Acid–base titration across the membrane system of rat-liver mitochondria: Catalysis by uncouplers

1. Pulsed acid–base titrations of suspensions of rat-liver mitochondria under anaerobic equilibrium conditions show fast and slow titration processes. 2. The fast process is the titration of the outer aqueous phase of the mitochondria, which is continuous with the suspension medium, and the slow process can be identified with the titration of the inner aqueous phase of the mitochondria, which is separated from the outer aqueous phase by the non-aqueous osmotic barrier or M phase of the cristae membrane system. 3. The buffering power of the outer and inner phases have been separately measured over a range of pH values. 4. The rate of titration of the inner aqueous phase under a known protonmotive force across the M phase has been characterized by an effective proton conductance coefficient, which, near pH7 and at 25°, is only 0·45μmho/cm.² of the M-phase membrane. 5. The low effective proton conductance of the M phase will account quantitatively for the observed respiratory control in state 4, assuming that oxidoreduction and phosphorylation are coupled by a circulating proton current as required by the chemi-osmotic hypothesis. 6. The addition of 2,4-dinitrophenol (or carbonyl cyanide p-trifluoromethoxyphenylhydrazone) at normal uncoupling concentrations causes a large increase in the effective proton conductance of the M phase of the cristae membrane. 7. The increase of the effective proton conductance of the M phase by 2,4-dinitrophenol (or carbonyl cyanide p-trifluoromethoxyphenylhydrazone) will account quantitatively for the short-circuiting effect of the uncoupling agent on the proton current and for the observed rise of the rate of respiration to that characteristic of state 3 or higher.     

Further evidence for a proton pump in mouse kidney phagolysosomes: Effect of nigericin and 2,4-dinitrophenol on the stimulation of intralysosomal proteolysis by ATP

The lipid soluble acid 2,4-dinitrophenol completely abolished the stimulatory effect of ATP on intralysosomal proteolysis in mouse kidney phagolysosomes at pH 8. The protonophore had no effect in the absence of ATP at pH 8 but inhibited intralysosomal proteolysis in unbuffered media. The ionophorous antibiotic nigericin also prevented the action of ATP at pH 8 but had no effect in the absence of ATP in unbuffered media. Nigericin also inhibited intralysosomal proteolysis at pH 8 in the absence of ATP. These observations support the hypothesis that the phagolysosome membrane contains an ATP-driven proton pump which functions to maintain intralysosomal acidity.     

Respiration-driven proton translocation in rat liver mitochondria

1. Pulses of acidity of the outer aqueous phase of rat liver mitochondrial suspensions induced by pulses of respiration are due to the translocation of H⁺ (or OH⁻) ions across the osmotic barrier (M phase) of the cristae membrane and cannot be attributed to the formation (with acid production) of a chemical intermediate that subsequently decomposes. 2. The effective quantity of protons translocated per bivalent reducing equivalent passing through the succinate-oxidizing and β-hydroxybutyrate-oxidizing spans of the respiratory chain are very close to 4 and 6 respectively. These quotients are constant between pH5·5 and 8·5 and are independent of changes in the ionic composition of the mitochondrial suspension medium provided that the conditions permit the accurate experimental measurement of the proton translocation. 3. Apparent changes in the →H⁺/O quotients may be induced by conditions preventing the occurrence of the usual backlash; these apparent changes of →H⁺/O are attributable to a very fast electrically driven component of the decay of the acid pulses that is not included in the experimental extrapolations. 4. Apparent changes in the →H⁺/O quotients may also be induced by the presence of anions, such as succinate, malonate and phosphate, or by cations such as Na⁺. These apparent changes of →H⁺/O are due to an increase in the rate of the pH-driven decay of the acid pulses. 5. The uncoupling agents, 2,4-dinitrophenol, carbonyl cyanide p-trifluoromethoxyphenylhydrazone and gramicidin increase the effective proton conductance of the M phase and thus increase the rate of decay of the respiration-driven acid pulses, but do not change the initial →H⁺/O quotients. The increase in effective proton conductance of the M phase caused by these uncouplers accounts quantitatively for their uncoupling action; and the fact that the initial →H⁺/O quotients are unchanged shows that uncoupler-sensitive chemical intermediates do not exist between the respiratory-chain system and the effective proton-translocating mechanism. 6. Stoicheiometric acid–base changes associated with the activity of the regions of the respiratory chain on the oxygen side of the rotenone- and antimycin A-sensitive sites gives experimental support for a suggested configuration of loop 3.     

