Oxidative stress is involved in the permeabilization of the inner membrane of brain mitochondria exposed to hypoxia/reoxygenation and low micromolar Ca2+

From in vivo models of stroke it is known that ischemia/reperfusion induces oxidative stress that is accompanied by deterioration of brain mitochondria. Previously, we reported that the increase in Ca2+ induces functional breakdown and morphological disintegration in brain mitochondria subjected to hypoxia/reoxygenation (H/R). Protection by ADP indicated the involvement of the mitochondrial permeability transition pore in the mechanism of membrane permeabilization. Until now it has been unclear how reactive oxygen species (ROS) contribute to this process. We now report that brain mitochondria which had been subjected to H/R in the presence of low micromolar Ca2+ display low state 3 respiration (20% of control), loss of cytochrome c, and reduced glutathione levels (75% of control). During reoxygenation, significant mitochondrial generation of hydrogen peroxide (H2O2) was detected. The addition of the membrane permeant superoxide anion scavenger TEMPOL (4-hydroxy-2,2,6,6-tetramethylpiperidine-N-oxyl) suppressed the production of H2O2 by brain mitochondria metabolizing glutamate plus malate by 80% under normoxic conditions. TEMPOL partially protected brain mitochondria exposed to H/R and low micromolar Ca2+ from decrease in state 3 respiration (from 25% of control to 60% of control with TEMPOL) and permeabilization of the inner membrane. Membrane permeabilization was obvious, because state 3 respiration could be stimulated by extramitochondrial NADH. Our data suggest that ROS and Ca2+ synergistically induce permeabilization of the inner membrane of brain mitochondria exposed to H/R. However, permeabilization can only partially be prevented by suppressing mitochondrial generation of ROS. We conclude that transient deprivation of oxygen and glucose during temporary ischemia coupled with elevation in cytosolic Ca2+ concentration triggers ROS generation and mitochondrial permeabilization, resulting in neural cell death.     

A Simulation Study of Calcium Dynamics Features Caused by Exchange between the Cytosol and Organellar Stores of Neurons

The objects of the study were single-compartment mathematical models corresponding to a fragment of the dendrite of a cerebellar Purkinje neuron. The fragments contained the mitochondria (model 1) or a cistern of the endoplasmic reticulum, ER (model 2), functioning as calcium stores. With simulating single excitatory synaptic actions, we examined the dependence of the dynamics of intracellular Ca²⁺ levels on the maximum rate of Ca²⁺ exchange between the cytosol and these stores, as well as on the intensity of the diffusion flow into adjacent organelle-free regions. The plasma membrane of the compartment had ion channels (including those of the synaptic current) and the calcium pump characteristic of the mentioned neurons. The model equations took into account Ca²⁺ exchange between the cytosol, extracellular environment, and organellar stores, as well as the diffusion process. In model 1, the mitochondria exchanged Ca²⁺ with the cytosol through the uniporter and sodium-calcium exchanger; mitochondrial processes, such as the tricarboxylic acid cycle and aerobic cellular respiration, were also included. In model 2, the ER membrane had the calcium pump, leak channels, and channels of calcium-induced and inositol-3-phosphate-dependent Ca²⁺ release. The stores (mitochondria or ER) occupied 36% of the total volume of the compartment. An increase in the maximum rate of calcium exchange with the stores led to a proportional decrease in the peak Ca²⁺ concentrations in the cytosol ([Ca²⁺]_i), more pronounced in the case of the ER; the Ca²⁺ concentration in both types of stores increased significantly. Due to the higher storage rate, the ER was able to absorb several times greater amounts of Ca²⁺ than the mitochondria did. With smaller diffusion flux (e.g., similarly to the case of diffusion from a larger-sized head into the neck of the dendritic spine), the intensity of cytosolic transients increased at fixed kinetics of flux exchange with the stores. Therefore, the organellar stores can significantly modulate not only the intensity but also the time course of changes in the intracellular Ca²⁺ levels.     

