Interaction of Sendai (HVJ) Virus with Human Erythrocytes: A Morphological Study of Haemolysis Cell Fusion

1. Fusogenic and non-fusogenic chemicals were tesetd for their ability to allow 45Ca2+ and 3H2O to enter hen and human erythrocytes. 2. The ratio of 45Ca2+/3H2O in treated cells to that in untreated cells is referred to as the entry ratio. 3. Within 1 min at 37 degrees C both water-soluble and lipid-soluble fusogens increased the value of the entry ratio, which reached maximum values in 5–10 min. 4. Values of the entry ratio in the range of 4–12 were found under conditions that led to cell fusion. 5. Closely related but non-fusogenic chemicals did not significantly alter the entry ratio. 6. The entry ratios for 86Rb+, 22Na+ and 35SO42- were also significantly increased by both lipid-soluble and water-soluble fusogens, though the increases were not as large as those for 45Ca2+. 7. It is suggested that fusogenic compounds increase the permeability of biological membranes to ions, and that an increase in the concentration of intracellular Ca2+ initiates or facilitates events that lead to the chemically induced fusion of erythrocytes.

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"Ultramicroinjection" of macromolecules or small particles into animal cells. A new technique based on virus-induced cell fusion.

The Journal of Cell Biology ◽

10.1083/jcb.66.2.292 ◽

1975 ◽

Vol 66 (2) ◽

pp. 292-304 ◽

Cited By ~ 60

Author(s):

A Loyter ◽

N Zakai ◽

R G Kulka

Keyword(s):

Cell Fusion ◽

Sendai Virus ◽

Human Erythrocytes ◽

New Method ◽

New Technique ◽

Second Step ◽

Small Particles ◽

Animal Cells ◽

Latex Spheres ◽

A New Technique

A new method is described for the introduction of macromolecules and small particles into animal cells. The first step in this procedure is the trapping of particles in ghosts of human erythrocytes. This is achieved by the gradual hemolysis of erythrocytes in the presence of the particles to be trapped. The second step is the Sendai virus-induced fusion of the ghosts containing the particles with cells. By this method, ferritin and latex spheres (diameter 0.1 mum) have been "injected" into cells.

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Divalent cations, phospholipid asymmetry and osmotic swelling in electrically-induced lysis, cell fusion and giant cell formation with human erythrocytes

Biochimica et Biophysica Acta (BBA) - Biomembranes ◽

10.1016/0005-2736(93)90157-u ◽

1993 ◽

Vol 1148 (1) ◽

pp. 30-38 ◽

Cited By ~ 11

Author(s):

Lin Ye Song ◽

Quet F. Ahkong ◽

Jocelyn M. Baldwin ◽

Rita O' Reilly ◽

Jack A. Lucy

Keyword(s):

Giant Cell ◽

Cell Fusion ◽

Divalent Cations ◽

Cell Formation ◽

Human Erythrocytes ◽

Osmotic Swelling ◽

Phospholipid Asymmetry ◽

Giant Cell Formation

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Membrane proteins in human erythrocytes during cell fusion induced by oleoylglycerol

Biochemical Journal ◽

10.1042/bj1760159 ◽

1978 ◽

Vol 176 (1) ◽

pp. 159-167 ◽

Cited By ~ 28

Author(s):

Susan J. Quirk ◽

Quet Fah Ahkong ◽

Gaynor M. Botham ◽

Jan Vos ◽

Jack A. Lucy

Keyword(s):

