Changes in E. coli cell envelope structure caused by uncouplers of active transport and colicin E1

It is of interest to inquire whether agents that uncouple or deenergize membranes cause concomitant structural changes. The agents considered here are the uncoupler carbonyl cyanide-p-trifluoromethoxyphenylhydrazone and the bacteriocidal protein colicin E1, agents for which there is some precedent for believing that they interact with membranes. In intact E. coli ML 308-225 cells the inhibition of [¹⁴C]-proline active transport by FCCP increases with uncoupler concentration from ～ 20% at 2 μM to ～100% at 5 μM. The increase in the rotational relaxation time (ρ) of the cell-bound fluorescent probe N-phenyl-1-naphthylamine (PhNap)

1 Abbreviations: FCCP – carbonyl cyanide p-trifluoromethoxyphenylhydrazone; ANS – 8-anilino-1-naphthalenesulfonate; PhNap, N-phenyl-1-naphthylamine; EDTA – ethylenediaminetetraacetate.

and 8-anilino-1-naphthalene-sulfonate (ANS) under these conditions shows the same dependence on FCCP concentration. For cells treated with EDTA to remove part of the outer lipopolysaccharide layer, inhibition of proline transport and the increase in ρ value of ANS show the same dependence on FCCP concentration with saturation at 0.3 μM. EDTA treatment causes a large increase in the binding and rotational relaxation time of PhNap, the latter quantity approaching a value obtained with purified inner membrane. Similar effects are produced in untreated cells by 5 μM FCCP. It is concluded that (a) EDTA treatment removes a permeability barrier t o FCCP and PhNap in the outer membrane; (b) uncoupling by FCCP removes a similar permeability barrier to PhNap; (c) binding of amphiphilic ANS, assumed to be located in the outer membrane, is hardly changed by these treatments; (d) deenergization of the inner membrane by FCCP thus causes a structural change in the outer membrane as measured by the permeability change to hydrophobic PhNap and the increase in ρ values of the amphiphilic ANS; (e) The binding sites reached by PhNap within the permeability barrier at or near the inner membrane are changed by FCCP from their initial state. This is inferred from an increase in PhNap quantum yield extrapolated to infinite cell concentration, and from removal by FCCP of an apparent phase transition sensed by the PhNap rotational relaxation time. Thus, uncoupling and deenergization by FCCP appears to cause structural change both in the outer membrane and inside the permeability barrier of the outer membrane. Transmission of the colicin E1 response in the envelope of intact and EDTA-treated cells can also be monitored by an increase in ANS and PhNap fluorescence intensity, a smaller fractional increase in dye binding, and a large increase in probe rotational relaxation time. The fluorescence changes of ANS again imply structural effects in the outer membrane caused by colicin. The binding and fluorescence changes of PhNap caused by colicin E1 acting on intact cells again imply an effect of deenergization on the permeability barrier of the outer membrane. Fluorescence changes with PhNap in intact and EDTA-treated cells show that the dye binding sites are altered in the presence of colicin E1. It is also shown that the PhNap intensity change can be blocked by low concentrations of vitamin B12, which competes for the colicin E1 receptor. Some properties are presented of the probe chlorotetracycline, which has been proposed by others to be an indicator of magnesium. The probe appears to reside in an environment somewhat similar to that of ANS, but the colicin-induced changes in its fluorescence parameters appear to be small under our conditions.     

The state of energization of the membrane of Escherichia coli as affected by physiological conditions and colicin K.

The bacterial protein colicin K, when added to sensitive Escherichia coli in the presence of 3,3'-dihexyloxacarbocyanine, cuases a doubling in fluorescence of the probe. Glucose and oxygen cause a decreased fluorescence while anoxia and cyanide cause a rise in fluorescence. These results in conjunction with the work of other laboratories suggest that colicin K causes a depolarization of the transmembrane electrical potential. Fluorescence in the absence of colicin K was relatively independent of KCl, NaCl, and MgCl2 concentrations below 0.1 M. Although colicin K caused rapid efflux of the K+ analogue 86Rb+, the fluorescence rise was only partially blocked by 0.13 M KCl. The level of fluorescence caused by the action of colcin K was inversely proportional to the logarithm of the concentration of MgCl2 over the range of 2 muM to 4 mM. This suggests that a Nernst electrochemical potential for an anion can counteract a membrane depolarization caused by colcin. After colcin K action, the fluorescence of the carbocyanine could be further increased by anoxia or cyanide. The distribution of the weak base dimethyloxazolidinedione indicated that the pH in the interior of aerobic E. coli supplied with lactate was alkaline by 0.1 unit and unaffected by colicin. These results suggest that colicin K does not completely depolarize the membrane potential and does not interfere with the component of membrane energization generated by electron transport. Colicin K does not act as a cationophore. The partial depolarization of the membrane may account for the inhibition of active solute transport caused by colicin K.     