Mitochondrial reactive oxygen species in cell death signaling

During apoptosis, mitochondrial membrane permeability (MMP) increases and the release into the cytosol of pro-apoptotic factors (procaspases, caspase activators and caspase-independent factors such as apoptosis-inducing factor (AIF)) leads to the apoptotic phenotype. Apart from this pivotal role of mitochondria during the execution phase of apoptosis (documented in other reviews of this issue), it appears that reactive oxygen species (ROS) produced by the mitochondria can be involved in cell death. These toxic compounds are normally detoxified by the cells, failing which oxidative stress occurs. However, ROS are not only dangerous molecules for the cell, but they also display a physiological role, as mediators in signal transduction pathways. ROS participate in early and late steps of the regulation of apoptosis, according to different possible molecular mechanisms. In agreement with this role of ROS in apoptosis signaling, inhibition of apoptosis by anti-apoptotic Bcl-2 and Bcl-x(L) is associated with a protection against ROS and/or a shift of the cellular redox potential to a more reduced state. Furthermore, the fact that active forms of cell death in yeast and plants also involve ROS suggests the existence of an ancestral redox-sensitive death signaling pathway that has been independent of caspases and Bcl-2.     

Multicellular redox regulation: integrating organismal biology and redox chemistry

Early in the 20th century, Charles Manning Child attributed organismal gradients in metabolism to interactions among groups of cells. Metabolic gradients are now firmly grounded in redox chemistry, yet modern work on metabolic signaling has consistently focused on the cellular level. Multicellular redox regulation, however, may occur when redox state is determined by the behavior of a group of cells. For instance, typically an abundance of substrate will shift the redox state of mitochondria in the direction of reduction, leading to increased reactive oxygen species (ROS). These ROS, in turn, may modify the conformation and activity of proteins involved in signaling pathways, resulting in phenotypic changes. In contrast, if substrate triggers the contractions of a muscular structure comprising mitochondrion-rich cells, the resulting metabolic demand may shift the redox state in the direction of oxidation, with a corresponding decrease of ROS and different phenotypic effects. Indeed, colonial hydroids exemplify this process. Parallel examples may occur whenever mitochondria are concentrated in cells of structures that can respond to environmental perturbations with increased metabolic demand. In these circumstances, predicting the direction of metabolic signaling may require an understanding of events at the organismal level.     

Oxyconformity in the intertidal worm Sipunculus nudus: the mitochondrial background and energetic consequences

The energetic consequences of strict oxyconformity in the intertidal worm S. nudus were studied by characterizing the Po2 dependence of respiration in mitochondria isolated from the body wall tissue. Mitochondrial respiration rose in a Po2 range between 2.8 and 31.3 kPa from a mean of 56.5 to 223.9 nmol O mg protein(-1) h(-1). Respiration was sensitive to both salicylhydroxamic acid (SHAM) and KCN. Po2 dependence remained unchanged with saturating and non-saturating substrate levels (malate, glutamate and ADP). A concomitant decrease of the ATP/O ratio revealed a lower ATP yield of aerobic metabolism at elevated Po2. Obviously, oxyconforming respiration implies progressive uncoupling of mitochondria. The decrease in ATP/O ratios at higher Po2 was completely reversible. Addition of 90.9 micromol H2O2 l(-1) did not inhibit ATP synthesis. Both observations suggest that oxidative injury did not contribute to oxyconformity. The contribution of the rates of mitochondrial ROS production and proton leakiness to mitochondrial oxygen consumption and uncoupling was investigated by using oligomycin as a specific inhibitor of the ATP synthase. The maximum contribution of oligomycin independent respiration to state 3 respiration remained below 6% and showed a minor, insignificant increase at elevated Po2, at a slope significantly lower than the increment of state 3 respiration. Therefore, Po2 dependent mitochondrial proton leakage or ROS production cannot explain oxyconformity. In conclusion Po2 dependent state 3 respiration likely relates to the progressive contribution of an alternative oxidase (cytochrome o), which is characterized by a low affinity to oxygen and an ATP/O ratio similar to the branched respiratory system of bacteria. The molecular nature of the alternative oxidase in lower invertebrates is still obscure.     

