Action of valinomycin in vivo on Ehrlich ascites tumor cells. A change in the ultrastructure of the tumor cells under the influence of valinomycin]

It was found with the help of electron microscopy that valinomycin administered to mice with Ehrlich ascitic tumors in a dose inhibiting the proliferating activity induced impairements in the mitochondria. The changes were similar to those under the effect of valinomycin in vitro. An increase in the antibiotic dose resulted in more pronounced and irreversible changes not only in the mitochondria but also in other structures of the tumor cells.     

Direct measurement of the membrane potential of Ehrlich ascites tumor cells: lack of effect of valinomycin and ouabain.

The membrane potential of Ehrlich ascites tumor cells and the effects of valinomycin and ouabain upon it have been determined. The membrane potential in control cells was 12.0 mV, inside negative. Neither valinomycin nor ouabain alone affected this value. However, valinomycin and ouabain in combination resulted in a slight hyperpolarization of the membrane. Concomitant determinations of cellular Na+, K+ and Cl- showed that valinomycin induced net losses of K+ and Cl- and a net gain in Na+ when compared to ouabain-inhibited cells. K+ permeability was increased by approximately 30% in the presence of valinomycin. In addition, valinomycin caused a rapid depletion of cellular ATP. Inhibition of Na/K transport by ouabain was without sparing effect on the rate of ATP depletion. Possible mechanisms for the electroneutral increase in K+ permeability induced by valinomycin are discussed.     

Effect of valinomycin on mitochondrial ultrastructure and function of intact Ehrlich ascites tumor cells

Ultrastructural changes in the mitochondria of intact Ehrlich ascites tumor cells were observed after stimulation by valinomycin of the energy-dependent transport of K⁺ into mitochondria. The mitochondria in cells taken directly from the animal displayed an orthodox configuration. After repeated washings of the cells, the mitochondria were converted to the ‘condensed’ or ‘aggregated’ state. The addition of valinomycin resulted in a transformation of mitochondria from the condensed to orthodox and markedly swollen forms. Alterations in cell size, O₂ uptake, and K⁺ content accompanied the changes in mitochondrial morphology.     

Characterization of the binding of valinomycin to bacteriorhodopsin

Circular dichroism spectroscopy has been used to investigate the binding of valinomycin to bacteriorhodopsin in purple membrane suspensions. Addition of valinomycin to purple membrane suspensions obtained from Halobacterium halobium causes the circular dichroism spectrum to shift from an aggregate spectrum to one resembling a monomer spectrum, indicating a loss of chromophore-chromophore interactions. By observing the spectral change upon titration of valinomycin, an apparent dissociation constant of 30–40 M for valinomycin binding was determined. Kinetics of dark adaptation for valinomycin-treated purple membrane are comparable to those for monomeric bacteriorhodopsin. Centrifugation studies demonstrate that valinomycin-treated purple membrane sediments the same as untreated purple membrane suspensions. These results are consistent with a model in which valinomycin binds specifically to bacteriorhodopsin without disrupting the purple membrane fragments.Abbreviations BR bacteriorhodopsin - CD circular dichroism - Tricine N-[tris-(hydroxymethyl) methyl] glycine     

Effects of valinomycin,ouabain, and potassium on glycolysis and intracellular pH of Ehrlich ascites tumor cells

