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.     

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.     

Characterization of sulphydryl groups of the mitochondrial phosphate translocator by a maleimide spin label

A maleimide spin label strongly inhibits the phosphate/H+ symporter of rat liver mitochondria. While inducing half-maximal inhibition of transport, the spin label reacts preferentially with the SH groups of the carrier, which are at least of two types. One type of SH group is localized close to the surface of the membrane and its environment does not significantly influence the mobility of the probe. The second type of SH group is buried in the membrane, is not accessible to ascorbate or chromium oxalate and its environment greatly restricts the motion of the probe.     

Photoaffinity labeling of the mitochondrial phosphate carrier by 4-azido-2-nitrophenyl phosphate

The effect of 4-azido-2-nitrophenyl phosphate (ANPP), a photoreactive analogue of phosphate, on the phosphate carrier of pig-heart mitochondria has been investigated. In the dark, ANPP inhibits the transport of phosphate in a competitive manner with a Ki of 3.2 mM. Upon photoirradiation with visible light, [32P]ANPP binds covalently to the phosphate carrier and the inhibition becomes irreversible. Both the inhibition of phosphate transport and the incorporation of [32P]ANPP into the phosphate carrier depend on the concentration of the inhibitor and the pH of the medium. Incubation of the mitochondria with phosphate during illumination in the presence of ANPP protects the carrier against inactivation and decreases the amount of radioactivity which is found to be associated with the purified protein. By extrapolation it is calculated that at 100% inactivation of the phosphate carrier 0.35 mol of reagent are bound per mol of 33 kDa carrier protein. It is concluded that ANPP can be used for photoaffinity labeling of the mitochondrial phosphate carrier at the substrate-binding site.     

Effect of phosphate and ionophores on (14C)-NEM incorporation in mitochondrial membranes and relationships with phosphate carrier system.

Phosphate transport in mitochondria was investigated with respect to its inhibition by NEM. The reactivity of the Pi carrier SH groups was influenced by phosphate or ionophores during preincubation before the addition of NEM. Furthermore in order to obtain some mitochondrial protein fractions where the typical effects of phosphate and ionophores on [14C]-NEM fixations were observed, mitochondria were submitted to hypotonic treatment and sonication. The following results were obtained: 1. -- Phosphate and grisorixin (a new ionophore of the nigericin group) decreased the inhibition of phosphate transport by NEM. The same effect was observed for [14C]-NEM incorporation. 2. -- Valinomycin increased [14C]-NEM incorporation. The valinomycin effect was abolished by phosphate. ClCCP alone affected [14C]-NEM incorporation slightly. Valinomycin plus ClCCP decreased NEM inhibition of phosphate transport and [14C]-NEM incorporation like grisorixin. 3. -- The variability of SH group reactivity can be interpreted by a control of SH group accessibility by transmembrane delta pH as previously suggested. 4. -- Typical effects of phosphate or ionophores were observed in whole pig heart and rat liver mitochondria. These effects were enhanced in the same supernatant protein fraction resulting from sonication in pig heart mitochondria : phosphate decreased [14C]-NEM incorporation by 1,50 nmoles/mg protein, grisorixin by 0.95 nmoles, whereas valinomycin increased it by 0.75 nmoles. For rat liver mitochondria the phosphate effect and the valinomycin increased it by 0.75 nmoles. For rat liver mitochondria the phosphate effect valinomycin effect on [14C]-NEM incorporation were observed in the subparticular fraction obtained after sonification.     

Yeast mitochondria lacking the phosphate carrier/p32 are blocked in phosphate transport but can import preproteins after regeneration of a membrane potential.

