Mitochondrial precursor signal peptide induces a unique permeability transition and release of cytochrome c from liver and brain mitochondria.

This study tested the hypothesis that mitochondrial precursor targeting peptides can elicit the release of cytochrome c from both liver and brain mitochondria by a mechanism distinct from that mediated by the classical, Ca2+-activated permeability transition pore. Human cytochrome oxidase subunit IV signal peptide (hCOXIV1-22) at concentrations from 15 to 100 microM induced swelling, a decrease in membrane potential, and cytochrome c release in both types of mitochondria. Although cyclosporin A and bongkrekic acid were without effect, dibucaine, propanolol, dextran, and the uncoupler FCCP were each able to inhibit signal peptide-induced swelling and cytochrome c release. Adenylate kinase was coreleased with cytochrome c, arguing against a signal peptide-induced cytochrome c-specific pathway of efflux across the outer membrane. Taken together, the data indicate that a human mitochondrial signal peptide can evoke the release of cytochrome c from both liver and brain mitochondria by a unique permeability transition that differs in several characteristics from the classical mitochondrial permeability transition.

Palmitic acid opens a novel cyclosporin A-insensitive pore in the inner mitochondrial membrane.

An assortment of agents can induce mitochondria to undergo a permeability transition, which results in the inner mitochondrial membrane becoming nonselectively permeable to small (<1500 Da) solutes. This mitochondrial permeability transition (MPT) is characterized by a strict dependence on matrix Ca2+ and sensitivity to cyclosporin A (CsA). However, it is becoming increasingly clear that other experimental conditions can elicit increases in mitochondrial permeability that are distinct from this classic MPT. For example, butylated hydroxytoluene (BHT; Sokolove, P. M., and Haley, L. M. (1996) J. Bioenerg. Biomembr. 28, 199-206) and signal peptides (Sokolove, P. M., and Kinnally, K. W. (1996) Arch. Biochem. Biophys. 336, 69-76) promote increases in mitochondrial permeability that are CsA-insensitive. It has been suggested (Gudz, T., Eriksson, O., Kushnareva, Y., Saris, N.-E., and Novgorodov, S. A. (1997) Arch. Biochem. Biophys. 342, 143-156) that BHT might be opening a CsA-insensitive pore by increasing phospholipase A2 activity and thereby producing an accumulation of free fatty acids and lysophospholipids. We have therefore examined the effect of the saturated free fatty acid, palmitic acid (PA), on the permeability of isolated rat liver mitochondria. The following results were obtained: (1) In the absence of additional triggers, PA (20-60 microM) induced concentration-dependent, CsA-insensitive mitochondrial swelling. (2) Swelling required mitochondrial energization. (3) PA-induced swelling was fast and occurred without a lag. (4) Both Ca2+ and Sr2+ supported PA-induced swelling; the site of cation action was the matrix. (5) EGTA and BSA were potent inhibitors of PA-induced swelling. (6) PA opened a pore rather than disrupting mitochondrial membrane structure. (7) The pore opened by PA closed spontaneously. These results suggest that palmitic acid promotes a nonclassic permeability increase that is clearly distinguishable from the occurrence of the MPT.

Free fatty acid effects on mitochondrial permeability: an overview.

A variety of experimental conditions elicit increases in mitochondrial permeability that can be differentiated from the classic cyclosporin A (CsA)-sensitive mitochondrial permeability transition (MPT). For example, butylated hydroxytoluene, signal peptides, and the hormone thyroxine have been shown to promote increases in mitochondrial permeability that are CsA-insensitive. Our laboratory has recently demonstrated that palmitic acid, a saturated 16-carbon free fatty acid (FFA), can also open a CsA-insensitive pore. This nonclassic permeability transition (NCPT) is further distinguished by a nonselective dependence on divalent cations and by spontaneous closure. To determine if induction of the NCPT is specific to palmitic acid and to resolve conflicting reports as to the mechanisms by which FFAs alter mitochondrial permeability, we examined in detail mitochondrial swelling induced by FFAs that differ in chain length and degree of saturation. The following results were obtained: (1) In the presence of modest Ca2+ concentrations (75 nmol/mg protein), medium-chain FFAs (C12-C18) were more effective in eliciting mitochondrial swelling than were shorter or longer FFAs; medium-chain alkanols and amines had no effect. (2) Under these conditions, saturated FFAs induced CsA-insensitive swelling with all the characteristics of the NCPT, while unsaturated FFAs triggered the MPT. (3) When matrix Ca2+ concentration was further elevated, unsaturated FFAs triggered the NCPT. (4) Mitochondrial swelling induced by saturated FFAs was inhibited by unsaturated FFAs but not by other saturated FFAs or medium-chain alkanols. These results suggest that ambient conditions can greatly influence the nature of the increase in mitochondrial permeability induced by FFAs. They are also consistent with our earlier proposal that Ca2+ (or Sr2+) binding to FFAs in the inner leaflet of the inner mitochondrial membrane underlies the NCPT.