Membrane Proteins ◽

Cell Fusion ◽

Gel Electrophoresis ◽

Band 3 ◽

Human Erythrocytes ◽

Proteolytic Degradation ◽

Fracture Face ◽

Band 3 Protein ◽

Osmotic Lysis ◽

Very High

1. The fusion of human erythrocytes into multicellular bodies that is induced by microdroplets of oleoylglycerol was investigated by optical and electron microscopy, and by gel electrophoresis of membrane proteins. 2. At the highest concentrations of oleoylglycerol and Ca2+ used, at least 80% of the cells fused after 30min at 37°C and only about 5% of the cells had completely lysed; the shapes of fused multicellular bodies were usually retained in ‘ghosts’ prepared by hypo-osmotic lysis. 3. The rate of cell fusion was related to the concentration of Ca2+, although some cells fused when no exogenous Ca2+ was present. 4. Interactions of microdroplets of oleoylglycerol with the cells led to abnormalities in the structural appearance of the erythrocyte membrane; subsequent membrane fusion occurred, at least in some instances, at the sites of the microdroplets. 5. The intramembranous particles on the P-fracture face of the treated cells were more randomly distributed, but not significantly increased in number by comparison with the control cells. 6. Gel electrophoresis of the proteins of ‘ghosts’ prepared from fused human erythrocytes showed a production of material of very high molecular weight, the development of a new component in the band-3 region, an increased staining of bands 4.3 and 4.5, and a new component moving slightly faster than band 6. 7. Bands 2.1–2.3 were altered, band 3 was decreased and band 4.1 was lost. 8. Most, but not all, of the changes in the membrane proteins appeared to result from the entry of Ca2+ into the cell. 9. 1-Chloro-4-phenyl-3-l-toluene-p-sulphonamidobutan-2-one partially inhibited both cell fusion and the associated decrease in band-3 protein. 10. The possibility that proteolytic degradation of membrane proteins may be involved in cell fusion induced by oleoylglycerol is considered, and some implications of this possibility are discussed.

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Movements of fluorescent probes in the mechanism of cell fusion induced by poly(ethylene glycol)

Journal of Cell Science ◽

10.1242/jcs.88.3.389 ◽

1987 ◽

Vol 88 (3) ◽

pp. 389-398

Author(s):

Q.F. Ahkong ◽

J.P. Desmazes ◽

D. Georgescauld ◽

J.A. Lucy

Keyword(s):

Ethylene Glycol ◽

Cell Fusion ◽

Fluorescent Probes ◽

Human Erythrocytes ◽

Phospholipid Bilayer ◽

Poly Ethylene Glycol ◽

Fusion Event ◽

Isotonic Buffer ◽

Poly Ethylene ◽

Rapid Transfer

It has been claimed that purified poly(ethylene glycol) (PEG) is able only to aggregate cells and not to fuse them. In our hands, purified PEG 6000 (recrystallized/dialysed) induces both aggregation and fusion of human erythrocytes, and the mechanism of fusion by the purified polymer has been investigated with fluorescent probes. No movement of a carbocyanine probe or of octadecyl rhodamine B chloride from labelled to unlabelled cells occurred in the absence of PEG or with cells treated with concanavalin A, protamine or spermine. With 40% PEG, however, both probes immediately started to diffuse into the membranes of unlabelled cells. This indicates that continuity between the phospholipid bilayer membranes of adjacent erythrocytes (i.e. membrane fusion) is established within seconds in concentrated solutions of the polymer, and precedes the cell fusion event that is induced by purified PEG. These observations are consistent with the idea that micro-regions of shared phospholipid bilayer may be formed in the membranes of cells when they are forced together as a consequence of the dehydrating action of PEG. Intact erythrocytes were cytoplasmically labelled with 6-carboxyfluorescein to avoid the possibility that loading the cells with a cytoplasmic marker by hypotonic haemolysis might modify their response to PEG. Unlike the lipid probes, carboxyfluorescein did not diffuse from labelled to unlabelled cells in the presence of 40% PEG, and there was little diffusion on subsequent dilution of the polymer solution to 13%. However, after the PEG solution had been replaced by an isotonic buffer, a rapid transfer of the cytoplasmic fluorophore to unlabelled cells often occurred. This is considered to be more consistent with the osmotic rupture of a membranous barrier, such as a shared bilayer, between the labelled and unlabelled cells than with the return of cytoplasmic viscosity to normal when the PEG is removed. Possible reasons are discussed for the reported inability of purified PEG to fuse fibroblasts with hypotonically loaded human erythrocytes.

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