Parthenogenetic activation of domestic cat oocytes using ethanol, calcium ionophore, cycloheximide and a magnetic field

The objective of this study was to evaluate parthenogenetic activation of domestic cat oocytes after being exposed to either ethanol, magnetic field, calcium ionophore A23187, or cycloheximide and a combination of these agents. We also wished to evaluate the usefulness of the magnetic field for oocyte activation. In vitro matured oocytes subjected to artificial activation were randomly assigned into eight groups according to activating agents: (1) 10% ethanol; (2) the magnetic field (slow-changing, homogenous magnetic field with low values of induction); (3) 10% ethanol plus magnetic field; (4) 10 microM calcium ionophore A23187; (5) 10 microM calcium ionophore A23187 plus magnetic field; (6) 10% ethanol and 10 microg/mL of cycloheximide; (7) 10% ethanol and 10 microg/mL of cycloheximide plus magnetic field; (8) oocytes were not exposed to any of the activating agents. After activation oocytes were stained with Hoechst 33258 and parthenogenetic activation was defined as oocytes containing pronuclei and second polar bodies or two to four or six nuclei (embryonic cleavage). The total activation rate by using different activation treatments was 40%. The addition of the magnetic field to ethanol or calcium ionophore treatments resulted in increased parthenogenetic activation rates from 47% to 75%, and from 19% to 48%, respectively (P<0.001). Instead, when the magnetic field was added to ethanol and cycloheximide treatment, activation rate decreased from 48% to 30%. Oocytes activated with magnetic field only gave the lowest activation rate (12%). We concluded that a magnetic field can be used as an activating agent, and the combination of ethanol and magnetic field is an effective method for domestic cat oocyte activation.     

Differential Emergence of Cortical Granule Breakdown and Electrophysiological Responses during Meiotic Maturation of Toad Oocytes

Oocytes of the toad, Bufo bufo japonicus , at various stages of progesterone-induced maturation were stimulated by pricking or treatment with Ca-ionophore A23187. Upon pricking, oocytes 14 hr after hormone treatment (PHT) underwent sequential activation responses, such as development of an activation potential, cortical granule breakdown (CGBD), and formation of a perivitelline space (PVS), like those of mature oocytes (18 hr PHT). When oocytes were pricked at 14 hr PHT, it took about 10 min for the wave of CGBD to spread over all the oocyte surface, in contrast to the case with mature oocytes in which it took about 150 sec. The rate of spread of CGBD was significantly less in the vegetal hemisphere than in the animal hemisphere in both mature and immature oocytes. Treatment with A23187 (1 μM) for 5 min induced an activation potential, and PVS formation by the oocytes from 10 hr PHT, which was 3–4 hr earlier than the time when these responses could be induced by pricking. Oocytes at 8–9 hr PHT also showed CGBD in response to A23187, but without formation of an activation potential. Several patches of local PVS caused by the non-propagating CGBD were observed in oocytes treated with the ionophore 5–7 hr PHT. When a high concentration (10 μM) of A23187 was employed, CGBD without PVS formation was induced even in oocytes at 0 hr PHT. These results indicate that the responsiveness to a Ca²⁺ surge that is a prerequisite for both CGBD and genesis of an activation potential is acquired for the repective responses at different stages of oocyte maturation.     

Induction and activation of meiosis and subsequent parthenogenetic development of growing pig oocytes using calcium ionophore A23187

The pig ovary contains a large number of growing oocytes, which do not mature in vitro and cannot be readily used in various biotechnologies. This study was conducted to determine the possibility of inducing meiotic maturation in growing pig oocytes with an internal diameter of 110 μm, which had developed partial meiotic competence. Most of these oocytes spontaneously stopped maturation at the metaphase I stage (68%); a limited number proceeded to the metaphase II stage (26%). Treatment with calcium ionophore A23187 (50 μM for 5 or 10 min) after 24 h in vitro culture overcame the block at the metaphase I stage, and treated growing pig oocytes matured to the metaphase II stage (66%). Oocytes in which maturation had been induced by calcium ionophore were again treated with calcium ionophore. Up to 58% of the treated oocytes were activated. Parthenogenetic development in oocytes treated with ionophore for meiosis induction and activation was very limited. The portion which reached morula stage did not exceed 8% and at most 3% developed to the blastocyst stage.     

