The mitochondrial inner membrane anion channel. Regulation by divalent cations and protons

It is now well established that incubation of mitochondria at pH 8 or higher opens up an electrophoretic anion transport pathway in the inner membrane. It is not known, however, whether this transport process has any physiological relevance. In this communication we demonstrate that anion uniport can take place at physiological pH if the mitochondria are depleted of matrix divalent cations with A23187 and EDTA. Using the light-scattering technique we have quantitated the rates of uniport of a wide variety of anions. Inorganic anions such as Cl-, SO4(2-), and Fe(CN)6(4-) as well as physiologically important anions such as HCO3-, Pi-, citrate, and malate are transported. Some anions, however, such as gluconate and glucuronate do not appear to be transported. On the basis of the finding that the rate of anion uniport assayed in ammonium salts exhibits a dramatic decline associated with loss of matrix K+ via K+/H+ antiport, we suggest that anion uniport is inhibited by matrix protons. Direct inhibition of anion uniport by protons in divalent cation-depleted mitochondria is demonstrated, and the apparent pK of the binding site is shown to be about 7.8. From these properties we tentatively conclude that anion uniport induced by divalent cation depletion and that induced by elevated pH are catalyzed by the same transport pathway, which is regulated by both matrix H+ and Mg2+.     

Anion uniport in plant mitochondria is mediated by a Mg(2+)-insensitive inner membrane anion channel.

It has long been established that the inner membrane of plant mitochondria is permeable to Cl-. Evidence has also accumulated which suggests that a number of other anions such as Pi and dicarboxylates can also be transported electrophoretically. In this paper, we present evidence that anion uniport in plant mitochondria is mediated via a pH-regulated channel related to the so-called inner membrane anion channel (IMAC) of animal mitochondria. Like IMAC, the channel in potato mitochondria transports a wide variety of anions including NO3-, Cl-, ferrocyanide, 1,2,3-benzene-tricarboxylate, malonate, Pi, alpha-ketoglutarate, malate, adipate, and glucuronate. In the presence of nigericin, anion uniport is sensitive to the medium pH (pIC50 = 7.60, Hill coefficient = 2). In the absence of nigericin, transport rates are much lower and much less sensitive to pH, suggesting that matrix H+ inhibit anion uniport. This conclusion is supported by measurements of H+ flux which reveal that "activation" of anion transport at high pH by nigericin and at low pH by respiration is associated with an efflux of matrix H+. Other inhibitors of IMAC which are found to block anion uniport in potato mitochondria include propranolol (IC50 = 14 microM, Hill coefficient = 1.28), tributyltin (IC50 = 4 nmol/mg, Hill coefficient = 2.0), and the nucleotide analogs Erythrosin B and Cibacron Blue 3GA. The channel in plant mitochondria differs from IMAC in that it is not inhibited by matrix Mg2+, mercurials, or N,N'-dicyclohexylcarbodiimide. The lack of inhibition by Mg2+ suggests that the physiological regulation of the plant channel may differ from IMAC and that the plant IMAC may have functions such as a role in the malate/oxaloacetate shuttle in addition to its proposed role in volume homeostasis.     

On the regulation of the mitochondrial inner membrane anion channel by magnesium and protons

