Inhibition of membrane transport in Streptococcus faecalis by uncouplers of oxidative phosphorylation and its relationship to proton conduction

We studied the effect of compounds that uncouple oxidative phosphorylation on membrane function in Streptoccocus faecalis, an organism which relies upon glycolysis for the generation of metabolic energy. At low concentrations (ranging from 10(-7) to 10(-4)m), tetrachlorosalicylanilide, tetramethyldipicrylamine, carbonylcyanide m-chlorophenylhydrazone, pentachlorophenol, and dicoumarol strongly inhibited energy-dependent transport of rubidium, phosphate, and certain amino acids. However, these compounds had little effect on the generation of adenosine triphosphate via glycolysis or on its utilization for the synthesis of macromolecules. They also did not seriously inhibit uptake of those monosaccharides and amino acids which do not require concurrent metabolism. It is proposed that the uncouplers interfere with the utilization of metabolic energy for membrane transport. The uncouplers accelerated the translocation of protons across the cytoplasmic membrane. It appears that a proton-impermeable membrane is required for transport, perhaps, because a proton gradient is involved in the coupling of metabolic energy to the translocation of substrates across the membrane.     

Exclusion of Induced Bacteriophage from Cells of a Lysogenic Bacillus megaterium Committed to Sporulation

In Escherichia coli ML 308-225, d-ribose is transported into the cell by a constitutive active transport system of high activity. The activity of this transport system is severely reduced in cells subjected to osmotic shock, and the system is not present in membrane vesicles. The mechanism by which metabolic energy is coupled to transport of ribose was investigated. Substrates which generate adenosine 5'-triphosphate primarily through oxidative phosphorylation are poor energy sources for ribose uptake in DL-54, a mutant of ML 308-225 which lacks activity for the membrane-bound Ca(2+), Mg(2+)-dependent adenosine triphosphatase required for oxidative phosphorylation. Arsenate severely inhibits ribose uptake, whereas, under the same conditions, uptake of l-proline is relatively insensitive to arsenate. Anaerobiosis does not significantly inhibit ribose uptake in ML 308-225 or DL-54 when glucose is the energy source. A significant amount of ribose uptake is resistant to uncouplers of oxidative phosphorylation such as 2,4-dinitrophenol. These results indicate that the phosphate bond energy of adenosine 5'-triphosphate, rather than an energized membrane state, couples energy to ribose transport in ML 308-225.     

pH dependence of the Coxiella burnetii glutamate transport system.

The transport of glutamate, apparently a primary energy source for Coxiella burnetii, has been examined. C. burnetii is shown to possess a pH-dependent active transport system for L-glutamate with an apparent Kt of 61.1 microM and Vmax of 8.33 pmol/s per mg at pH 3.5. Both L-glutamine and L-asparagine competitively inhibited transport of glutamate, but D-glutamate, L-aspartate, L-glutamate-gamma-methyl ester, methionine sulfoximine, or alpha-ketoglutarate did not compete. This transport system is both temperature and energy dependent. Uptake of glutamate is highly sensitive to uncouplers of oxidative phosphorylation such as 2,4-dinitrophenol and carbonyl cyanide-m-chlorophenyl hydrazone that decrease the proton motive force across the cytoplasmic membrane. ATPase inhibitors such as dicyclohexylcarbodiimide or metabolic poisons such as KCN, NaF, or arsenite were much less effective as inhibitors of glutamate transport. Uptake of glutamate did not appear to be coupled to Na+ symport as in Escherichia coli since no monovalent cation requirement could be demonstrated. Instead, the Vmax of glutamate transport showed good correlation with the transmembrane pH gradient (delta pH). From these results, we propose that L-glutamate transport by C. burnetii is energized via a proton motive force.     

On the mechanism of action of oligomycin and acidic uncouplers on proton translocation and energy transfer in “sonic” submitochondrial particles

A study is presented of the effect of acidic uncouplers and oligomycin on energy-linked and passive proton translocation, oxidative phosphorylation, and energy-linked nicotinamide-adenine-nucleotide transhydrogenase in EDTA submitochondrial particles from beef-heart. A flow potentiometric technique has been applied to resolve the kinetics of the initial rapid phase of the redox proton pump. Rapid kinetics analysis shows that carbonyl-cyanide-p-trifluoromethoxyphenyl-hydrazone (FCCP) does not exert any direct effect on redox-linked active proton transport. The uncoupling action of FCCP on oxidative phosphorylation and energy-linked transhydrogenase is shown to be quantitatively accounted for by its promoting effect of passive proton-diffusion across the mitochondrial membrane. Oligomycin depresses passive proton diffusion in EDTA sonic particles and this effect accounts for the coupling action exerted by the antibiotic on oxidative phosphorylation and energy-linked transhydrogenase. In fact, rapid kinetic analysis demonstrates that oligomycin does not directly affect the redox-linked proton pump. The present results show that there does not exist any labile intermediate in the redox-linked proton pump which is sensitive to acidic uncouplers.     

