The inhibition of phosphate entry into rat liver mitochondria by organic mercurials and by formaldehyde

The mitochondrial phosphate carrier: Role in oxidative metabolism, calcium handling and mitochondrial disease

The mitochondrial phosphate carrier (PiC) is a mitochondrial solute carrier protein, which is encoded by SLC25A3 in humans. PiC delivers phosphate, a key substrate of oxidative phosphorylation, across the inner mitochondrial membrane. This transport activity is also relevant for allowing effective mitochondrial calcium handling. Furthermore, PiC has also been described to affect cell survival mechanisms via interactions with cyclophilin D and the viral mitochondrial-localized inhibitor of apoptosis (vMIA). The significance of PiC has been supported by the recent discovery of a fatal human condition associated with PiC mutations. Here, we present first the early studies that lead to the discovery and molecular characterization of the PiC, then discuss the very recently developed mouse models for PiC and pathological mutations in the human SLC25A3 gene.

Involvement of the mitochondrial death pathway in chemopreventive benzyl isothiocyanate-induced apoptosis

In the present study, we studied the molecular mechanism underlying cell death induced by a cancer chemoprotective compound benzyl isothiocyanate (BITC). The cytotoxic effect of BITC was examined in rat liver epithelial RL34 cells. Apoptosis was induced when the cells were treated with 20 mum BITC, characterized by the appearance of phosphatidylserine on the outer surface of the plasma membrane and caspase-3 activation, whereas no caspase activation and propidium iodide incorporation into cell were detected with 50 mum BITC that induced necrosis. The mitochondrial death pathway was suggested to be involved in BITC-induced apoptosis because the treatment of cells with BITC-induced caspase-9-dependent apoptosis and mitochondrial transmembrane potential (Delta Psi m) alteration. We demonstrated here for the first time that BITC directly modifies mitochondrial functions, including inhibition of respiration, mitochondrial swelling, and release of cytochrome c. Moreover, glutathione depletion by diethyl maleate significantly accelerated BITC-triggered apoptosis, suggesting the involvement of a redox-dependent mechanism. This was also implicated by the observations that intracellular accumulation of reactive oxygen species, including superoxide (O(2)) and hydroperoxides (HPOs), was indeed detected in the cells treated with BITC and that the intracellular HPO level was significantly attenuated by pretreatment with N-acetylcysteine. The treatment with a pharmacological scavenger of O(2), Tiron, also diminished the HPO formation by approximately 80%, suggesting that most of the HPOs were H(2)O(2) derived from the dismutation of O(2). These results suggest that BITC induces apoptosis through a mitochondrial redox-sensitive mechanism.