Prooxidants open both the mitochondrial permeability transition pore and a low-conductance channel in the inner mitochondrial membrane.

Mitochondria can be induced by a variety of agents/conditions to undergo a permeability transition (MPT), which nonselectively increases the permeability of the inner membrane (i.m.) to small (<1500 Da) solutes. Prooxidants are generally considered to trigger the MPT, but some investigators suggest instead that prooxidants open a Ca(2+)-selective channel in the inner mitochondrial membrane and that the opening of this channel, when coupled with Ca(2+) cycling mediated by the Ca(2+) uniporter, leads ultimately to the observed increase in mitochondrial permeability [see, e.g., Schlegel et al. (1992) Biochem. J. 285, 65]. S. A. Novgorodov and T. I. Gudz [J. Bioenerg. Biomembr. (1996) 28, 139] propose that the i.m. contains a pore that, upon exposure to prooxidants, can open to two states, one of which conducts only H(+) and one of which is the classic MPT pore. Given the current interest in increased mitochondrial permeability as a factor in apoptotic cell death, it is important to determine whether i.m. permeability is regulated in one or multiple ways and, in the latter event, to characterize each regulatory mechanism in detail. This study examined the effects of the prooxidants diamide and t-butylhydroperoxide (t-BuOOH) on the permeability of isolated rat liver mitochondria. Under the experimental conditions used, t-BuOOH induced mitochondrial swelling only in the presence of exogenous Ca(2+) (>2 microM), whereas diamide was effective in its absence. In the absence of exogenous inorganic phosphate (P(i)), (1) both prooxidants caused a collapse of the membrane potential (DeltaPsi) that preceded the onset of mitochondrial swelling; (2) cyclosporin A eliminated the swelling induced by diamide and dramatically slowed that elicited by t-BuOOH, without altering prooxidant-induced depolarization; (3) collapse of DeltaPsi was associated with Ca(2+) efflux but not with efflux of glutathione; (4) neither Ca(2+) efflux nor DeltaPsi collapse was sensitive to ruthenium red; (5) collapse of DeltaPsi was accompanied by an increase in matrix pH; no stimulation of respiration was observed; (6) Sr(2+) was able to substitute for Ca(2+) in supporting t-BuOOH-induced i.m. depolarization, but not swelling; (7) in addition to being insensitive to CsA, the collapse of DeltaPsi was also resistant to trifluoperazine, spermine, and Mg(2+), all of which block the MPT; and (8) DeltaPsi was restored (and its collapse was inhibited) upon addition of dithiothreitol, ADP, ATP or EGTA. We suggest that these results indicate that prooxidants open two channels in the i.m.: the classic MPT and a low-conductance channel with clearly distinct properties. Opening of the low-conductance channel requires sulfhydryl group oxidation and the presence of a divalent cation; both Ca(2+) and Sr(2+) are effective. The channel permits the passage of cations, including Ca(2+), but not of protons. It is insensitive to inhibitors of the classic MPT.

Signal presequences increase mitochondrial permeability and open the multiple conductance channel.