Respiration-Linked Proton Transport, Changes in External pH, and Membrane Energization in Cells of Escherichia coli

The kinetics of respiration-dependent proton efflux and membrane energization have been studied in intact cells of logarithmic-phase Escherichia coli. Parallel measurements of the rate and extent of proton efflux into the external medium (half-time, about 10 s; ratio of H(+) to O, about 0.5) and the oxidation of E. coli cytochrome b (half-time, 相似文献   

ATP- and phosphate-induced configurational changes of submitochondrial particles

Light scattering was employed to monitor configurational changes of submitochondrial particles. Such changes were induced by ATP but not by analogues of this nucleotide. Mg²⁺ in an equimolar concentration to ATP enhanced the effect of the nucleotide. The ATP-induced changes were inhibited by oligomycin and uncouplers. Atractyloside was effective as an inhibitor only when loaded within the particles. The ATP-induced changes were decreased by phosphate. The effect of phosphate was partially inhibited by mersalyl. Sodium phosphate and ammonium phosphate were more effective than potassium phosphate.

The observed changes in light scattering were due to (a) events involved in energization and de-energization of the membrane, and (b) events concerning transport over the particulate membrane.

The changes were specific for adenine nucleotides and phosphate.     

Distinct phases of the fluorescence response of the lipophilic probe N-phenyl-1-naphthylamine in intact cells and membrane vesicles of Escherichia coli

The fluorescence of the lipophilic probe N-phenyl-1-naphthylamine (NPN) bound to intact cells of Escherichia coli is quenched by the addition of glucose, succinate, D-lactate, pyruvate, formate and glycerol. Partial recovery of fluorescence occurs on anaerobiosis. Use of mutants with defects in the ATP synthase or the respiratory chain show that quenching of fluorescence may be energized either by ATP hydrolysis or by substrate oxidation through the respiratory chain. Permeabilization of the outer membrane by treatment of intact cells with EDTA, or use of a mutant with an outer membrane permeable to lipophilic substances, results in a more rapid binding of NPN and in a decrease in quenching observed on substrate addition. NPN binds rapidly to everted membrane vesicles, but does not respond to membrane energization. It is proposed that inner membrane energization in intact cells alters the binding or environment of NPN in the outer membrane. The fluorescence recovery which occurs on anaerobiosis has two components. One component represents a reversal of the changes which occur on membrane energization. The other component of the fluorescence change is insensitive to the uncoupler CCCP and resembles the behaviour of NPN with everted membrane vesicles. It is suggested that a portion of the fluorescence events seen with NPN involves a response of the probe to changes in the inner membrane.     

Response of an Escherichia coli-Bound Fluorescent Probe to Colicin E1

The fluorescent probe, 8-anilino-1-napthalenesulfonate (ANS) binds to Escherichia coli, showing an enhanced fluorescence. The interaction of colicin E1 with sensitive cells causes an increase of about 100% in the fluorescence of the bound ANS, and this change at equilibrium has an apparent "all-or-none" nature as a function of E1 multiplicity. Approximately 6 to 8% of the ANS is bound to the cells at equilibrium. The colicin E1-induced fluorescence increase can be attributed partly to an increase in ANS binding and partly to an increase in the fluorescence yield of the bound ANS. The kinetics of the E1-induced fluorescence increase in sensitive cells are very similar to those of the adenosine triphosphate decrease. The phosphorylation uncoupler p-trifluoromethoxy-carbonylcyanidephenylhydrazone also causes a large change in the fluorescence of bound ANS. Colicin E2 or E3 does not cause any fluorescence change, nor does colicin E1 cause fluorescence change with a colicinogenic strain. ANS appears to be a probe of structural or conformational change in the cell envelope that is closely associated with the colicin E1-induced adenosine triphosphate decrease.     

