Electric Field-induced Fusion of Sea Urchin Eggs

An electrical method is described which permits the fusion of denuded eggs of the sea urchin species Paracentrotus lividus . In a nearly non-conductive medium, containing 1.2 M glucose at pH 6.0–8.4, eggs or fertilized stages are brought into close membrane contact by dielectrophoresis arising from the application of a highly inhomogeneous alternating electric field. During this process the eggs aligne parallel to the field forming "egg-chains". In well pigmented eggs pigmentcapping is observed in the areas of cell contact. After completion of the alignment, the application of an additional single high field pulse of μs duration induces fusion of two or more eggs. The mechanism underlying the fusion process is the reversible electric breakdown of membranes in the zones of cell-to-cell contact. Fusion proceeds within 1–10 min at 10–20°C. Fused eggs have intact nuclei, can be fertilized, but undergo abortive cleavage.     

A cytosolic sperm factor stimulates repetitive calcium increases and mimics fertilization in hamster eggs

Microinjection of cytosolic sperm extracts into unfertilized golden hamster eggs caused a series of increases in cytoplasmic free calcium, Ca2+i, and membrane hyperpolarizing responses, HRs. These HRs and Ca2+i transients are similar to those seen during in vitro fertilization of hamster eggs. The sperm factor that is responsible for causing these effects appears to be of high molecular weight and protein based. Injection of sperm factor activated eggs and mimicked fertilization in causing repetitive HRs in the presence of phorbol esters and in sensitizing the egg to calcium-induced calcium release. Since these effects cannot be mimicked by injecting G-protein agonists or calcium-containing solutions, it seems unlikely that a receptor-G-protein signalling system is involved at fertilization. These data instead suggest a novel signal transduction system operates during mammalian fertilization in which a protein factor is transferred from the sperm into the egg cytoplasm after gamete membrane fusion.     

The Cell Cycle Governs the Onset of Spherulation of Xenopus Eggs Fused by an Electric Field

The mechanism of electric field-induced fusion has been studied in detail (Zimmermann, Biochim. Biophys. Acta. 694 (1982) 227), but little is known about the process by which the two fused cells become a single entity, a process we term spherulation. We observe a clear difference between activated and unactivated Xenopus eggs in the time after electic field (EF) application when spherulation starts, and in the time required for spherulation to be completed. In unactivated eggs, spherulation started 7 min after EF application and was completed within 5 1/2 min. In activated eggs, the lag between EF application and the start of spherulation increased with the cell cycle. At the end of the first cell cycle spherulation started 78 min after EF application and was competed 30 min later. The lag period is not due to delayed fusion, for electric coupling between activated eggs can be recorded before the start of spherulation. The morphology of the contact zone between paired eggs, as observed by light and electron microscopy, is also described. We suggest that the difference in the timing of spherulation reflects a difference in the lability of the cytoskeleton through the cell cycle.     

Fusion of hamster and pig zona-free eggs stimulated by boar and guinea pig sperm at fertilization in vitro

In the course of in vitro fertilization of zona-free hamster and pig eggs by boar and guinea-pig spermatozoa it was observed that homologous and heterologous eggs fused together, forming cell hybrids between two or more cells. The fusogenic activity was attributed to spermatozoa and this was the hypothesis tested. The fusogenic activity (coinciding with sperm penetration activity) was dependent on the duration of sperm preincubation, which may be regarded as capacitation in vitro. Fusion occurred only after 3 hr of sperm preincubation and a narrow optimum was detected at 4–4.5 hr. Fusion of eggs was also dependent on sperm concentration. A relatively high proportion of fusions was observed at a sperm concentration of 4.0 × 10⁴ per ml and an optimum was attained at a concentration of 5.0 × 10⁵ per ml. The first fusions were observed at 90 min after semination. After 3 hr more than a half of the eggs reacted, and by 20 hr of incubation 80% of ova were fused. The fusability of eggs was tested and found to occur at 14 hr after ovulation. The fusion process was also studied using transmission electron microscopy. It is supposed that the process of egg fusion may be caused either by a similar mechanism to sperm-egg fusion, or by products released during the sperm acrosome reaction.     