Simultaneous extraction and concentration of penicillin G by hollow fiber renewal liquid membrane

In this article, hollow fiber renewal liquid membrane (HFRLM) technique was used for recovery of penicillin G from aqueous solution. The organic solution of 7 vol % di‐n‐octylamine (DOA) + 30 vol % iso‐octanol + kerosene was used as liquid membrane phase, and Na₂CO₃ aqueous solution was used as stripping phase. Experiments were performed as a function of carrier concentration in the organic phase, organic/aqueous volume ratio, pH, and initial penicillin G concentration in the feed phase, pH in the stripping phase, flow rates, etc. The results showed that the HFRLM process was stable and could carry out simultaneous extraction and concentration of penicillin G from aqueous solutions. As a carrier facilitated transport process, the addition of DOA in organic phase could greatly enhance the mass transfer rate; and there was a favorable organic/aqueous volume ratio of 1:20 to 1:30 for this system. The mass transfer flux and overall mass transfer coefficient increased with decreasing pH in the feed phase and increasing pH in the stripping phase, because of variation of the mass transfer driving force caused by pH gradient and distribution equilibrium. The flow rate of the shell side had significant influence on the mass transfer performance, whereas the effect of flow rate of lumen side on the mass transfer performance was slight because of the mass transfer intensification of renewal effect in the lumen side. The results indicated that the HFRLM process was a promising method for the recovery of penicillin G from aqueous solutions. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Absence of kinetic barrier for transfer of protons from aqueous phase to membrane-water interface

The kinetics of interfacial proton transfer reaction is an important factor in proton transport across membranes. The following experimental system was designed in order to measure this kinetics. Sonicated liposomes having the protonophore SF6847 was suspended in Tris buffer. Application of a temperature jump (in ∼ 3 μs) caused a drop in the aqueous phase pH which was subsequently sensed by the membrane-bound SF6847. The kinetics of this interfacial proton transfer reaction was monitored on μs timescales. The estimated bimolecular rate constant of 2×10¹¹ M⁻¹ s_#x2212;1 for this process show that there is no kinetic barrier for the transfer of protons from the aqueous phase to the membrane-water interface.     

Generation of a large, protonophore-sensitive proton motive force and pH difference in the acidophilic bacteria Thermoplasma acidophilum and Bacillus acidocaldarius.

The mechanism by which acidophilic bacteria generate and maintain their cytoplasmic pH close to neutrality was investigated. For this purpose we determined the components of proton motive force in the eubacterium Bacillus acidocaldarius and the archaebacterium Thermoplasma acidophilum. After correction for probe binding, the proton motive force of untreated cells was 190 to 240 mV between external pH 2 and 4. Anoxia diminished total proton motive force and the transmembrane pH difference by 60 to 80 mV. The protonophore 2,4-dinitrophenol abolished the total proton motive force almost completely and diminished the transmembrane pH difference by at least two units. However, even after correction for probe binding, protonophore-treated cells maintained a pH difference of approximately one unit.     

Estimation of the cytoplasmic pH of Coxiella burnetii and effect of substrate oxidation on proton motive force.

