Journal of Cell Science, Vol 10, 769-787, Copyright © 1972 by Company of Biologists

Submitted on October 1, 1971

Studies on Chemically Induced Cell Fusion

¹ Department of Biochemistry, Royal Free Hospital School of Medicine, University of London, 8 Hunter St., London WC1N 1BP, England

Hen erythrocytes that were fixed after treatment with lysolecithin in aqueous solution for 30 s at 37 °C showed evidence of bridge formation between adjacent lysed cells. Generally, the homokaryons that were produced using lysolecithin in this way contained large numbers of nuclei. These giant syncytia had damaged nuclear membranes and unstable plasma membranes; complete disintegration of the syncytia occurred within 1 min of adding lysolecithin to the erythrocytes.

In order to localize the action of lysolecithin, the fusing agent was incorporated into microdroplets of lipid. Cell fusion following the addition of lysolecithin in an aqueous glyceridelecithin emulsion was slower than with lysolecithin in aqueous solution, taking 10-30 min, and it was accompanied by considerably less damage to the plasma and nuclear membranes. The fused erythrocytes, which usually contained only two or three nuclei, lysed slowly during the 45 min following fusion, and lysis could be arrested by cooling the fused cells. The plasma membranes of lysed, multinucleated cells remained intact at 37°C for at least 90 h.

Mouse fibroblast-hen erythrocyte heterokaryons formed with the aid of the emulsion were more stable than those produced with lysolecithin in solution, but the hybrid cells nevertheless had damaged subcellular organelles. Viable clones of hybrid mouse-hamster fibroblast cells were obtained using the emulsion although, possibly owing to reduced viability of the lysolecithin-treated cells, only at twice the frequency of spontaneously produced hybrids.

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