Two different functions have been proposed for the phosphate carrier protein/p32 of Saccharomyces cerevisiae mitochondria: transport of phosphate and requirement for import of precursor proteins into mitochondria. We characterized a yeast mutant lacking the gene for the phosphate carrier/p32 and found both a block in the import of phosphate and a strong reduction in the import of preproteins transported to the mitochondrial inner membrane and matrix. Binding of preproteins to the surface of mutant mitochondria and import of outer membrane proteins were not inhibited, indicating that the inhibition of protein import occurred after the recognition step at the outer membrane. The membrane potential across the inner membrane of the mutant mitochondria was strongly reduced. Restoration of the membrane potential restored preprotein import but did not affect the block of phosphate transport of the mutant mitochondria. We conclude that the inhibition of protein import into mitochondria lacking the phosphate carrier/p32 is indirectly caused by a reduction of the mitochondrial membrane potential (delta(gamma)), and we propose a model that the reduction of delta(psi) is due to the defective phosphate import, suggesting that phosphate transport is the primary function of the phosphate carrier/p32.     

The mitochondrial tricarboxylate carrier of silver eel: chemical modification by sulfhydryl reagents

The tricarboxylate (or citrate) carrier was purified from eel liver mitochondria and functionally reconstituted into liposomes. Incubation of the proteoliposomes with various sulfhydryl reagents led to inhibition of the reconstituted citrate transport activity. Preincubation of the proteoliposomes with reversible SH reagents, such as mercurials and methanethiosulfonates, protected the eel liver tricarboxylate carrier against inactivation by the irreversible reagent N-(1-pyrenyl)maleimide (PM). Citrate and L-malate, two substrates of the tricarboxylate carrier, protected the protein against inactivation by sulfhydryl reagents and decreased the fluorescent PM bound to the purified protein. These results suggest that the eel liver tricarboxylate carrier requires a single population of free cysteine(s) in order to manifest catalytic activity. The reactive cysteine(s) is most probably located at or near the substrate binding site of the carrier protein.     

Elevated phosphate transporting activity and phosphate carrier content in mitochondria of rat hepatoma with high glycolytic capacity

Transport of inorganic phosphate into Zajdela hepatoma mitochondria proceeds with approximately the same Km and about two times higher Vmax than the transport into mitochondria of rat liver. As detected by (a) titration of the inhibition of mitochondrial phosphate-stimulated respiration and phosphate-induced swelling by mersalyl and (b) binding of /14C/-NEM and /14C/-DCCD to a 33 kDa protein in mitochondria, the higher phosphate transporting activity of the hepatoma mitochondria is due to about a three fold increase in phosphate carrier content in the tumor mitochondria.     

Phosphate transport protein of rat heart mitochondria: location of its SH-groups and exploration of their environment

(1) The properties of the SH groups of the phosphate transport protein of rat heart mitochondria were investigated on the basis of inhibition caused by SH reagents under different conditions. (2) The essential thiol groups are located near the external surface, as they are accessible to impermeable reagents from the external space. (3) The environment of the sulfhydryl groups influences their reactivity, as alteration of the external pH affects adversely their reactions with ionizable and non-ionizable SH reagents. (4) Intramitochondrial pH exerts a transmembrane effect: alkalinization augments and acidification diminishes the reaction rate of the sulfhydryl groups on the opposite surface of the membrane. (5) Changes of the concentration of the transported substrate occurring exclusively in the extramitochondrial space do not influence the reactivity of the essential SH groups. (6) It is concluded that in transport studies the phosphate transport protein of heart and liver mitochondria show basic similarity. It is suggested that the amino-acid sequence around the NEM-reactive cysteine (i.e., Lys-41 - Cys-42 - Arg-43) does not participate in substrate binding.     

Characterization of essential arginine residues implicated in the renal transport of phosphate and glucose.

