Use of 23Na nuclear magnetic resonance spectroscopy to determine the true intracellular concentration of free sodium in a halophilic eubacterium.

We present new data obtained by 23Na nuclear magnetic resonance spectroscopy, which can distinguish free intracellular sodium from cell-bound sodium, showing that the intracellular concentration of Na+ the halophilic eubacterium Vibrio costicola is only 5 to 20% of that in the extracellular medium. Previous methods could not distinguish free intracellular Na+ from that bound to cell structures, and it was believed that in halophilic eubacteria the total monovalent cation concentration inside matched that of the NaCl outside. Information obtained by the newer technology raises fundamental questions about the ways in which these organisms and others which live in hypersaline environments function and cope with osmotic stress.

13C NMR study of the interrelation between synthesis and uptake of compatible solutes in two moderately halophilic eubacteria. Bacterium Ba1 and Vibro costicola.

The synthesis and uptake of intracellular organic osmolytes (compatible solutes) were studied with the aid of natural abundance 13C NMR spectroscopy in two unrelated, moderately halophilic eubacteria: Ba1 and Vibrio costicola. In minimal media containing 1 M NaCl, both microorganisms synthesized the cyclic amino acid, 1,4,5,6-tetrahydro-2-methyl-4-pyrimidinecarboxylic acid (trivial name, ectoine) as the predominant compatible solute, provided that no glycine betaine was present in the growth medium. When, however, the minimal medium was supplemented with glycine betaine or the latter was a component of a complex medium, it was transported into the cells and the accumulating glycine betaine replaced the ectoine. In Ba1, grown in a defined medium containing glucose as the single carbon source, ectoine could only be detected if the NaCl concentration in the medium was higher than 0.6 M; the ectoine content increased with the external salt concentration. At NaCl concentrations below 0.6 M, alpha,alpha-trehalose was the major organic osmolyte. The concentration of ectoine reached its peak during the exponential phase and declined subsequently. In contrast, the accumulation of glycine betaine continued during the stationary phase. The results presented here indicate that, at least in the two microorganisms studied, ectoine plays an important role in haloadaptation.

An NADH:quinone oxidoreductase of the halotolerant bacterium Ba1 is specifically dependent on sodium ions.

The rate of NADH oxidation by inverted membrane vesicles prepared from the halotolerant bacterium Ba1 of the Dead Sea is increased specifically by sodium ions, as observed earlier in whole cells. The site of this sodium effect is identified as the NADH: quinone oxidoreductase, similarly to the other such system known, Vibrio alginolyticus (H. Tokuda and T. Unemoto (1984) J. Biol. Chem. 259, 7785-7790). Sodium accelerates quinone reduction severalfold, but oxidation of the quinol, with oxygen as terminal electron acceptor, is unaffected. The sodium-dependent pathway of quinone reduction exhibits higher apparent affinity to extraneous quinone (Q-2) than the sodium-insensitive pathway, and is specifically inhibited by 2-heptyl-4-hydroxyquinoline N-oxide. ESR spectra of the membranes contain a feature at g = 1.98 which is tentatively identified as one originating from semiquinone. This feature is increased by NADH and decreased by addition of Na+, suggesting that, as proposed from different kinds of evidence for the V. alginolyticus system, sodium affects the semiquinone reduction step. As in the other system, the site of sodium stimulation in Ba1 probably corresponds to the site of sodium translocation, which was shown earlier (S. Ken-Dror, R. Shnaiderman, and Y. Avi-Dor (1984) Arch. Biochem. Biophys. 229, 640-649) to be linked directly to a redox reaction in the respiratory chain.

Functional characterization of the uncoupler-insensitive Na+ pump of the halotolerant bacterium, Ba1.

Respiration initiates Na+ efflux from Na+-preloaded cells of the halotolerant bacterium, Ba1. This efflux can take place against the concentration and electrochemical gradients. Since it is not inhibited by carbonylcyanide-p-trifluoromethoxyphenyl-hydrazone or N'N'-dicyclohexylcarbodiimide, it seems unlikely that either delta p (electrochemical potential difference of H+ across the membrane) generated by the primary proton pump or ATP play a role in the transduction of the energy supplied by electron transport. The electrogenic extrusion of Na+ causes passive counterflow of protons and/or simultaneous flux of permeant anions. In the absence of permeant anions the charge compensation attained by influx of protons is not complete. The membrane potential which persists in this case is inside negative and insensitive to uncoupler. The influx of protons builds up a delta pH of reversed sign (more acid inside), which is insensitive to uncoupler. The simultaneous efflux of Na+ and permeant anions diminishes the intracellular salt content and, as a corollary, causes volume contraction. Thus, the respiration-linked, uncoupler-insensitive Na+ pump may play a role in the regulation of the intracellular salt content.