The inner membrane of mitochondria possesses a pH-regulated anion uniporter which is activated by depletion of matrix divalent cations with A23187 (Beavis, A. D., and Garlid, K. D. (1987) J. Biol. Chem. 262, 15085-15093). It is now shown that Cl- transport through this pathway is inhibited by Mg2+ and Ca2+. There appear to be two sites for inhibition by Mg2+. One has an IC50 = 38 microM at pH 7.4 and appears to be on the inside since it is only observed in the presence of A23187 (10 nmol/mg). The other has an IC50 = 440 microM at pH 7.4 and appears to be on the outside since it is observed in mitochondria pretreated with very low doses of A23187 (0.25 nmol/mg or less) and in A23187-pretreated mitochondria washed to remove A23187. Ca2+ is found to inhibit anion uniport in the presence or absence of A23187 with an IC50 of about 17 microM. In contrast to these findings Cl- uniport, activated by addition of valinomycin to respiring mitochondria without depleting endogenous Mg2+ is found to be very insensitive to exogenous Mg2+, being inhibited with an IC50 of 3.2 mM. This is explained by examination of the pH dependence of the Mg2+ IC50 in non-respiring mitochondria. The internal IC50 is found to be pH-dependent, rising to about 250 microM at pH 8.4. The external IC50 is also pH-dependent, rising to 2.5 mM or above at pH 8.4. These data are consistent with a model in which Mg2+ can only bind to the protein when it is protonated at a site with a pK of about 6.8 located in the matrix. Thus, both the intrinsic activity of the uniporter and its inhibition by Mg2+ appear to be regulated by matrix protons. This makes the rate of anion uniport much more sensitive to changes in matrix pH which is physiologically advantageous for its proposed role in volume homeostasis.     

pH dependence of phosphate transport across the red blood cell membrane after modification by dansyl chloride

Dansylation of the red blood cell membrane inhibits monovalent anion transport as measured by means of 36C1 and enhances divalent anion transport as measured by means of 35SO4 (Legrum, Fasold and Passow (1980) Hoppe-Seyler's Z. Physiol. Chem. 361, 1573-1590 and Lepke and Passow (1982) J. Physiol. (London) 328, 27-48). In the present work the effect of dansylation on phosphate equilibrium exchange was studied over the pH range where the ratio between monovalent and divalent phosphate anions varies. At high pH, phosphate equilibrium exchange was enhanced; at low pH, exchange was inhibited. The pH maximum of phosphate equilibrium exchange, seen at pH 6.3 in untreated ghosts is now replaced by a plateau. The inverse effects of dansylation on the rates of exchange at high and low pH suggest that both monovalent and divalent phosphate anions are accepted as substrates by the anion transport protein. A tentative attempt to obtain a quantitative estimate of the ratio of monovalent and divalent phosphate transport indicates that in the untreated red cell membrane over the pH range 7.2-8.5 the transport of HPO42- is negligible compared to the transport of H2PO4-.     

On the inhibition of the mitochondrial inner membrane anion uniporter by cationic amphiphiles and other drugs

Depleting the mitochondrial matrix of divalent cations with the ionophore A23187 activates a pH-sensitive, anion uniport pathway which can transport many anions normally regarded as impermeant (Beavis, A. D., and Garlid, K. D. (1987) J. Biol. Chem. 262, 15085-15093). Addition of valinomycin to respiring mitochondria can also induce the uptake of a wide variety of anions; however, the mechanism of anion transport during this "respiration-induced" swelling is less certain. In this paper, I demonstrate that both of these processes are inhibited by a variety of cationic amphiphiles including propranolol, quinine, amiodarone, imipramine and amitriptyline, and the benzodiazepine R05-4864. Although the IC50 values for the two processes are not equal, the ratio of IC50 values for the two processes appears to be the same for all drugs. Measurements of net transmembrane proton fluxes that occur during the assays reveal that respiration-induced swelling is associated with extensive proton ejection, the peak of which coincides with the maximum rate of anion transport. Moreover, from measurements of matrix buffering power, it is estimated that the matrix pH is 3 units more alkaline during respiration-induced swelling than during A23187-induced swelling. It is also shown that the IC50 for A23187-induced transport is pH-dependent in a manner consistent with modulation of drug binding by protonation of two sites. These findings allow the difference in IC50 values for the two types of assay to be explained by the pH dependence of the binding constant for the drug. Furthermore, the pH gradient generated during respiration-induced swelling is so large that the electrical component of the proton-motive force will be negligible. Thus, despite the fact that the mitochondria are "energized," rapid electrophoretic anion influx is possible. These data provide evidence that the transport of anions in these two types of assay occurs via the same pathway.     