We have reported that the signal presequence of cytochrome oxidase subunit IV from Neurospora crassa increases the permeability of isolated rat liver mitochondria [P. M. Sokolove and K. W. Kinnally (1996) Arch. Biochem. Biophys. 336, 69] and regulates the behavior of the mutiple conductance channel (MCC) of yeast inner mitochondrial membrane [T. A. Lohret and K. W. Kinnally (1995) J. Biol. Chem. 270, 15950]. Here we examine in greater detail the action of a number of mitochondrial presequences from various sources and of several control peptides on the permeability of isolated rat liver mitochondria and on MCC activity monitored via patch-clamp techniques in both mammalian mitoplasts and a reconstituted yeast system. The data indicate that the ability to alter mitochondrial permeability is a property of most, but not all, signal peptides. Furthermore, it is clear that, although signal peptides are characterized by positive charge and the ability to form amphiphilic alpha helices, these two characteristics are not sufficient to guarantee mitochondrial effects. Finally, the results reveal a strong correlation between peptide effects on the permeability of isolated mitochondria and on MCC activity: peptides that induced swelling of mouse and rat mitochondria also activated the quiescent MCC of mouse mitoplasts and induced flickering of active MCC reconstituted from yeast mitochondrial membranes. Moreover, relative peptide efficacies were very similar for mitochondrial swelling and both types of patch-clamp experiments. We propose that patch-clamp recordings of MCC activity and the high-amplitude swelling induced by signal peptides reflect the opening of a single channel. Based on the selective responsiveness of that channel to signal peptides and the dependence of its opening in isolated mitochondria on membrane potential, we further suggest that the channel is involved in the mitochondrial protein import process.

The role of low (< or = 1 mM) phosphate concentrations in regulation of mitochondrial permeability: modulation of matrix free Ca2+ concentration.

Under a variety of conditions, the permeability of the inner mitochondrial membrane to small solutes can be nonselectively increased. A classic mitochondrial permeability transition (MPT) was originally identified based on its dependence on matrix Ca2+ and its extreme sensitivity to cyclosporin A (CsA). It is now clear, however, that several additional and distinct processes can also produce increases in mitochondrial permeability. Both mitochondrial signal peptides (P. M. Sokolove and K. W. Kinnally, 1996, Arch. Biochem. Biophys. 336, 69-76) and butylated hydroxytoluene (BHT) (P. M. Sokolove and L. M. Haley, 1996, J. Bioenerg. Biomembr. 28, 199-206), for example, induce permeability increases that are relatively CsA insensitive and that persist in the presence of EGTA. Inorganic phosphate (Pi) appears to play a key role in each of these permeability increases. High (>1 mM) Pi levels facilitate the classic MPT, while Pi concentrations below 1 mM stimulate the permeability increase induced by signal peptides and inhibit that triggered by BHT. The effect of high Pi concentrations can most probably be explained by exchange of the anion for matrix ADP and the resulting alleviation of ADP-mediated inhibition of the MPT (R. G. Lapidus and P. M. Sokolove, 1994, J. Biol. Chem. 269, 18931-18936). In the experiments reported here, the mechanisms underlying the effects of low Pi concentrations on mitochondrial permeability were investigated, by monitoring mitochondrial volume, with the following results: (1) A hitherto unrecognized ability of Pi (<1 mM) to increase the lag preceding induction of the classic MPT by diamide, phenylarsine oxide, and t-butylhydroperoxide was identified. (2) Data were obtained suggesting that all of the effects of low Pi concentration, stimulation of signal peptide-induced swelling, blockade of BHT-induced swelling, and delay of the classic MPT, can be attributed to the capacity of the anion to complex Ca2+ in the mitochondrial matrix. (3) Differences in the responses of these three systems for enhancing mitochondrial permeability to experimental manipulation indicate that matrix Ca2+ plays more than one role in the regulation of mitochondrial permeability. An additional important finding is the observation that failure of EGTA to alter a mitochondrial process need not mean that the process is Ca2+ independent. In a multicompartment system, absence of EGTA action may instead reflect failure of the chelator to gain access to regulatory Ca2+.

A mitochondrial signal peptide from Neurospora crassa increases the permeability of isolated rat liver mitochondria.

Mitochondria that contain Ca2+ can be induced by a variety of triggering agents and conditions to undergo a permeability transition (PT); the inner membrane becomes nonselectively permeable to small solutes. Mastoparan, an amphipathic peptide from wasp venom, has recently been reported to induce this transition (Pfeiffer et al., 1995, J. Biol. Chem. 270,4923). We have examined the effect on the permeability of isolated rat liver mitochondria of a second amphipathic peptide, the signal sequence of cytochrome oxidase subunit IV from Neurospora crassa (pCoxIV, amino acids 3-22), which targets subunit IV to its mitochondrial location. Permeability increases were visualized via mitochondrial swelling with the following results. (1) pCoxIV (5-100 microM) induced concentration-dependent mitochondrial swelling. Control peptides from the N- and C-termini of the voltage-dependent anion-selective channel had no such effect. (2) Swelling required mitochondrial energization; it was eliminated or halted by the uncoupler carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone. (3) Peptide-induced swelling was slowed by increasing concentrations of KCl. (4) Swelling was enhanced by inorganic phosphate (<1 mM). (5) Trifluoperazine (50 microM), propranolol (0.5 mM), and dibucaine (0.5 mM) were potent inhibitors of peptide-induced swelling, whereas other inhibitors of the classical PT (cyclosporin A, EGTA, and ADP) inhibited only partially. (6) pCoxIV opened a pore rather than disrupting mitochondrial membrane structure, but 50% inhibition of peptide-induced swelling required polyethylene glycol of molecular weight substantially larger than that needed to inhibit the Ca2+-induced PT to the same extent. In summary, pCoxIV opens a pore in isolated mitochondria. The dependence of pore opening on membrane potential and the inhibition of the peptide-induced permeability increase by increasing salt concentration suggest that this effect of the signal peptide is related to its interactions with mitochondria during protein import. The peptide-induced pore appears, however, to be distinct from both the classical permeability transition pore and the mastoparan-induced permeability increase.