Mutant of Escherichia coli defective in response to colicin K and in active transport.

A mutant of Escherichia coli has been isolated that grows poorly on succinate and exhibits a markedly reduced sensitivity to colicin K. This mutant is also deficient in the respiration-linked transport of proline and thiomethyl-beta-D-galactoside but appears normal for the adenosine triphosphate-dependent transport of glutamine and arginine. A temperature-conditional revertant of the mutant grows on succinate and is sensitive to colicin K at 27 C, but fails to grow on succinate and is insensitive to colicin K at 42 C. Proline transport in the temperature-conditional revertant is reduced at 42 C when either glucose or succinate is used as energy source. Glutamine transport, on the other hand, is normal at 42 C with glucose as energy source, but is reduced with succinate, although not to the same extent as is proline transport. The lack of growth on succinate and the deficiencies in transport at 42 C are not due to a temperature-dependent lesion in either the electron transport chain or in Ca2+, Mg2+-activated adenosine triphosphatase activity. Membrane vesicles prepared from the temperature-conditional revertant are impaired in proline transport at both 27 and 42 C. These findings suggest the existence in the cytoplasmic membrane of E. coli cells of a component, presumably protein, that is required for colicin K action and that functions in respiration-linked and, to a lesser degree, in adenosine triphosphate-dependent active transport systems. This protein may serve as the primary target of colicin K action.     

Energy transduction in photosynthetic bacteria VI. Respiratory sites of energy conservation in membranes from dark-grown cells of Rhodopseudomonas capsulata

Membranes prepared from Rhodopseudomonas capsulata grown heterotrophically in the dark perform phosphorylation linked to oxidation of NADH and succinate, with P/2e⁻ ratios of about 0.5 and 0.15, respectively. The localization of the sites of energy conservation was investigated by observing the respiration-induced quenching of the fluorescence of atebrine.

Energization of the membrane can be demonstrated when NADH is oxidized by O₂, ferricyanide or Q₁, when succinate is oxidized by O₂ or by oxidized diaminodurene, and during the oxidation of reduced diaminodurene.

Antimycin A completely inhibits energization between succinate and O₂ or succinate and diaminodurene; however, it only inhibits partially NADH or succinate oxidases and energization between NADH and O₂. KCN inhibits NADH oxidase in a biphasic way: the first level of inhibition is observed at concentrations which block the oxidation of exogenous cytochrome c or of diaminodurene and energization between succinate or ascorbate-diaminodurene and O₂. The second level corresponds to the inhibition of the antimycin-insensitive oxidase.

The results are interpreted as evidence of the presence in these bacteria of a respiratory chain branching after the dehydrogenase system, one arm of the chain being sensitive to antimycin A and low concentrations of KCN and capable of energy conservation, the other being represented by a completely uncoupled system.     

Distinct phases of the fluorescence response of the lipophilic probe N-phenyl-1-naphthylamine in intact cells and membrane vesicles of Escherichia coli

The fluorescence of the lipophilic prbe N-phenyl-1-naphthylamine (NPN) bound to intact cells of Escherichia coli is quenched by the addition of glucose, succinate, -lactate, pyruvate, formate and glycerol. Partial recovery of fluorescence occurs on anaerobiosis. Use of mutants with defects in the ATP synthase or the respiratory chain show that quenching of fluorescence may be energized either by ATP hydrolysis or by substrate oxidation through the respiratory chain. Permeabilization of the outer membrane by treatment of intact cells with EDTA, or use of a mutant with an outer membrane permeable to lipophilic substances, results in a more rapid binding of NPN and in a decrease in quenching observed on substrate addition. NPN binds rapidly to everted membrane vesicles, but does not respond to membrane energization. It is proposed that inner membrane energization in intact cells alters the binding or environment of NPN in the outer membrane. The fluorescence recovery which occurs on anaerobiosis has two components. One component represents a reversal of the changes which occur on membrane energization. The other component of the fluorescence change is insensitive to the uncoupler CCCP and resembles the behaviour of NPN with everted membrane vesicles. It is suggested that a portion of the fluorescence events seen with NPN involves a response of the probe to changes in the inner membrane.     

