal of neurochemistry.

[33]  A. Vercesi,et al.  Ca2+-stimulated mitochondrial reactive oxygen species generation and permeability transition are inhibited by dibucaine or Mg2+. , 1998, Archives of biochemistry and biophysics.

[34]  V. Skulachev,et al.  High protonic potential actuates a mechanism of production of reactive oxygen species in mitochondria , 1997, FEBS letters.

[35]  M. Dossena,et al.  Relationships between gamma-aminobutyrate and succinate cycles during and after cerebral ischemia. , 1982, Journal of neuroscience research.

[36]  C. Hackenbrock ULTRASTRUCTURAL BASES FOR METABOLICALLY LINKED MECHANICAL ACTIVITY IN MITOCHONDRIA , 1968, The Journal of cell biology.

[37]  C. Hackenbrock Chemical and physical fixation of isolated mitochondria in low-energy and high-energy states. , 1968, Proceedings of the National Academy of Sciences of the United States of America.