Formation of an ion transport supercomplex in Escherichia coli. An experimental model of direct transduction of energy.
(42/66)
Hydrogen gas production was observed to occur during ATP-driven H+/K+ exchange in anaerobically grown E. coli. Neither process was found in aerobically grown cells or anaerobic cells grown on nitrate medium or when the osmotic pressure was decreased or K+ removed, or finally when DCCD, arsenate or CCCP was applied. Dithiothreitol restored the process even in the presence of CCCP but not in other cases of inhibition. A model of a multienzyme transport super-complex is proposed. The supercomplex consists of three genetically independent mechanisms: F0F1 H+-ATPase to provide energy, the K+-transporting Trk system as energy sink and formate-hydrogen lyase as donor of reducing equivalents. Within this supercomplex direct transduction of energy is accomplished via oxidation of 2 SH to S-S. (+info)
Reconstitution of the mitochondrial non-selective Na+/H+ (K+/H+) antiporter into proteoliposomes.
(43/66)
Mitochondria contain two Na+/H+ antiporters, one of which transports K+ as well as Na+. The physiological role of this non-selective Na+/H+ (K+/H+) antiporter is to provide mitochondrial volume homeostasis. The properties of this carrier have been well documented in intact mitochondria, and it has been identified as an 82,000-dalton inner membrane protein. The present studies were designed to solubilize and reconstitute this antiporter in order to permit its isolation and molecular characterization. Proteins from mitoplasts made from rat liver mitochondria were extracted with Triton X-100 in the presence of cardiolipin and reconstituted into phospholipid vesicles. The reconstituted proteoliposomes exhibited electroneutral 86Rb+ transport which was reversibly inhibited by Mg2+ and quinine with K0.5 values of approximately 150 and 300 microM, respectively. Incubation of reconstituted vesicles with dicyclohexylcarbodiimide resulted in irreversible inhibition of 86Rb+ uptake into proteoliposomes. Incubation of vesicles with [14C]dicyclohexylcarbodiimide resulted in labeling of an 82,000-dalton protein. These properties, which are also characteristic of the native Na+/H+ (K+/H+) antiporter, lead us to conclude that this mitochondrial carrier has been reconstituted into proteoliposomes with its known native properties intact. (+info)
K+/H+-antiporter nigericin arrests DNA synthesis in Ehrlich ascites carcinoma cells.
(44/66)
Acidification of the cytoplasm of Ehrlich ascites carcinoma cells to pH 6.3 arrests DNA synthesis in these cells. Such an effect can be achieved by incubating the cells at pH 6.2 or by adding low concentrations of the K+/H+ antiporter, the antibiotic nigericin, at neutral pH. Glucose and anaerobiosis potentiate the nigericin effect. The inhibition of DNA synthesis by nigericin occurs without any significant decrease in the ATP concentration and in the mitochondrial membrane potential. The DNA synthesis inhibition is caused neither by a decrease in the intracellular [K+] nor by an increase in the intracellular [Na+] accompanying the nigericin effect (at least at low concentrations of the antibiotic). Nigericin should thus be regarded as a type of a cytostatic primarily affecting intracellular pH. (+info)
Matrix magnesium and the permeability of heart mitochondria to potassium ion.
(45/66)
Isolated beef heart mitochondria were treated with A23187 in the presence of different concentrations of Mg2+ or EDTA to establish varying levels of total mitochondrial Mg2+. The Mg2+ content was related to the rate of passive swelling of the mitochondria in potassium acetate and other potassium salts in which swelling is presumed to depend on K+ entry via an endogenous K+/H+ antiport. Swelling in these salts does not commence until Mg2+ has been depleted from an initial value of 36 nmol X mg-1 of protein to 8 nmol/mg-1, or less. Below this level, swelling increases linearly with decreasing Mg2+ to a maximum rate at 2 nmol of Mg2+ X mg-1. Rotenone-treated heart mitochondria suspended in 75 mM potassium acetate at pH 7.80 show no delta pH by 5,5-dimethyl-2,4-oxazolidinedione distribution. Distribution of methylamine also shows essentially no delta pH under these conditions when allowance is made for binding of [14C]methylamine by mitochondrial membranes under these conditions. Addition of A23187 results in a small and transient delta pH (delta pH less than 0.14, acid interior) as measured by methylamine distribution. Estimation of the maximum matrix free Mg2+ concentration from the maximum delta pH observed and the external free Mg2+ concentration at equilibrium with A23187 shows that swelling is not initiated until matrix free Mg2+ is decreased to below 150 microM. An independent estimate of free Mg2+ using a null-point procedure gives a lower, but quite similar value (50 microM) for maximum matrix free Mg2+ when swelling commences. The large depletion of total and free Mg2+ that is required to activate swelling in potassium acetate (and presumably K+/H+ antiport activity) does not appear to be compatible with previous indications that free Mg2+ acts as a "carrier brake" to regulate K+ extrusion from the mitochondrion on such an antiport (Garlid, K. D. (1980) J. Biol. Chem. 255, 11273-11279). The removal of a tightly bound component of mitochondrial Mg2+ is closely related to increased K+ permeability and increased passive swelling in potassium salts. This Mg2+ appears to play a role in the maintenance of mitochondrial membrane structure and integrity. (+info)
Evidence for multiple K+ export systems in Escherichia coli.