We have characterized the reaction of arginine-specific reagents with the phosphate and glucose carriers of the kidney brush-border membrane. The inhibition of phosphate and glucose transport by phenylglyoxal follows pseudo-first-order kinetics. The rate of inactivation of phosphate transport by 50 mM phenylglyoxal was about 3-fold higher than that for glucose transport (kapp was 0.052 s-1 for the uptake of phosphate and 0.019 s-1 for the uptake of glucose). The order of the reaction, n, with respect to phenylglyoxal was 1.25 and 1.31 for the inactivation of phosphate and glucose transport, respectively. The inactivation of phosphate flux by p-hydroxyphenylglyoxal also follows pseudo-first-order kinetics, but the inhibition rate (kapp = 0.0012 s-1) was slower than with phenylglyoxal. The inactivation increased with the alkalinity of the preincubation medium for both phosphate and glucose fluxes and was maximal at pH 9.0. The inactivation of phosphate flux by phenylglyoxal depends upon the presence of an alkaline intravesicular pH. Extravesicular pH does not affect the reaction. Phenylglyoxal does not interfere with the recycling of the protonated carrier since phosphate uptake is inhibited independently of the pH used for transport measurements. Moreover, phenylglyoxal completely abolished trans stimulation by phosphate. Trans sodium inhibited phosphate uptake and abolished the pH profile of phosphate uptake.     

Inhibition of the mitochondrial phosphate carrier by a reaction with a carboxyl group reagent

The effect of N-ethyl-5-phenylisoxazolium 3"-sulfonate (Woodward's reagent K, WRK), a reagent forming covalent bonds with protein carboxyl groups, on the activity of the mitochondrial phosphate carrier was investigated. Treatment with WRK of mitochondria or of extracted carrier incorporated into liposomes, inhibited phosphate transport in a reconstituted liposomal system. Increasing the binding of WRK resulted in increased inhibition: the modified carrier protein showed a reduced affinity for phosphate, but binding of WRK had no effect on the Vmax of phosphate transport. It was concluded that WRK caused a conformational change in the carrier protein not involving the phosphate or H+ carrier sites such that its affinity for phosphate was lowered.     

Stimulation of phosphate transport in rat-liver mitochondria by thyroid hormones

The effect of hyperthyroidism on the transport of phosphate in rat-liver mitochondria has been examined. Thyroid hormones administered in vivo increased carrier mediated (mersalyl-sensitive) phosphate transport. Kinetic analysis of the phosphate transport showed that the thyroid hormone affects the Vmax of this process, while having no effect on the Km values. The higher activity of the phosphate carrier was found not to be due to a change in the endogenous content of phosphate nor to a change in the transmembrane delta pH value. Inhibitor titrations with mersalyl showed that mitochondria from both control and hyperthyroid rats required the same concentrations of inhibitor to produce total inhibition of phosphate transport, thus suggesting that the amount of functional translocase present is unaffected. The level of cardiolipin was significantly higher in mitochondrial membranes from hyperthyroid rats as compared to the control rats. The thyroid hormone induced change in the activity of the phosphate carrier appears to be due to a more favorable lipid microenvironment (cardiolipin content) surrounding the carrier molecule in the mitochondrial membrane.     

Action of a new compound, derived from NEM and DTE, on anionic translocation in mitochondria

The activity of translocating system which mediates the transport of Pi and citric cycle intermediates in mitochondria, has been determined with the multi-layer centrifugation technique. Contrary to all expectation it has been found that NEM, which binds tightly to SH groups, and DTE which reacting with disulphides increases the number of thiol groups of mitochondrial membrane, both inhibited the Pi leads to OH- and increased the initial rate of succinate leads to Pi exchange diffusion reactions. Identical results were obtained when mitochondria were preincubated with both NEM and DTE. The possibility that in these last conditions the effect on the translocator could be not determined by NEM and DTE per se but by a compound derived from their interaction, has been tested. Indeed solutions of NEM and DTE added in the concentration ratio of 2 to 1 and in absence of mitochondria, promoted the formation of a new compound, indicated as DTS, evidentiable by following the disappearance of both the absorbance of NEM at 302 nm and the free SH groups of DTE. Succinate leads to Pi and Pi leads to OH- exchange reactions were respectively stimulated and inhibited by DTS with a behaviour comparable to that observed in presence of NEM and/or DTE. The results are interpreted as a further and decisive support to the hypothesis that SH groups cannot be considered as functional active sites of the translocating system.     

