Abstract

For maltose uptake in Saccharomyces cerevisiae, multiple kinetic forms of transport as well as inhibition of transport by high concentrations of maltose at the trans side of the plasma membrane have been described. Most of these studies were hampered by a lack of genetically well-defined mutants and/or the lack of an artificial membrane system to study translocation catalysis in vitro. A genetically well-defined S. cerevisiae strain lacking the various MAL loci was constructed by gene disruption. Expression of the maltose transport protein (Mal61p) was studied by using various plasmid vectors that differed in copy number and/or type of promoter. The expression levels were quantitated by immunoblotting with antibodies generated against the N-terminal half of Mal61p. The levels of expression as well as the initial uptake rates were increased 20-fold compared with those in a yeast strain carrying only one chromosomal MAL locus. Similar results were obtained when the transport activities were compared in hybrid membranes of the corresponding strains. To generate a proton motive force, isolated membranes were fused with liposomes containing cytochrome c oxidase as a proton pump. Fusion was achieved by a cycle of freeze-thawing, after which the hybrid membranes were passed through a filter with a defined pore size to obtain unilamellar membrane vesicles. Proton motive force-driven maltose uptake, maltose efflux down the concentration gradient, and equilibrium exchange of maltose in the hybrid membranes vesicles have been analyzed. The data indicate that maltose transport by the maltose transporter is kinetically monophasic and fully reversible under all conditions tested.

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