Cytoplasmic activation of starfish oocytes by sperm and divalent ionophore A-23187

The relationship between onset of the early cytoplasmic stages of oocyte activation (vitelline membrane separation and elevation) and nuclear meiotic maturation was investigated in starfish oocytes after their exposure to divalent ionophore (A-23187) or sperm. Meiotically mature oocytes, isolated in calcium-free seawater, underwent activation in response to sperm or ionophore as previously reported. Large, immature starfish oocytes, arrested in prophase I of meiosis (germinal vesicle stage), underwent vitelline membrane elevation when treated with divalent ionophore A-23187 or starfish sperm. Histological studies demonstrated that cortical granule breakdown in the oocyte cortex was associated with vitelline membrane elevation after these treatments. Activation of oocytes by sperm occurred only in response to starfish sperm. Sea urchin, sand dollar, surf clam, or marine worm sperm did not induce vitelline membrane elevation of either immature or mature starfish oocytes. Sperm- or ionophore-activated immature oocytes underwent nuclear maturation after addition of the meiosis-inducing hormone, l-methyladenine; however, parthenogenetic development did not occur and embryonic development was markedly inhibited. In contrast to previous studies, the present results indicate that cytoplasmic activation can be initiated before and without hormone induction of the nuclear maturation process. Differentiation of the oocyte cell surface or cortex reactivity therefore appears to occur during oogenesis rather than as a consequence of maturation. The data further support the view that divalent ions mediate certain of the early activation responses initiated by sperm at the time of fertilization and that synchronization of fertilization to the meiotic process in the oocyte is important for the occurrence of normal development.     

Bovine oocyte development following different oocyte maturation and sperm capacitation procedures

Various procedures have been reported for successful in vitro maturation and in vitro fertilization (IVM/IVF) of bovine follicular oocytes. Direct comparisons of these different recommended procedures have been rare. In this research, involving a total of 5,128 oocytes, a series of experiments were conducted to compare oocyte maturation, fertilization, and development in vitro with 2 maturation systems (with or without added hormones) and 3 types of sperm treatment procedures. Oocytes were collected from ovarian antral follicles (2–7 mm in diameter) within 3 hr after slaughter of cows or heifers. Those with intact or at least 4 layers of cumulus cells were selected for IVM/IVF. Oocytes were incubated for 22 hr in either Medium 199 with 7.5% fetal calf serum (M199 + FCS) alone or M199 + FCS with added hormones (M199 + FCS + H; oFSH 0.5 μg/ml, oLH 5.0 μg/ml, and E₂ 1.0 μg/ml) at 39°C in 5% CO₂ and 95% air. For IVF, frozen-thawed sperm were treated with either 0.1 μM calcium ionophore A23187 (A23187) for 1 min, or 10 or 100 μg/ml heparin (H10 or H100) for 15 min. Our results demonstrated the following: (1) both M199 + FCS and M199 + FCS + H supported maturation development to the metaphase II stage (90–95%, P > 0.05); (2) when oocytes were matured in M199 + FCS without added hormones, A23187 sperm treatment was superior to H10 or H100 treatment for fertilization and blastocyst development of the inseminated oocytes (P < 0.05); (3) when oocytes were matured in M199 + FCS + H, A23187 treated sperm again produced a higher fertilization rate than the H10 group (P < 0.05), but the development to the blastocyst stage was similar among all 3 sperm treatment groups (P > 0.05); (4) direct comparison of the 2 maturation systems with A23187 treated sperm resulted in no difference in all criteria measured; however, (5) when compared retrospectively, beneficial effects of added hormones are evident for blastocyst development (but not for fertilization) when sperm were treated with heparin procedures. © 1993 Wiley-Liss, Inc.     

猪体细胞核移植重构胚的体外发育(英文)

以卵丘细胞为核供体细胞组成重构胚 ,卵裂率达到 5 6.7% ,发育至桑椹胚率达到1 1 .7% ,囊胚率为 6.7% ,显著高于成纤维细胞重构胚 (P <0 .0 5 )。本文还研究了卵母细胞的采集方法、激活程序和卵龄对卵丘细胞核移植重构胚体外发育的影响。以血清饥饿法将卵丘细胞诱导至G0 G1 期 ,抽吸法 解剖法采集卵母细胞 ,体外培养 3 3～ 44h ,将卵丘细胞放至去核卵母细胞的卵周隙中 ,重构胚以钙离子载体A2 3 81 7或电脉冲结合 6 DMAP激活处理 ,体外培养 6d。研究表明 ,卵母细胞采集方法、激活液中细胞松弛素 (CB)、激活程序并不影响重构胚的发育 (以卵龄 44h的卵母细胞为受体 ) ;而以电脉冲结合 6 DMAP激活处理能提高重构胚发育能力 (以卵龄 3 3h的卵母细胞为受体 ) (P <0 .0 5 )。本研究显示 ,以电脉冲结合 6 DMAP激活卵丘细胞重构胚 ,体外能发育至囊胚     

Activation at the germinal vesicle stage of starfish oocytes produces parthenogenetic development through the failure of polar body extrusion