Mitochondrial ROS-induced ROS release: an update and review

Unstable mitochondrial membrane potential and redox transitions can occur following insults including ischemia/reperfusion injury and toxin exposure, with negative consequences for mitochondrial integrity and cellular survival. These transitions can involve mechanisms such as the recently described process, "Reactive Oxygen Species (ROS)-induced ROS-release" (RIRR), and be generated by circuits where the mitochondrial permeability transition (MPT) pore and the inner membrane anion channel (IMAC) are involved. The exposure to excessive oxidative stress results in an increase in ROS reaching a threshold level that triggers the opening of one of the requisite mitochondrial channels. In turn, this leads to the simultaneous collapse of the mitochondrial membrane potential and a transient increased ROS generation by the electron transfer chain. Generated ROS can be released into cytosol and trigger RIRR in neighboring mitochondria. This mitochondrion-to-mitochondrion ROS-signaling constitutes a positive feedback mechanism for enhanced ROS production leading to potentially significant mitochondrial and cellular injury. This review and update considers a variety of RIRR mechanisms (involving MPT, IMAC and episodes of mitochondrial transient hyperpolarization). RIRR could be a general cell biology phenomenon relevant to the processes of programmed mitochondrial destruction and cell death, and may contribute to other mechanisms of post-ischemic pathologies, including arrhythmias.     

Role of mitochondria in the operation of calcium signaling system in heat-stressed plants

Mild heat stress induces the expression of heat shock proteins (HSPs) that protect plants from death during damaging heat treatments. It was assumed that the appearance in the cell of denatured proteins triggers the expression of HSP; however, recent results show that protein denaturation is not a prerequisite for this process. In this work we discuss a hypothetical mechanism for activation under heat stress of HSP expression promoted by short-term elevation of cytosolic Ca²⁺ level. According to our hypothesis, a prolonged elevation of Ca²⁺ has a negative influence on HSP expression. Therefore, calcium is transported from the cytosol into intracellular compartments, including mitochondria. The Ca²⁺ entry into mitochondria is accompanied by hyperpolarization of the inner mitochondrial membrane and by the increased production of reactive oxygen species (ROS). The increased ROS production contributes to the activation of HSP expression under mild heat stress but leads to plant death under severe heat shock. Thus, mitochondria and, possibly, other organelles play the crucial role in determining life or death fate of heat-treated plant cells by controlling the cytosolic Ca²⁺ content and ROS production.     

The effect of permeability transition pore opening on reactive oxygen species production in rat brain mitochondria

The influence of mitochondrial permeability transition pore (MPTP) opening on reactive oxygen species (ROS) production in the rat brain mitochondria was studied. It was shown that ROS production is regulated differently by the rate of oxygen consumption and membrane potential, dependent on steady-state or non-equilibrium conditions. Under steady-state conditions, at constant rate of Ca2+-cycling and oxygen consumption, ROS production is potential-dependent and decreases with the inhibition of respiration and mitochondrial depolarization. The constant rate of ROS release is in accord with proportional dependence of the rate of ROS formation on that of oxygen consumption. On the contrary, transition to non-equilibrium state, due to the release of cytochrome c from mitochondria and progressive respiration inhibition, results in the loss of proportionality in the rate of ROS production on the rate of respiration and an exponential rise of ROS production with time, independent of membrane potential. Independent of steady-state or non-equilibrium conditions, the rate of ROS formation is controlled by the rate of potential-dependent uptake of Ca2+ which is the rate-limiting step in ROS production. It was shown that MPTP opening differently regulates ROS production, dependent on Ca2+ concentration. At low calcium MPTP opening results in the decrease in ROS production because of partial mitochondrial depolarization, in spite of sustained increase in oxygen consumption rate by a cyclosporine A-sensitive component due to simultaneous work of Ca2+-uniporter and MPTP as Ca2+-influx and efflux pathways. The effect of MPTP opening at low Ca2+ concentrations is similar to that of Ca2+-ionophore, A-23187. At high calcium MPTP opening results in the increase of ROS release due to the rapid transition to non-equilibrium state because of cytochrome c loss and progressive gating of electron flow in respiratory chain. Thus, under physiological conditions MPTP opening at low intracellular calcium could attenuate oxidative damage and the impairment of neuronal functions by diminishing ROS formation in mitochondria.     