The magnitude of the proton motive force generated during in vitro substrate oxidation by Coxiella burnetii was examined. The intracellular pH of C. burnetii varied from about 5.1 to 6.95 in resting cells over an extracellular pH range of 2 to 7. Similarly, delta psi varied from about 15 mV to -58 mV over approximately the same range of extracellular pH. Both components of the proton motive force increased during substrate oxidation, resulting in an increase in proton motive force from about -92 mV in resting cells to -153 mV in cells metabolizing glutamate at pH 4.2. The respiration-dependent increase in proton motive force was blocked by respiratory inhibitors, but the delta pH was not abolished even by the addition of proton ionophores such as carbonyl cyanide-m-chlorophenyl hydrazone or 2,4-dinitrophenol. Because of this apparently passive component of delta pH maintenance, the largest proton motive force was obtained at an extracellular pH too low to permit respiration. C. burnetii appears, therefore, to behave in many respects like other acidophilic bacteria. Such responses are proposed to contribute to the extreme resistance of C. burnetii to environmental conditions and subsequent activation upon entry into the phagolysosome of eucaryotic cells in which this organism multiplies.     

Kinetics of proton transfer reactions of lysozyme with p-nitrophenol near neutral pH—a study of dynamic properties of Glu 35 and His 15

Kinetics of proton transfer between lysozyme and a pH indicator p-nitrophenol (p-Np) were measured by the temperature-jump method in a pH range of 6.0–7.0. Two well-defined relaxation processes were observed. The fast process (τ ? 15 μsec) was also observed for a lysozyme derivative succinylated at the terminal α-amino group of Lys 1. Therefore, the fast process was found to be attributable to the proton transfer reaction of His 15 with p-Np. The slow process (τ ? 50 μsec) was found to be characteristic of the proton transfer reaction of Glu 35, because it disappeared completely in solution containing a lysozyme derivative having an ester crosslink between the carboxyl group of Glu 35 and indol C-2 of Trp 108. The rate constants for proton transfer from Glu 35 and His 15 to p-Np were found to be 9 × 10⁶/sec/M (±65%, 23°C) and 3 × 10⁸/sec/M (±20%, 25°C), respectively. These data indicate that the proton of the carboxyl group of Glu 35 is kinetically stabilized in lysozyme.     

The concentration of glycine by preparations of the yeast Saccharomyces Carlsbergensis depleted of adenosine triphosphate: Effects of proton gradients and uncoupling agents.

1. At pH 4.5 and 30degreesC, yeast preparations depleted of ATP in the presence of antimycin and deoxyglucose spontaneously lost K+, gaining roughly an equivalent amount of H+. 2. Five proton conductors including azide and 2,4-dinitrophenol accelerated this process, as did [14C]glycine, which was absorbed with two extra equivalents of H+. 3. The rate of glycine uptake at pH 4.5 diminished fourfold when cellular K+ fell by 20%. 4. The distribution of [14C]propionate indicated that the intracellular pH fell from 6.2 to 5.7 when the cellular content of K+ fell by 30%. 5. Glycine uptake from a 5 muM solution was about 400 times faster at pH 4.5 than it was at pH 7.4 with 100mM-KC1 present ostensibly to lower the membrane potential. 6. Yeast preparations containing 2mM-[14C]glycine absorbed a further amount from a 0.1 muM solution at pH 4.5. After about 10 min a net movement of [14C]glycine out of the yeast occurred. The ratio of the cellular [14Ia1glycine concentration to the concentration outside the yeast reached 4 X 10(4) in these assays, whereas at pH 7.4 in the presence of 100mM-KC1 it did not exceed 15 in 3h. Dimitrophenol lowered the accumulation ratio at pH 4.5, apparently by causing proton conduction. 7. The observations are consistent with the notion that glycine uptake is driven by a proton symport mechanism. 8. Possible factors governing the strikingly low rate of glycine efflux as opposed to its optimum rate of influx are discussed.     