Induction of a permeability transition in rat kidney mitochondria by pentachlorobutadienyl cysteine: a beta-lyase-independent process.

A Ca2+-dependent inner mitochondrial membrane permeability transition is induced by a number of agents, an effect which is thought to cause cytotoxicity. This transition involves formation of a pore allowing the passage of solutes of up to 1500 Da; it is blocked by cyclosporine A and Ca2+ chelating agents. The mitochondrial nephrotoxicant S-(1,2,3,4, 4-pentachlorobutadienyl)-L-cysteine (PCBC) caused collapse of the mitochondrial membrane potential, Ca2+-independent oxidation of pyridine nucleotides and release of accumulated Ca2+ in isolated rat kidney mitochondria, three hallmarks of the permeability transition. These effects were blocked by cyclosporine A and by ethylene glycol bis(beta-aminoethyl ether) tetraacetic acid (EGTA). Furthermore, EGTA was capable of reversing the collapse of the membrane potential. These data indicate that PCBC induced an inner membrane permeability transition. Interestingly, addition of aminoxyacetic acid, a beta-lyase inhibitor, did not prevent the permeability transition, and a nonmetabolizable analog of PCBC, S-(1,2,3,4, 4-pentachlorobutadienyl)-L-alpha-methyl cysteine, induced the permeability transition. Thus PCBC may act to induce the permeability transition through a mechanism that does not require metabolism by a beta-lyase. Since metabolism by a beta-lyase is required for PCBC toxicity, it is not clear that the permeability transition is involved in cysteine conjugate-mediated renal cell injury.

Butylated hydroxytoluene and inorganic phosphate plus Ca2+ increase mitochondrial permeability via mutually exclusive mechanisms.

Mitochondria undergo a permeability transition (PT)2, i.e., become nonselectively permeable to small solutes, in response to a wide range of conditions/compounds. In general, opening of the permeability transition pore (PTP) is Ca2+- and P(i)-dependent and is blocked by cyclosporin A (CsA), trifluoperazine (TFP), ADP, and butylated hydroxytoluene (BHT). Gudz and coworkers have reported [7th European Bioenergetics Conference, EBEC Short Reports (1992) 7, 125], however, that, under some conditions, BHT increases mitochondrial permeability via a process that may not share all of these characteristics. Specifically, they determined that the BHT-induced permeability transition was independent of Ca2+ and was insensitive to CsA. We have used mitochondrial swelling to compare in greater detail the changes in permeability induced by BHT and by Ca2+ plus P(i) with the following results. (1) The dependence of permeability on BHT concentration is triphasic: there is a threshold BHT concentration (ca. 60 nmol BHT/ mg mitochondrial protein) below which no increase occurs; BHT enhances permeability in an intermediate concentration range; and at high BHT concentrations (>120 nmol/mg) permeability is again reduced. (2) The effects of BHT depend on the ratio of BHT to mitochondrial protein. (3) Concentrations of BHT too low to induce swelling block the PT induced by Ca2+ and P(i). (4) The dependence of the Ca2+-triggered PT on P(i) concentration is biphasic. Below a threshold of 50-100 mu M, no swelling occurs. Above this threshold swelling increases rapidly. (5) P(i) levels too low to support the Ca2+-induced PT inhibit BHT-induced swelling. (6) Swelling induced by BHT can be stimulated by agents and treatments that block the PT induced by Ca2+ plus P(i). These data suggest that BHT and Ca2+ plus P(i) increase mitochondrial permeability via two mutually exclusive mechanisms.