Calcium microdomains at the immunological synapse: how ORAI channels, mitochondria and calcium pumps generate local calcium signals for efficient T-cell activation

Cell polarization enables restriction of signalling into microdomains. Polarization of lymphocytes following formation of a mature immunological synapse (IS) is essential for calcium-dependent T-cell activation. Here, we analyse calcium microdomains at the IS with total internal reflection fluorescence microscopy. We find that the subplasmalemmal calcium signal following IS formation is sufficiently low to prevent calcium-dependent inactivation of ORAI channels. This is achieved by localizing mitochondria close to ORAI channels. Furthermore, we find that plasma membrane calcium ATPases (PMCAs) are re-distributed into areas beneath mitochondria, which prevented PMCA up-modulation and decreased calcium export locally. This nano-scale distribution-only induced following IS formation-maximizes the efficiency of calcium influx through ORAI channels while it decreases calcium clearance by PMCA, resulting in a more sustained NFAT activity and subsequent activation of T cells.     

Mathematical modeling of transmembrane calcium transport kinetics in smooth muscle cells

A mathematical model, which describes kinetics of transmembrane calcium transport in a smooth muscular cell, has been elaborated and investigated taking into account that the change of calcium cations concentration within a cell is determined by two mutually opposite processes: an increase of a carrying capacity of calcium channels of plasma membrane under signal substance action and calcium removal from the intracellular space by Mg2+, ATP-dependent calcium pump localized on the plasma membrane. The fundamental difference of the proposed model against the models analyzed in literature before is that the cellular system returns to the initial stationary state after enzyme-catalysed transformation of the signal substance. The results of calculations showed that this model really described the experimental kinetics of the transmembrane calcium transport. In this paper the influence of different parameters (Michaelis constant and ultimate rate of calcium pump, initial concentrations of signal substance and enzyme decomposing it, rate constants) on kinetics of calcium transport through the plasma membrane has been investigated in detail.     

Voltage-dependent anion channels control the release of the superoxide anion from mitochondria to cytosol

Several reactions in biological systems contribute to maintain the steady-state concentrations of superoxide anion (O(2)*-) and hydrogen peroxide (H(2)O(2)). The electron transfer chain of mitochondria is a well documented source of H(2)O(2); however, the release of O(2)*- from mitochondria into cytosol has not been unequivocally established. This study was aimed at validating mitochondria as sources of cytosolic O(2)*-, elucidating the mechanisms underlying the release of O(2)*- from mitochondria into cytosol, and assessing the role of outer membrane voltage-dependent anion channels (VDACs) in this process. Isolated rat heart mitochondria supplemented with complex I or II substrates generate an EPR signal ascribed to O(2)*-. Inhibition of the signal in a concentration-dependent manner by both manganese-superoxide dismutase and cytochrome c proteins that cannot cross the mitochondrial membrane supports the extramitochondrial location of the spin adduct. Basal rates of O(2)*- release from mitochondria were estimated at approximately 0.04 nmol/min/mg protein, a value increased approximately 8-fold by the complex III inhibitor, antimycin A. These estimates, obtained by quantitative spin-trapping EPR, were confirmed by fluorescence techniques, mainly hydroethidine oxidation and horseradish peroxidase-based p-hydroxyphylacetate dimerization. Inhibitors of VDAC, 4'-diisothiocyano-2,2'-disulfonic acid stilbene (DIDS), and dextran sulfate (in a voltage-dependent manner) inhibited O(2)*- production from mitochondria by approximately 55%, thus suggesting that a large portion of O(2)*- exited mitochondria via these channels. These findings are discussed in terms of competitive decay pathways for O(2)*- in the intermembrane space and cytosol as well as the implications of these processes for modulating cell signaling pathways in these compartments.     

Gating kinetics of batrachotoxin-modified Na+ channels in the squid giant axon. Voltage and temperature effects.

The gating kinetics of batrachotoxin-modified Na+ channels were studied in outside-out patches of axolemma from the squid giant axon by means of the cut-open axon technique. Single channel kinetics were characterized at different membrane voltages and temperatures. The probability of channel opening (Po) as a function of voltage was well described by a Boltzmann distribution with an equivalent number of gating particles of 3.58. The voltage at which the channel was open 50% of the time was a function of [Na+] and temperature. A decrease in the internal [Na+] induced a shift to the right of the Po vs. V curve, suggesting the presence of an integral negative fixed charge near the activation gate. An increase in temperature decreased Po, indicating a stabilization of the closed configuration of the channel and also a decrease in entropy upon channel opening. Probability density analysis of dwell times in the closed and open states of the channel at 0 degrees C revealed the presence of three closed and three open states. The slowest open kinetic component constituted only a small fraction of the total number of transitions and became negligible at voltages greater than -65 mV. Adjacent interval analysis showed that there is no correlation in the duration of successive open and closed events. Consistent with this analysis, maximum likelihood estimation of the rate constants for nine different single-channel models produced a preferred model (model 1) having a linear sequence of closed states and two open states emerging from the last closed state. The effect of temperature on the rate constants of model 1 was studied. An increase in temperature increased all rate constants; the shift in Po would be the result of an increase in the closing rates predominant over the change in the opening rates. The temperature study also provided the basis for building an energy diagram for the transitions between channel states.     