(46/66)
The role of the K+ transport systems encoded by the kefB (formerly trkB) and kefC (formerly trkC) genes of Escherichia coli in K+ efflux has been investigated. The rate of efflux produced by N-ethylmaleimide (NEM), increased turgor pressure, alkalinization of the cytoplasm, or 2,4-dinitrophenol in a mutant with null mutations in both kef genes was compared with the rate of efflux in a wild-type strain for kef. The results show that these two genes encode the major paths for NEM-stimulated efflux. However, neither efflux system appears to be a significant path of K+ efflux produced by high turgor pressure, by alkalinization of the cytoplasm, or by addition of high concentrations of 2,4-dinitrophenol. Therefore, this species must have at least one other system, besides those encoded by kefB and kefC, capable of mediating a high rate of K+ efflux. The high, spontaneous rate of K+ efflux characteristic of the kefC121 mutation increases further when the strain is treated with NEM. Therefore, the mutational defect that leads to spontaneous efflux in this strain does not abolish the site(s) responsible for the action of NEM. (+info)
Kinetics of inhibition and binding of dicyclohexylcarbodiimide to the 82,000-dalton mitochondrial K+/H+ antiporter.
(47/66)
Inhibition of K+/H+ antiport by N,N'-dicyclohexylcarbodiimide in Mg2+ depleted mitochondria follows first order kinetics, exhibiting a half-time of 13 min when mitochondria are incubated with 50 nmol/mg inhibitor at 0 degrees C. 14C radiolabeled N,N'-dicyclohexylcarbodiimide binds to the 82,000-dalton protein, and the second order rate constant for binding is found to be approximately the same as the second order rate constant for inhibition. These findings provide additional confirmation of the identification of this porter with the 82,000-dalton protein and permit us to estimate that rat liver mitochondria contain about 8 pmol/mg of K+/H+ antiporter with a turnover number of 700 s-1. The K+/H+ antiporter of rat liver mitochondria is protected from N,N'-dicyclohexylcarbodiimide inhibition and binding by quinine and by endogenous Mg2+. An 82,000-dalton, [14C]N,N'-dicyclohexylcarbodiimide-binding protein is also observed in rat liver submitochondrial particles, establishing this as an integral protein of the inner membrane. Submitochondrial particles, presumed to be inverted in membrane orientation, are protected from radiolabeling by external Mg2+, supporting the contention that the Mg2+ binding site is localized to the matrix side of the K+/H+ antiporter. (+info)
On the mechanism by which dicyclohexylcarbodiimide and quinine inhibit K+ transport in rat liver mitochondria.
(48/66)
Passive uptake of potassium acetate into the mitochondrial matrix can be induced by nigericin, a K+/H+ antiporter, or by A23187, a Mg2+/2H+ antiporter. The latter process is thought to reflect operation of the Mg2+-dependent, endogenous K+/H+ antiporter, but there is ambiguity with respect to the mechanism of K+ transport in this assay (Nakashima, R.A., and Garlid, K.D. (1982) J. Biol. Chem. 257, 9252-9254). Kinetic analysis of potassium acetate transport provides verification that Mg2+ depletion 1) unmasks the K+/H+ antiporter, 2) opens up an intrinsic anion uniporter, 3) has no effect on acetic acid transport, and 4) does not induce high K+ uniport conductance. Mg2+-dependent uptake of potassium acetate is thereby shown to be mediated specifically by operation of the endogenous K+/H+ antiporter, as previously proposed. An extension of this analysis confirms that N,N'-dicyclohexylcarbodiimide and quinine block potassium acetate uptake via specific action on the K+/H+ antiporter. These findings support those of a previous study (Martin, W.H., Beavis, A.D., and Garlid, K.D. (1984) J. Biol. Chem. 259, 2062-2065) in which binding of [14C]N,N'-dicyclohexylcarbodiimide to membrane proteins under selective conditions was used to identify an 82,000-dalton band as the protein responsible for K+/H+ antiport in mitochondria. (+info)