Evidence for three different electrophoretic pathways in yeast mitochondria: Ion specificity and inhibitor sensitivity

We identified three electrophoretic pathways by spectrophotometrically following the swelling of isolated yeast mitochondria:

Evidence for more than one Ca2+ transport mechanism in mitochondria.

The active transport and internal binding of the Ca2+ analogue Mn2+ by rat liver mitochondria were monitored with electron paramagnetic resonance. The binding of transported Mn2+ depended strongly on internal pH over the range 7.7-8.9. Gradients of free Mn2+ were compared with K+ gradients measured on valinomycin-treated samples. In the steady state, the electrochemical Mn2+ activity was larger outside than inside the mitochondria. The observed gradients of free Mn2+ and of H+ could not be explained by a single "passive" uniport or antiport mechanism of divalent cation transport. This conclusion was further substantiated by observed changes in steady-state Ca2+ and Mn2+ distributions induced by La3+ and ruthenium red. Ruthenium red reduced total Ca2+ or Mn2+ uptake, and both inhibitors caused release of divalent cation from preloaded mitochondria. A model is proposed in which divalent cations are transported by at least two mechanisms: (1) a passive uniport and (2) and active pump, cation antiport or anion symport. The former is more sensitive to La3+ and ruthenium red. Under energized steady-state conditions, the net flux of Ca2+ or Mn2+ is inward over (1) and outward over (2). The need for more than one transport system inregulating cytoplasmic Ca2+ is discussed.     

Plant inner membrane anion channel (PIMAC) function in plant mitochondria

To date, the existence of the plant inner membrane anion channel (PIMAC) has been shown only in potato mitochondria, but its physiological role remains unclear. In this study, by means of swelling experiments in K(+) and ammonium salts, we characterize a PIMAC-like anion-conducting pathway in mitochondria from durum wheat (DWM), a monocotyledonous species phylogenetically far from potato. DWM were investigated since they possess a very active potassium channel (PmitoK(ATP)), so implying a very active matching anion uniport pathway and, possibly, a coordinated function. As in potato mitochondria, the electrophoretic uptake of chloride and succinate was inhibited by matrix [H(+)], propranolol, and tributyltin, and was insensitive to Mg(2+), N,N'-dicyclohexylcarbodiimide (DCCD) and mercurials, thus showing PIMAC's existence in DWM. PIMAC actively transports dicarboxylates, oxodicarboxylates, tricarboxylates and Pi. Interestingly, a novel mechanism of swelling in ammonium salts of isolated plant mitochondria is reported, based on electrophoretic anion uptake via PIMAC and ammonium uniport via PmitoK(ATP). PIMAC is inhibited by physiological compounds, such as ATP and free fatty acids, by high electrical membrane potential (Delta Psi), but not by acyl-CoAs or reactive oxygen species. PIMAC was found to cooperate with dicarboxylate carrier by allowing succinate uptake that triggers succinate/malate exchange in isolated DWM. Similar results were obtained using mitochondria from the dicotyledonous species topinambur, so suggesting generalization of results. We propose that PIMAC is normally inactive in vivo due to ATP and Delta Psi inhibition, but activation may occur in mitochondria de-energized by PmitoK(ATP) (or other dissipative systems) to replace or integrate the operation of classical anion carriers.     

Anion exchange in oxyntic cell apical membrane: Relationship to thiocyanate inhibition of acid secretion