Embryo toxicity and teratogenicity of formaldehyde

C-14 formaldehyde crosses the placenta and enters fetal tissues. The incorporated radioactivity is higher in fetal organs (i.e., brain and liver) than in maternal tissues. The incorporation mechanism has not been studied fully, but formaldehyde enters the single-carbon cycle and is incorporated as a methyl group into nucleic acids and proteins. Also, formaldehyde reacts chemically with organic compounds (e.g., deoxyribonucleic acid, nucleosides, nucleotides, proteins, amino acids) by addition and condensation reactions, thus forming adducts and deoxyribonucleic acid-protein crosslinks. The following questions must be addressed: What adducts (e.g., N-methyl amino acids) are formed in the blood following formaldehyde inhalation? What role do N-methyl-amino adducts play in alkylation of nuclear and mitochondrial deoxyribonucleic acid, as well as mitochondrial peroxidation? The fact that the free formaldehyde pool in blood is not affected following exposure to the chemical does not mean that formaldehyde is not involved in altering cell and deoxyribonucleic acid characteristics beyond the nasal cavity. The teratogenic effect of formaldehyde in the English literature has been sought, beginning on the 6th day of pregnancy (i.e., rodents) (Saillenfait AM, et al. Food Chem Toxicol 1989, pp 545-48; Martin WJ. Reprod Toxicol 1990, pp 237-39; Ulsamer AG, et al. Hazard Assessment of Chemicals; Academic Press, 1984, pp 337-400; and U.S. Department of Health and Human Services. Toxicological Profile of Formaldehyde; ATSDR, 1999 [references 1-4, respectively, herein]). The exposure regimen is critical and may account for the differences in outcomes. Pregnant rats were exposed (a) prior to mating, (b) during mating, (c) or during the entire gestation period. These regimens (a) increased embryo mortality; (b) increased fetal anomalies (i.e., cryptochordism and aberrant ossification centers); (c) decreased concentrations of ascorbic acid; and (d) caused abnormalities in enzymes of mitochondria, lysosomes, and the endoplasmic reticulum. The alterations in enzymatic activity persisted 4 mo following birth. In addition, formaldehyde caused metabolic acidosis, which was augmented by iron deficiency. Furthermore, newborns exposed to formaldehyde in utero had abnormal performances in open-field tests. Disparities in teratogenic effects of toxic chemicals are not unusual. For example, chlorpyrifos has not produced teratogenic effects in rats when mothers are exposed on days 6-15 (Katakura Y, et al. Br J Ind Med 1993, pp 176-82 [reference 5 herein]) of gestation (Breslin WJ, et al. Fund Appl Toxicol 1996, pp 119-30; and Hanley TR, et al. Toxicol Sci 2000, pp 100-08 [references 6 and 7, respectively, herein]). However, either changing the endpoints for measurement or exposing neonates during periods of neurogenesis (days 1-14 following birth) and during subsequent developmental periods produced adverse effects. These effects included neuroapoptosis, decreased deoxyribonucleic acid and ribonucleic acid synthesis, abnormalities in adenylyl cyclase cascade, and neurobehavioral effects (Johnson DE, et al. Brain Res Bull 1998, pp 143-47; Lassiter TL, et al. Toxicol Sci 1999, pp 92-100; Chakraborti TK, et al. Pharmacol Biochem Behav 1993, pp 219-24; Whitney KD, et al. Toxicol Appl Pharm 1995, pp 53-62; Chanda SM, et al. Pharmacol Biochem Behav 1996, pp 771-76; Dam K, et al. Devel Brain Res 1998, pp 39-45; Campbell CG, et al. Brain Res Bull 1997, pp 179-89; and Xong X, et al. Toxicol Appl Pharm 1997, pp 158-74 [references 8-15, respectively, herein]). Furthermore, the terata caused by thalidomide is a graphic human example in which the animal model and timing of exposure were key factors (Parman T, et al. Natl Med 1999, pp 582-85; and Brenner CA, et al. Mol Human Repro 1998, pp 887-92 [references 16 and 17, respectively, herein]). Thus, it appears that more sensitive endpoints (e.g., enzyme activity, generation of reactive oxygen species, timing of exposure) for the measurement of toxic effects of environmental agents on embryos, fetuses, and neonates are more coherent than are gross terata observations. The perinatal period from the end of organogenesis to the end of the neonatal period in humans approximates the 28th day of gestation to 4 wk postpartum. Therefore, researchers must investigate similar stages of development (e.g., neurogenesis occurs in the 3rd trimester in humans and neonatal days occur during days 1-14 in rats and mice, whereas guinea pigs behave more like humans). Finally, screening for teratogenic events should also include exposure of females before mating or shortly following mating. Such a regimen is fruitful inasmuch as environmental agents cause adverse effec

Acrolein inhibits respiration in isolated brain mitochondria

Lipid peroxidation is elevated in diseased regions of brain in several neurodegenerative diseases. Acrolein (2-propenal) is a major cytotoxic product of lipid peroxidation and its adduction to neuronal proteins has been demonstrated in diseased brain regions from patients with Alzheimer's disease. Mitochondrial abnormalities are implicated in several neurodegenerative disorders, and mitochondria are targets of alkenal adduction in vivo. We examined the effects of acrolein upon multiple endpoints associated with the mitochondrial involvement in neurodegenerative disease. Acrolein inhibited state 3 respiration with an IC(50) of approx. 0.4 micromol/mg protein; however, there was no reduction in activity of complexes I-V. This inhibition was prevented by glutathione and N-acetylcysteine. Acrolein did not alter mitochondrial calcium transporter activity or induce cytochrome c release. These studies indicate that acrolein is a potent inhibitor of brain mitochondrial respiration.

