Selective electrode for dibenzyl dimethyl amoonium cation as indicator of the membrane potential in biological systems

The electrode sensitive to dibenzyl dimethyl ammonium (DDA⁺), which is considered to be an indicator of the membrane potential, was constructed by using tetraphenyl borone (TPB^?) embedded in dichloroethane. Rapid and Nernstian responses were exhibited against DDA⁺ solutions ranging between 10^?2 and 3 · 10^?6 M in concentration. High selectivity for DDA⁺ was observed in the presence of various inorganic salts, ADP, ATP, oxidizable substrates and sugars. The electrode developed here was used to measure the DDA⁺ uptake in Streptococcus faecalis and the results agreed with those reported by Harold, F.M. and Papineau, D. ((1972) J. Membrane Biol. 8, 27–44 and 45–62). While they determined the DDA⁺ concentration in the medium by measuring the absorbance of the filtrate treated with the ion-exchangers, the electrode can measure directly the DDA⁺ concentration in the bacterial suspension without any pretreatment. It was also shown that the electrode can measure the DDA⁺ uptake in mitochondria during energization.     

Membrane potential of mitochondria measured with an electrode sensitive to tetraphenyl phosphonium and relationship between proton electrochemical potential and phosphorylation potential in steady state

Summary The membrane potential of mitochondria was estimated from the accumulation of tetraphenyl phosphonium (TPP⁺), which was determined with the TPP⁺-selective electrode developed in the present study. The preparation and some operational parameters of the electrode were described. The kinetics for uptake by mitochondria of TPP⁺ and DDA⁺ (dibenzyldimethyl ammonium) were analyzed, and it was found that TPP⁺ permeated the mitochondrial membrane about 15 times faster than DDA⁺. The final amounts of accumulation of TPP⁺ and DDA⁺ by mitochondria were approximately equal. For the state-4 mitochondria, the membrane potential was about 180 mV (interior negative). Simulataneous measurements of TPP⁺-uptake and oxygen consumption showed that the transition between states 3 and 4 was detectable by use of the TPP⁺-electrode. After the TPP⁺-electrode showed that state-4 was reached, the extramitochondrial phosphorylation potential was measured. The difference in pH across the membrane was measured from the distribution of permeant anion, acetate, so as to calculate the proton electrochemical potential. The ratio of extra-mitochondrial phosphorylation potential to proton electro-chemical potential,n was close to 3. This value ofn was also found to be 3 when ATP was hydrolyzed under the condition that the respiratory chain was arrested. The implication thatn=3 was discussed.     

Cation transport and electrogenesis byStreptococcus faecalis

Summary Uptake of the lipid-soluble cations dibenzyldimethylammonium (DDA⁺) and triphenylmethylphosphonium (TPMP⁺) byStreptococcus faecalis is biphasic. The initial phase is a rapid binding of the ions which does not require a source of metabolic energy and apparently consists of cation exchange at the cell surface. Upon addition of glucose further uptake of the cations occurs, by exchange for Na⁺ and H⁺. Evidence is presented suggesting that this metabolic uptake of DDA⁺ and TPMP⁺ is not due to active transport. It rather appears that uptake results from the generation of an electrical potential, interior negative, by the extrusion of H⁺ and, indirectly, of Na⁺. Accumulated DDA⁺ and TPMP⁺ are discharged by proton-conducting uncouplers. The cationconducting antibiotics valinomycin, monactin, nigericin and monensin do not inhibit uptake. Potassium and, under certain conditions, H⁺ displace DDA⁺ and TPMP⁺. Generation of an electrical difference across the membrane was verified by the accumulation of K⁺ in the presence of valinomycin. The concentration ratios achieved correspond to potentials of the order of –150 to –200 mV.     