The effects of SCN- on H+-accumulation by inside-out gastric vesicles derived from the apical membrane of secreting oxyntic cells are reported. SCN- inhibited the formation of pH gradients in Cl- and isethionate media. In Cl-, the concentration of SCN- required to achieve a certain degree of inhibition of H+ uptake (or dissipation of performed gradients) was increased with the increase in Cl- concentration, indicating some competitive phenomena between these anions. Comparison of the rates of dissipation of similar pH gradients achieved in Cl- vs. isethionate suggested the existence of a fast Cl-/SCN- exchange. In addition, direct isotopic fluxes confirmed the existence of rapid anion exchange and K-salt transport for both Cl- and SCN-. The rates of anion-exchange and K-salt transport were of similar magnitude, and the rates for SCN- in either countertransport against Cl- or cotransport with K+ were twice as fast as the equivalent values for Cl-. These mediated pathways in the apical membrane provide the possible means for rapid access of SCN- to the acidic canalicular spaces of the oxyntic cell that is implicit in recent proposals to explain SCN- inhibition of gastric HCl secretion.     

Triorganotins inhibit the mitochondrial inner membrane anion channel.

The inner membrane of liver and heart mitochondria possesses an anion uniport pathway, known as the inner membrane anion channel (IMAC). IMAC is inhibited by matrix Mg2+, matrix H+, N,N'-dicyclohexycarbodiimide, mercurials and amphiphilic amines such as propranolol. Most of these agents react with a number of different mitochondrial proteins and, therefore, more selective inhibitors have been sought. In this paper, we report the discovery of a new class of inhibitors, triorganotin compounds, which block IMAC completely. One of the most potent, tributyltin (TBT) inhibits malonate uniport via IMAC 95% at 0.9 nmol/mg. The only other mitochondrial protein reported to react with triorganotins, the F1F0ATPase, is inhibited by about 0.75 nmol/mg. The potency of inhibition of IMAC increases with hydrophobicity in the sequence trimethyltin much less than triethyltin much less than tripropyltin less than triphenyltin less than tributyltin; which suggests that the binding site is accessible from the lipid bilayer. It has long been established that triorganotins are anionophores able to catalyze Cl-/OH- exchange; however, TBT is able to inhibit Cl- and NO3- transport via IMAC at doses below those required to catalyze rapid rates of Cl-/OH- exchange. Consistent with previous reports, the data indicate that about 0.8 nmol of TBT per mg of mitochondrial protein is tightly bound and not available to mediate Cl-/OH- exchange. We have also shown that the mercurials, p-chloromercuribenzene sulfonate and mersalyl, which only partially inhibit Cl- and NO3- transport can increase the IC50 for TBT 10-fold. This effect appears to result from a reaction at a previously unidentified mercurial reactive site. The inhibitory dose is also increased by raising the pH and inhibition by TBT can be reversed by S2- and dithiols but not by monothiols.     

Evidence for the existence of an inner membrane anion channel in mitochondria

Mitochondria normally exhibit very low electrophoretic permeabilities to physiologically important anions such as chloride, bicarbonate, phosphate, succinate, citrate, etc. Nevertheless, considerable evidence has accumulated which suggests that heart and liver mitochondria contain a specific anion-conducting channel. In this review, a postulated inner membrane anion channel is discussed in the context of other known pathways for anion transport in mitochondria. This anion channel exhibits the following properties. It is anion-selective and inhibited physiologically by protons and magnesium ions. It is inhibited reversibly by quinine and irreversibly by dicyclohexylcarbodiimide. We propose that the inner membrane anion channel is formed by inner membrane proteins and that this pathway is normally latent due to regulation by matrix Mg2+. The physiological role of the anion channel is unknown; however, this pathway is well designed to enable mitochondria to restore their normal volume following pathological swelling. In addition, the inner membrane anion channel provides a potential futile cycle for regulated non-shivering thermogenesis and may be important in controlled energy dissipation.     