Summary Both valinomycin and ouabain block reaccumulation of K⁺ by Ehrlich ascites tumor cells depleted of K⁺ and cause loss of K⁺ from high-K⁺ cells. Glucose largely reverses the effect of valinomycin and to a lesser extent that of ouabain.In cells depleted of K⁺, glucose utilization and lactate production are impaired. Neither extracellular pH (pH_e) nor intracellular pH (pH_i) falls to the extent seen in non-depleted glycolyzing cells. Addition of K⁺ to depleted cells reverses these effects. Valinomycin increases glycolysis in K⁺-depleted cells but to a greater extent in nondepleted or K⁺-repleted cells. The increase in lactate production caused by valinomycin is accompanied by a correspondingly greater fall in pH_e and pH_i. Valinomycin, unlike other uncoupling agents, does not abolish the pH gradient across the plasma membrane. Increased utilization of glucose resulting from addition of K⁺ to K⁺-depleted cells or addition of valinomycin either to depleted or non-depleted cells can be entirely accounted for by increased lactate production. Ouabain blocks the stimulatory effect of added K⁺ on K⁺-depleted cells and has an inhibitory effect on glycolysis in non-depleted cells. It does not obliterate the difference in glycolytic activity between K⁺-depleted and nondepleted cells. Ouabain does not completely block the effect of valinomycin in augmenting glycolysis in depleted or non-depleted cells. Increased accumulation of glycolytic intermediates, particularly dihydroxyacetone phosphate, is found in glycolyzing K⁺-depleted cells. The most marked accumulation was found in ouabain-treated K⁺-deficient cells.This investigation was supported by U.S. Public Health Service grant no. GM 13606 from the National Institute of General Medical Sciences and by grant no. P-603 from the American Cancer Society.PHS Research Career Program Award 4 K06 GM 19429 from the National Institute of General Medical Sciences.     

Direct measurement of the membrane potential of ehrlich ascites tumor cells: Lack of effect of valinomycin and ouabain

The Journal of Membrane Biology - The membrane potential of Ehrlich ascites tumor cells and the effects of valinomycin and ouabain upon it have been determined. The membrane potential in control...     

Cation binding by valinomycin and trinactin at the air-water interface: Cooperativity in cation binding by valinomycin

A previous communication reported the uptake of monovalent cations by a valinomycin monolayer at the air-water interface (Colacicco, G., Gordon, E. E. and Berchenko, G. (1968) Biophys. J. 8,22a). A similar study has been done with trinactin. As in the case of valinomycin, an elevated surface potential is obtained when the cation-ionophore complex is formed. A surface potential of 0.82 V was obtained for the trinactin-cation complex, as compared with 0.54 V for uncomplexed trinactin. The observed cation selectivity NH₄⁺ > K⁺ > Rb⁺ > Cs⁺, Na⁺ and Li⁺ is in agreement with partition and bilayer conductance experiments.A minimum packing area of 130 Ų obtained for the trinactin-cation complex was in excellent agreement with the 125 Ų predicted from space filling models, reinforcing the suggestion that area-per-molecule calculations obtained at the air-wate interface can provide useful information on the molecular dimensions of these hydrophobic, relatively low molecular weight transport antibiotics.Comparison of the data obtained previously with valinomycin and with trinactin revealed two striking differences: (1) a large inflection in the force-area curve concurrent with cation binding and indicative of a conformational change was obtained with valinomycin,, but no evidence was found with trinactin; (2) the uptake of cations by trinactin could be predicted by simple equilibrium expressions, but the uptake of cations by valinomycin was strongly cooperative. Possible mechanisms for this cooperative association fo cations are discussed.     

The effect of valinomycin in fibroblasts from patients with fatty acid oxidation disorders

Disorders of the carnitine cycle and of the beta oxidation spiral impair the ability to obtain energy from fats at time of fasting and stress. This can result in hypoketotic hypoglycemia, cardiomyopathy, cardiac arrhythmia and other chronic medical problems. The in vitro study of fibroblasts from patients with these conditions is impaired by their limited oxidative capacity. Here we evaluate the capacity of valinomycin, a potassium ionophore that increases mitochondrial respiration, to increase the oxidation of fatty acids in cells from patients with inherited fatty acid oxidation defects. The addition of valinomycin to fibroblasts decreased the accumulation of the lipophilic cation tetraphenylphosphonium (TPP⁺) at low concentrations due to the dissipation of the mitochondrial membrane potential. At higher doses, valinomycin increased TPP⁺ accumulation due to the increased potassium permeability of the plasma membrane and subsequent cellular hyperpolarization. The incubation of normal fibroblasts with valinomycin increased [¹⁴C]-palmitate oxidation (measured as [¹⁴C]O₂ release) in a dose-dependent manner. By contrast, valinomycin failed to increase palmitate oxidation in fibroblasts from patients with very long chain acyl CoA dehydrogenase (VLCAD) deficiency. This was not observed in fibroblasts from patients heterozygous for this condition. These results indicate that valinomycin can increase fatty acid oxidation in normal fibroblasts and could be useful to differentiate heterozygotes from patients affected with VLCAD deficiency.     