The effect of SH group inhibitors on phosphate transport in Chlorella pyrenoidosa]

The effect of Sulphydryl reagents have been investigated. pCMB inhibits the transport of phosphate in Chlorella pyrenoidosa. This inhibition is immediate and does not change as a function of time of incubation. This inhibition affects non starved and starved cells (phosphate omitted). pCMPS and Mersalyl act in the same manner as pCMB. When these compounds are used at low concentrations, inhibition of phosphate uptake is observed only in starved cells. The substrate (phosphate) cannot provide protection against this inhibition. NEM inhibits phosphate uptake and this inhibition increases as a function of time of incubation. When the time of incubation is very short (about 15 seconds) the effects seems to be superficial and NEM reacts with SH groups involved in the transport system. When phosphate is present (for 15 seconds of incubation with NEM) the inhibition is less important than when phosphate is omitted. The substrate protects against NEM, but this protection disappears as the incubation with NEM is prolonged. NEM inhibits phosphate uptake in non starved and starved cells, however, it is observed that the inhibition is less important in starved cells than in non starved cells. The authors conclude that two kinds of SH groups might exist in the phosphate transport system, one reacting with pCMB and the other with NEM.     

Fuscin, an inhibitor of mitochondrial SH-dependent transport-linked functions

1. 1. Fuscin, a mould metabolite, is a colored quinonoid compound which reacts readily with −SH groups to give colorless addition derivatives.

2. 2. Binding of fuscin to mitochondria has been monitored spectrophotometrically. Fuscin binding is prevented by −SH reagents such as N-ehylmaleimide, N-Methylmaleimide, mersalyl or p-chloromercuribenzoate. Conversely, fuscin prevents the binding of −SH reagents as shown with N-[¹⁴C]ethylmaleimide. Once bound to mitochondria, fuscin is not removable by washing of mitochondria.

3. 3. High affinity-fuscin binding sites (K_d = 1 μM, N = 4–8 nmoles/mg protein) are present in whole mitochondria obtained from rat heart, rat liver, pigeon heart or yeast (Candida utilis). They are lost upon sonication but are still present in digitonin inner membrane + matrix vesicles. On the other hand, lysis of mitochondria by Triton X-100 does not increase the number of high affinity binding sites indicating that all these sites are accessible to fuscin in whole mitochondria. The number of fuscin high affinity sites appears to correlate with the glutathione content of mitochondrial preparations.

4. 4. Fuscin as well as N-ethylmaleimide and avenaciolide are penetrant SH-reagents;

5. 5. Fuscin interferes with the ADP-stimulated respiration of mitochondria on NAD-linked substrates, several functions of the mitochondrial respiratory apparatus being inhibited by fuscin in a non-competitive manner, but to various extents: (a) The electron transfer chain (K_i in the range of 0.1 mM); (b) the lipoamide dehydrogenase system (K_i = 5–10 μM); (c) the transport systems of phosphate (K_i ≈ 20 μM) and of glutamate (K_i = 3–5 μM); (d) the ADP transport, indirectly (K_i ≈ 10 μM).

6. 6. Like N-ethylmaleimide, fuscin inhibits the glutamate-OH⁻ carrier, the inhibition of that carrier bringing about an apparent increase of aspartate entry in glutamate-loaded mitochondria by the glutamate-aspartate carrier.

7. 7. The inhibition of phosphate transport by fuscin probably accounts for the inhibition of the reduction of endogenous NAD by succinate in intact pigeon heart mitochondria.

8. 8. By binding the −SH groups of mitochondrial membrane specifically unmasked by addition of micromolar amounts of ADP, fuscin, like N-ethylmaleimide, prevents the functioning of ADP translocation.