Opposite effects of metallothionein I and spermine on mitochondrial function.

Previously, we reported that the stress-induced protein metallothionein I (MT) modulated the oxygen consumption (VO2) of isolated rat liver mitochondria [Life Sci. 55 221-226, 1994]. We now present confirmation of this finding, and the additional observations that in rat liver mitochondria, MT caused swelling and depolarization. These actions of MT were inhibited by the aliphatic polyamine, spermine. Our findings suggest that mitochondrial function could be influenced by the balance between MT and spermine.

The reconstituted mitochondrial adenine nucleotide translocator: effects of lipid polymorphism.

This study investigates the role of polymorphic or nonbilayer lipids in the function of an integral membrane protein which is a key component of the mitochondrial energy transduction apparatus. The adenine nucleotide translocator (AdNT) has been isolated from rat heart mitochondria and reconstituted into ATP-containing liposomes composed of dioleoylphosphatidylcholine (DOPC), dioleoylphosphatidylethanolamine (DOPE), and cardiolipin (CL). CL content was held constant at 11.1 mol%; the ratio of DOPC:DOPE was varied to manipulate R0, the intrinsic radius of curvature of the bilayer [S. M. Gruner (1985) Proc. Natl. Acad. Sci. USA 82, 3665-3669]. Translocator activity was determined fluorometrically, using a coupled enzyme system to measure ADP-induced efflux of ATP. Specific activity was calculated based on the number of functional translocators in each preparation, quantified using the tight-binding inhibitor carboxyatractylate (CAT). AdNT specific activity was a smooth function of R0, with a maximum at a lipid composition similar to that of the inner mitochondrial membrane. Protein incorporation was constant at DOPC:DOPE ratios > 1, but appeared to increase at ratios < or = 1. The fraction of reconstituted AdNT incorporated in the native mitochondrial orientation, estimated from inhibition by 10 microM CAT, was independent of lipid composition and > 85%. Leakage of encapsulated ATP increased at low R0 values both in the presence and absence of protein.

Interactions of adriamycin aglycones with mitochondria may mediate adriamycin cardiotoxicity.

Adriamycin and related anthracyclines are potent oncolytic agents, the clinical utility of which is limited by severe cardiotoxicity. Aglycone metabolites of Adriamycin (5-20 microM) induce a Ca(2+)-dependent increase in the permeability of the inner mitochondrial membrane of both heart and liver mitochondria to small (< 1,500 Da) solutes; this phenomenon is accompanied by release of mitochondrial Ca2+, mitochondrial swelling, collapse of the membrane potential, oxidation of mitochondrial pyridine nucleotides [NAD(P)H], uncoupling, and a transition from the condensed to the orthodox conformation and is inhibited by ATP, dithiothreitol, the immunosuppressant cyclosporin A, and the ubiquitous polyamine spermine. Aglycones also modify mitochondrial sulfhydryl groups and induce a Ca2+ independent oxidation of mitochondrial NAD(P)H which appears to reflect electron transport from NADH to oxygen, mediated by the aglycones and resulting in the production of superoxide (O2-). Selenium deficiency and butylated hydroxytoluene inhibit aglycone-induced Ca2+ release from liver, but not heart, mitochondria, suggesting that the interactions of the aglycones with mitochondria differ in these two tissues. It can be proposed that the effects of Adriamycin aglycones on heart mitochondria are responsible for the cardiotoxicity of the parent drug.

The mitochondrial permeability transition. Interactions of spermine, ADP, and inorganic phosphate.

Mitochondria that have accumulated Ca2+ can be induced to undergo a permeability transition: the inner membrane becomes nonselectively permeable to small (< 1500 daltons) solutes. Our laboratory has recently identified the polyamine spermine as an inhibitor of the permeability transition of isolated rat heart and liver mitochondria. Here, we have used swelling of liver mitochondria as an indicator of transition occurrence to investigate the connection between spermine, another transition antagonist, ADP, and several key triggering agents: P(i), Ca2+, and t-butyl hydroperoxide (t-BH). Our results demonstrate that: 1) ADP strongly inhibits only the swelling induced by P(i); transitions induced by t-BH and Ca2+ are minimally affected. 2) The sensitivity of the permeability transition to P(i) is enhanced in mitochondria depleted of adenine nucleotides. 3) Incubation with P(i) decreases mitochondrial ADP and ATP content. 4) Spermine inhibits less well in adenine nucleotide-depleted than control mitochondria, regardless of triggering agent. 5) Spermine and ADP act synergistically to inhibit the transition. 6) ADP replenishment makes P(i) a worse triggering agent. Triggering by Ca2+ and t-BH is enhanced. 7) P(i) overcomes spermine inhibition; Ca2+ and t-BH do not. We propose that P(i) triggers the transition by lowering the matrix concentration of the inhibitor ADP and that spermine inhibits the transition by enhancing ADP effectiveness. In addition, these data clearly distinguish the triggering action of P(i) from that of Ca2+ and t-BH.