Action of phenazine methyl sulfate,inhibitors, and uncouplers on the light-induced proton transport by cells ofRhodospirillum rubrum

Summary Suspensions of log phase cells ofRhodospirillum rubrum at pH 5.5 show a light-induced decrease in the pH of the medium which is reversed during the subsequent dark period. The velocity and magnitude of the pH change were the same whether the cells were bubbled with air, CO₂-free air or N₂ during experimentation. The pH response is temperature dependent. Phenazine methyl sulfate (PMS) at concentrations above 0.05mm stimulates the light-induced pH change. PMS at 1mm gives a 2-fold increase in the initial rate upon illumination and a 1.5-fold increase in the total change in pH after 2 min of illumination. The inhibition of the proton transport by 10 g/ml antimycin A or 20 m 2-n-heptyl-4-hydroxyquinoline-N-oxide can be partially relieved by PMS. However, inhibition of the light-induced proton transport with 0.5mm 2,4-dinitrophenol or 3 m carbonylcyanide-m-chlorophenylhydrazone (CCCP) cannot be overcome by addition of PMS. Valinomycin, at a concentration of 3 m, caused a slight stimulation of the light-induced proton transport in the presence of 200mm KCl. The inhibition of proton transport by 3 m CCCP was partially relieved with 3 m valinomycin in the presence of 200mm KCl, but the antibiotic was without effect when the cells were suspended in 200mm NaCl. The results are discussed in terms of current theories of the action of PMS, antimycin A, valinomycin, and uncouplers on the light-induced electron flow and photophosphorylation inR. rubrum.     

Observation of the phosphatidyl ethanolamine amino proton magnetic resonance in phospholipid vesicles: inside/outside ratios and proton transport.

The amino proton resonance of phosphatidyl ethanolamine in sonicated mixed phospholipid vesicles is observed 3.3 ppm downfield from H₂O. Above pH ～ 5 it is broadened beyond detectability as a result of exchange with H₂O protons. In low salt, resonances of amino protons inside the vesicles appear to persist as the pH is raised, while those on the outside disappear. Solvent catalized proton conduction along the surface is proposed, with an effective -NH₂ to -NH₃ transfer rate of about 8 × 10⁵ sec^?1 at 25°C.     

Evidence for amino-acid: proton cotransport in Ricinus cotyledons

During germination and early growth of the castor-bean (Ricinus communis L.), protein in the endosperm is hydrolyzed and the amino acids are transferred into the cotyledons and then via the translocation stream to the axis of the growing seedling. The cotyledons retain the ability to absorb amino acids after removal of the endosperm and hypocotyl, exhibiting rates of transport up to 70 mol g^-1 h^-1. The transport of L-glutamine was not altered by KCl or NaCl in low concentrations (0–20 mM). High concentrations of KCl (100 mM) inhibited transport, presumably by decreasing the membrane potential. An increase in the pH of the medium bathing the cotyledons was observed for 10 min following addition of L-glutamine but not with D-glutamine, which is not transported. The rate of proton uptake was dependent on the concentration of L-glutamine in the external solution. Inhibitors and uncouplers of respiration (azide, 2, 4-dinitrophenol, carbonyl cyanide phenylhydrazone and N-ethylmaleimide) inhibited both L-glutamine uptake and L-glutamine-induced proton uptake. Amino acids other than L-glutamine also caused a transient pH rise and the rate of proton uptake was proportional to the rate of amino-acid uptake. The stoichiometry was 0.3 protons per amino acid transported. Addition of sucrose also caused proton uptake but the alkalisation by sucrose and by amino acids were not additive. Nevertheless, when sucrose was added 60 min after providing L-glutamine at levels saturating its uptake system, a rise in pH was again observed. The results were consistent with amino-acid transport and sucrose transport in castor-bean cotyledons both occurring by a proton cotransport in the same membrane system but involving separate carriers.     

Distribution and effect of the weak acids 5,5-dimethyl-2,4-oxazolidinedione (DMO) and 2,4-dinitrophenol (DNP) in membrane vesicles of Micrococcus denitrificans.