Calcium requirement and time course of capacitation of goat spermatozoa assessed by chlortetracycline assay

We standardized chlortetracycline fluorescent assay for studies of calcium requirement and time course of capacitation of goat spermatozoa. Three distinct fluorescent patterns were easily detected in goat spermatozoa incubated under capacitating conditions. Categorised according to nomenclature reported earlier, these are: 'F' with bright fluorescence in the postacrosomal region, characteristic of uncapacitated acrosomal-intact cells; 'B' with bright fluorescence on the anterior portion of the head and dark band in the postacrosomal region, characteristic of capacitated, acrosome-intact cells; 'AR' with lack of fluorescence on the head characteristic of acrosome-reacted cells. A close correspondence was observed when the results of CTC assay were compared with those obtained by transmission electron microscopy. Goat spermatozoa were not capacitated when calcium was omitted from the medium and 80% had CTC fluorescence of 'F' type. The size of 'B' cell population increased with increase in calcium concentration; at 1.0 mmol l-1 a peak representing 65-70% capacitated cells accumulated in 4 h. At higher concentrations, 'AR' cells were found along with 'B' cells and the two cell types were in equal proportions at 1.71 mmol l-1. Time course studies revealed a 2 h incubation period at 1.0 mmol l-1 and 1 h at 2 mmol l-1 calcium concentration before transformation of 'F' cells to 'B' cells was noticed. However, at no time were 'AR' cells found exclusively pointing to an equilibrium between the two sperm populations. Goat spermatozoa were also not capacitated when phosphate was omitted from the medium. Permeant anions (NO3-, SCN-), permeant weak acid (HCO3-) and organic phosphates (beta-glycerophosphate, glucose-6-phosphate) were unable to replace phosphate. The reason for their failure for the incidence of capacitation was traced to low uptake of calcium by goat spermatozoa. In the presence of phosphate, a 6-8-fold increase was measured over the calcium uptake when phosphate was omitted (2-4 nmol l-1 10(8) cells-1). Mersalyl inhibited the calcium uptake by goat spermatozoa as well as its capacitation most likely by inhibiting the calcium phosphate transporter located in the sperm plasma membrane.

Phosphate transport in mitochondria: past accomplishments, present problems, and future challenges

The requirement of inorganic phosphate (Pi) for oxidative phosphorylation in eukaryotic cells is fulfilled through specific Pi transport systems. The mitochondrial proton/phosphate symporter (Pic) is a membrane-embedded protein which translocates Pi from the cytosol into the mitochondrial matrix. Pic is responsible for the very rapid transport of most of the Pi used in ATP synthesis. During the past five years there have been advances on several fronts. Genomic and cDNA clones for yeast, bovine, rat, and human Pic have been isolated and sequenced. Functional expression of yeast Pic in yeast strains deficient in Pi transport and expression in Escherichia coli of a chimera protein involving Pic and ATP synthase alpha subunit have been accomplished. Pic, in contrast to other members of the family of transporters involved in energy metabolism, was demonstrated to have a presequence, which optimizes the import of the precursor protein into mitochondria. Six transmembrane segments appear to be a structural feature shared between Pic and other mitochondrial anion carriers, and recent-site directed mutagenesis studies implicate structure-functional relationships to bacteriorhodopsin. These recent advances on Pic will be assessed in light of a more global interpretation of transport mechanism across the inner mitochondrial membrane.