Spermine inhibition of the permeability transition of isolated rat liver mitochondria: an investigation of mechanism.

Mitochondria that have accumulated Ca2+ can be induced to undergo a permeability transition: the inner membrane becomes nonselectively permeable to small (< 1500 Da) solutes. The molecular mechanism(s) underlying this transition, which is Ca(2+)-dependent and cyclosporin A-sensitive, has yet to be clearly elucidated. Our laboratory has recently identified the polyamine spermine as an inhibitor of the permeability transition of isolated rat heart mitochondria. In this study, we have used spermine, in combination with a series of triggering agents, to clarify several mechanistic details of the transition process in isolated rat liver mitochondria. Mitochondrial swelling was monitored as an indicator of transition occurrence. Our results indicate that: (1) spermine inhibits the permeability transition of isolated rat liver mitochondria; (2) the sensitivity of the permeability transition of liver mitochondria to spermine is highly dependent on the ionic composition of the assay medium; (3) K+ interacts with a site outside the mitochondria to decrease spermine effectiveness; (4) spermine likewise acts at an external site; and (5) the Ca2+ uniporter in its inactive form is not the protein responsible for mediating the permeability transition.

Interaction of adriamycin aglycones with isolated mitochondria. Effect of selenium deficiency.

Adriamycin (AdM) aglycones have dramatic effects on isolated heart mitochondria, oxidizing pyridine nucleotides, modifying sulfhydryl groups, and triggering a permeability transition of the inner membrane that results in free passage of solutes smaller than 1500 Da. In this investigation, the role of glutathione (GSH) peroxidase in these actions of the aglycones was evaluated, by comparing mitochondria from selenium-deficient and selenium-supplemented rats, with the following results. Selenium deficiency was without effect on the permeability transition of heart mitochondria, followed via Ca2+ release and triggered by AdM aglycone or by t-butyl hydroperoxide (TBH) or H2O2, both of which are authentic substrates of the peroxidase. The permeability transition of liver mitochondria was delayed by selenium deficiency regardless of the triggering agent; however, substantial triggering by the aglycone and TBH persisted in mitochondria from selenium-deficient animals. Selenium deficiency inhibited thiol modification elicited by AdM aglycone and H2O2 in heart mitochondria and by the aglycone, TBH, and possibly H2O2 in liver mitochondria. It would thus appear that AdM aglycone, TBH, and H2O2 can induce the permeability transition of isolated heart mitochondria via a process (or processes) distinct from the catalytic activity of the peroxidase. Furthermore, even in liver, where involvement of the peroxidase is observed, mechanisms other than the GSH cycle can contribute to transition induction by the aglycone and by TBH. Finally, mitochondrial-SH group modification by the aglycones appeared not to be causally linked to induction of the permeability transition. This laboratory has suggested that the effects of aglycone metabolites of AdM on mitochondria mediate the cardiotoxicity that limits use of the parent drug. The data presented in this paper argue against the involvement of GSH peroxidase in that process. They are in agreement with in vivo studies, which have generally failed to find evidence for amelioration of AdM cardiotoxicity in selenium-deficient animals.

Use of carboxyatractylate and tight-binding inhibitor theory to determine the concentration of functional mitochondrial adenine nucleotide translocators in a reconstituted system.