Calcium-induced generation of reactive oxygen species in brain mitochondria is mediated by permeability transition

Mitochondrial uptake of calcium in excitotoxicity is associated with subsequent increase in reactive oxygen species (ROS) generation and delayed cellular calcium deregulation in ischemic and neurodegenerative insults. The mechanisms linking mitochondrial calcium uptake and ROS production remain unknown but activation of the mitochondrial permeability transition (mPT) may be one such mechanism. In the present study, calcium increased ROS generation in isolated rodent brain and human liver mitochondria undergoing mPT despite an associated loss of membrane potential, NADH and respiration. Unspecific permeabilization of the inner mitochondrial membrane by alamethicin likewise increased ROS independently of calcium, and the ROS increase was further potentiated if NAD(H) was added to the system. Importantly, calcium per se did not induce a ROS increase unless mPT was triggered. Twenty-one cyclosporin A analogs were evaluated for inhibition of calcium-induced ROS and their efficacy clearly paralleled their potency of inhibiting mPT-mediated mitochondrial swelling. We conclude that while intact respiring mitochondria possess powerful antioxidant capability, mPT induces a dysregulated oxidative state with loss of GSH- and NADPH-dependent ROS detoxification. We propose that mPT is a significant cause of pathological ROS generation in excitotoxic cell death.     

Comparative Model Analysis of Calcium Exchange between the Cytosol and Stores of Mitochondria or Endoplasmic Reticulum

The objects of the study were single-compartment mathematical models corresponding to a fragment of the dendrite of a cerebellar Purkinje neuron containing the mitochondria (model 1) or a cistern of the endoplasmic reticulum, ER, (model 2) as the calcium stores. We investigated the dependence of the intracellular Ca²⁺ dynamics on geometrical sizes of calcium exchanging parts of the intracellular space and the difference between the kinetic characteristics of storing in two types of stores occupying different portions of the compartment volume. The plasma membrane of the compartment bore the ion channels, particularly those conducting excitatory synaptic current, and the calcium pump typical of this neuron type. The model equations took into account Ca²⁺ exchange between the cytosol, extracellular medium, organelle stores, non-organelle endogenous buffers, and an exogenous buffer (fluorescent dye), and also the diffusion of Са²⁺ into adjacent regions of the dendrite. In model 1, the mitochondria exchanged Са²⁺ with the cytosol via the uniporter and sodium/calcium exchanger; mitochondrial processes, such as the tricarboxylic acid cycle and aerobic cellular respiration, were also taken into account. In model 2, the ER membrane contained the calcium pump, channels of passive leak, and channels of calcium-induced and inositol-3-phosphate-dependent release of Са²⁺. Increases in the portion of the stores in the total volume of the compartment from 1 to 36% led to a proportional increase in the peak values of the cytosolic calcium concentration ([Ca²⁺] _i ); the concentration of Са²⁺ in the mitochondria ([Ca²⁺]_mit) or ER ([Ca²⁺]_ER) increased correspondingly. During generation of bell-shaped cytosolic calcium signals of equal intensity and duration, the ER (due to a greater rate of storing, as compared with that in the mitochondria) was able to uptake several times more Са²⁺ (four times at 36% filling of the volume by the organelles). It is suggested that the revealed different kinetic characteristics of Са²⁺ storing by different organelles are determined by the rates of binding to transport molecules present in the store membrane and, therefore, are defined by concentrations (surface densities) of these molecules and their saturation at certain levels of [Ca²⁺]i. It has been shown that the occupancy of the intracellular volume by organelle stores of any type is a structural factor, which is able to essentially modulate the values of Ca²⁺ concentration.     