Interaction of mitochondrial phosphate carrier with fatty acids and hydrophobic phosphate analogs

Mitochondrial transporters, in particular uncoupling proteins and the ADP/ATP carrier, are known to mediate uniport of anionic fatty acids (FAs), allowing FA cycling which is completed by the passive movement of FAs across the membrane in their protonated form. This study investigated the ability of the mitochondrial phosphate carrier to catalyze such a mechanism and, furthermore, how this putative activity is related to the previously observed HgCl(2)-induced uniport mode. The yeast mitochondrial phosphate carrier was expressed in Escherichia coli and then reconstituted into lipid vesicles. The FA-induced H(+) uniport or Cl(-) uniport were monitored fluorometrically after HgCl(2) addition. These transport activities were further characterized by testing various inhibitors of the two different transport modes. The phosphate carrier was found to mediate FA cycling, which led to H(+) efflux in proteoliposomes. This activity was insensitive to ATP, mersalyl or N-ethylmaleimide and was inhibited by methylenediphosphonate and iminodi(methylenephosphonate), which are new inhibitors of mitochondrial phosphate transport. Also, the HgCl(2) induced Cl(-) uniport mediated by the reconstituted yeast PIC, was found to be inhibited by these reagents. Both methylenediphosphonate and iminodi(methylenephosphonate) blocked unidirectional Cl(-) uptake, whereas Cl(-) efflux was inhibited by iminodi(methylenephosphonate) and phosphonoformic acid only. These results suggest that a hydrophobic domain, interacting with FAs, exists in the mitochondrial phosphate carrier, which is distinct from the phosphate transport pathway. This domain allows for FA anion uniport via the phosphate carrier and consequently, FA cycling that should lead to uncoupling in mitochondria. This might be considered as a side function of this carrier.     

The pho-controlled outer membrane porin PhoE does not contain specific binding sites for phosphate or polyphosphates

Purified PhoE-porins were reconstituted into black lipid bilayer membranes, and the selectivity and size of the reconstituted pores were determined. Addition of polyphosphates influenced the internal charge situation of the pore resulting in a shift from anion to cation selectivity. However, the pore size as judged from single channel conductances was not influenced by the addition of polyphosphates. A strong inhibition of the pore conductance only occurred when Mg2+ was also present in the aqueous phase. The inhibition of the pore function is presumably caused by the formation of a chelate between the divalent cation and the polyphosphate. Nevertheless, neither this inhibition nor the selectivity shift are specific to phosphate, because both effects can be mimicked by other polyvalent anions such as citrate. Inhibition of the PhoE pore function by polyphosphate in in vivo experiments confirmed the results of in vitro experiments that polyphosphate is only able to affect the permeability of the outer membrane toward beta-lactam antibiotics if Mg2+ is present. The outcome of the in vivo and the in vitro experiments are consistent with the assumption that the PhoE-porins do not contain a specific binding site for phosphate or polyphosphates but are anion selective because of an excess of positively charged amino acids inside or at the surface of the pore.     

New insights into mechanisms of anion uniport through the uncoupling protein of brown adipose tissue mitochondria.

GDP-sensitive Cl- uniport is a widely studied property of the uncoupling protein of brown adipose tissue mitochondria; nevertheless, little is known about its mechanism and there is even controversy over whether this protein transports Cl-. Using a fluorescent probe assay, we have demonstrated non-ohmic, electrophoretic, GDP-sensitive Cl- uniport into proteoliposomes reconstituted with purified uncoupler protein. We have also identified a large number of new anionic substrates for this porter that also inhibit Cl- uniport competitively. Anion transport, its inhibition by GDP and anion inhibition of Cl- uniport are all strongly dependent on anion hydrophobicity. These surprising results are consequential for hypotheses of common transport mechanisms in the gene family of mitochondrial anion porters.     

Regulation of pancreatic islet-cell plasma membrane Ca2+ + Mg2+-ATPase by Calmodulin

The carboxyl group reagent dicyclohexylcarbodiimide inhibits the electrogenic entry of Cl^? and NO₃^? into rat liver mitochondria at alkaline pH. The inhibition is time dependent and 50% inhibition is obtained by the addition of 3–4 nmol DCCD/mg protein. The blockage of the pH-dependent anion-conducting pore appears to be unrelated to the other known actions of DCCD on rat liver mitochondria but seems similar to its effect on the uncoupling protein of brown adipose tissue.     