Neurite formation and membrane changes of mouse neuroblastoma cells induced by valinomycin

A clonal cell line of mouse neuroblastoma cells was found to undergo morphological differentiation in the presence of a K⁺ ionophore, valinomycin, in the assay medium. This effect was blocked by increasing the concentration of KCl of the medium, suggesting that the changes in resting membrane potential and ion fluxes may be involved in the mechanism of the formation of neurites. No enhancement of the neurite formation was observed in salines containing high concentrations of KCl in the absence of valinomycin. Depolarizing agents including veratridine, gramicidin and ouabain did not stimulate the outgrowth of neurites. Neither electrophoretic mobility of the cells nor molecular anisotropy of fluorescence probes in the membranes was modified by the treatment of valinomycin. Instead, it modified the slow binding phase in kinetics of the interaction of 1-anilinonaphthalene-8-sulfonate (ANS) with the cells, which is related to the penetration process of the probe into membranes. Valinomycin also enhanced the fluorescence intensity of ANS by increasing the binding sites in neuroblastoma cells.     

Evidence for the presence of a specific ganglioside GM1/valinomycin complex in mixed monolayers

The effect of a negatively charged mono-sialoglyco-sphingolipid (GM1-ganglioside) on the molecular organization and on physiochemical properties of lipid/peptide (valinomycin) systems was investigated in monolayers at the air/water interface. At a high molar fraction of GM1, the surface pressure/area isotherms of the two-component films of the system GM1/valinomycin and the isotherm of the pure ganglioside monolayer are identical concerning the space requirement of the molecules and thereby the packing of the monolayer. Using space-filling molecular models, a simple calculation gives the theoretical amount of 4.5 ganglioside molecules associated with one molecule of the depsipeptide valinomycin. The average surface potential indicates, that valinomycin, interacting with the polar head group of GM1, becomes partly embedded within the lipid interface. For GM1/eicosanol and valinomycin/eicosanol mixtures, the agreement between theory and experimental data strongly supports the model of ideal mixing without any molecular interactions between the different components. The results suggest the formation of a ganglioside/valinomycin complex with simultaneous alteration of the surface potential and molecular structure of the single components.     

Effects and mechanisms of action of ionophorous antibiotics valinomycin and salinomycin-Na on Babesia gibsoni in vitro

Valinomycin and salinomycin-Na, 2 ionophorous antibiotics, exhibited in vitro antibabesial activities against Babesia gibsoni that infected normal canine erythrocytes containing low potassium (LK) and high sodium concentrations, i.e., LK erythrocytes, which completely lack Na,K-ATPase activity. The level of parasitemia of B. gibsoni was significantly decreased when the parasites were incubated in culture medium containing either 10(-1) ng/ml valinomycin or 10(2) ng/ml salinomycin-Na for 24 hr. Four-hour incubation in the culture medium containing 5 μg/ml salinomycin-Na led to the destruction of most parasites. In contrast, when the parasites infected canine erythrocytes containing high potassium (HK) and low sodium concentrations, i.e., HK erythrocytes, the in vitro antibabesial activities of both ionophorous antibiotics seemed to be weakened, apparently due to the protection by the host cells. Therefore, differential influences of ionophorous antibiotics on LK and HK erythrocytes were observed. In LK erythrocytes, the intracellular concentrations of potassium, sodium, and adenosine triphosphate (ATP) were not modified, and hemolysis was not observed after incubation in the medium containing each ionophorous antibiotic. These results suggested that these ionophorous antibiotics did not affect cells without Na,K-ATPase, and directly affected B. gibsoni. In HK erythrocytes, the ionophorous antibiotics increased the intracellular sodium concentration, and decreased the intracellular potassium and ATP concentrations, causing obvious hemolysis. Additionally, the decrease of the intracellular ATP concentration and the hemolysis in HK erythrocytes caused by valinomycin disappeared when the activity of Na,K-ATPase was inhibited by ouabain. These results indicate that modification of the intracellular cation concentrations by the ionophorous antibiotics led to the activation of Na,K-ATPase and increased consumption of intracellular ATP, and that the depletion of intracellular ATP resulted in hemolysis in HK erythrocytes. Moreover, the antibabesial activity of valinomycin disappeared when B. gibsoni in LK erythrocytes were incubated in culture media containing high potassium concentrations. This showed that the intracellular cation concentration in the parasites was not modified in those media and would remain the same.     