Regulation of respiration by Na+ and K+ in the halotolerant bacterium, Ba1.

In the obligate aerobe, moderate halophile bacterium, Ba1, the ion composition of the medium was found to have a profound influence on the response of the respiratory system to changes in the external pH. In the pH range 6.5 to 8.5 the respiratory activity either increased or decreased progressively, depending whether K+ or Na+ ions were omitted from the medium. A nearly constant rate of respiration was observed in the entire pH range when both K+ and Na+ were present simultaneously. The stimulatory effect of Na+ was expressed especially in the alkaline pH range, where it induced acidification of the intracellular milieu. It was manifest in whole cells as well as in inverted membrane vesicles, and was not affected by either uncoupler or inhibitor of H+-ATPase. In contrast, the respiratory stimulation induced by K+ was most prominent in the acidic pH range and was accompanied by alkalinization of the internal pH. The effect of K+ was observed only in intact cells. Agents which interfered with energy transfer suppressed the effect of K+. With ethanol as the electron donor, Na+ was found to decrease the extent of reduction of the cellular NAD+ in the aerobic steady state, and to cause increased reduction of the cytochromes. K+ had no appreciable effect on the extent of reduction of any component in the respiratory chain. The implications of the above findings are discussed in relation to the mechanism(s) involved in the cation-mediated regulation of respiration and intracellular pH.

Interrelation between salvage of purine nucleotides and protein synthesis in rat heart cells.

The effect of transition from a respiring to a respiration-inhibited state on the rate of protein synthesis was investigated in glycolyzing, cultured rat heart cells. The rate was found to be significantly lower after blocking respiration, and it was further decreased by L-lactate. In contrast, pyruvate or phenazine methosulfate prevented the drop in the rate caused by lack of respiration. The changes in the respiratory state also affected the steady-state concentration of ATP, which varied in the same sense as the rate of protein synthesis. Pyruvate or phenazine methosulfate induced an increment in the concentration of ATP of respiration-inhibited cells. This increment could not be accounted for by more extensive phosphorylation of the available purine nucleotides, but required repletion of the pool by synthesis of purine nucleotides through the salvage pathway. Pyruvate and phenazine methosulfate were found to stimulate incorporation of labeled hypoxanthine into the purine nucleotide fraction in general, and into the nucleotide triphosphates in particular. Under similar incubation conditions an increase in the ATP/ADP ratio was also noted. The stimulatory effect of pyruvate on protein synthesis and on the cellular level of ATP was also observed in respiration-inhibited 3T6 cells and in human fibroblasts, but not in human fibroblasts deficient in the salvage enzyme, hypoxanthine-guanine-phosphoribosyltransferase. Based on the demonstrated influence of L-lactate, pyruvate, and phenazine methosulfate on the salvage synthesis of purine nucleotides [K. Ravid, P. Diamant, and Y. Avi-Dor, (1984) Arch. Biochem. Biophys. 229, 632-639] and on the present findings, the connection between protein synthesis and the salvage activity is discussed.

Uncoupler-stimulated Na+ pump and its possible role in the halotolerant bacterium, Ba.

In cells of Ba1 suspended in K salt as the osmoticum, the respiratory rate declined by 80% between the pH values of 6.5 and 8.5. Catalytic amounts of Na+ ions prevented this drop. The possibility that Na+ exerted its effect by an influence on proton fluxes across the membrane (Na+/H+ exchange) was explored. Addition of catalytic amounts of Na+ ions to cells respiring at pH 8.5 elicited an influx of protons and, as a result, the delta pH across the membrane became diminished. delta psi (membrane potential) was not affected by Na+. At pH 6.5, Na+ caused no proton influx. FCCP (carbonylcyanide-p-trifluoromethoxyphenylhydrazone) collapsed delta psi, but the Na+-dependent proton influx observed at pH 8.5 became enhanced, leading to an inversion of delta pH (more acid inside). When a Na salt was used as the osmoticum, delta pH of reversed polarity was generated by respiration also in the absence of FCCP. Respiring, inverted membrane vesicles responded to a Na+ pulse essentially as the intact cells. Based on the above and some additional findings it is suggested that these Na+-dependent effects are suited to prevent a raise in the intracellular pH over the level which hinders the respiratory activity. It may also play a role in the regulation of intracellular Na salt content.

