18 research outputs found
LmrA activity enhances cell survival.
<p>A, Viability of energized cells (solid bar, LmrA; grey bar, non-expressing control) adapted for 30 min in buffer containing 0.5 M sucrose without or with 100 mM NaCl, 100 mM KCl or 50 mM Na<sub>2</sub>SO<sub>4</sub>, followed by 100-fold dilution into ultrapure water, or in buffer containing 0.125 M sucrose and 25 mM NaCl (control referred to as 4-fold dilution). B, Effect of mutations in LmrA on the viability after dilution of cells pre-exposed to 100 mM NaCl plus 0.5 M sucrose under conditions as in (A). (<i>n</i> = 10)</p
Ion transport in intact cells.
<p>A, Cl<sup>−</sup> efflux in cells preloaded with Na<sup>36</sup>Cl (100 µM) upon the addition of glucose (▪, LmrA; □, non-expressing control; ⧫, EE LmrA; ○, ΔK388 LmrA). B, Effect of the concentration of Na<sup>+</sup>, NMG<sup>+</sup> or Cl<sup>−</sup> on the ATPase activity of purified LmrA (open symbols) or LmrCD (•) measured at 2 mM Mg-ATP. C,D,E, H<sup>+</sup> efflux in energized cells, loaded with pH probe CFDASE to monitor the intracellular pH (pH<sub>in</sub>) in the absence (C) or presence of (D) 0.25 M NaCl or (E) 0.672 M sucrose in the external buffer (each equivalent to 521 mOsm) (▪, LmrA; □, non-expressing control; ⧫, EE LmrA; •, E314A LmrA; ▴, ΔK388 LmrA). Metabolic energy was generated in the cells by the addition of 20 mM glucose (at t = 0 min in the figures), 15 min after the addition of the NaCl or sucrose or solvent control. (<i>n</i> = 8)</p
Ion-coupled transport in proteoliposomes.
<p>A, B, <sup>36</sup>Cl<sup>−</sup> uptake (100 µM) by LmrA-MD (•), E314A LmrA-MD (⋄), EE LmrA-MD (▪) or empty liposomes (▵) in the presence of a Δψ (interior negative) of −120 mV (A) or -ZΔpH (interior alkaline) of −49 mV (B). In the duplicate experiment for LmrA-MD (□) in (B), the addition of uncoupler (valinomycin plus nigericin, 1 µM each) at the arrow resulted in efflux of accumulated <sup>36</sup>Cl<sup>−</sup>, indicating concentrative uptake of the ion. C, ΔpH (interior alkaline)-dependent <sup>36</sup>Cl<sup>−</sup> uptake by LmrA (•), EE LmrA (▪) or empty liposomes (▵). D, ΔpH (interior alkaline)-dependent uptake of non-radioactive Cl<sup>−</sup> (1 mM) by LmrA is observed as a quench in the fluorescence of the SPQ fluorophore trapped in the lumen of the proteoliposomes. Quenching was also observed in empty liposomes (control) in the presence of the Cl<sup>−</sup>/OH<sup>−</sup> antiporter TBT-Cl (1 µM). E, Kinetic analysis of ΔpH (interior alkaline)-dependent <sup>36</sup>Cl<sup>−</sup> uptake by LmrA. F, ΔpH (interior alkaline)-dependent uptake of <sup>22</sup>Na (25 µM) by LmrA-MD. G, Uptake of unlabelled Na<sup>+</sup> (10 mM) by LmrA was detected as an increase in the fluorescence of the membrane-impermeable sodium green probe trapped in the lumen. H, Na<sup>+</sup> (100 µM) stimulates the ΔpH-dependent uptake of <sup>36</sup>Cl<sup>−</sup> (100 µM) by LmrA compared to control containing 99 µM NMG<sup>+</sup> plus 1 µM Na<sup>+</sup>. I, H<sup>+</sup> efflux in proteoliposomes loaded with pH probe BCECF in the presence of an outwardly directed NaCl gradient. Control, empty liposomes. (<i>n</i> = 5)</p