The effects of 5,5-dimethyl-2,4-oxazolidinedione (DMO) and 2,4-dinitrophenol (DNP) on membrane vesicles of Micrococcus denitrificans were compared. DMO did not affect the ability of these vesicles to accumulate glycine in the presence of the substrate l-lactate. Both glycine transport and l-lactate oxidation were inhibited by DNP; the concentration of DNP required for inhibition of respiration was fortyfold higher than that required for inhibition of transport. Using the technique of equilibrium dialysis with membrane residues from which the lipid had been extracted, no binding of [¹⁴C]DMO to membrane protein was detected. However, [¹⁴C]DNP did bind to membrane protein. At 100 μm DNP, 12% of the [¹⁴C]DNP was bound, equivalent to 1.56 nmol/mg protein. The pH inside vesicles respiring on l-lactate was calculated from the distribution of [¹⁴C]DMO and was found not to differ from the pH of the suspending buffer. The mechanism of action of DNP on active transport in M. denitrificans vesicles appears not to involve proton conduction.     

Bacteriorhodopsin in ice. Accelerated proton transfer from the purple membrane surface

The photocycle and the proton pumping kinetics of bacteriorhodopsin, as well as the transfer rate of protons from the membrane surface into the aqueous bulk phase were examined for purple membranes in water and ice. In water, the optical pH indicator pyranine residing in the aqueous bulk phase monitors the H(+)-release later than the pH indicator fluorescein covalently linked to the extracellular surface of BR. In the frozen state, however, pyranine responds to the ejected H+ as fast as fluorescein attached to BR, demonstrating that the surface/bulk transfer is in ice no longer rate limiting. The pumped H+ appears at the extracellular surface during the transition of the photocycle intermediate L550 to the intermediate M412. The Arrhenius plot of the M formation rate suggests that the proton is translocated through the protein via an ice-like structure.     

3-Nitroadipate, a Metabolic Intermediate for Mineralization of 2,4-Dinitrophenol by a New Strain of a Rhodococcus Species

The bacterial strain RB1 has been isolated by enrichment cultivation with 2,4-dinitrophenol as the sole nitrogen, carbon, and energy source and characterized, on the basis of 16S rRNA gene sequence comparison, as a Rhodococcus species closely related to Rhodococcus opacus. Rhodococcus sp. strain RB1 degrades 2,4-dinitrophenol, releasing the two nitro groups from the compound as nitrite. The release of nitro groups from 2,4-dinitrophenol occurs in two steps. First, the 2-nitro group is removed as nitrite, with the production of an aliphatic nitro compound identified by ¹H nuclear magnetic resonance and mass spectrometry as 3-nitroadipate. Then, this metabolic derivative is further metabolized, releasing its nitro group as nitrite. Full nitrite assimilation upon reduction to ammonia requires that an additional carbon source be supplied to the medium.     

Electrical evidence for different mechanisms of uptake for basic, neutral, and acidic amino acids in oat coleoptiles

The application of neutral or acidic amino acids to oat coleptiles induced transient depolarizations of the membrane potentials. The depolarizations are considered to reflect H⁺ -amino acid co-transport, and the spontaneous repolarizations are believed to be caused by subsequent electrogenic H⁺ extrusion. The basic amino acids depolarized the cell membrane strongly, but the repolarizations were weak or absent. The depolarizations induced by the basic amino acids were weakly sensitive to manipulations of the extracellular and intracellular pH. The depolarizations induced by the other amino acids, in contrast, were more strongly affected by the pH changes. Several amino acids induced distinct but diminished depolarizations in the presence of 2,4-dinitrophenol or cyanide, but the repolarizations were generally eliminated. These experiments support the co-transport theory but suggest somewhat different mechanisms for the transport of the neutral, acidic, and basic amino acids. We suggest that the neutral amino acids are co-transported with a single H⁺ and that accumulation depends upon both the ΔpH and the membrane potential components of the proton motive force. The acidic amino acids appear to be accumulated by a similar mechanism except that the transport of each molecule may be associated with a cation in addition to a single proton. The permanently protonated basic amino acids appear not to be co-transported with an additional proton. Accumulation would depend only on the membrane potential component of the proton motive force.     