Respiratory uncoupling by UCP1 and UCP2 and superoxide generation in endothelial cell mitochondria

Mitochondria represent a major source of reactive oxygen species (ROS), particularly during resting or state 4 respiration wherein ATP is not generated. One proposed role for respiratory mitochondrial uncoupling proteins (UCPs) is to decrease mitochondrial membrane potential and thereby protect cells from damage due to ROS. This work was designed to examine superoxide production during state 4 (no ATP production) and state 3 (active ATP synthesis) respiration and to determine whether uncoupling reduced the specific production of this radical species, whether this occurred in endothelial mitochondria per se, and whether this could be modulated by UCPs. Superoxide formation by isolated bovine aortic endothelial cell (BAE) mitochondria, determined using electron paramagnetic resonance spectroscopy, was approximately fourfold greater during state 4 compared with state 3 respiration. UCP1 and UCP2 overexpression both increased the proton conductance of endothelial cell mitochondria, as rigorously determined by the kinetic relationship of respiration to inner membrane potential. However, despite uncoupling, neither UCP1 nor UCP2 altered superoxide formation. Antimycin, known to increase mitochondrial superoxide, was studied as a positive control and markedly enhanced the superoxide spin adduct in our mitochondrial preparations, whereas the signal was markedly impaired by the powerful chemical uncoupler p-(trifluoromethoxyl)-phenyl-hydrazone. In summary, we show that UCPs do have uncoupling properties when expressed in BAE mitochondria but that uncoupling by UCP1 or UCP2 does not prevent acute substrate-driven endothelial cell superoxide as effluxed from mitochondria respiring in vitro.     

Molecular mechanism of 'mitocan'-induced apoptosis in cancer cells epitomizes the multiple roles of reactive oxygen species and Bcl-2 family proteins

Mitochondria have emerged recently as effective targets for novel anti-cancer drugs referred to as 'mitocans'. We propose that the molecular mechanism of induction of apoptosis by mitocans, as exemplified by the drug alpha-tocopheryl succinate, involves generation of reactive oxygen species (ROS). ROS then mediate the formation of disufide bridges between cytosolic Bax monomers, resulting in the formation of mitochondrial outer membrane channels. ROS also cause oxidation of cardiolipin, triggering the release of cytochrome c and its translocation via the activated Bax channels. This model may provide a general mechanism for the action of inducers of apoptosis and anticancer drugs, mitocans, targeting mitochondria via ROS production.     

Cytosolic organelles shape calcium signals and exo-endocytotic responses of chromaffin cells

The concept of stimulus-secretion coupling was born from experiments performed in chromaffin cells 50 years ago. Stimulation of these cells with acetylcholine enhances calcium (Ca(2+)) entry and this generates a transient elevation of the cytosolic Ca(2+) concentration ([Ca(2+)](c)) that triggers the exocytotic release of catecholamines. The control of the [Ca(2+)](c) signal is complex and depends on various classes of plasmalemmal calcium channels, cytosolic calcium buffers, the uptake and release of Ca(2+) from cytoplasmic organelles, such as the endoplasmic reticulum, mitochondria, chromaffin vesicles and the nucleus, and Ca(2+) extrusion mechanisms, such as the plasma membrane Ca(2+)-stimulated ATPase, and the Na(+)/Ca(2+) exchanger. Computation of the rates of Ca(2+) fluxes between the different cell compartments support the proposal that the chromaffin cell has developed functional calcium tetrads formed by calcium channels, cytosolic calcium buffers, the endoplasmic reticulum, and mitochondria nearby the exocytotic plasmalemmal sites. These tetrads shape the Ca(2+) transients occurring during cell activation to regulate early and late steps of exocytosis, and the ensuing endocytotic responses. The different patterns of catecholamine secretion in response to stress may thus depend on such local [Ca(2+)](c) transients occurring at different cell compartments, and generated by redistribution and release of Ca(2+) by cytoplasmic organelles. In this manner, the calcium tetrads serve to couple the variable energy demands due to exo-endocytotic activities with energy production and protein synthesis.     

p53 regulates mitochondrial membrane potential through reactive oxygen species and induces cytochrome c-independent apoptosis blocked by Bcl-2.