Complex formation between the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and valinomycin in the presence of potassium

Spectroscopic evidence is presented which indicates that the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and the peptide antibiotic valinomycin form a complex in the presence of potassium. Complex formation has been observed both in aqueous and nonaqueous media. Several techniques have been used to indicate the existence of a complex in aqueous solution. In the presence of valinomycin and K+, the absorption spectrum of FCCP is significantly perturbed, and there is also a large induced circular dichroism signal. In addition, the previously characterized complex which forms between valinomycin, K+, and the fluorescent probe 8-anilino-1-naphthalene-sulfonate (ANS) in aqueous solution is apparently disrupted by the addition of FCCP. The result is an effective quenching of the fluorescence due to the bound probe as it is displaced from the valinomycin.K+ by the uncoupler. In a nonpolar solvent, the absorption spectrum of FCCP is also perturbed by valinomycin in the presence of K+, again indicating the formation of a complex. These data point to the importance of considering the role of valinomycin.K+.uncoupler complex in interpreting physiological or ion transport data in which these substances have been used together.     

Determination of Mitochondrial Membrane Potential and Reactive Oxygen Species in Live Rat Cortical Neurons

Mitochondrial membrane potential (ΔΨm) is critical for maintaining the physiological function of the respiratory chain to generate ATP. A significant loss of ΔΨm renders cells depleted of energy with subsequent death. Reactive oxygen species (ROS) are important signaling molecules, but their accumulation in pathological conditions leads to oxidative stress. The two major sources of ROS in cells are environmental toxins and the process of oxidative phosphorylation. Mitochondrial dysfunction and oxidative stress have been implicated in the pathophysiology of many diseases; therefore, the ability to determine ΔΨm and ROS can provide important clues about the physiological status of the cell and the function of the mitochondria. Several fluorescent probes (Rhodamine 123, TMRM, TMRE, JC-1) can be used to determine Δψm in a variety of cell types, and many fluorescence indicators (Dihydroethidium, Dihydrorhodamine 123, H₂DCF-DA) can be used to determine ROS. Nearly all of the available fluorescence probes used to assess ΔΨm or ROS are single-wavelength indicators, which increase or decrease their fluorescence intensity proportional to a stimulus that increases or decreases the levels of ΔΨm or ROS. Thus, it is imperative to measure the fluorescence intensity of these probes at the baseline level and after the application of a specific stimulus. This allows one to determine the percentage of change in fluorescence intensity between the baseline level and a stimulus. This change in fluorescence intensity reflects the change in relative levels of ΔΨm or ROS. In this video, we demonstrate how to apply the fluorescence indicator, TMRM, in rat cortical neurons to determine the percentage change in TMRM fluorescence intensity between the baseline level and after applying FCCP, a mitochondrial uncoupler. The lower levels of TMRM fluorescence resulting from FCCP treatment reflect the depolarization of mitochondrial membrane potential. We also show how to apply the fluorescence probe H₂DCF-DA to assess the level of ROS in cortical neurons, first at baseline and then after application of H₂O₂. This protocol (with minor modifications) can be also used to determine changes in ∆Ψm and ROS in different cell types and in neurons isolated from other brain regions.     

Stimulation of triglyceride synthesis in mammalian liver and adipose tissue by two cytosolic compounds.

The enhancement of 1-anilino-8-naphthalenesulfonate fluorescence was observed followed by the binding of the probe to the $\text{E. coli}$ membrane. The fluorescence intensity of the probe is quenched upon energization of intact cells. The experiments with sonicated membrane particles, in which the orientation of the membrane is “inside-out”, showed an energy linked enhancement of the fluorescence intensity of the probe. The changes in the fluorescence intensity of fluorochrome-stained membranes can also be induced by generation of K⁺ ion diffusion potential.     