Fertilization Cone of Carp Eggs as Revealed by Scanning Electron Microscopy

The process of formation of the fertilization cone in carp eggs was examined by scanning electron microscopy. The fertilized eggs responded to penetration of one sperm by primary and secondary steps of formation of a fertilization cone of unique morphology. In the primary step, the earliest fertilization cone was seen at the superior or anterosuperior part of a fused sperm head in inseminated eggs fixed 20 sec after immersion in fresh water. The cone reached a maximum of more than 10 μm in length and 3–4 μm in thickness by 40 sec, resulting in a transient plugging of the micropylar canal. In the secondary step, usually seen at 105–120 sec, a conformation reminiscent of a very small caldera volcano was formed, with the shortened earlier cone and part of the sperm tail at its top. By 2.5 min, the fertilization cone had become conical, and the sperm tail still extended from its top. At 3 min, the sperm tail was often not detectable, but a cytoplasmic eminence was still seen as a trace of the fertilization cone. The role of the earlier fertilization cone in blocking polyspermy is discussed.     

Oocyte Maturation and Furrow Formation in an Unfertilized Egg by Fusion with a Fertilized Egg or Blastomeres in the Ascidian, Ascidia sydneiensis divisa

A technique for fusing an ascidian egg with blastomeres using a chemical fusiogen was established and then used to identify cytoplasmic factors that regulate the process of oocyte maturation in ascidian eggs. Unfertilized eggs fused with fertilized eggs or blastomeres in hypotonic artificial sea water containing 20% polyvinyl alcohol within 10 min. After fusion polar bodies were extruded from the unfertilized portion of the fused eggs. Furrows were formed not only in the fertilized portion but also in the unfertilized portion in the fused eggs. No polar body extrusion and furrow formation occur in either portion of fused unfertilized eggs. These results suggest that fertilized eggs and blastomeres contain a factor that induces oocyte maturation. Polar body extrusion and furrow formation were not suppressed in the fertilized portion of fused eggs, suggesting that unfertilized eggs do not contain a factor that inhibits oocyte maturation.     

Observations of hamster sperm-egg fusion in freeze-fracture replicas including the use of filipin as a sterol marker

We have extended the observations of previous transmission electron microscopy studies of sperm-egg fusion to include those of freeze-fracture replicas showing sperm-egg interactions before, during, and following sperm head fusion with the egg membrane. Hamster eggs were incubated with hamster sperm under polyspermic conditions and were observed after a period of 5-30 minutes. After fixation, the eggs and sperm were exposed to filipin, which binds beta-OH-sterols to form visible complexes in freeze-fracture replicas. Filipin can act as a marker for egg plasma membrane wherein it is abundant, while filipin is relatively scarce in the acrosome-reacted hamster sperm membrane, found only in the plasma membrane of the equatorial segment. The earliest sperm-egg interactions are observed between the egg microvilli and the perforatorium and the equatorial segment of the sperm, and the initial fusion between egg and sperm occurs in the vicinity of the equatorial segment. At later stages of fusion involving the postacrosomal segment, a clear line of demarcation is observed between the filipin-rich egg membrane and the filipin-poor sperm postacrosomal segment, suggesting that filipin binding lipids from the egg intercalate into the sperm membrane following membrane fusion. The anterior segment of the sperm does not fuse with the egg but is instead incorporated into a cytoplasmic vesicle derived from both sperm and egg membranes. In this latter step, filipin-sterol complexes are not found in sperm-derived membranes suggesting that there may be barriers to the movement of filipin binding lipids from the egg into these sperm membranes.     

In vitro double fertilization in Nicotiana tabacum (L.): polygamy compared with selected single pair somatic protoplast and chloroplast fusions

In vitro polygamy was studied mainly by using isolated sperm and central cells of tobacco in order to elucidate the mechanism that might be involved in preventing in vivo polygamy. In 17.5% 4000 M.W. polyethylene glycol, only when two sperm cells were made close enough to each other and adhered to a female cell simultaneously was polygamy possible. If one sperm cell fused with the egg or central cell, within 30 min another sperm cell could not fuse with the same egg or central cell. Similar phenomena were found in selected single somatic cell fusion. When more than two protoplasts adhered to each other simultaneously, fusion was always successful; after two protoplasts fused, within 30 min the fusion products could not fuse with another protoplast under the same conditions. This comparative study revealed this characteristic to be shared by both sexual and somatic cell fusion. However, after cytoplasm reorganization was complete in the fusion product, it was possible for the fusion product to fuse with the third protoplast. This indicates that the obstruction to additional fusion was present only during a certain period after the preceding fusion under certain condition. The possible reason for the effect is discussed. Received: 7 March 2000 / Revision accepted: 15 June 2000     

Comparison of Hoechst 33342 and propidium iodide as fluorescent markers for sperm fusion with hamster oocytes.

