6533b7dcfe1ef96bd12721aa

RESEARCH PRODUCT

Involvement of osmotic cell shrinkage on the proton extrusion rate in Saccharomyces cerevisiae

Patrick GervaisRaphaëlle Tourdot-maréchalIñigo Martínez De Marañón

subject

0106 biological sciencesOsmotic shockPRESSION OSMOTIQUESaccharomyces cerevisiaeXylitol01 natural sciencesMicrobiologyPermeability03 medical and health scienceschemistry.chemical_compoundOsmotic Pressure010608 biotechnologyGlycerolExtracellularOsmotic pressure[SDV.MP] Life Sciences [q-bio]/Microbiology and ParasitologyComputingMilieux_MISCELLANEOUS030304 developmental biology0303 health sciencesChromatographyOsmotic concentrationCell MembraneOsmolar ConcentrationGeneral MedicineCulture Media[SDV.MP]Life Sciences [q-bio]/Microbiology and ParasitologychemistryOsmoregulationSorbitolProtonsFood Science

description

Saccharomyces cerevisiae has been subjected to hyperosmotic shocks by using permeating (sorbitol, xylitol, glycerol, NaCl) and nonpermeating (PEG 600) solutes. The proton extrusion rate decreased as the osmotic pressure increased, whichever solute was used. However, the total inhibition of the cellular H+ extrusion depended on the solute used. A total inhibition was observed at about 20 MPa with glycerol, xylitol and sorbitol. With PEG 600, a total inhibition of extracellular acidification was obtained at 8.5 MPa. NaCl, with an extracellular pressure of 37.8 MPa (near saturation), did not completely inhibit the extracellular acidification. These results showed that the total inhibition of proton extrusion, involving probably the membrane H+-ATPase. was not correlated to the hydric state of the external medium but was strictly linked to the degree of permeation of solutes across the plasma membrane. The extracellular acidification was totally inhibited by a critical final cell volume reached after the osmotic shrinkage, whichever solute was used. This critical final cell volume represented 50% of the initial cell volume. This result suggests that the final cell volume reached after an osmotic stress represents a key thermodynamic parameter for cell osmoregulation in which H+-ATPase would be implicated.

yearjournalcountryeditionlanguage
2001-01-01
https://hal.inrae.fr/hal-02677243