Photoaffinity labelling of submitochondrial membranes with the 3-azido analogue of 9-amino-3-chloro-7-methoxyacridine

9-Amino-3-azido-7-methoxyacridine has been synthesized and shown to be a suitable photoaffinity probe for the site(s) of interaction of 9-amino-3-chloro-7-methoxyacridine with submitochondrial membranes. Both the excitation and emission spectra of the azido analogue covalently bound to membranes in the energized state display distinctive differences from the spectra of labelled, non-energized membranes (i.e., in the absence of oxidizable substrate, or its presence when uncoupler (FCCP) is also present during photolysis). Enzymatic analyses indicate that the probe interacts with the ATPase and the respiratory chain enzymes; energization appears to afford some protection against inactivation. Electrophoresis of the labelled membranes and isolation of their lipid and protein components indicate that the spectral differences are attributable to differing interactions with the lipid components of energized, relative to non-energized, membranes. Similar results have been obtained with the 3-azido analogue of quinacrine (Mueller, D.M., Hudson, R.A. and Lee, C.P. (1982) Biochemistry 21, 1445-1453), which differs significantly, however, in the extent of its interactions with the enzymes of the respiratory chain and the ATPase. These results indicate that the energy-linked fluorescence responses of 9-aminoacridines with submitochondrial membranes arise from direct interactions with membrane components and may involve redistribution of the probe molecules and/or alteration of their microenvironments upon energization.     

H NMR detection of the specific change to the uncoupled state of the mitochondrial membrane

The spin-lattice relaxation times T1 of H2O in mitochondrial suspensions at various energy states were measured at 28 degrees C. It was found that de-energization on the addition of an uncoupler of oxidative phosphorylation affects T1: after the addition of the uncoupler, T1 first decreases and then increases to a value greater than those at other different energy states. The T1 values of the unfrozen water in mitochondrial suspensions were measured at -15 degrees C after the energy state of the mitochondria was freeze-trapped. It was found that they increase only in the presence of an uncoupler. These changes in T1 are discussed in relation to the specific change of the mitochondrial membrane in the uncoupled state.     

Rhodamine 123 as a probe of mitochondrial membrane potential: evaluation of proton flux through F(0) during ATP synthesis

Rhodamine 123 (RH-123) was used to monitor the membrane potential of mitochondria isolated from rat liver. Mitochondrial energization induces quenching of RH-123 fluorescence and the rate of fluorescence decay is proportional to the mitochondrial membrane potential. Exploiting the kinetics of RH-123 fluorescence quenching in the presence of succinate and ADP, when protons are both pumped out of the matrix driven by the respiratory chain complexes and allowed to diffuse back into the matrix through ATP synthase during ATP synthesis, we could obtain an overall quenching rate proportional to the steady-state membrane potential under state 3 condition. We measured the kinetics of fluorescence quenching by adding succinate and ADP in the absence and presence of oligomycin, which abolishes the ADP-driven potential decrease due to the back-flow of protons through the ATP synthase channel, F(0). As expected, the initial rate of quenching was significantly increased in the presence of oligomycin, and conversely preincubation with subsaturating concentrations of the uncoupler carbonyl cyanide p-trifluoro-metoxyphenilhydrazone (FCCP) induced a decreased rate of quenching. N,N'-dicyclohexylcarbodiimide (DCCD) behaved similarly to oligomycin in increasing the rate of quenching. These findings indicate that RH-123 fluorescence quenching kinetics give reliable and sensitive evaluation of mitochondrial membrane potential, complementing steady-state fluorescence measurements, and provide a mean to study proton flow from the mitochondrial intermembrane space to the matrix through the F(0) channel.     

Effect of uncouplers on the bioenergetic properties of a carbonyl cyanide m-chlorophenylhydrazone-resistant mutant Escherichia Coli UV6

The effects of carbonyl cyanide m-chlorophenylhydrazone (CCCP) and tri-n-butyltin chloride (Bu₃SnCl) on proline transport, proton uptake and the transmembrane pH gradient in intact cells have been compared in a CCCP-resistant mutant strain Escherichia coli UV6, and its parent strain, AN180. CCCP and Bu₃SnCl inhibited proline uptake in AN180 but the pH gradient was affected only by CCCP. Neither uncoupler affected the pH gradient in UV6 although inhibition of proline uptake occurred at high concentrations. CCCP caused efflux of accumulated proline in both strains but Bu₃SnCl was ineffective. Bu₃SnCl did not prevent the efflux of proline induced by CCCP, indicating that Bu₃SnCl had not inactivated the transport carrier. In contrast with the parent strain, CCCP failed to reverse the oxidation-dependent inhibition of the phosphotransferase system in UV6 even at concentrations causing inhibition of proline uptake. The phosphorylation potential of UV6 with succinate as substrate was lower than in AN180. This was associated with a 10-fold higher concentration of phosphate in succinate-grown UV6 than in AN180. These results suggest that CCCP and Bu₃SnCl have different sites of action on the membrane energization system of intact cells of E. coli. A possible explanation of the differences between AN180 and UV6 is that the energization system is altered in the CCCP-resistant mutant. Both uncouplers stimulated the uptake of protons by intact cells to the same extent in UV6 as in AN180. In UV6, and in AN180 with Bu₃SnCl, this was not accompanied by effects on the transmembrane pH gradient. The extent of proton uptake appeared to be related to the level of the highly anionic membrane-associated oligosaccharides in the periplasmic space. It is proposed the outer membrane acts as a partial barrier to protons and that the uncouplers can equilibrate protons between the extracellular medium and the periplasmic space in intact cells.     