Hamster oocytes were loaded with the DNA dyes Hoechst 33342 or propidium iodide. Oocytes incubated in 10 mumol Hoechst 333421(-1) showed intracellular fluorescence within 10-20 s of exposure, as did hamster and guinea-pig spermatozoa. Impaled oocytes to which acrosome-intact hamster spermatozoa were bound before injection of Hoechst 33342 showed dye transfer to adhering spermatozoa within 2 min of injection. Oocytes loaded passively with Hoechst 33342 showed dye transfer to bound, acrosome-intact hamster spermatozoa within 10 min. On ultra-structural examination, no bound, acrosome-intact hamster spermatozoa (n = 311) were found to be fused. By contrast, oocytes incubated with 10 mumol propidium iodide l-1 showed no intracellular fluorescence after 2 h, although in approximately 50% of oocytes, fluorescence developed rapidly in the first polar body. Oocytes injected with propidium iodide showed intracellular fluorescence but no dye transfer to bound, acrosome-intact hamster spermatozoa. Oocytes impaled on pipettes containing propidium iodide showed no dye transfer to unlabelled oocytes with which they were brought into contact, whereas in similar experiments using Hoechst 33342 detectable dye transfer to an adjacent oocyte occurred within 10 min. Oocytes loaded with propidium iodide transferred propidium iodide to fusion-competent guinea-pig spermatozoa during in vitro fertilization. Normally, between 20 and 40 spermatozoa bound per oocyte, and the percentage of spermatozoa showing dye transfer varied between 0 and 41%. Dye transfer occurred within 5-45 min. Only those nuclei that showed propidium iodide transfer subsequently decondensed, suggesting that dye transfer is correlated with fusion. The presence of fused spermatozoa was confirmed by ultrastructural examination of oocytes. In separate experiments, hamster and guinea-pig spermatozoa showed detectable fluorescence from propidium iodide within 20 s of osmotic rupture or membrane stripping by detergent, suggesting the lag in dye transfer to sperm nuclei during fertilization reflects a delay in sperm-oocyte fusion following adhesion. This evidence suggests that Hoechst 33342 could be an unreliable marker for sperm-oocyte fusion in fertilization because of its capacity for passive movement from oocyte to spermatozoon. This problem can be overcome using oocytes injected with propidium iodide. With this technique, it was possible to show that fusion-competent guinea-pig spermatozoa that are held in pipettes will fuse with hamster oocytes when placed mechanically against the oocyte surface.     

Axis establishment and microtubule-mediated waves prior to first cleavage in Beroe ovata

The single axis (oral-aboral) and two planes of symmetry of the ctenophore Beroe ovata become established with respect to the position of zygote nucleus formation and the orientation of first cleavage. Bisection of Beroe eggs at different times revealed that differences in egg organisation are established in relation to the presumptive oral-aboral axis before first cleavage. Lateral fragments produced after but not before the time of first mitosis developed into larvae lacking comb-plates on one side. Time-lapse video demonstrated that waves of cytoplasmic reorganisation spread through the layer of peripheral cytoplasm (ectoplasm) of the egg during the 80 minute period between pronuclear fusion and first cleavage, along the future oral-aboral axis. These waves are manifest as the progressive displacement and dispersal of plaques of accumulated organelles around supernumerary sperm nuclei, and a series of surface movements. Their timing and direction of propagation suggest they may be involved in establishing cytoplasmic differences with respect to the embryonic axis.Inhibitor experiments suggested that the observed cytoplasmic reorganisation involves microtubules. Nocodazole and taxol, which prevent microtubule turnover,blocked plaque dispersal and reduced surface movements.The microfilament-disrupting drug cytochalasin B did not prevent plaque dispersal but induced abnormal surface contractions. We examined changes in microtubule organisation using immunofluorescence on eggs fixed at different times and in live eggs following injection of rhodamine-tubulin. Giant microtubule asters become associated with each male pronucleus after the end of meiosis. Following pronuclear fusion they disappear successively, those nearest the zygote nucleus shrinking first, to establish gradients of aster size within single eggs. Regional differences in microtubule behaviour around the time of mitosis were revealed by brief taxol treatment, which induced the formation of small microtubule asters in the region of the nucleus or spindle during both first and second cell cycles. The observed wave of change may thus reflect the local appearance and spreading of mitotic activity as the zygote nucleus approaches mitosis.     