The mitochondrial aspartate/glutamate and ADP/ATP carrier switch from obligate counterexchange to unidirectional transport after modification by SH-reagents

The influence of various SH-reagents on the aspartate/glutamate carrier was investigated in the reconstituted system. When liposomes carrying partially purified carrier protein were treated with 5,5'-dithiobis(2-nitrobenzoic acid) or N-ethylmaleimide, antiport activity was strongly reduced. Several mercury compounds exerted a dual effect. They completely blocked the antiport and, in addition, induced an efflux pathway for internal aspartate. The maximum rate of this unidirectional flux was comparable to the original antiport activity. Induction of efflux always was coupled to inhibition of antiport. Efflux was neither due to unspecific leakage of proteoliposomes nor to a possible contamination by porin, but depended on active carrier protein, as elucidated by the sensitivity to proteinases and protein-modifying reagents. Besides efflux of aspartate, HgCl2 and mersalyl also induced a slow efflux of ATP from liposomes carrying coreconstituted aspartate/glutamate and ADP/ATP carrier. The two efflux activities could be discriminated taking advantage of the differential effectiveness of several inhibitors and proteinases. Although basic carrier properties were changed by the applied mercurials (Dierks, T., Salentin, A. and Krämer, R. (1990) Biochim. Biophys. Acta 1028, 281), aspartate and ATP efflux could clearly be correlated with the aspartate/glutamate and the ADP/ATP carrier, respectively. When purifying these two translocators the respective efflux activity copurified with the antiporter, thus elucidating that the two different transport functions are mediated by the same protein. These results argue for a participation of the aspartate/glutamate and the ADP/ATP carrier in the generally observed increase of mitochondrial permeability after treatment with SH-reagents.

Significance and redox state of SH groups in pyruvate carrier isolated from bovine heart mitochondria

The role and properties of -SH groups of purified pyruvate (monocarboxylate) carrier were investigated. After isolation, this protein has all -SH groups in the oxidized state. Upon reduction, the carrier can be labelled with eosin-5-maleimide. The shift in apparent Mr after the labelling points to the presence of at least two cysteine residues. Pyruvate uptake in the reconstituted system is inhibited by both permeable (eosin-5-maleimide at 1 mM concentration) and impermeable (mersalyl, p-chloromercuribenzoate) -SH group reagents. Phenylarsine oxide inhibits pyruvate transport only slightly (20%), but the inhibition is enhanced after preincubation with the substrate.

Interaction of phenylisothiocyanates with the mitochondrial phosphate carrier. I. Covalent modification and inhibition of phosphate transport

The effects of phenylisothiocyanate (PITC) and of the polar analogue p-sulfophenylisothiocyanate (p-sulfoPITC) on the phosphate carrier of bovine heart mitochondria have been investigated. Incubation of mitochondria with the two phenylisothiocyanates leads to inhibition of the phosphate carrier protein. The inhibition of phosphate transport by PITC is unaffected by the addition of dithioerythritol (DTE) or by variation of the pH. The inhibition by p-sulfoPITC is in part removed by DTE; the remaining inactivation of the phosphate carrier, which can be attributed to the reaction with NH2 groups, is temperature and pH-dependent. Inhibition of phosphate transport by both p-sulfoPITC and PITC depends on the time of incubation and the concentration of the inhibitor. Preincubation with mersalyl protects the carrier protein against the inactivation by p-sulfoPITC but not against PITC. Other SH reagents tested do not show any protective effect. It can thus be concluded that two types of lysine residues are essential for the activity of the phosphate carrier. Lysine(s) of the former type are located at the surface of the membrane and are topologically related to the functional SH groups of the protein. Lysine residue(s) of the latter type are buried in the hydrophobic phase of the membrane.

