Kimberly M. Broekemeier scite author profile

The mitochondrial permeability transition pore allows solutes with a m.w. approximately less than 1500 to equilibrate across the inner membrane. A closed pore is favored by cyclosporin A acting at a high-affinity site, which may be the matrix space cylophilin isozyme. Early results obtained with cyclosporin A analogs and metabolites support this hypothesis. Inhibition by cyclosporin does not appear to require inhibition of calcineurin activity; however, it may relate to inhibition of cyclophilin peptide bond isomerase activity. The permeability transition pore is strongly regulated by both the membrane potential (delta psi) and delta pH components of the mitochondrial protonmotive force. A voltage sensor which is influenced by the disulfide/sulhydryl state of vicinal sulfhydryls is proposed to render pore opening sensitive to delta psi. Early results indicate that this sensor is also responsive to membrane surface potential and/or to surface potential gradients. Histidine residues located on the matrix side of the inner membrane render the pore responsive to delta pH. The pore is also regulated by several ions and metabolites which act at sites that are interactive. There are many analogies between the systems which regulate the permeability transition pore and the NMDA receptor channel. These suggest structural similarities and that the permeability transition pore belongs to the family of ligand gated ion channels.

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Inhibition of the mitochondrial permeability transition by cyclosporin A during long time frame experiments: relationship between pore opening and the activity of mitochondrial phospholipases

Broekemeier

Pfeiffer²

1995

Biochemistry

218

139

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Inhibition of the mitochondrial permeability transition pore by cyclosporin A or trifluoperazine is transient on the time scale of cell injury studies (hours). However, these agents act synergistically and produce long-lasting inhibition when used in combination. The cause of this synergism has been investigated from the perspective of the known action of trifluoperazine as an inhibitor of mitochondrial phospholipase A2. Free fatty acids, which are phospholipase reaction products, facilitate pore opening in a concentration-dependent manner (I50 approximately 2 nmol/mg of mitochondrial protein). Endogenous and exogenous fatty acids are similarly effective. Fatty acids of differing structure are also similarly effective, but long-chain alcohols and alkanes are ineffective. Free fatty acids accumulate in cyclosporin A-treated mitochondria when Ca2+ plus tert-butyl hydroperoxide or Ca2+ plus N-ethylmaleimide is present, but do not accumulate when Ca2+ plus inorganic phosphate is present. In the presence of cyclosporin A, bovine serum albumin markedly delays pore opening induced by tert-butyl hydroperoxide or N-ethylmaleimide, but has little effect on pore opening induced by inorganic phosphate, which is subject to long-lasting inhibition by cyclosporin A without trifluoperazine. Free fatty acid accumulation is thus a factor which limits pore inhibition by cyclosporin A. However, trifluoperazine has no effect on free fatty acid accumulation in intact, cyclosporin-inhibited mitochondria and thus does not act by inhibiting phospholipases. Comparing the actions of free fatty acids, trifluoperazine, long-chain acyl cations, and other effectors on the pore suggests that a more negative membrane surface potential favors pore opening and a more positive potential favors a closed pore. Expected surface potential effects of trifluoperazine can explain the synergism between this compound and cyclosporin A as pore inhibitors. Surface potential may influence the pore through the voltage-sensing element which responds to transmembrane potential. The present data also suggest that long-lived, solute-selective forms of the pore exist when it is opened in the presence of inhibitors. The implications of these findings for pore regulation and for the use of cyclosporin A to identify pore opening as a component of cell injury mechanisms are discussed.

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Mitochondrial iPLA2 Activity Modulates the Release of Cytochrome c from Mitochondria and Influences the Permeability Transition

Gadd

Broekemeier

Crouser

et al. 2006

Journal of Biological Chemistry

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The mitochondrial Ca 2؉ -independent phospholipase A 2 is activated during energy-dependent Ca 2؉ accumulation under conditions where there is a sustained depression of the membrane potential. This activation is not dependent on induction of the mitochondrial permeability transition. Bromoenol lactone, which inhibits the phospholipase, is effective as an inhibitor of the transition, and this action can be overcome by low levels of exogenous free fatty acids. Apparently, activation of the Ca 2؉ -independent phospholipase is a factor in the mechanisms by which depolarization and Ca 2؉ accumulation promote opening of the permeability transition pore. Sustained activity of the Ca 2؉ -independent phospholipase A 2 promotes rupture of the outer mitochondrial membrane and spontaneous release of cytochrome c on a time scale similar to that of apoptosis occurring in cells. However, more swelling of the matrix space must occur to provoke release of a given cytochrome c fraction when the enzyme is active, compared with when it is inhibited. Through its effects on the permeability transition and release of intermembrane space proteins, the mitochondrial Ca 2؉ -independent phospholipase A 2 may be an important factor governing cell death caused by necrosis or apoptosis.Mitochondria from rat liver and rabbit heart have been shown to contain a Ca 2ϩ -independent phospholipase A 2 (iPLA 2 ) 3 that has a molecular mass of ϳ80 kDa (1, 2). Like phospholipases of this type from other sources (3, 4), the mitochondrial enzyme is inactivated by bromoenol lactone (BEL), which acts through an activity-dependent mechanism, leading to a covalent modification within the active site (5). No physiological function of the iPLA 2 in mitochondria has been established, but it has been shown that pretreatment with BEL attenuates the loss of phospholipids that accompanies ischemia/reperfusion injury and reduces the size of infarcts by ϳ50% (2).The relationship between mitochondrial energetic status and iPLA 2 activity is an important factor to consider when contemplating potential physiological and pathophysiological roles of the enzyme. More specifically, activity is not seen in mitochondria that are respiring under state 4 conditions but is manifest upon the addition of uncoupler and is fully manifest following the development of inner membrane pores (1). The former property suggests that transient periods of deenergization might cause a transient activation of the iPLA 2 in vivo, with a resulting accumulation of free fatty acids in mitochondria. Such an accumulation could be of interest in many regards, including opening of the permeability transition pore, which is favored by low levels of these compounds (6 -8). Occurrence of the permeability transition leads to apoptosis in many cell types (9 -11), so scenarios arise in which the iPLA 2 contributes to the control of apoptosis by influencing the permeability transition and wherein the facilitative effects of depolarization on the transition (12, 13) might occur through activity of this enzyme...

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Cyclosporin A-sensitive and insensitive mechanisms produce the permeability transition in mitochondria

Broekemeier

Pfeiffer

1989

Biochemical and Biophysical Research Communications

123

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