Genetic Analysis of Myoblast Fusion: blown fuse Is Required for Progression Beyond the Prefusion Complex

The events of myoblast fusion in Drosophila are dissected here by combining genetic analysis with light and electron microscopy. We describe a new and essential intermediate step in the process, the formation of a prefusion complex consisting of “paired vesicles.” These pairs of vesicles from different cells align with each other across apposed plasma membranes. This prefusion complex resolves into dense membrane plaques between apposed cells; these cells then establish cytoplasmic continuity by fusion of small areas of plasma membrane followed by vesiculation of apposed membranes. Different steps in this process are specifically blocked by mutations in four genes required for myoblast fusion. One of these genes, blown fuse, encodes a novel cytoplasmic protein expressed in unfused myoblasts that is essential for progression beyond the prefusion complex stage.     

A cell surface block to polyspermy occurs in golden hamster eggs

We have examined the frequency and fate of supernumerary sperm in the perivitelline space (PVS) of in vitro fertilized hamster eggs to determine if there is a cell surface block to polyspermy. The zona pellucida block to polyspermy is very effective since only one sperm penetrated the zona pellucida in 72.8% of the 876 fertilized eggs examined. Of the polypenetrated eggs, 41.6% had a supernumerary sperm within the PVS. The proportion of polypenetrated eggs with PVS sperm did not change when the duration of coincubation was increased from 3 to 6 hr. PVS sperm were found in 67% of the inseminations. From these data we conclude that there is a cell surface block to polyspermy in the hamster. To investigate the mechanism of the cell surface block, we used the Hoechst-transfer technique (R. Hinkley, B. Wright, and J. Lynn, 1986, Dev. Biol. 118, 148-154) to monitor sperm-egg fusion. We first demonstrated that dye transfer from zona pellucida-free eggs to sperm only occurred when fusion was possible, i.e., in the presence of calcium, and that dye was transferred to all fused sperm. When cumulus-free, zona-intact eggs were preloaded with Hoechst dye and viewed 3 hr postinsemination, three classes of eggs with supernumerary sperm in the PVS were observed: eggs with only Hoechst-positive sperm (62%), eggs with only Hoechst-negative sperm (27%), and eggs with both a Hoechst-positive and a Hoechst-negative sperm (11%). Because of the limited time resolution of the Hoechst-transfer technique, the cell surface block could operate by preventing sperm fusion (Hoechst-negative), by the failure of the eggs to incorporate fused sperm (Hoechst-positive), and/or by the "unfusing" of fused sperm (Hoechst-positive and Hoechst-negative). We are unable at this time to differentiate between these mechanisms.     

Erythrocyte-mediated microinjection of horseradish peroxidase into BHK cells

In order to establish the distribution with time of proteins microinjected into mammalian cells, horseradish peroxidase (HRP) was microinjected into baby hamster kidney (BHK) cells using chicken erythrocyte ghosts. At time intervals following initiation of fusion between ghosts and target cells, samples were fixed with aldehydes and the peroxidase visualized by reaction with diaminobenzidine and viewing by light and electron microscopy. At 10 min, the reaction product was observed within the cytoplasm of 60% of the microinjected cells, but was excluded from the nucleus and membranous organelles. In the other 40% of microinjected cells, the reaction product was also observed within the nucleus. At 30 min, the reaction product was observed to be evenly distributed throughout the cell, including the nucleus but excluded from organelles. By 6 h, the reaction product was present almost exclusively within the nucleus of 63% of microinjected cells. At all time points, 20–30% of the erythrocytes ghosts appear to have been taken up by cells by phagocytosis rather than fusion, as evidenced by the presence of peroxidase reaction product within intact and fragmented erythrocyte ghosts in the cytoplasm of target cells. Cells incubated with a lanthanum solution following fusion excluded this electron dense tracer, indicating that the cytoplasmic compartment is not opened during exposure to polyethylene glycol.     