Inhibition of DNA replication in Escherichia coli by dibromophenol and other uncouplers.

DNA replication in Escherichia coli is inhibited by uncouplers such as 2,4-dibromophenol and 3,3'4',5-tetrachlorosalicylanilide. Inhibition occurs in either aerobically or anaerobically growing cells or in cells made permeable by toluene. With anaerobically growing cells, inhibition by dibromophenol is reversible and occurs under conditions in which there is no change in pools of ATP or deoxynucleoside triphosphates. With toluenized cells, inhibition is not due to breakdown of deoxynucleoside triphosphates. The rates of protein and RNA synthesis are not inhibited either in vivo or in toluenized cells by concentrations of dibromophenol or tetrachlorosalicylanilide which inhibit replication. It is generally believed that uncouplers inhibit many other cellular processes by collapsing a proton gradient across a membrane. However, the relative effectiveness of eight uncouplers and related compounds to inhibit replication did not parallel their ability to transport protons into E. coli cells. Therefore, the inhibition by uncouplers does not suggest that replication depends on a chemiosmotic process. A possible explanation for the uncoupler sensitivity is provided by the finding that many of the purified enzymes tested, including DNA polymerases II and III, are inhibited by dibromophenol and tetrachlorosalicylanilide.     

Trimethylamine oxide respiration in Proteus sp. strain NTHC153: electron transfer-dependent phosphorylation and L-serine transport

Cells of Proteus sp. strains NTHC153 grown anaerobically with glucose and trimethylamine oxide (TMAO) were converted to spheroplasts by the penicillin method. The spheroplasts were lysed by osmotic shock, and the membrane vesicles were purified by sucrose gradient centrifugation. Vesicles energized electron transfer from formate to TMAO displayed active anaerobic transport of serine. An anaerobic cell-free extract of Proteus sp. disrupted in a French pressure cell reduced TMAO with formate and NADH with the concomitant formation of organic phosphate. The net P/2e- ratios determined were 0.1 and 0.3, respectively. The NADH- and TMAO-dependent phosphorylation was sensitive to uncouplers of oxidative phosphorylation (protonophores), and the formate- and TMAO-dependent serine transport was sensitive to ionophores and protonophores. We conclude that TMAO reduction in Proteus sp. fulfills the essential features of anaerobic respiration.     

Studies on the transport of carnitine in the brain using synaptosomes isolated from guinea-pig cerebral cortex

Synaptosomes isolated from guinea pig cerebral cortex accumulate L-carnitine from the medium in an active process, dependent on the sodium gradient across the plasma membrane and on (Na+ + K+)-ATPase activity. L-Carnitine uptake is inhibited by oxidative phosphorylation uncouplers and by ouabain, a known inhibitor of (Na+ + K+)-ATPase. In addition, the omission of Na+ or its replacement by Li+ inhibited the transport, which was also competitively inhibited by gamma-aminobutyrate. The kinetics of carnitine uptake show that the overall process would consist of two components: a passive diffusion and a carrier-mediated transport which is saturated at 1-2 mM carnitine concentration.     

Proline transport in rat liver mitochondria.

Proline transport across the inner membrane of rat liver mitochondria shows the following properties: (a) It is stereospecific; the penetration of l-proline is two times faster than the penetration of dl-proline. (b) Proline is accumulated against a concentration gradient, (c) The transport of proline is enhanced in the presence of respiratory substrates such as succinate or tetramethylphenylenediamine + ascorbate; it is inhibited by uncouplers of oxidative phosphorylation. (d) Proline transport is inhibited by mersalyl and p-chloromercuribenzoate, but not by hydrophobic thiol blocking reagents; thus, proline transport involves thiol groups located in a very hydrophilic environment. The penetration of several other neutral amino acids (alanine, glycine, serine) is almost insensitive to mersalyl. These results suggest that proline does not travel across the mitochondrial membrane by free diffusion, but that its transport is mediated by a specific carrier. The rate of proline transport has been compared with the rates of the first two steps of proline oxidation: All of these rates are very similar, indicating that proline transport is not a limiting factor of proline metabolism in rat liver mitochondria.     