9. 9. Because of their specific and analogous effects on some well defined mitochondrial functions such as glutamate transport and ADP transport, fuscin and N-ethylmaleimide can be distinguished from other −SH reagents. The lipophilic nature of fuscin and N-ethylmaleimide which accounts for the accessbility of these compounds to hydrophobic sites in the mitochondrial membrane or on the matrix side of this membrane may be partly responsible for their characteristic inhibitory effects on mitochondrial functions.

Stimulation of adenine nucleotide translocation in reconstituted vesicles by phosphate and the phosphate transporter

Highly purified adenine nucleotide transporter from bovine heart mitochondria was reconstituted with phospholipids to form vesicles which catalyzed atractyloside-sensitive adenine nucleotide translocation. When internal ATP was exchanged with external ADP, this reaction was enhanced by agents capable of collapsing a membrane potential, but not by inorganic phosphate. When the purified nucleotide transporter was reconstituted together with a second protein fraction, nucleotide transport was stimulated by inorganic phosphate. The stimulated rate was eliminated by mersalyl or other SH reagents. The second protein fraction could be replaced by preparations of purified phosphate transporter.     

Identification of the N-ethylmaleimide reactive protein of the mitochondrial phosphate transporter.

The mitochondrial phosphate carrier is inhibited by the SH reagents p-(hydroxymercuri)benzoate and N-ethylmaleimide. Based on an analysis utilizing dodecyl sulfate-polyacrylamide gels, an SH-containing 32 000-dalton protein has been identified as a component of the phosphate carrier system. Two other N-[3H]ethylmaleimide-labeled proteins of the inner mitochondrial membrane have been eliminated from this role [Wholrab, H., & Greaney, J., Jr. (1978) Biochim. Biophys. Acta 503, 425] on the basis that band IV (45,000 daltons) is absent from heart sonic submitochondrial particles and band VII (6 500 daltons) does not react with p-(hydroxymercuri)benzoate. The mobility of the 32 000-dalton protein (0.43) is lower than that of the gamma subunit of the mitochondrial ATPase (0.46) and the carboxyatractyloside binding protein (0.48) on 12.5% dodecyl sulfate-polyacrylamide gels. In these flight muscle mitochondria, 0.87 nmol of N-[3H]ethylmaleimide per nmol of cytochrome a is bound to the 32,000-dalton protein.     

Homodimeric mitochondrial phosphate transport protein. Transient subunit/subunit contact site between the transport relevant transmembrane helices A

The three Cys of the yeast (Saccharomyces cerevisiae) mitochondrial phosphate transport protein (PTP) subunit were replaced with Ser. The seven mutants (single, double, and complete Cys replacements) were expressed in yeast, and the homodimeric mutant PTPs were purified from the mitochondria and reconstituted. The pH gradient-dependent net phosphate (Pi) transport uptake rates (initial conditions: 1 mM [Pi]e, pHe 6.80; 0 mM [Pi]i, pHi 8.07) catalyzed by these reconstituted mutants are similar to those of the wild-type protein and range from 15 to 80 micromol Pi/min mg PTP protein. Aerobic media inhibit only the Pi uptake rates catalyzed by PTPs with the conserved (yeast and bovine) Cys28. This inhibition in the proteoliposomes is 84-95% and can be completely reversed by dithiothreitol. Transport by the wild type as well as by all mutant proteins with Cys28 is more than 90% inhibited by mersalyl. Transport catalyzed by mutant proteins with only Cys300 or only Cys134 is less sensitive, and that catalyzed by the no Cys mutant shows 40% inhibition by mersalyl. When dithiothreitol is removed from purified single Cys mutant proteins, only the mutant protein with Cys28 appears as a homodimer in a nonreducing SDS polyacrylamide gel. Thus, the function relevant transmembrane helix A, with Cys 28 about equidistant from the two inner membrane surfaces, is in close contact with parts of transmembrane helix A of the other subunit in the functional homodimeric PTP. The results identify for the first time not only a transmembrane helix contact site between the two subunits of a homodimeric mitochondrial transport protein but also a contact site that if locked into position blocks transport. The results are related to two available secondary transporter structures (lactose permease, glycerol-3-phosphate transporter) as well as to a low resolution projection structure and a high resolution structure of monomers of inhibitor ADP/ATP carrier complexes.     