Transport mechanism for calcium and phosphate in ram spermatozoa

Calcium uptake into ejaculated ram spermatozoa is highly enhanced by the addition of extracellular phosphate. Under identical conditions, extracellular calcium stimulates the uptake of phosphate by the cells. Both calcium and phosphate uptake are comparably inhibited by the sulfhydryl reagent mersalyl. The I50 was found to be 6.36 and 10.14 nmol mersalyl per mg protein for phosphate and calcium uptake, respectively. Calcium uptake is inhibited by mersalyl whether phosphate is present or not. Extracellular fructose causes a 5-fold increase in calcium uptake. When fructose and phosphate are present in the cell's medium, there is an additive effect, which indicates that two independent systems are involved in calcium transport into the cell. Ruthenium red, which blocks Ca2+ transport into the mitochondria, causes 70% and 95% inhibition of calcium uptake in the absence or in the presence of fructose, respectively. Ruthenium red does not affect phosphate uptake unless calcium was present in the incubation medium. The stimulatory effect of fructose upon calcium uptake can be mimicked by L-lactate and can be inhibited by the glycolytic inhibitor 2-deoxyglucose. Fructose and L-lactate stimulate mitochondrial respiration in a comparable way. Oligomycin, which inhibits mitochondrial ATP synthesis, does not inhibit Ca2+ uptake. This indicates that ATP is not involved in the mechanism by which mitochondrial respiration stimulates Ca2+ uptake. The calcium channel blocker, verapamil, inhibits Ca2+ uptake in the presence or absence of extracellular phosphate. The phosphate-dependent calcium transport mechanism is more sensitive to verapamil than is the phosphate-independent transporter. In summary, the data indicate that the plasma membrane of mammalian spermatozoa contains a calcium/phosphate symporter, a phosphate-independent calcium carrier and a calcium-independent phosphate carrier.

Oxaloacetate and malate transport by plant mitochondria

The permeability of mitochondria from pea (Pisum sativum L. var Kleine Rheinländerin) leaves, etiolated pea shoots, and potato (Solanum tuberosum) tuber for malate, oxaloacetate, and other dicarboxylates was investigated by measurement of mitochondrial swelling in isoosmolar solutions of the above mentioned metabolites. For the sake of comparison, parallel experiments were also performed with rat liver mitochondria. Unlike the mammalian mitochondria, the plant mitochondria showed only little swelling in ammonium malate plus phosphate media but a dramatic increase of swelling on the addition of valinomycin. Similar results were obtained with oxaloacetate, maleate, fumarate, succinate, and malonate. n-Butylmalonate and phenylsuccinate, impermeant inhibitors of malate transport in mammalian mitochondria, had no marked inhibitory effect on valinomycin-dependent malate and oxaloacetate uptake of the plant mitochondria. The swelling of plant mitochondria in malate plus valinomycin was strongly inhibited by oxaloacetate, at a concentration ratio of oxaloacetate/malate of 10(-3). From these findings it is concluded: (a) In a malate-oxaloacetate shuttle transferring redox equivalents from the mitochondrial matrix to the cytosol, malate and oxaloacetate are each transported by electrogenic uniport, probably linked to each other for the sake of charge compensation. (b) The transport of malate between the mitochondrial matrix and the cytosol is controlled by the oxaloacetate level in such a way that a redox gradient can be maintained between the NADH/NAD systems in the matrix and the cytosol. (c) The malate-oxaloacetate shuttle functions mainly in the export of malate from the mitochondria, whereas the import of malate as a respiratory substrate may proceed by the classical malate-phosphate antiport.

Functional changes in mitochondrial properties as a result of their membrane cryodestruction. I. Influence of freezing and thawing on succinate-ferricyanide reductase of intact liver mitochondria

The interaction of the succinate dehydrogenase complex of rat liver mitochondria with an artificial electron acceptor (K3Fe(CN)6), impermeable to the mitochondrial membrane as an index of a cryoinjury is investigated. It is shown that the freeze-thawing stimulates succinate-ferricyanide reductase (SFCR) activity of intact mitochondria. The increase of the freezing and thawing rates leads to a decrease in the released SFCR activity. The released SFCR activity after low-temperature treatment is a consequence of a nonspecific change in membrane ferricyanide permeability. The released SFCR activity decreases as the freezing and thawing rates increase.