The adenine nucleotide translocator (AdNT) has been isolated from rat heart mitochondria and reconstituted into liposomes containing ATP. Translocator activity was determined using a coupled enzyme system to measure the ADP-induced efflux of ATP from the liposomes. In order to determine specific activity, the number of functional translocators must also be known. Carboxyatractylate (CAT) is a highly selective inhibitor of the AdNT, with Ki < 10 nM, a value sufficiently low relative to the concentration of protein in transport assays to suggest the use of tight-binding inhibitor theory to quantify functional translocators. Ackermann-Potter plots of velocity vs proteoliposome concentration at several different CAT concentrations were used both to demonstrate the occurrence of tight-binding inhibition and to determine the concentration of AdNT catalytic sites in the native orientation. The results obtained agreed well with earlier reports based on [14C]CAT binding; functionally reconstituted AdNT represented 5-10% of the protein added to the system. Specific activities were ca. 7-10 mumol/min mg depending on the lipid composition of the liposomes. Unincorporated protein did not appreciably affect the measurements. This methodology should be readily applicable to any reconstituted systems for which high-affinity inhibitors which bind only to active protein are known.

Inhibition by spermine of the inner membrane permeability transition of isolated rat heart mitochondria.

The effect of spermine on the permeability transition of the inner mitochondrial membrane of isolated rat heart mitochondria was evaluated. The permeability transition was triggered using a series of agents (t-butyl hydroperoxide, phenylarsine oxide, carboxyatractylate, and elevated Ca2+ and inorganic phosphate concentrations), and was monitored via Ca(2+)-release, mitochondrial swelling and pyridine nucleotide oxidation. By all three criteria, spermine inhibited the transition. A C50 of 0.38 +/- 0.06 (SD) mM was measured for inhibition.

Duramycin effects on the structure and function of heart mitochondria. II. Energy conversion reactions.

The polypeptide antibiotic duramycin has been reported to interact selectively with phosphatidylethanolamine (PE) and monogalactosyldiacylglycerol (Navarro et al., 1985, Biochemistry 24, 4645-4650). PE is a major component of mitochondrial membranes. Duramycin was used to probe the role of PE in mitochondrial energy conversion reactions with the following results: (i) Duramycin uncoupled mitochondrial respiration, decreasing the respiratory control ratio to 1 at 5 microM. At concentrations of duramycin in excess of 10 microM, ADP addition inhibited electron transport. (ii) Duramycin inhibited oxidative phosphorylation (C50 less than 2 microM). (iii) Duramycin stimulated mitochondrial ATP hydrolysis modestly. The antibiotic was 7- to 16-fold less effective in this regard than concentrations of carbonylcyanide p-trifluoromethoxyphenylhydrazone (F-CCP) which produced comparable uncoupling. (iv) Duramycin inhibited uncoupled ATPase activity (C50 = 8 microM). Inhibition of the ATPase activity of intact mitochondria was blocked by 1 mM MgCl2 and 5 mM CaCl2; inhibition persisted in sub-mitochondrial particles assayed in the presence of 3 mM MgCl2. The effects on mitochondrial function of free fatty acids (FFA) and duramycin are similar in many respects. It is suggested that duramycin, like FFA, uncouples via a nonclassical mechanism, possibly by disrupting intramembrane H+ transfer between redox and ATPase complexes. In addition, interaction of duramycin, either direct or indirect, with the F0 moiety of the mitochondrial ATPase and with one or more components of the respiratory electron transport chain is proposed.

Oxidation of mitochondrial pyridine nucleotides by aglycone derivatives of adriamycin.

Adriamycin (AdM) and related anthracyclines are potent antineoplastic agents, the clinical utility of which is limited by severe cardiotoxicity. Aglycone derivatives of AdM have recently been reported to trigger the release of Ca2+ from isolated, preloaded rat heart mitochondria and to modify mitochondrial sulfhydryl (-SH) groups. Both mitochondrial Ca2+ retention and -SH status are sensitive to mitochondrial NAD(P)+/NAD(P)H ratios. This investigation examined the effects of AdM and its aglycone derivatives on the pyridine nucleotide redox status of isolated, intact heart mitochondria with the following results. (i) AdM aglycones induced the slow, Ca2(+)-independent oxidation of mitochondrial NAD(P)H. Oxidation was proportional to aglycone concentration between 5 and 60 microM. (ii) In terms of potency, 7-deoxy AdM aglycone greater than or equal to 7-hydroxy AdM aglycone much greater than AdM. (iii) Inhibitor data suggested that NAD(P)H oxidation reflects the rotenone-insensitive reduction of AdM aglycone and subsequent electron transfer to O2 generating superoxide. (iv) NAD(P)H oxidation mediated by AdM aglycone could be distinguished from the Ca2(+)-dependent NAD(P)H oxidation associated with mitochondrial Ca2+ release. This communication is the first to describe redox interactions of AdM with intact mitochondria.