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Abstract
Echinocytes formed from discocytic erythrocytes by electric field pulses at 0 degrees C return to the discoytic shape upon incubation at 37 degrees C and subsequently turn into stomatocytes. Active and passive components of phospholipid translocation are involved in this shape recovery. Following low-field-strength pulses (5 kV cm-1), shape recovery is fully suppressed by ATPase inhibitors, such as vanadate. When vanadate is only added after stomatocyte formation has been completed, the cells return to the stage of echinocytosis prevailing before recovery. At higher field strength (7 kV cm-1) and in particular after repetitive field pulses, the subsequent incubation at 37 degrees C results in partial shape recovery even in the presence of vanadate. On the basis of the enhanced passive transmembrane mobilities of phospholipid probes observed previously following electroporation, the shape changes in the presence of vanadate are proposed to be due to a passive net movement of phospholipids from the outer to the inner membrane leaflet, as a consequence of the different mobilities of the various membrane phospholipids. Repetitive pulses at higher field strengths lead to a progressively more discocytic stationary shape during subsequent resealing. This phenomenon is explained by the progressively increased transbilayer mobility of the normally almost immobile phospholipid sphingomyelin and a consecutive progressive symmetrization of all membrane phospholipds.