The rapid intermixing of cell surface antigens after formation of mouse human heterokaryons

Abstract

Cells from established tissue culture lines of mouse (CIID) and human (VA-2) origin were fused together with Sendai virus, producing heterokaryons bearing both mouse and human surface antigens which were then followed by the indirect fluorescent antibody method. Within 40 min following fusion, total mixing of both parental antigens occurred in over 90 % of the heterokaryons. Mouse H-2 (histocompatibility) and human surface antigens were visualized by successive treatment of the heterokaryons with a mixture of mouse alloantiserum and rabbit anti-VA-2 antiserum, followed by a mixture of fluorescein-labelled goat anti-mouse IgG and tetramethyl- rhodamine-labelled goat anti-rabbit IgG(Fc). The CIID × VA-2 fusions were carried out in suspension and maintained at 37°C in a shaking water bath; aliquots were removed at various intervals and stained with the above reagents. The heterokaryon population was observed to change from an initial one (5-min post-fusion) of non-mosaics (unmixed cell surfaces of red and green fluorescence) to one of over 90 % mosaics (total intermixing of the 2 fluorochromes) by 40 min after fusion. Mouse-human hybrid lines, derived from similar fusions, gave fluorescence patterns identical to those of the mosaic heterokaryons. Four possible mechanisms would yield such results: (i) a very rapid metabolic turnover of the antigens; (ii) integration of units into the membrane from a cytoplasmic precursor pool; (iii) movement, or ‘diffusion ‘of antigen in the plane of the membrane; or (iv) movement of existing antigen from one membrane site into the cytoplasm and its emergence at a new position on the membrane. In an effort to distinguish among these possibilities, the following inhibitor treatments were carried out: (1) both short- and long-term (6-h pre-treatment) inhibition of protein synthesis by puromycin, cycloheximide, and chloramphenicol; (2) short-term inhibition of ATP formation by dinitrophenol (DNP) and NaF; (3) short- and long-term inhibition of glutamine- dependent pathways with the glutamine analogue 6-diazo-5-oxonorleucine; and (4) general metabolic suppression by lowered temperature. The only treatment found effective in preventing the mosaicism was lowered temperature, from which resulted a sigmoidal curve for per cent mosaics versus incubation temperature. These results would be consistent with mechanisms iii and/or iv but appear to rule out i and ii. From the speed with which the antigen markers can be seen to propagate across the cell membrane, and from the fact that the treatment of parent cells with a variety of metabolic inhibitors does not inhibit antigen spreading, it appears that the cell surface of heterokaryons is not a rigid structure, but is ‘fluid’ enough to allow free ‘diffusion’ of surface antigens resulting in their intermingling within minutes after the initiation of fusion.