Interactions between diphtheria toxin entry and anion transport in Vero cells. IV. Evidence that entry of diphtheria toxin is dependent on efficient anion transport

Entry of prebound diphtheria toxin at low pH occurred rapidly in the presence of isotonic NaCl, NaBr, NaSCN, NaI, and NaNO3, but not in the presence of Na2SO4, 2-(N-morpholino)ethanesulfonic acid neutralized with Tris, or in buffer osmotically balanced with mannitol. SCN- was the most efficient anion to facilitate entry. Uptake studies with radioactively labeled anions showed that SCN- was transported into cells 3 times faster than Cl-, while the entry of SO2-4 occurred much more slowly. The anion transport inhibitors 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid and piretanide inhibited entry at low pH even in the presence of permeant anions. When cells with bound toxin were exposed to low pH in the absence of permeant anions, then briefly exposed to neutral pH and subsequently exposed to pH 4.5 in the presence of isotonic NaCl, toxin entry was induced. The data indicate that efficient anion transport at the time of exposure to low pH is required for entry of surface-bound diphtheria toxin into the cytosol. Since insertion of diphtheria toxin into the membrane occurs even in the absence of permeant anions, the results indicate that low pH is required not only for insertion of fragment B into the membrane, but also for the subsequent entry of fragment A into the cytosol.     

Respiration-dependent contraction of swollen heart mitochondria: Participation of the K+/H+ antiporter

Respiration-dependent contraction of heart mitochondria swollen passively in K⁺ nitrate is activated by the ionophore A23187 and inhibited by Mg²⁺. Ion extrusion and osmotic contraction under these conditions are strongly inhibited by quinine, a known inhibitor of the mitochondrial K⁺/H⁺ antiporter, as measured in other systems. The inhibition by quinine is relieved by the exogenous antiporter nigericin. Respiration-dependent contraction is also inhibited by dicyclohexylcarbodiimide (DCCD) when reacted under conditions known to inhibit K⁺/H⁺ antiport (Martinet al., J. Biol. Chem. 259, 2062–2065, 1984). These studies strongly support the concept that K⁺ is extruded from the matrix by the endogenous K⁺/H⁺ antiporter and that inhibition of this component by quinine or DCCD inhibits respiration-dependent contraction. The extrusion of K⁺ nitrate is accompanied by a respiration-dependent efflux of a considerable portion of the endogenous Mg²⁺. This Mg²⁺ efflux does not occur in the presence of nigericin or when the mitochondrial Na⁺/H⁺ antiporter is active. Mg²⁺ efflux may take place on the K⁺/H⁺ antiporter. DCCD, reacted under conditions that do not result in inhibition of the K⁺/H⁺ antiporter, blocks a monovalent cation uniport pathway. This uniport contributes to futile cation cycling at elevated pH, and its inhibition by DCCD stimulates respiration-dependent contraction.     

The pH dependence of red cell membrane transport of titratable anions studied by NMR spectroscopy