Glycolysis of sea urchin eggs : Rate-limiting steps and activation at fertilization

The amounts of glycolytic intermediates and adenine nucleotides in unfertilized Anthocidaris crassispina eggs and in fertilized eggs or embryos were measured. The determinations on unfertilized and fertilized (30 min) eggs of Pseudocentrotus depressus showed the same results. Calculation of both mass action ratios and free energy changes for each enzymatic step of glycolysis showed that reactions catalysed by α-glucan phosphorylase (EC 2.4.1.1), phosphofructokinase (EC 2.7.1.11) and pyruvate kinase (EC 2.7.1.40) were rate-limiting steps of glycolysis in both unfertilized and fertilized eggs. It also suggested that these three key or rate-limiting enzymes were activated by fertilization. Phosphorylase is activated at fertilization as is also pyruvate kinase. Activation of phosphorylase is also shown by the measurement of the activity in homogenate. Phosphofructokinase showed no increase in activity until 20 min after fertilization, the increase then being closely correlated with a decline in phosphate potential. On the basis of their mass action ratios, none of these rate-limiting enzymes appears to have reached a state of equilibrium by hatching (20 h). The temporal discontinuities in the activation pattern of these three enzymes suggests that no single control mechanism can be operative during the first hour following fertilization.     

Optimization strategies for production of mammalian embryos by nuclear transfer

In order to optimize each of the individual steps in the nuclear transfer procedure, we report alternative protocols useful for producing recipient cytoplasts and for improving the success rate of nuclear transfer embryos in cattle, rhesus monkey, and hamster. Vital labeling of maternal chromatin/spindle is accomplished by long wavelength fluorochromes Sybr14 and rhodamine labeled tubulin allowing constant monitoring and verification during enucleation. The use of Chinese hamster ovary (CHO) donor cells expressing the viral influenza hemagglutinin fusion protein (HA-300a+), to adhere and induce fusion between the donor cells and enucleated cow, rhesus and hamster oocytes was examined. Cell surface hemagglutinin was activated with trypsin prior to nuclear transfer and fusion was induced by a short incubation of a newly created nuclear transfer couplet at pH 5.2 at room temperature. Donor cell cytoplasm was dynamically labeled with CMFDA, or further transfected with the green fluorescence protein (GFP) gene, so that fusion could be directly monitored using live imaging. High rates of fusion were observed between CHO donor cells and hamster (100%), rhesus (100%), and cow recipient cytoplasts (81.6%). Live imaging during fusion revealed rapid intermixing of cytoplasmic components between a recipient and a donor cell. Prelabeled donor cytoplasmic components were uniformly distributed throughout the recipient cytoplast, within minutes of fusion, while the newly introduced nucleus remained at the periphery. The fusion process did not induce activation as evidenced by unchanged distribution and density of cortical granules in the recipient cytoplasts. After artificial activation, the nuclear transfer embryos created in this manner were capable of completing several embryonic cell divisions. These procedures hold promise for enhancing the efficiency of nuclear transfer in mammals of importance for biomedical research, agriculture, biotechnology, and preserving unique, rare, and endangered species.     

FERTILIZATION IN PLUMBAGO ZEYLANICA: GAMETIC FUSION AND FATE OF THE MALE CYTOPLASM

Developmental phases surrounding the processes of gametic delivery and fusion were examined ultrastructurally in the reduced megagametophyte of Plumbago zeylanica, which lacks synergids. Gametic delivery occurs at the end of pollen tube growth and results in deposition of two male gametes, a vegetative nucleus, and a limited amount of pollen cytoplasm between the egg and central cell. Discharge of these materials from the tube is accompanied by loss of inner and outer pollen tube plasma membranes, loss of sperm-associated cell wall components, and disruption of the formerly continuous cell wall between the egg and central cell. The dispersion of egg cell wall components directly exposes female reproductive cell membranes to the unfused male gametes and pollen tube without disrupting gametic cell plasma membranes. Presence of unfused sperms within the female gametophyte appears to be a transitory phenomenon, lasting less than 5 min at the end of over 8½ hr of pollen tube growth. At the time of gametic deposition, plasma membranes of unfused sperm cells become directly appressed to plasma membranes of both the egg and central cell. Gametic fusion is initiated by a single fusion event between membranes of participating male and female cells, which is rapidly followed by subsequent, secondary fusion events between the same two cells at different locations along their surface. Gametic fusion results in the transmission of male gamete nuclei with co-transmission of nearly the entire sperm cytoplasmic volume and organellar complement, and it is possible to identify heritable male cytoplasmic organelles within both the incipient zygote and endosperm. Paternally originating plastids may be distinguished from maternal plastids by differences in morphology and staining characteristics, whereas paternal mitochondria may be distinguished from maternal mitochondria by populational differences in mitochondrial size which are statistically significant. Such observations further indicate that transmitted paternal mitochondria seem to remain viable, as judged by their ultrastructural appearance, and are transmitted exclusively by sperm cytoplasm rather than discharged pollen cytoplasm. The presence of anucleate, membrane-bounded cytoplasmic bodies between the egg and central cell are identifiable on the basis of their enclosed organelles and indicate that fragmentation of a small amount of the sperm cytoplasm associated with the vegetative nucleus commonly occurs. The presence and identification of sperm cytoplasmic organelles and associated membranes within female reproductive cells following gametic transmission represents strong evidence in support of the cellular basis of nuclear and cytoplasmic transmission during sexual reproduction in Plumbago.     