Reactivity of the sulphydryl groups of the mitochondrial phosphate carrier

The rate of reaction of - SH groups of the mitochondrial phosphate carrier with 5,5'-dithiobis(2-nitrobenzoic acid) (Nbs2) and N-ethylmaleimide (MalNEt) was followed by measuring the inhibition of phosphate transport. The changes in the rate of reaction caused by alterations of the ionic composition of the matrix were compared with changes of the total intramitochondrial phosphate content, the intramitochondrial K+ content and the value of intramitochondrial pH. The ionic composition was manipulated by addition of valinomycin to non-respiring or to respiring mitochondria and by addition of inorganic phosphate to respiring and non-respiring mitochondria. From all these variables it was the changes of the intramitochondrial pH which correlated with the - SH group reactivity. Internal acidification decreased and internal alkalinization increased the rate of reaction of mitochondrial phosphate carrier with both Nbs2 and MalNEt. Nbs2 did not penetrate the inner mitochondrial membrane as assayed by determination of the acid-soluble thiol content of the matrix. From this fact it follows that the Nbs2-reactive SH groups of the carrier were accessible from the outer surface of the inner membrane in our experiments. It is concluded that intramitochondrial pH modifies the reactivity of the externally oriented - SH groups indirectly. A hypothesis is presented according to which protonation and deprotonation of the carrier molecule on the inner side could induce a conformational change of the whole protein altering also the microenvironment of the - SH groups near the opposite surface.

Phosphate carrier of liver mitochondria: the reaction of its SH groups with mersalyl, 5,5'-dithio-bis-nitrobenzoate, and N-ethylmaleimide and the modulation of reactivity by the energy state of the mitochondria

The inhibitory effect of three SH reagents, mersalyl, 5,5'-dithio-bis-nitrobenzoate, and N-ethylmaleimide, on Pi transport in rat liver mitochondria was investigated under a variety of conditions. Mersalyl binds at room temperature with both high (Kd less than 10 microM) and low affinity to mitochondria. Inhibition of Pi transport by mersalyl goes in parallel with titration of the high-affinity sites, inhibition being complete when 3.5-4.5 nmol/mg protein is bound to the mitochondria. At concentrations of mersalyl equal to or higher than 10 microM, inhibition of Pi transport occurs in less than 10 sec. At concentrations of mersalyl lower than 10 microM, the rate of reaction with the Pi carrier is considerably decreased. At a concentration of 100 microM, 5,5'-dithio-bis-nitrobenzoate fully inhibits Pi transport in about 1 min at room temperature. Nearly total inhibition is attained when as little as 40-50 pmol/mg is bound to mitochondria. Upon incubation longer than 1 min, additional SH groups, not belonging to the Pi carrier, begin to react. The uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone decreases the rate of reaction of mersalyl, 5,5'-dithio-bis-nitrobenzoate, and N-ethylmaleimide with the Pi carrier. Preincubation with Pi has a similar effect. We propose that both carbonyl cyanide p-trifluoromethoxyphenylhydrazone and Pi act by increasing the acidity of the mitochondrial matrix. Protonation of the Pi carrier at the matrix side would change the accessibility of its SH groups at the outer surface of the inner membrane. This might correspond to a membrane-Bohr effect, possibly related to the opening of a gating pore in the Pi carrier.

Effect of an anti-tumor platinum complex, Pt(II) diaminotoluene, on mitochondrial membrane properties

The effects of platinum complexes, selected for their potent anti-tumor activities, have been studied on rat liver mitochondria. Among the mitochondrial properties which have been studied, the most marked effects of platinum complexes were obtained on functions linked to the inner membrane. cis-Pt(II)(3,4-diaminotoluene) dichloride is shown to stimulate state 4 respiration. It inhibits the phosphate transport into mitochondria, decreases the accumulation of Ca2+, and induces a more rapid release of the accumulated Ca2+. A release of Mg2+ from mitochondria incubated in the absence of added divalent cations, and an efflux of divalent cations from mitochondrial membranes are also observed. All these results indicate a profound modification of the of the permeability of mitochondrial membrane.

The isolation of mitochondria from dipteran flight muscle

Procedures for the isolation of mitochondria from dipteran flight muscle have been investigated in an attempt to determine the extent and to identify the causes of deterioration associated with isolation. In the light of the results obtained isolation procedures have been improved by minimising mechanical damage, avoiding the development of anoxic conditions, and by the use of an isolation medium of a more physiological nature, containing the potassium salt of an organic anion as the principal osmoeffector, phosphate as the principal buffer, and low concentrations of free Mg2+. The oxidative capacity of mitochondria isolated by the improved method is adequate to support the in vivo requirements of the flight system.