A study of the conformations of valinomycin in solution phase

Vibrational absorption and vibrational circular dichroism (VCD) spectra of valinomycin are measured, in different solvents, in the ester and amide carbonyl stretching regions. The influence of cations, namely Li(+), Na(+), K(+), and Cs(+), in methanol-d(4) solvent is also investigated. Ab initio quantum mechanical calculations using density functional theory and 6-31G* basis set are used to predict the absorption and VCD spectra. A bracelet-type structure for valinomycin that reproduces the experimental absorption and VCD spectra in inert solvents is identified. For the structure of valinomycin in polar solvents, a propeller-type structure was optimized, but further investigations are required to confirm this structure. A symmetric octahedral environment for the ester carbonyl groups in the valinomycin-K(+) complex is supported by the experimental VCD spectra. The results obtained in the present study demonstrate that even for large macrocyclic peptides, such as valinomycin, VCD can be used as an independent structural tool for the study of conformations in solution.     

The mechanism of action of valinomycin on the thylakoid membrane

Summary Most of the studies devoted to the mechanism by which certain antibiotics increase the ion permeability ofbiological membranes have been carried out on artificialmodel systems. Undoubtedly one of the major reasons for this was that some of the most relevant biological membrane systems are of submicroscopic dimensions and thus inaccessible to the common electrochemical measuring techniques. This holds for the inner membrane systems of chloroplasts, mitochondria, and retinal rods. Since it is not trivial that a mechanism of action found for a model membrane works as well in a biological one with a much higher structural complexity, it seemed worth-while to study the mechanism of action of ionophorous antibiotics on the above-mentioned biological membranes. In this paper, a nonelectrochemical method for measuring both the voltage and the current across the inner chloroplast membrane (or thylakoid membrane) is established in extension of earlier work. This method is used to characterize the mode of action of valinomycin on the thylakoid membrane.     

Toxicity of valinomycin on insects

Valinomycin was administered to Musca domestica, Periplaneta americana, Aedes aegypti, and mice. Although topical application to house flies did not cause appreciable toxicity, the substance was highly toxic when injected or administered per os, characteristic nervous symptoms occurring in intoxicated flies. Injected valinomycin was almost equally toxic to cockroaches. Aedes aegypti larvae, on the other hand, were hardly affected by the substance.On the cockroach semi-isolated heart preparation, heart block occurred also at low concentrations.Preliminary trials showed that valinomycin abolished the response of leg muscles to both direct and indirect stimulation and interrupted conduction of stimulus on the nervous cord connectives.     

Effect of valinomycin on ion transport in bacterial cells and on bacterial growth

The antimicrobial action of valinomycin relative to the K⁺ and Na⁺ contents of the medium has been investigated in several species of bacteria, particularly in Streptococcus faecalis, which effects energy-linked transport exclusively via degradation of glycolytic ATP, Micrococcus lysodeikticus, effecting active ion transport by respiration and Staphylococcus aureus, the energy-dependent ion transport of which is due to both glycolytic ATP degradation and respiration. It was demonstrated that valinomycin does not act on K⁺ transport in the glycolysing cells in the same manner as it does on respiring cells under similar conditions. Addition of valinomycin to respiring cells leads to an increase in K⁺ influx against the concentrational gradient in both growing and resting cells. In contrast to this, antibiotic-treated glycolysing cells experience passive K⁺ outflow down the concentrational gradient. It was thus concluded that the electrical potential cannot be the driving force for the energy-linked K⁺ transport in glycolysing cells.     