Effect of heliomycin on the respiration and oxidative phosphorylation of the liver mitochondria of the rat

The effect of heliomycin and known uncouplers of oxidative phosphorylation on respiration and oxidative phosphorylation was studied comparatively. Heliomycin, as well as 2,4-dinitrophenol, valinomycin and gramicidin S inhibited the mitochondrial synthesis of ATP. This process was inhibited completely by heliomycin at a concentration of 1.5 x 10(-5) M. The synthesis of inorganic pyrophosphate, the other macroergic compound, was also inhibited by heliomycin, ATPase and pyrophosphatase of uncoupled mitochondria being not inhibited by the antibiotic. Like 2,4-dinitrophenol, heliomycin stimulated the synthesis of ATPase and respiration in intact mitochondria. Probably, heliomycin inhibited the synthesis of ATP and pyrophosphate by uncoupling the processes of respiration and oxidative phosphorylation. It was shown earlier that heliomycin, a specific inhibitor of bacterial RNA synthesis, also affected energy metabolism of bacterial cells by inhibiting the synthesis of ATP and active transport.     

An analysis of lactose permease "sugar specificity" mutations which also affect the coupling between proton and lactose transport. I. Val177 and Val177/Asn319 permeases facilitate proton uniport and sugar uniport

The sugar specificity mutants of the lactose permease containing Val177 or Val177/Asn319 were analyzed with regard to their ability to couple H+ and sugar co-transport. Both mutants were able to transport lactose downhill to a significant degree. The Val177 mutant was partially defective in the active accumulation of galactosides, whereas the Val177/Asn319 mutant was completely defective in the uphill accumulation of sugars. With regard to coupling, the Val177 mutant was shown to catalyze the uncoupled transport of H+ to a substantial degree. This led to a decrease in the H+ electrochemical gradient under aerobic conditions and also resulted in faster H+ uptake when a transient H+ electrochemical gradient was generated under anaerobic conditions. Interestingly, galactosides were shown to diminish the rate of uncoupled H+ transport in the Val177 strain. The Val177/Asn319 strain also catalyzed uncoupled H+ transport, but to a lesser degree than the single Val177 mutant. In addition, the Val177/Asn319 mutant was shown to transport galactosides with or without H+. The observed H+/lactose stoichiometry was 0.30 in the double mutant compared to 0.98 in the wild-type strain. When an H+ electrochemical gradient was generated across the membrane, the Val177/Asn319 mutant permease was shown to facilitate an extremely rapid net H+ leak if nonmetabolizable galactosides had been equilibrated across the membrane. The mechanism of this leak is consistent with a circular pathway involving H+/galactoside influx and uncoupled galactoside efflux. The magnitude of the H+ leak in the presence of nonmetabolizable galactosides was so great in the double mutant that low concentrations of certain galactosides (i.e. 0.5 mM thiodigalactoside) resulted in a complete inhibition of growth. These results are discussed with regard to the possibility that cation and sugar binding to the lactose permease may involve a direct physical coupling at a common recognition site.     

Evidence for interactions between the energy-dependent transport of sugars and the membrane potential in the yeastRhodotorula gracilis (Rhodosporidium toruloides)

Summary A membrane potential (inside negative) across the plasma membrane of the obligatory aerobic yeastRhodotorula gracilis is indicated by the intracellular accumulation of the lipid-soluble cations tetraphenylphosphonium and triphenylmethylphosphonium. The uptake of these ions is inhibited by anaerobic conditions, by uncouplers, by addition of diffusible ions, or by increase of the leakiness of the membrane caused by the polyene antibiotic nystatin. The membrane potential is strongly pH-dependent, its value increasing with decreasing extracellular proton concentration. Addition of transportable monosaccharides causes a depolarization of the electrical potential difference, indicating that the H⁺-sugar cotransport is electrogenic. The effect on the membrane potential is enhanced by increasing the sugar concentration. The half-saturation constants of depolarization ford-xylose andd-galactose were comparable to those of the corresponding transport system for the two sugars. All agents that depressed the membrane potential inhibited monosaccharide transport; hence the membrane potential provides energy for active sugar transport in this strain of yeast.     