The Influence of H+ on the Membrane Potential and Ion Fluxes of Nitella

The resting membrane potential of the Nitella cell is relatively insensitive to [K]_o, but behaves like a hydrogen electrode. K⁺ and Cl^- effluxes from the cell were measured continuously, while the membrane potential was changed either by means of a negative feedback circuit or by external pH changes. The experiments indicate that P_K and P_Cl are independent of pH but are a function of membrane potential. Slope ion conductances, G_K, G_Cl, and G_Na were calculated from efflux measurements, and their sum was found to be negligible compared to membrane conductance. The possibility that a boundary potential change might be responsible for the membrane potential change was considered but was ruled out by the fact that the peak of the action potential remained at a constant level regardless of pH changes in the external solution. The conductance for H⁺ was estimated by measuring the membrane current change during an external pH change while the membrane potential was clamped at K⁺ equilibrium potential. In the range of external pH 5 to 6, H⁺ chord conductance was substantially equal to the membrane conductance. However, the [H]_i measured by various methods was not such as would be predicted from the [H]_o and the membrane potential using the Nernst equation. In artificial pond water containing DNP, the resting membrane potential decreased; this suggested that some energy-consuming mechanism maintains the membrane potential at the resting level. It is probable that there is a H⁺ extrusion mechanism in the Nitella cell, because the potential difference between the resting potential and the H⁺ equilibrium potential is always maintained notwithstanding a continuous H⁺ inward current which should result from the potential difference.     

Adenine nucleotide translocase as a site of regulation by ADP of the rat liver mitochondria permeability to H+ and K+ lons

In the presence of oligomycin ADP inhibits the osmotic swelling of the nonenergized rat liver mitochondria in the NH₄NO₃ medium. With the energized mitochondria ADP enhances contraction of the mitochondria swollen in the NH₄NO₃ medium. Carboxyatractyloside and atractyloside abolish or prevent the effects of ADP. The direct measurements of the proton conductance of rat liver mitochondria shows that the inhibitory action of ADP + oligomycin on the H⁺ permeability does not depend on the energization of mitochondria. In these experiments the local anesthetic nupercaine and ADP additively inhibit the inner membrane conductance for protons, but carboxyatractyloside abolishes only the effect of ADP. In the presence of oligomycin ADP also inhibits the osmotic swelling of the nonenergized liver mitochondria in the KNO₃ medium, and the energy-dependent swelling of rat liver mitochondria in the medium with K⁺ ions and P_i. The inhibition by ADP of the membrane passive permeability for K⁺ is also sensitive to carboxyatractyloside. It is concluded that rat liver mitochondria possess an ADP-regulated channel for H⁺ and K⁺. The properties of this pathway for protons and potassium ions favor the idea that ADP regulates the mitochondrial permeability via adenine nucleotide translocase. It is assumed that the adenine nucleotides carrier should operate according to the “gated pore” mechanism.     

Ca2+ transport against its electrochemical gradient in cytochrome oxidase vesicles reconstituted with mitochondrial hydrophobic proteins

Cytochrome oxidase vesicles have recently been shown to accumulate Ca²⁺ in an energy-dependent manner. Energization of these vesicles with internally trapped cytochrome c and externally added ascorbate and phenazine methylsulfate generated an internally positive membrane potential and prevented Ca²⁺ influx (R. N. Rosier and T. E. Gunter, 1980, FEBS Lett.109, 99–103). In contradistinction, when cytochrome oxidase vesicles were reconstituted with complex V, a mitochondrial protein fraction containing the uncoupler binding site (Y. Hatefi, D. L. Stiggall, Y. Galante and W. G. Hanstein, 1974, Biochem. Biophys. Res. Commun.61, 313–321), both Ca²⁺ uptake and generation of an internally positive membrane potential were observed. The uptake was specifically dependent on energization of electron transport. Control experiments verified that the energization conditions used produced appropriately oriented membrane potentials. Other partially purified hydrophobic mitochondrial protein complexes were found to be less effective than complex V. The reconstituted system showed cation selectivity since Ca²⁺, Mn²⁺, and Rb⁺ were transported, while Na⁺ was not. Low levels of uncoupler, which did not affect oxidation rates, were found to partially inhibit Ca²⁺ uptake regardless of the membrane potential polarity. Uncoupling levels of uncoupler markedly inhibited Ca²⁺ uptake in internally negative cytochrome oxidase vesicles; however, inhibition in internally positive cytochrome oxidase vesicles was less relative to that at lower levels of uncoupler. The uncoupling combination of nigericin, valinomycin, and K⁺ was inhibitory to uptake regardless of membrane potential polarity. A reconstituted system of oxidative phosphorylation, which contains a hydrophobic protein fraction, energized with cytochrome oxidase similarly accumulated Ca²⁺ despite formation of an internally positive membrane potential. The results suggest that cytochrome oxidase, when coupled to appropriate hydrophobic mitochondrial proteins, can act as an electrogenic Ca²⁺ pump deriving its energy directly from electron transport.     