The mechanism of phosphate permeation in purified bean mitochondria

The permeability properties and mechanism of Pi transport wereinvestigated in purified bean mitochondria.

1. Purified bean mitochondria are impermeable to small moleculesand ions. However, Pi, arsenate, acetate and formate can enterthe osmotically active space of bean mitochondria.
2. Nigericinor the association of valinomycin and FCCP cause mitochondrialswelling in isoosmotic potassium phosphate.
3. The SH-blockingreagents mersalyl, pHMB and NEM inhibit variousmitochondrialfunctions dependent on the translocation of Piand arsenateacross the membrane. These include the respirationstimulatedby ADP, Ca²⁺+Pi, and K⁺+valinomycin +Pi; the swellingin ammoniumphosphate medium and, in the presence of nigericin,in potassiumphosphate medium; the energy-linked yalinomycin-inducedswellingand the subsequent CICCP-induced shrinking. The uncoupler-stimulatedrespiration, as well as the other processes when acetate issubstituted for Pi, are not influenced by SH reagents.
4. Mersalyland pHMB cause complete inhibition at about 20 nmoles/mgprotein,whereas, NEM is effective at about 1 µmole/mgprotein.The inhibition by mersalyl and pHMB, but not that byNEM, issigmoidal and reversed by 2-mercaptoethanol. Non-inhibitoryamounts of mersalyl protect the Pi transport from irreversibleinhibition by NEM.
5. We concluded that a carrier-mediated transportsystem for Piis present in bean mitochondria, and that someof its propertiesare similar to the Pi carrier of animal mitochondria.

(Received June 5, 1975; )     

Purification and characterization of the phosphate/hydroxyl ion antiport protein from rat liver mitochondria.

The phosphate transport protein was purified from rat liver mitochondria by extraction in an 8% (v/v) Triton X-100 buffer followed by adsorption chromatography on hydroxyapatite and Celite. SDS/polyacrylamide-gel electrophoresis (10%, w/v) demonstrated that the purified polypeptide was apparently homogeneous when stained with Coomassie Blue and had a subunit Mr of 34,000. However, lectin overlay analysis of this gel with 125I-labelled concanavalin A demonstrated the presence of several low- and high-Mr glycoprotein contaminants. To overcome this problem, mitochondria were pre-extracted with a 0.5% (v/v) Triton X-100 buffer as an additional step in the purification of phosphate transport protein. SDS/polyacrylamide gradient gel electrophoresis (14-20%, w/v) of the hydroxyapatite and Celite eluates revealed one major band of Mr 34,000 when stained with Coomassie Blue. The known thiol group sensitivity of the phosphate transporter was employed to characterize the isolated polypeptide further. Labelling studies with N-[2-3H]ethylmaleimide showed that only the 34,000-Mr band was labelled in both the hydroxyapatite and Celite fractions, when purified from rat liver mitochondria. Further confirmation of its identity has been provided with an antiserum directed against the 34,000-Mr protein. Specific partial inhibition of phosphate uptake, as measured by iso-osmotic swelling in the presence of (NH4)2HPO4, was achieved when mitoplasts (mitochondria minus outer membrane) were incubated with this antiserum. Finally, amino acid analysis of the rat liver mitochondrial phosphate/hydroxyl ion antiport protein indicates that it is similar in composition to the equivalent protein isolated from ox heart.