能量化时线粒体内膜表面电荷的变化

本文报告用荧光探剂1,8—ANS和电泳激光光散射技术,研究鼠肝线粒体内膜在加入ATP的能量化过程中其膜表面电荷的变化。实验结果表明在加入ATP后线粒体内膜的能量化使其膜表面的负电荷减少。作者论讨了用上述二种方法研究线粒体内膜在能量化时表面电荷变化的有关问题。     

Does the energy state of mitochondria influence the surface potential of the inner mitochondrial membrane? A critical appraisal

Binding of 8-anilino-1-naphthalene sulphonate (ANS) to rat liver mitochondria and submitochondrial inside-out particles was measured under energized and de-energized conditions. In mitochondria, energization/de-energization changed the binding capacity for ANS extrapolated for its infinitely high concentration, whereas the apparent Kd value remained unchanged. In submitochondrial particles apparent Kd was changed but the extrapolated maximum binding was not altered. These results are compatible with theoretical considerations assuming a free permeability of mitochondrial membranes to ANS and its distribution according to the transmembrane potential. The spin-labelled cationic amphiphile, 4-(dodecyl dimethyl ammonium)-1-oxyl-2,2,6,6-tetramethyl piperidine bromide (CAT12), was trapped by de-energized mitochondria in such a way that about half of the bound probe became inaccessible to reduction by externally added ascorbate. This inaccessible fraction was increased by energization. This indicates that this cationic probe can penetrate through the inner mitochondrial membrane. De-energization produced a parallel shift of the Lineweaver-Burk plots for the oxidation of external ferrocytochrome c by mitoplasts and of succinate by submitochondrial particles. A similar shift was obtained by a partial inhibition of succinate oxidation by antimycin A. Thus, the observed changes of the kinetics of the two membrane-bound enzyme systems on de-energization can be interpreted as reflecting changes of the control points of mitochondrial respiration rather than changes of the surface potential. It is concluded that neither the fluorescent probe ANS, the spin-labelled amphiphilic cation CAT12, nor the kinetics of some respiratory enzyme systems provide a sufficient proof for changes of the surface potential of the inner mitochondrial membrane upon energization.     

Bax translocation to mitochondria subsequent to a rapid loss of mitochondrial membrane potential

Bax, a pro-apoptotic member of the Bcl-2 family, is a cytosolic protein that inserts into mitochondrial membranes upon induction of cell death. Using the green fluorescent protein fused to Bax (GFP-Bax) to quantitate mitochondrial binding in living cells we have investigated the cause of Bax association with mitochondria and the time course relative to endogenous and induced changes in mitochondrial membrane potential (DeltaPsi(m)). We have found that staurosporine (STS) induces a loss in DeltaPsi(m) before GFP-Bax translocation can be measured. The onset of the DeltaPsi(m) loss is followed by a rapid and complete collapse of DeltaPsi(m) which is followed by Bax association with mitochondria. The mitochondria uncoupler FCCP, in the presence of the F(1)-F(0) ATPase inhibitor oligomycin, can trigger Bax translocation to mitochondria suggesting that when ATP levels are maintained a collapse of DeltaPsi(m) induces Bax translocation. Neither FCCP nor oligomycin alone alters Bax location. Bax association with mitochondria is also triggered by inhibitors of the electron transport chain, antimycin and rotenone, compounds that collapse DeltaPsi(m) without inducing rapid ATP hydrolysis that typically occurs with uncouplers such as FCCP. Taken together, our results suggest that alterations in mitochondrial energization associated with apoptosis can initiate Bax docking to mitochondria.