Downstream mediators of p53 in apoptosis induction remain to be elucidated. We report that p53-induced apoptosis occurred in the absence of cytochrome c release into the cytosol. Although Bax was upregulated, it remained largely in the cytosol and there was no detectable translocation to the mitochondria. Bid was not activated as no cleavage could be detected. Thus, the absence of cytochrome c release may be due to the lack of Bax translocation to mitochondria and/or Bid inactivation. Nevertheless, p53-induced apoptosis is still caspase dependent because it could be abolished by z-VAD-fmk. To search for alternative downstream targets of p53, we detected production of reactive oxygen species (ROS) as well as mitochondrial membrane potential (Deltapsi). p53 induced ROS generation, which then caused a transient increase of Deltapsi followed by a decrease. Antioxidants could inhibit the alterations of Deltapsi, thereby preventing apoptosis. z-VAD-fmk was unable to abrogate Deltapsi elevation but inhibited Deltapsi decrease, indicating that Deltapsi elevation and its decrease are two independent events. Bcl-2 may abolish elevation as well as decrease of Deltapsi without interfering with ROS levels. Thus, the ROS-mediated disruption of Deltapsi constitutes a pivotal step in the apoptotic pathway of p53, and this pathway does not involve cytochrome c release.     

The kinetic and physical basis of K(ATP) channel gating: toward a unified molecular understanding

K(ATP) channels can be formed from Kir6.2 subunits with or without SUR1. The open-state stability of K(ATP) channels can be increased or reduced by mutations throughout the Kir6.2 subunit, and is increased by application of PIP(2) to the cytoplasmic membrane. Increase of open-state stability is manifested as an increase in the channel open probability in the absence of ATP (Po(zero)) and a correlated decrease in sensitivity to inhibition by ATP. Single channel lifetime analyses were performed on wild-type and I154C mutant channels expressed with, and without, SUR1. Channel kinetics include a single, invariant, open duration; an invariant, brief, closed duration; and longer closed events consisting of a "mixture of exponentials," which are prolonged in ATP and shortened after PIP(2) treatment. The steady-state and kinetic data cannot be accounted for by assuming that ATP binds to the channel and causes a gate to close. Rather, we show that they can be explained by models that assume the following regarding the gating behavior: 1) the channel undergoes ATP-insensitive transitions from the open state to a short closed state (C(f)) and to a longer-lived closed state (C(0)); 2) the C(0) state is destabilized in the presence of SUR1; and 3) ATP can access this C(0) state, stabilizing it and thereby inhibiting macroscopic currents. The effect of PIP(2) and mutations that stabilize the open state is then to shift the equilibrium of the "critical transition" from the open state to the ATP-accessible C(0) state toward the O state, reducing accessibility of the C(0) state, and hence reducing ATP sensitivity.     

Hypoxia triggers AMPK activation through reactive oxygen species-mediated activation of calcium release-activated calcium channels

AMP-activated protein kinase (AMPK) is an energy sensor activated by increases in [AMP] or by oxidant stress (reactive oxygen species [ROS]). Hypoxia increases cellular ROS signaling, but the pathways underlying subsequent AMPK activation are not known. We tested the hypothesis that hypoxia activates AMPK by ROS-mediated opening of calcium release-activated calcium (CRAC) channels. Hypoxia (1.5% O(2)) augments cellular ROS as detected by the redox-sensitive green fluorescent protein (roGFP) but does not increase the [AMP]/[ATP] ratio. Increases in intracellular calcium during hypoxia were detected with Fura2 and the calcium-calmodulin fluorescence resonance energy transfer (FRET) sensor YC2.3. Antioxidant treatment or removal of extracellular calcium abrogates hypoxia-induced calcium signaling and subsequent AMPK phosphorylation during hypoxia. Oxidant stress triggers relocation of stromal interaction molecule 1 (STIM1), the endoplasmic reticulum (ER) Ca(2+) sensor, to the plasma membrane. Knockdown of STIM1 by short interfering RNA (siRNA) attenuates the calcium responses to hypoxia and subsequent AMPK phosphorylation, while inhibition of L-type calcium channels has no effect. Knockdown of the AMPK upstream kinase LKB1 by siRNA does not prevent AMPK activation during hypoxia, but knockdown of CaMKKβ abolishes the AMPK response. These findings reveal that hypoxia can trigger AMPK activation in the apparent absence of increased [AMP] through ROS-dependent CRAC channel activation, leading to increases in cytosolic calcium that activate the AMPK upstream kinase CaMKKβ.