Role of Metabolic Energy in the Transport of β-Galactosides by Streptococcus lactis

Streptococcus lactis (ATCC 7962) accumulated thiomethyl-β-galactoside (TMG) and other galactosides against concentration gradients when the cells were supplied with a metabolizable substrate, such as glucose. The accumulated TMG was free and not phosphorylated. In the absence of glucose, TMG rapidly entered the cell to a concentration equal to that of the medium. Agents that uncouple oxidative phosphorylation abolished active transport but not the carrier-facilitated entry of TMG. Evidence that the transport carriers were functional in the absence of glucose or in the presence of uncoupling agents included the demonstration of counterflow, which depends on competitive inhibition for the carrier for exit.     

Active transport of L-sorbose and 2-deoxy-D-galactose in Saccharomyces fragilis.

Sorbose and 2-deoxy-D-galactose are taken up in Saccharomyces fragilis by an active transport mechanism, as indicated by the energy requirement of the process and the accumulation of free sugar against the concentration gradient. There are no indications for transport-associated phosphorylation as mechanism of energy coupling with these two sugars. The measured sugar-proton cotransport and the influx inhibition by uncouplers suggest a chemiosmotic coupling mechanism. Thus there are at least two different active transport mechanisms operative in Saccharomyces fragilis: transport-associated phosphorylation in the case of 2-deoxy-D-glucose and chemiosmotic coupling in the case of sorbose and 2-deoxy-D-galactose. The differences between the two mechanisms are discussed. Uncouplers do not stimulate downhill sorbose transport in energy-depleted cells and evoke an almost complete inhibition of efflux and of exchange transport. The differences between this sugar-proton cotransport system and similar systems in bacteria and Chlorella are discussed.     

Active transport of l-sorbose and 2-deoxy-d-galactose in Saccharomyces fragilis

Sorbose and 2-deoxy-d-galactose are taken up in Saccharomyces fragilis by an active transport mechanism, as indicated by the energy requirement of the process and the accumulation of free sugar against the concentration gradient. There are no indications for transport-associated phosphorylation as mechanism of energy coupling with these two sugars.The measured sugar-proton cotransport and the influx inhibition by uncouplers suggest a chemiosmotic coupling mechanism. Thus there are at least two different active transport mechanisms operative in Saccharomyces fragilis: transport-associated phosphorylation in the case of 2-deoxy-d-galactose and chemiosmotic coupling in the case of sorbose and 2-deoxy-d-galactose. The difference between the two mechanisms are discussed.Uncouplers do not stimulate downhill sorbose transport in energy-depleted cells and evoke an almost complete inhibition of efflux and of exchange transport.The differences between this sugar-proton cotransport system and similar systems in bacteria and Chlorella are discussed.     

Uncoupler-resistant mutants of bacteria.

The chemiosmotic model of energy transduction offers a satisfying and widely confirmed understanding of the action of uncouplers on such processes as oxidative phosphorylation; the uncoupler, by facilitating the transmembrane movement of protons or other compensatory ions, reduces the electrochemical proton gradient that is posited as the energy intermediate for many kinds of bioenergetic work. In connection with this formulation, uncoupler-resistant mutants of bacteria that neither exclude nor inactivate these agents represent a bioenergetic puzzle. Uncoupler-resistant mutants of aerobic Bacillus species are, in fact, membrane lipid mutants with bioenergetic properties that are indeed challenging in connection with the chemiosmotic model. By contrast, uncoupler-resistant mutants of Escherichia coli probably exclude uncouplers, sometimes only under rather specific conditions. Related phenomena in eucaryotic and procaryotic systems, as well as various observations on uncouplers, decouplers, and certain other membrane-active agents, are also briefly considered.     

Inhibition of bacterial transport by uncouplers of oxidative phosphorylation. Effects of pentachlorophenol and analogues in Bacillus subtilis.

Analogues of the potent uncoupler of oxidative phosphorylation pentachlorophenol were tested as inhibitors of proline and glycine transport by Bacillus subtilis. These analogues included less highly substituted chlorophenols and pentachlorothiophenol. Like pentachlorophenol, they are non-competitive inhibitors of proline transport and uncompetitive inhibitors of glycine transport. However, the less highly substituted chlorophenols are weaker acids than pentachlorophenol and also weaker inhibitors. Analysis indicated that the anionic form of the uncouplers is the inhibiting species. Pentachlorothiophenol, a water-insoluble anion, is also a potent inhibitor. These results support previous studies that concluded that uncouplers of oxidative phosphorylation inhibit amino acid transport by binding at specific sites on proteins, the free energy of interaction stabilizing 'unproductive' conformations. Such specific interactions of uncoupler with protein are probably commonplace.     