Involvement of the proton electrochemical gradient in genetic transformation in Escherichia coli

Plasmid pIY2 DNA which encodes for ampicillin-resistance was used to study the energetics of Ca⁺⁺-induced transformation in Escherichia coli. When cells are exposed to DNA in the presence of carbonylcyanide-m-chlorophenylhydrazone or 2,4-dinitrophenol, two protonophores that collapse the proton electrochemical gradient across the cell membrane ($\text{Δ}\text{μ}{}_{\mathrm{H}}\text{+}$), transformation to ampicillin-resistance is drastically reduced with little or no effect on viability. Furthermore, when the components of $\text{Δ}\text{μ}{}_{\mathrm{H}}\text{+}$ are altered by varying ambient pH or by performing transformation in the presence of valinomycin or nigericin, the efficiency of transformation is directly correlated with the magnitude of the membrane potential and changes in the pH gradient have no significant effect. It is concluded that $\text{Δ}\text{μ}{}_{\mathrm{H}}\text{+}$, more specifically the membrane potential, plays a critical role in Ca⁺⁺-induced transformation.     

ORGANIC MERCURIAL ENCEPHALOPATHY: IN VIVO AND IN VITRO EFFECTS OF METHYL MERCURY ON SYNAPTOSOMAL RESPIRATION

—A reproducible model of subacute methyl mercury (MeHg) intoxication was developed in the adult rat following the daily intragastric administration of 10 mg methyl mercury/kg body wt. Synaptosomes isolated from animals during the latent phase of mercury neurotoxicity (6-10 days) demonstrated no significant change in respiratory control, State 3, State 4, or 2,4-dinitrophenol stimulated respiration with succinate, glutamate or pyruvate plus malate. During the neurotoxic phase, a significant decline in respiratory control was evident with all substrates. Cerebellar synaptosomes revealed qualitatively similar but quantitatively greater inhibition of 2,4-dinitrophenol stimulated respiration during the latent and neurotoxic phases with glutamate. In vitro studies of synaptosome respiration, oxidative phosphorylation and respiratory control with 5-15 μm -methyl mercury revealed a stimulation of initial State 4 respiration, loss of RCI, inhibition of State 3 but no change in the gramicidin or 2,4-dinitrophenol uncoupled rate supported by pyruvate-malate. Phosphate did not relieve the State 3 inhibition. At 25 μm -methyl mercury and above, considerable inhibition of electron transfer occurred. At this concentration, cytochrome c oxidase was inhibited 50%. Isosmotic replacement of medium KC1 by mannitol reduced the MeHg stimulation of State 4 respiration but had no effect on MeHg inhibition of ADP stimulated respiration. Half-maximal stimulation of State 4 respiration by MeHg occurred at [K]⁺⋍ 6 mm . These findings are compatible with an energy-linked methyl mercury induced cation translocation across the synaptosome (mitochondrial) membrane.     

Elimination of proton donor strongly affects directionality and efficiency of proton transport in ESR,a light-driven proton pump from Exiguobacterium sibiricum

ESR from Exiguobacterium sibiricum is a retinal protein which functions as a proton pump. Unusual feature of ESR is that a lysine residue is present at a site for the internal proton donor, which in other proton pumps is a carboxylic residue. Replacement of Lys96 with alanine slows reprotonation of the Schiff base by two orders of magnitude, indicating that Lys96 and interacting water molecules function as internal proton donor to the Schiff base. In this work we examined time resolved generation of light-induced electric potential ΔΨ by the K96A mutant reconstituted into proteoliposomes. We found that the ΔΨ component, which accompanied reprotonation of the Schiff base in wild type ESR, was not only slowed but also decreased greatly in the mutant, and negative phase appeared at high pH. This indicates a higher probability of back reactions in ESR than in bacteriorhodopsin since no negative components have been observed in homologous mutants of BR, D96N and D96A. The higher rate of back reactions in ESR is probably caused by different arrangement of the proton acceptor site compared to that in BR and different sequence of proton release and uptake. Addition of sodium azide, which substitutes for the internal proton donor, restores both the rate and amplitude of the ΔΨ components related to the Schiff base reprotonation in the K96A mutant. This indicates that overall proton transport results from competition of forward and reverse reactions, and emphasizes the importance of internal donor for high efficiency and directionality of H⁺ transfer.