Total in vitro biosynthesis of the nonribosomal macrolactone peptide valinomycin

Natural products are important because of their significant pharmaceutical properties such as antiviral, antimicrobial, and anticancer activity. Recent breakthroughs in DNA sequencing reveal that a great number of cryptic natural product biosynthetic gene clusters are encoded in microbial genomes, for example, those of Streptomyces species. However, it is still challenging to access compounds from these clusters because many source organisms are uncultivable or the genes are silent during laboratory cultivation. To address this challenge, we develop an efficient cell-free platform for the rapid, in vitro total biosynthesis of the nonribosomal peptide valinomycin as a model. We achieve this goal in two ways. First, we used a cell-free protein synthesis (CFPS) system to express the entire valinomycin biosynthetic gene cluster (>19 kb) in a single-pot reaction, giving rise to approximately 37 μg/L of valinomycin after optimization. Second, we coupled CFPS with cell-free metabolic engineering system by mixing two enzyme-enriched cell lysates to perform a two-stage biosynthesis. This strategy improved valinomycin production ~5000-fold to nearly 30 mg/L. We expect that cell-free biosynthetic systems will provide a new avenue to express, discover, and characterize natural product gene clusters of interest in vitro.     

Effects of valinomycin on calcium mobilization in vascular smooth muscle cells induced by angiotensin II

The effect of the specific potassium (K+) ionophore valinomycin on increase in intracellular calcium concentration [( Ca2+]i) was studied in vascular smooth muscle cells (VSMC). Valinomycin at more than 10(-9) M dose-dependently suppressed phasic increase in [Ca2+]i in VSMC induced by angiotensin II (AII) in both control and Ca2+-free solution, indicating that it suppressed the release of Ca2+ from intracellular Ca2+ stores. Nicorandil and cromakalim, which are both K+ channel openers, also suppressed the increases in [Ca2+]i induced by AII in the Ca2+ free solution. However, valinomycin did not suppress AII-induced production of inositol 1,4,5-trisphosphate (IP3), which is known to mediate the release of Ca2+. These results indicate that decrease of intracellular K+ induced by valinomycin suppressed the release of Ca2+ from intracellular Ca2+ stores induced by IP3.     

Location of valinomycin in lipid vesicles

The location of the cyclododecadepsipeptide, valinomycin in vesicles formed from two synthetic lipids is studied by differential scanning calorimetry, spin-label partitioning electron paramagnetic resonance and [¹H]-nuclear magnetic resonance. The results show that valinomycin is located near the head group region of dipalmitoyl phosphatidyl choline vesicles and in the hydrophobic core of the dimyristoyl phosphatidyl choline vesicles in the liquid crystalline phase.     

Influence of Ca2+ and temperature on the interaction of gangliosides with valinomycin in mixed monolayers at the air/water interface

The effects of Ca2+ and temperature on mixed ganglioside-valinomycin-monolayers at the air/water interface were studied. Surface pressure-area isotherms of the pure gangliosides (GM1, GD1a) exhibited the typical monolayer characteristics. Pressure-area isotherms of the cyclodepsipeptide, valinomycin, were determined. In mixed monolayers, positive and negative deviation from the mean molecular area indicated the two components were miscible. Especially in GD1a mixtures, the addition of 0.01 mM calcium exhibited, with low molar fractions of valinomycin, a demixing effect in the direction of the phase separation of the components.     

K+-independent effects of valinomycin in photosynthetic systems

With chromatophores ofRhodospirillum rubrum, valinomycin inhibited electron transport in the presence or absence of K⁺. NH₄Cl had no effect on photophosphorylation but uncoupled with valinomycin present. ATPase activity was stimulated by NH₄Cl plus valinomycin but not by either alone. K⁺ partially reversed the inhibition of phosphorylation and the stimulation of ATPase by valinomycin plus NH₄Cl.With chloroplasts, valinomycin inhibited coupled but not basal electron transport. The inhibition was only partially reversed by uncouplers. Valinomycin stimulated the light-activated Mg²⁺-dependent ATPase similar to several uncouplers such as quinacrine, methylamine, and S-13. In addition, valinomycin inhibited delayed light emission and stimulated the H⁺/e^– ratio. These contrasting activities in chloroplasts are not easily explained.Contribution number 389 of the Charles F. Kettering Research Laboratory.