Regulation of the salvage pathway of purine nucleotide synthesis by the oxidation state of NAD+ in rat heart cells.

The rate of salvage of purine nucleotides from hypoxanthine in glycolyzing, cultured rat heart cells was found to be decreased when respiration was suppressed. Pyruvate or phenazine methosulfate, acting as hydrogen acceptors, reversed the effect of the respiratory block. The inhibition and the reversal could not be attributed to the limitation of energy supply or of 5-phosphoribosyl-1-pyrophosphate. A causal connection was, however, shown to exist between this inhibition and the concomitant shift in the redox state of NAD+ in favor of NADH. NADH also inhibited the key enzyme of the salvage pathway, hypoxanthine-guanine-phosphoribosyltransferase, in cell-free extracts. Regulation of purine nucleotide synthesis by the redox state of NAD+ in heart cells might gain significance during transition from respiring to hypoxic state and vice versa.

The effect of antibiotics on the photocycle and protoncycle of purple membrane suspensions.

The interrelation was studied between the phototransient absorbing maximally at 412 nm (M412) and light-induced proton release under steady-state conditions in aqueous suspensions of 'purple membrane' derived from Halobacterium halobium. The decay of M412 was slowed down by the simultaneous application of the ionophoric antibiotics valinomycin and beauvericin. The former had only slight activity alone and the latter was effective only in conjunction with valinomycin. The steady-state concentration of M412 which was formed on illumination was a direct function of the concentration of valinomycin. Maximum stabilization of M412 was obtained when the valinomycin was approximately equimolar with the bacteriorhodopsin. Addition of salts to the medium increased the number of protons released per molecule of M412 without affecting the level of M412 which was produced by continuous illumination. The effectiveness of the salts in this respect depended on the nature of the cation. Ca2+ and their antagonists La3+ and ruthenium red were found to have especially high affinity for the system. The extent of light-induced acidification could not be enhanced by increasing the pH of the medium from 6.5 to 7.8. The possible mechanism of action of the ionophores and of the cations on the photocycle and on the proton cycle is discussed.

Chloride-dependent restoration of coupling by oligomycin in rat liver mitochondria.

In rat liver mitochondria suspended in KC1 medium, oligomycin interfered with the effect of uncouplers on energy conservation. It antagonized the effect of uncouplers that are weak acids (2,4-dinitrophenol etc.), but enhanced that of the lipid-penetrating cation NN-dimethyl-N'N'-dibenzylammonium. Oligomycin caused none of the above effects when Br- or NO-/3 was substituted for C1- as the major anionic species in the assay medium. The concentration of oligomycin that exerted the above-mentioned effects was lower than that necessary for the inhibition of energy transfer, but was in the range that induced C1- permeation through the cristae membrane. The possible connexion between the effect of oligomycin on C1- permeation and its interference with the action of uncouplers is discussed.

Stimulation of protein synthesis in cultured heart muscle cells by glucose.

Glucose stimulated the rate of incorporation of [3H]leucine into HCLO4-insoluble fraction of cultured rat heart muscle cells under both aerobic and anaerobic conditions. In the aerobic system the incorporation proceeded at a constant rate during 3h of incubation with and without glucose whereas in the anaeorbic system the incorporation ceased after approx. 60 min and could be renewed only by the addition of glucose. No correlation was found to exist between the above effect of glucose on protein synthesis and glucose-dependent changes in the intracellular ATP concentration. The extent of the stimulation of protein synthesis was related to the concentration of glucose. The effect of glucose was suppressed by cycloheximide but was not affected by actinomycin D. Glucose had no effect on the rate of transport of alpha-aminoisobutyric acid. Mannose also stimulated [3H]leucine incorporation. Substances that did not produce lactate were ineffective. Iodoacetate inhibited the stimulatory effect of glucose, but pyruvate, which by itself had no apprecialbe stimulatory action, relieved the inhibition induced by iodoacetate. There was no concomitant change in the concentration of ATP when iodoacetate inhibition was reversed by pyruvate. L-Lactate or other intermediates of energy metabolism could not relieve the inhibitory effect of iodoacetate.