Effect of long-chain fatty acids and acyl-CoA on mitochondrial permeability, transport, and energy-coupling processes

The following effects of fatty acids and acyl-CoA thioesters on energy metabolism of mitochondria can now be assumed: (1) Inhibition of adenine nucleotide translocation. This effect may increase the energy state of mitochondria respiring under state 3 conditions and decrease phosphorylation potential in the surrounding medium (the cytoplasm). (2) Increased permeability to monovalent cations. This may lead to a partial energy dissipation due to a futile recycling of K+ (or another cation), namely and energy-dependent uptake and a passive outflow. (3) True uncoupling due to increased permeability to protons. This effect probably occurs at high concentrations of fatty acids only. (4) Substrate effect. Fatty acids in the form of acyl-CoA are excellent respiratory substrates for mitochondria of most tissues. Their oxidation is coupled to the generation of high energy state of the mitochondrial membrane and, consequently, to ATP synthesis.

A kinetic study of mitochondrial calcium transport

This report describes a kinetic analysis of energy-linked Ca2+ transport in rat liver mitochondria, in which a ruthenium red/EGTA [ethanedioxy-bis(ethylamine)-tetraacetic acid] quenching technique has been used to measure rates of 45Ca2+ transport. Accurately known concentrations of free 45Ca2+ were generated with Ca2+/nitrilotriacetic acids buffers for the determination of substrate/velocity relationships. The results show that the initial velocity of transport is a sigmoidal function of Ca2+ concentration (Hill coefficient = 1.7), the Km being 4 muM Ca4 at 0 degrees C and pH 7.4. These values for the Hill coefficient and the Km remain constant in the presence of up to 2 mM phosphate, but with 10 mM acetate both parameters are increased slightly. Both permeant acids increase the maximum velocity to an extent dependent on their concentration. The Ca2+-binding site(s) of the carrier contains a group ionizing at pH approximately 7.5 at 0 degrees C, which is functional in the dissociated state. The stimulatory effect of permeant acids is ascribed to their facilitating the release of Ca2+ from the carrier to the internal phase, an interpretation which is strengthened by the lack of effect of the permeant anion SCN- on Ca2+ transport. Studies on the time-course of Ca2+ uptake and of EFTA-induced Ca2+ efflux from pre-loaded mitochondria demonstrate the reversibility of the carrier in respiring mitochondria and the extent to which this property is influenced by permeant acids. These data are accommodated in a carrier mechanism based on electrophoretic transport of Ca2+ bound to pairs of interacting acidic sites.

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. Mg-2+ 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.

The transport of sulphate and sulphite in rat liver mitochondria

1. The mechanism of sulphite and sulphate permeation into rat liver mitochondria was investigated. 2. Extramitochondrial sulphite and sulphate elicit efflux of intramitochondrial phosphate, malate, succinate and malonate. The sulphate-dependent effluxes and the sulphite-dependent efflux of dicarboxylate anions are inhibited by butylmalonate, phenylsuccinate and mersalyl. Inhibition of the phosphate efflux produced by sulphite is caused by mersalyl alone and by N-ethylmaleimide and butylmalonate when present together. 3. External sulphite and sulphate cause efflux of intramitochondrial sulphate, and this is inhibited by butylmalonate, phenylsuccinate and mersalyl. 4. External sulphite and sulphate do not cause efflux of oxoglutarate or citrate. 5. Mitochondria swell when suspended in an iso-osmotic solution of ammonium sulphite; this is not inhibited by N-ethylmaleimide or mersalyl. 6. Low concentrations of sulphite, but not sulphate, produce mitochondrial swelling in iso-osmotic solutions of ammonium malate, succinate, malonate, sulphate, or phosphate in the presence of N-ethylmaleimide. 7. It is concluded that both sulphite and sulphate may be transported by the dicarboxylate carrier of rat liver mitochondria and also that sulphite may permeate by an additional mechanism; the latter may involve the permeation of sulphurous acid or SO(2) or an exchange of the sulphite anion for hydroxyl ion(s).