Small organic solutes, including sugar derivatives, amino acids, etc., contribute significantly to the osmoregulation of mammalian cells. The present study explores the mechanisms of swelling-activated membrane permeability for electrolytes and neutral carbohydrates in Jurkat cells. Electrorotation was used to analyze the relationship between the hypotonically induced changes in the electrically accessible surface area of the plasma membrane (probed by the capacitance) and its permeability to the monomeric sugar alcohol sorbitol, the disaccharide trehalose, and electrolyte. Time-resolved capacitance and volumetric measurements were performed in parallel using media of different osmolalities containing either sorbitol or trehalose as the major solute. Under mild hypotonic stress in 200 mOsm sorbitol or trehalose solutions, the cells accomplished regulatory volume decrease by releasing cytosolic electrolytes presumably through pathways activated by the swelling-mediated retraction of microvilli. This is suggested by a rapid decrease of the area-specific membrane capacitance C(m) (microF/cm2). The cell membrane was impermeable to both carbohydrates in 200 mOsm media. Whereas trehalose permeability remained also very poor in 100 mOsm medium, extreme swelling of cells in a strongly hypotonic solution (100 mOsm) led to a dramatic increase in sorbitol permeability as evidenced by regulatory volume decrease inhibition. The different osmotic thresholds for activation of electrolyte release and sorbitol influx suggest the involvement of separate swelling-activated pathways. Whereas the electrolyte efflux seemed to utilize pathways preexisting in the plasma membrane, putative sorbitol channels might be inserted into the membrane from cytosolic vesicles via swelling-mediated exocytosis, as indicated by a substantial increase in the whole-cell capacitance C(C) (pF) in strongly hypotonic solutions.
Electrotransfection and electrofusion, both widely used in research and medical applications, still have to face a range of problems, including the existence of electroporation-resistant cell types, cell mortality and also great batch-to-batch variations of the transfection and fusion yields. In the present study, a systematic analysis of the parameters critical for the efficiency and robustness of electromanipulation protocols was performed on five mammalian cell types. Factors examined included the sugar composition of hypotonic pulse media (trehalose, sorbitol or inositol), the kinetics of cell volume changes prior to electropulsing, as well as the growth medium additives used for post-pulse cell cultivation. Whereas the disaccharide trehalose generally allowed regulatory volume decrease (RVD), the monomeric sugar alcohols sorbitol and inositol inhibited RVD or even induced secondary swelling. The different volume responses could be explained by the sugar selectivity of volume-sensitive channels (VSC) in the plasma membrane of all tested cell types. Based on the volumetric data, highest transfection and fusion yields were mostly achieved when the target cells were exposed to hypotonicity for about 2 min prior to electropulsing. Longer hypotonic treatment (10-20 min) decreased the yields of viable transfected and hybrid cells due to (1) the cell size reduction upon RVD (trehalose) or (2) the excessive losses of cytosolic electrolytes through VSC (inositol/sorbitol). Doping the plasma membrane with lipophilic anions prevented both cell shrinkage and ion losses (probably due to VSC inhibition), which in turn resulted in increased transfection and fusion efficiencies.
Interactions of structurally dissimilar anionic compounds with the plasma membrane of HEK293 cells were analyzed by patch clamp and electrorotation. The combined approach provides complementary information on the lipophilicity, preferential affinity of the anions to the inner/outer membrane leaflet, adsorption depth and transmembrane mobility. The anionic species studied here included the well-known lipophilic anions dipicryl- no mobile charges could be detected by electrorotation, despite their strong membrane adsorption. Our data suggest that the presence of oxygen atoms in the outer molecular shell is an important factor for the fast translocation ability of lipophilic anions.
The present study explores the impact of the molecular size on the permeation of low-molecular-weight polyethylene glycols (PEG200-1500) through the plasma membrane of Jurkat cells under iso- and hypotonic conditions. To this end, we analyzed the cell volume responses to PEG-substituted solutions of different osmolalities (100-300 mOsm) using video microscopy. In parallel experiments, the osmotically induced changes in the membrane capacitance and cytosolic conductivity were measured by electrorotation (ROT). Upon moderate swelling in slightly hypotonic solutions (200 mOsm), the lymphocyte membrane remained impermeable to PEG300-1500, which allowed the cells to accomplish regulatory volume decrease (RVD). During RVD, lymphocytes released intracellular electrolytes through the swelling-activated pathways, as proved by a decrease of the cytosolic conductivity measured by electrorotation. RVD also occurred in strongly hypotonic solutions (100 mOsm) of PEG600-1500, whereas 100 mOsm solutions of PEG300-400 inhibited RVD in Jurkat cells. These findings suggest that extensive hypotonic swelling rendered the cell membrane highly permeable to PEG300-400, but not to PEG600-1500. The swelling-activated channels conducting PEG300-400 were inserted into the plasma membrane from cytosolic vesicles via swelling-mediated exocytosis, as suggested by an increase of the whole cell capacitance. Using the hydrodynamic radii R(h) of PEGs (determined by viscosimetry), the observed size-selectivity of membrane permeation yielded an estimate of approximately 0.74 nm for the cut-off radius of the swelling-activated channel for organic osmolytes. Unlike PEG300-1500, the smallest PEG (PEG200, R(h)=0.5 nm) permeated the lymphocyte membrane under isotonic conditions thus leading to a continuous isotonic swelling. The results are of interest for biotechnology and biomedicine, where PEGs are widely used for cryopreservation of cells and tissues.
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