A biophysical approach to the optimisation of dendritic-tumour cell electrofusion

Electrofusion of tumour and dendritic cells (DCs) is a promising approach for production of DC-based anti-tumour vaccines. Although human DCs are well characterised immunologically, little is known about their biophysical properties, including dielectric and osmotic parameters, both of which are essential for the development of efficient electrofusion protocols. In the present study, human DCs from the peripheral blood along with a tumour cell line used as a model fusion partner were examined by means of time-resolved cell volumetry and electrorotation. Based on the biophysical cell data, the electrofusion protocol could be rapidly optimised with respect to the sugar composition of the fusion medium, duration of hypotonic treatment, frequency range for stable cell alignment, and field strengths of breakdown pulses triggering membrane fusion. The hypotonic electrofusion consistently gave a tumour-DC hybrid rate of up to 19%, as determined by counting dually labelled fluorescent hybrids in a microscope. This fusion rate is nearly twice as high as that usually reported in the literature for isotonic media. The experimental findings and biophysical approach presented here are generally useful for the development of efficient electrofusion protocols, especially for rare and valuable human cells.     

Surviving High-Intensity Field Pulses: Strategies for Improving Robustness and Performance of Electrotransfection and Electrofusion

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.     

Intracellular Delivery of Carbohydrates into Mammalian Cells through Swelling-activated Pathways

Volume changes of human T-lymphocytes (Jurkat line) exposed to hypotonic carbohydrate-substituted solutions of different composition and osmolality were studied by videomicroscopy. In 200 mOsm media the cells first swelled within 1–2 min and then underwent regulatory volume decrease (RVD) to their original isotonic volume within 10–15 min. RVD also occurred in strongly hypotonic 100 mOsm solutions of di- and trisaccharides (trehalose, sucrose, raffinose). In contrast to oligosaccharide media, 100 mOsm solutions of monomeric carbohydrates (glucose, galactose, inositol and sorbitol) inhibited RVD. The complex volumetric data were analyzed with a membrane transport model that allowed the estimation of the hydraulic conductivity and volume-dependent solute permeabilities. We found that under slightly hypotonic stress (200 mOsm) the cell membrane was impermeable to all carbohydrates studied here. Upon osmolality decrease to 100 mOsm, the membrane permeability to monomeric carbohydrates increased dramatically (apparently due to channel activation caused by extensive cell swelling), whereas oligosaccharide permeability remained very poor. The size-selectivity of the swelling-activated sugar permeation was confirmed by direct chromatographic measurements of intracellular sugars. The results of this study are of interest for biotechnology, where sugars and related compounds are increasingly being used as potential cryo- and lyoprotective agents for preservation of rare and valuable mammalian cells and tissues.This revised version was published online in June 2005 with a corrected cover date.     

Roles of Aquaporin-3 Water Channels in Volume-Regulatory Water Flow in a Human Epithelial Cell Line

Membrane water transport is an essential event not only in the osmotic cell volume change but also in the subsequent cell volume regulation. Here we investigated the route of water transport involved in the regulatory volume decrease (RVD) that occurs after osmotic swelling in human epithelial Intestine 407 cells. The diffusion water permeability coefficient (Pd) measured by NMR under isotonic conditions was much smaller than the osmotic water permeability coefficient (Pf) measured under an osmotic gradient. Temperature dependence of Pf showed the Arrhenius activation energy (Ea) of a low value (1.6 kcal/mol). These results indicate an involvement of a facilitated diffusion mechanism in osmotic water transport. A mercurial water channel blocker (HgCl₂) diminished the Pf value. A non-mercurial sulfhydryl reagent (MMTS) was also effective. These blockers of water channels suppressed the RVD. RT-PCR and immunocytochemistry demonstrated predominant expression of AQP3 water channel in this cell line. Downregulation of AQP3 expression induced by treatment with antisense oligodeoxynucleotides was found to suppress the RVD response. Thus, it is concluded that AQP3 water channels serve as an essential pathway for volume-regulatory water transport in, human epithelial cells.     

Regulation of volume-sensitive Cl- channels in multi-drug resistant MCF7 cells

The P-glycoprotein (P-gp) is thought to be involved in the regulation of volume-sensitive chloride channels. In this study, the possible coupling between P-gp and swelling-activated chloride channels has been examined in MCF7 cells with sensitive (MDR-), resistant (MDR+), and reversed resistant (MDR(REV)) phenotypes. Western blot analysis showed that incubation of cells with doxorubicin induced P-gp expression in a reversible manner. Exposure of MDR+ cells to hypotonicity resulted in an inhibition of P-gp activity while hypotonic challenges induced swelling-activated chloride currents (I(Cl-swell)) in MDR-, MDR+, and MDR(REV) MCF7 cells. While verapamil inhibited I(Cl-swell) in all cell types, doxorubicin and vincristine rapidly and reversibly inhibited I(Cl-swell) uniquely in MDR+. Intracellular dialysis of MDR+ cells with C219 anti-P-gp antibody abolished the sensitivity of I(Cl-swell) to doxorubicin and led to a response pattern very close to that of MDR- cells. Taken together, these results strongly suggest that the P-glycoprotein regulates I(Cl-swell) in resistant MCF7.     

The use of the electrolyte leakage method for assessing cell membrane stability as a water stress tolerance test in durum wheat

This work was carried out to adapt the electrolyte leakage technique todurum wheat and then to evaluate its relevance in the assessment of the cellmembrane stability as a mechanism of water stress tolerance in this species.Themethod currently used is based on in vitro desiccation ofleaf tissues by a solution of polyethylene glycol (PEG) and a subsequentmeasurement of electrolyte leakage into deionised water. It consists of threesuccessive steps: (1) a washing treatment to remove solutes from both leafsurfaces and cells damaged by cutting; (2) a stress period during which theleaftissues are plunged in a PEG-solution and (3) a rehydration period during whichafter-effects of the stress are evaluated. During the washing period, the majorpart of electrolytes was removed within 15 min. Varying the stressconditions influenced both the percent and the kinetics of electrolyte leakageduring rehydration. Electrolyte leakage exhibited a characteristic patternreflecting the condition of cellular membranes (repair and hardening). Inpractice, we recommend a 15-minute washing time, a10-hour stress period and 4 h of rehydration. Theextent of the cell membrane damage not only correlated well with the growthresponses of wheat seedlings belonging to various cultivars to withholdingwaterbut also with the recognised field performances of these cultivars. Therelativeproportion of endogenous ions lost in the effusate during the rehydration stepmay vary strongly according to the element analysed and the precise nutritionalstatus of the plant should therefore be considered. However, an increase ininorganic ion leakage does not fully explain the recorded PEG-induced increasein electrical conductivity (EC) during the subsequent rehydration step andorganic ions are probably also involved in such an increase.