Time course and pattern of cortical granule breakdown in hamster eggs after sperm fusion.

We have determined the temporal relationship between sperm fusion and cortical granule breakdown in the hamster egg. Sperm fusion was determined by the Hoechst-transfer method (Stewart-Savage and Bavister: Dev Biol 128:150-157, 1988), and cortical granules were visualized with fluorescein isothiocynate-conjugated Lens culinaris agglutinin (Cherr et al. J Exp Zool 246:81-93, 1988). By 55 min after insemination, there was an 85% reduction in the density of cortical granules (fewer than four granules/100 microns2). Taking this value as the completion of the cortical reaction, analysis of the data indicate that the cortical reaction was completed 9 min after sperm fusion and 3 min after the formation of the zona and cell surface blocks to polyspermy. There was no obvious spatial pattern of granule loss in eggs that had a Hoechst-positive sperm but had not completed the cortical reaction.     

An investigation of the latency period between sperm oolemmal adhesion and oocyte penetration

In clinical studies of the ability of capacitated human sperm to penetrate zona-free hamster eggs, we have previously observed that the ratio of oolemmal adherent to penetrating sperm varied between men. Sperm incorporation did not occur immediately following gamete adhesion and not all adherent sperm penetrated the egg. To further investigate this phenomenon, comparisons were made of the kinetics of gamete adhesion, membrane fusion, and sperm incorporation of capacitated mouse and human spermatozoa by zona-free hamster eggs and of mouse sperm by zona-free mouse and hamster eggs. Eggs were inseminated with either capacitated human or mouse sperm or combinations of both, washed out of sperm suspension after initial gamete adherence, and further incubated in sperm-free medium. Gamete membrane fusion was judged by dye transfer of Hoechst 33342 and sperm entry of the cortical ooplasm by observation of expanded sperm heads within acridine orange stained eggs. Oolemmal adherent mouse and human sperm fused with and penetrated zona-free hamster eggs at different times whether eggs were inseminated in parallel or with combinations of sperm of both species. Oolemmal adherent mouse sperm penetrated zona-free hamster eggs prior to their penetration of zona-free mouse eggs. Ultrastructural studies of zona-free human eggs inseminated with human sperm confirmed prior observations with hamster eggs that only acrosome-reacted human sperm adhere to the oolemma. These results have lead us to postulate that sperm entry into the egg may occur through a "zipper" mechanism involving the ligation of local gamete receptors similar to the incorporation of target particles by phagocytes and suggest that not all oolemmal adherent human sperm are capable of being incorporated although they have undergone an acrosome reaction.     

斑马鱼胚胎细胞和中国仓鼠卵巢细胞远缘杂交融合条件的优化

以斑马鱼胚胎细胞(ZEM-2s)和中国仓鼠卵巢细胞(CHO-k1)为实验材料,采用聚乙二醇(PEG)作为促融剂,从PEG的相对分子质量、浓度、作用温度和时间等方面进行单因子实验,以期寻找两种细胞融合的最佳条件。实验结果表明,融合的最适条件是融合温度为37℃,浓度为40%,分子量为2 000的PEG处理斑马鱼胚胎细胞和中国仓鼠卵巢细胞100sec,平均融合率高达25.3%,与未加入PEG的细胞相比,最佳条件下处理的两种细胞融合现象明显(p<0.05),表明该条件下的处理能够显著促进细胞的融合。