Impact of the growth phase on the activity of multidrug resistance pumps and membrane potential of S. cerevisiae: effect of pump overproduction and carbon source.

The potentiometric fluorescence probe diS-C3(3) is expelled from S. cerevisiae by ABC pumps Pdr5 and Snq2 and can conveniently be used for studying their performance. The activity of these pumps in a strain with wild-type PDR1 allele was shown to drop sharply on glucose depletion from the medium and then again at the end of the diauxic shift when the cells are adapted to growth on respiratory substrates. The presence of the PDR1-3 allele causing pump overproduction prevented this second drop and the pump activity typical for diauxic cells was largely retained. Growth phase-dependent changes of membrane potential measured by the same probe in pump-free mutants included a Deltapsi drop in the late exponential and diauxic growth phase, indicating lowered activity of H+ -ATPase. Suppression of activity of both ABC pumps and H+ -ATPase obviously signifies cell transition to an energy-saving mode. Challenging respiration-adapted cells with glucose showed a novel feature of yeast ABC pumps--a strong dependence of pump activity on the type of the carbon source.

Monitoring the kinetics and performance of yeast membrane ABC transporters by diS-C3(3) fluorescence.

Kinetic features (initial start-up phase, drug pumping velocity and efficiency as dependent on drug concentration and growth phase) of yeast plasma membrane multidrug resistance ABC pumps were studied by monitoring the uptake of the fluorescent potentiometric dye diS-C3(3), which has been found to be expelled from the cells by these pumps. The monitoring was done with Saccharomyces cerevisiae mutants AD1-8 and AD1-3 deleted in different ABC pumps, and in their pump-competent parent strain US50-18C overexpressing transcriptional activators Pdr1p and Pdr3p. On addition to the cells, diS-C3(3) is expelled by the Pdr5p, Yor1p and Snq2p pumps with overlapping substrate specificity. The pump action can be assessed as a difference between the dye uptake curve for pump-competent and pump-deleted cells. The pump-mediated dye efflux, which shows an initial lag of various lengths, maintains a certain residual intracellular dye level. In the absence of external glucose the dye efflux ability of the pumps depends on the growth phase; late exponential and stationary cells can maintain the export for tens of minutes, whereas exponential cells keep up the pump action for limited time periods. This may reflect an insufficient number of pump molecules in the membrane or an effect of insufficient pump energization from endogenous sources. This effect is not mediated by changes in membrane potential because lowered membrane potential caused by inhibition of the plasma membrane H+-ATPase does not affect the pump action.

Factors underlying membrane potential-dependent and -independent fluorescence responses of potentiometric dyes in stressed cells: diS-C(3)(3) in yeast.

The redistribution fluorescent dye diS-C(3)(3) responds to yeast plasma membrane depolarisation or hyperpolarisation by Delta psi-dependent outflow from or uptake into the cells, reflected in changes in the fluorescence maximum lambda(max) and fluorescence intensity. Upon membrane permeabilisation the dye redistributes between the cell and the medium in a purely concentration-dependent manner, which gives rise to Delta psi-independent fluorescence responses that may mimic Delta psi-dependent blue or red shift in lambda(max). These lambda(max) shifts after cell permeabilisation depend on probe and ion concentrations inside and outside the cells at the moment of permeabilisation and reflect (a) permeabilisation-induced Delta psi collapse, (b) changing probe binding capacity of cell constituents (inverse to the ambient ionic strength) and (c) hampering of probe equilibration by the poorly permeable cell wall. At low external ion concentrations, cell permeabilisation causes ion outflow and probe influx (hyperpolarisation-like red shift in lambda(max)) caused by an increase in the probe-binding capacity of the cell interior and, in the case of heat shock, protein denaturation unmasking additional probe-binding sites. At high external ion levels minimising net ion efflux and at high intracellular probe concentrations at the moment of permeabilisation, the Delta psi collapse causes a blue lambda(max) shift mimicking an apparent depolarisation.