The effects of varying extracellular pH on the rates of uptake of titratable anions by human erythrocytes under conditions of constant intracellular pH have been determined for a series of highly related anions, the phosphate "analogs." These compounds are simply substituted phosphorus oxyacids, differing in the number and acidity of titratable protons: phosphate (HPO4(2-), pKa 6.8); phosphite (HPO3(2-), pKa 6.4); hypophosphite (H2PO2-); methylphosphonate ((CH3)PO3(2-), pKa 7.4); dimethylphosphinate ((CH3)2PO2-); fluorophosphate [PO3F2-, pKa 4.7); and thiophosphate (HSPO3(2-), pKa 5.5). Suspensions of intact, Cl(-)-loaded erythrocytes (intracellular pH, 7.2) were incubated at 37 degrees C in isotonic buffers (pH 4-8) containing 60 mM phosphate analog for specified time intervals, whereupon influx was halted by the addition of 1 mM 4-acetamido-4'-isothiocyanatostilbene-2,2'-disulfonic acid (SITS), an inhibitor of anion exchange. The intracellular anion concentrations were determined from 31P or 19F nuclear magnetic resonance spectra from the erythrocyte suspensions. The influx rates for the titratable phosphate analogs exhibited bimodal pH dependence, reaching maximal levels at pH values that increased with increasing anion pK. This pH-dependent behavior is consistent with a transport channel that contains a titratable regulatory site which interacts with the translocated anion. Based upon the Henderson-Hasselbalch equation, the probability that a titratable anion will have an electric charge of equal magnitude to that of the titratable carrier is highest at a pH value exactly midway between the pK of the regulatory site and that of the anion. The pH maxima observed for the phosphate analogs indicate a pK for this site of 5.5 at 37 degrees C. Intracellular pH changes associated with influx indicated that transport of the "fast" anion phosphite is largely in monoionized form. Intracellular pH changes associated with transport of slow anions were predominantly determined by partial ionic equilibrium effects and did not indicate the ionization state of the transported anion.     

Dual Mechanism of Ion Permeation through VDAC Revealed with Inorganic Phosphate Ions and Phosphate Metabolites

In the exchange of metabolites and ions between the mitochondrion and the cytosol, the voltage-dependent anion channel (VDAC) is a key element, as it forms the major transport pathway for these compounds through the mitochondrial outer membrane. Numerous experimental studies have promoted the idea that VDAC acts as a regulator of essential mitochondrial functions. In this study, using a combination of molecular dynamics simulations, free-energy calculations, and electrophysiological measurements, we investigated the transport of ions through VDAC, with a focus on phosphate ions and metabolites. We showed that selectivity of VDAC towards small anions including monovalent phosphates arises from short-lived interactions with positively charged residues scattered throughout the pore. In dramatic contrast, permeation of divalent phosphate ions and phosphate metabolites (AMP and ATP) involves binding sites along a specific translocation pathway. This permeation mechanism offers an explanation for the decrease in VDAC conductance measured in the presence of ATP or AMP at physiological salt concentration. The binding sites occur at similar locations for the divalent phosphate ions, AMP and ATP, and contain identical basic residues. ATP features a marked affinity for a central region of the pore lined by two lysines and one arginine of the N-terminal helix. This cluster of residues together with a few other basic amino acids forms a “charged brush” which facilitates the passage of the anionic metabolites through the pore. All of this reveals that VDAC controls the transport of the inorganic phosphates and phosphate metabolites studied here through two different mechanisms.     

The ATP-Mg/Pi carrier of rat liver mitochondria catalyzes a divalent electroneutral exchange.

Net transport of ATP-Mg or ADP in exchange for phosphate in isolated rat liver mitochondria has been shown to be an electroneutral process mediated by the ATP-Mg/Pi carrier. We compared the steady state distribution ratios of phosphate, ATP-Mg, and ADP at a pH of 7.4 to determine whether the divalent or monovalent form of these anions is the transported substrate. The log of the divalent ATP-Mg distribution ratio (in/out) approached the log of the divalent phosphate distribution ratio (approximately 0.85), which was approximately twice the value of the delta pH (approximately 0.40) across the inner mitochondrial membrane. This steady state relationship held under several different conditions, e.g. when the medium ATP concentration was varied or if the phosphate gradient was modified by partial uncoupling with the proton ionophore, carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Unidirectional ADP efflux in exchange for external ADP or ATP-Mg was stimulated by an increase in matrix H+. The log of the trivalent ADP distribution ratio (approximately 1.20) approached 3 times the value of delta pH. All these data are consistent with the model of an electroneutral exchange of divalent phosphate (HPO2-4) for divalent ATP-Mg (ATP-Mg2-) or for divalent protonated ADP (HADP2-). We conclude that this transport mechanism accounts for the adenine nucleotide concentration gradient that normally exists between the matrix and external medium.