The assay of free potassium in biological buffers with a K+-selective glass electrode

Abstract

The performance of the Kent K⁺-selective glass electrode in several biological buffers at neutral pH was evaluated in terms of Nernstian response, repeatability, response time and selectivity. The electrode exhibited a linear response between 2 times 10^?5 to 5 times 10^?4 and 10^?2 M K⁺, with a slope of 54.9–63.1 mV per decade change in K⁺ activity. In successive calibrations in the range of 10^?5 to 10^?2 M K⁺, the coefficient of variation of the potential in a given K⁺ concentration decreased with increasing K⁺ concentration, and was lower than 5%, indicating that in this range of concentrations, the electrode exhibited good repeatability. The response time for a sudden tenfold increase in K⁺ concentration was 1.3–3.6 min for 10^?5 M, and 0.5–1 min for 10^?4 M K⁺. The influence of Ca²⁺ and Mg²⁺ on electrode, potential was very small, but Na⁺ and H⁺ strongly interfered with electrode response. The selectivity coefficient K⁺/Na⁺ was 0.11 and K⁺/H⁺ 3.8. The results suggested that in several biological buffers containing no Na⁺ and with neutral pH, the K⁺-selective glass electrode can be used to assay with accuracy and rapidity free potassium in the range of 10^?5 to 10^?2 M, being therefore an alternative to valinomycin-based electrodes.     

Osmotic swelling of heart mitochondria in acetate and chloride salts. Evidence for two pathways for cation uptake.

Swelling of nonenergized heart mitochondria suspended in acetate salts appears to depend on the activity of an endogenous cation/H⁺ exchanger. Passive swelling in acetate shows a characteristic cation selectivity sequence of Na⁺ >Li⁺ >K⁺, Rb⁺, Cs⁺, or tetramethylammonium, a sharp optimum at pH 7.2–7.3, activation by Ca²⁺, and loss of activity on aging which can be related to loss of endogenous K⁺. The reaction is nearly insensitive to either addition of exogenous Mg²⁺ or removal of membrane Mg²⁺ with EDTA. Each of these characteristics of passive swelling in acetate salts is duplicated in chloride media when tripropyltin is added to induce Cl^?/OH^? exchange. In contrast to nonenergized mitochondria, swelling of respiring mitochondria has been postulated to depend on electrophoretic uptake of cations in response to an interior negative membrane potential. Respiration-dependent swelling in acetate shows an indistinct cation selectivity sequence with Li⁺ and Na⁺ supporting higher rates of swelling at higher efficiency than K⁺, Rb⁺, and Cs⁺. The high rates of respiration-dependent swelling in Li⁺ and Na⁺ are inhibited by low levels of exogenous Mg²⁺ (K_i of 5–10 μm), but a significant swelling with almost no cation selectivity persists in the presences of 2 mm Mg²⁺. Removal of membrane Mg²⁺ by addition of EDTA strongly activates the rate of respiration-dependent swelling and converts a sigmoid dependency of swelling rate on Li⁺ concentration to a hyperbolic one with a Km of about 14 mm Li⁺. The cation selectivity and Mg²⁺ dependence of the reaction induced in chloride salts by tripropyltin are identical to these properties in acetate. Energy-dependent swelling in acetate shows optimum activity at pH 6.5 which appears related to the availability of free acetic acid, since the corresponding reaction induced in chloride shows a broad optimum at about pH 7.5. These studies support the concept that monovalent cations enter nonenergized mitochondria by electroneutral exchange with protons but penetrate respiring mitochondria by electrophoretic movement through one or more uniport pathways. They further suggest that both a Mg²⁺-sensitive uniport with high activity for Na⁺ and Li⁺ and a Mg²⁺-insensitive pathway with little cation discrimination are available in the membrane.     

Role of nonohmicity in the regulation of electron transport in plant mitochondria

The relationship between the respiratory rate and the membrane ionic current on the protonmotive force has been investigated in percoll purified potato mitochondria. The dependence of the membrane ionic current on the membrane potential was monitored using a methyltriphenylphosphonium-sensitive electrode and determining the maximal net rate of depolarization following the addition of a respiratory inhibitor. We have confirmed that a nonohmic relationship exists between the ionic conductance and membrane potential. Addition of ATPase inhibitors markedly increased the initial rate of dissipation suggesting that in their absence the dissipation rate induced by respiratory inhibitors is partially offset by H⁺-efflux due to the hydrolysis of endogenous ATP. This was corroborated by direct measurement of endogenous ATP levels which decreased significantly following dissipation of the membrane potential. Results are discussed in terms of the regulation of electron transport in plant mitochondria in vivo.