Energetics of glycylglycine transport in Escherichia coli

The transport system for glycylglycine in Escherichia coli behaves like a shock-sensitive transport system. The initial rate of transport is reduced 85% by subjecting whole cells to osmotic shock, and glycylglycine is not transported by membrane vesicles. The energetics of transport was studied with strain ML 308-225 and its mutant DL-54, which is deficient in Ca(2+)- and Mg(2+)-stimulated adenosine 5'-triphosphatase (EC 3.6.1.3) activity. It is concluded that active transport of glycylglycine, like other shock-sensitive transport systems, has an obligatory requirement for phosphate bond energy, but not for respiration or the energized state of the membrane. The major evidence for this conclusion is as follows. (i) Uptake of glycylglycine is severely inhibited by arsenate. (ii) Oxidizable energy sources such as d-lactate, succinate, and ascorbate, which is mediated by N-methylphenazinium methylsulfate, cannot serve as energy sources for the transport of glycylglycine in DL-54, which lacks oxidative phosphorylation. (iii) When energy is supplied only from adenosine-5'-triphosphate produced by glycolysis (anaerobic transport assays with glucose as the energy source in DL-54), substantial uptake of glycylglycine is observed. (iv) When the Ca(2+)-Mg(2+)-adenosine triphosphatase activity is absent but substrate-level phosphorylations and electron transport are operating (glucose as the energy source in DL-54), transport of glycylglycine shows significant resistance to the uncouplers, dinitrophenol and carbonyl cyanide-p-trifluoromethoxyphenylhydrazone.     

Energy coupling of the hexose phosphate transport system in Escherichia coli

The active transport of hexose phosphates in Escherichia coli was inhibited by many uncouplers or inhibitors of oxidative metabolism. Fluoride and the lipid soluble cation, triphenylmethylphosphonium, had little effect. The uninduced level of transport was sensitive to fluoride, but not to azide. After energy uncoupling of active transport, the cells could equilibrate their intracellular water with the glucose-6-phosphate in the medium and displayed exit counter-flow suggesting the existence of carrier-mediated transport in the energy-uncoupled cells. The uncoupled transport of glucose-6-phosphate was inhibited by fructose-6-phosphate; the uninduced level of glucose-6-phosphate transport was not inhibited by fructose-6-phosphate. After energy uncoupling, the influx had a low affinity suggesting that, unlike the transport of beta-galactosides, the energy coupling for the active transport of hexose phosphate involved a change in the affinity of influx.     

Biochemical mechanism of GSH depletion induced by 1,2-dibromoethane in isolated rat liver mitochondria. Evidence of a GSH conjugation process

HPLC measurements of GSH and GSSG levels in isolated rat liver mitochondria, on addition of 1,2-dibromoethane (DBE), revealed the presence of a glutathione (GSH)-conjugating pathway of DBE. This process required the structural integrity of the mitochondrial matrix and inner membrane complex and was inhibited by the uncouplers of oxidative phosphorylation, particularly 2,4-dinitrophenol. On the other hand it was not affected by the energetic state of the mitochondria, since other mitochondrial inhibitors like KCN and oligomycin did not have any effect on it. This process also did not require the involvement of mitochondrial inner membrane transport systems, based on the measurement of the mitochondrial transmembrane potential. The involvement of mitochondrial GSH-S-transferases, located either in the matrix or in the intermembrane space, is discussed.     

Succinate Transport in Escherichia coli Mutants Defective in Succinate Metabolism

To investigate the operation of a succinate transport system in Escherichia coli, mutants defective in succinate metabolism were isolated. Although the metabolic blocks in the mutant cells were not complete, the succinate transport assays became possible.

Pyruvate, lactate or many other carbon sources stimulated succinate uptake, and the uptake was strongly inhibited by some electron transport inhibitors, uncouplers of oxidative phosphorylation and sulfhydryl reagents. The mutant strains accumulated succinate into the cells against a concentration gradient when suitable energy sources were supplied.

Presence of glucose in the medium strongly repressed the formation of the succinate transport system. The optimum pH for the succinate uptake was between 7.8 and 8.0.