Starfish oocytes can be fertilized after germinal vesicle breakdown (GVBD) and artificial parthenogenesis can be induced by activating the oocytes after GVBD (post-GVBD activation). In the present study, parthenogenotes were obtained by the activation of immature oocytes with caffeine before treatment with 1-methyladenine (1-MeAde) to induce oocyte maturation. Most of the caffeine-treated eggs developed as tetraploids, as parthenogenotes produced by the post-GVBD activation. The parthenogenotes were derived only from eggs that failed to extrude polar bodies, mostly from eggs failing to extrude a second polar body. Eggs derived from immature oocytes activated by A23187, treated with 1-MeAde and post-treated with cytochalasin B failed to extrude polar bodies, and eventually developed into parthenogenetic embryos. These results indicate that the present parthenogenesis mechanism shares the same characteristics as that achieved by post-GVBD activation in the suppression of polar body formation as a key means for successful starfish parthenogenesis.     

影响猪体细胞核移植重构胚体外发育的若干因素

以卵丘细胞为核供体细胞组成重构胚,卵裂率达到56．7％,发育至桑椹胚达11．7％、孵化囊胚率为6．7％,显著高于成纤维细胞组成的重构胚（P＜0．05）。我们研究了卵母细胞的采集方法,激活方法和卵龄对卵丘细胞核移植重构胚体外发育的影响。以血清饥饿法将卵丘细胞诱导至G0或G1期,抽吸法／解剖法采集卵母细胞,体外培养33或44h,将卵丘细胞置于去核卵母细胞的卵周隙中,重构胚以钙离子载体A23817或电泳冲结合6－DMAP激活处理,体外培养6天,结果表明,卵 母细胞采集方法、激活液中细胞松弛素（CB）并不影响重构胚的发育（以卵龄44h的卵母细胞为受体）;而以电脉冲结合6－DMAP激活处理能提高重构胚发育能力（以卵龄33h的卵母细胞为受体）（P＜0．05）。本研究显示,以电脉冲结合6－DMAP激活卵丘细胞重构胚,能在体外发育至囊胚。     

Roscovitine in combination with calcium ionophore induces oocyte activation through reduction of M-phase promoting factor activity in mice

Summary The aim of the present study was to determine oocyte activation and change in M-phase promoting factor (MPF) activity induced by treatment with calcium ionophore and roscovitine in comparison with those induced by treatment with roscovitine alone and treatment with calcium ionophore and puromycin in mice. Freshly ovulated oocytes obtained from 6-8-week-old mice were divided into five groups (no activation treatment; 5 μM calcium ionophore A23187; 50 μM roscovitine; 5 μM calcium ionophore and 10 μg/ml puromycin; and 5 μM calcium ionophore and 50 μM roscovitine) and were incubated for 6 h. Oocyte activation, assessed by morphological changes, and changes in MPF activity in the five groups at 0, 2, 4 and 6 h of incubation were examined. Activated oocytes were defined as oocytes with at least one pronucleus. Oocytes treated with roscovitine alone were not activated during the 6-h incubation period. All of the oocytes in the calcium ionophore with puromycin group and in the calcium ionophore with roscovitine group were activated. The percentage activity of MPF in oocytes treated with roscovitine alone was decreased after 2 h and increased after 4 h of incubation. The percentage activity of MPF in oocytes treated with calcium ionophore and roscovitine was significantly decreased with suppression of MPF activity being maintained for 6 h, and this change was similar to that in oocytes treated with calcium ionophore and puromycin. Roscovitine with calcium ionophore is effective for induction of oocyte activation through suppression of MPF activity in mice.     

The induction of reversible and irreversible chromosome decondensation by protein synthesis inhibition during meiotic maturation of mouse oocytes

We investigated the effects of puromycin on mouse oocyte chromosomes during meiotic maturation in vitro. Puromycin treatment for 6 hr at 100 μg/ml almost completely, but reversibly, suppressed [³⁵S]methionine incorporation into oocyte protein at all stages of maturation tested. Nevertheless, oocytes treated at the germinal vesicle stage underwent germinal vesicle breakdown (GVBD) and chromosome condensation. These oocytes completed nuclear maturation to metaphase II (MII) if the inhibitor was withdrawn. Prolonged (24-hr) treatment, however, caused the chromsomes to degenerate. The chromosomes of oocytes treated shortly after GVBD for 6 hr remained condensed, but the oocytes failed to form a polar body. However, 24-hr treatment caused the chromosomes to decondense to form an interphase nucleus. Oocytes treated near MI for 6 hr gave off a polar body during the treatment, and their chromosomes decondensed to form a nucleus, which remained as long as the treatment was continued. However, if the puromycin was withdrawn, the chromosomes recondensed to a state morphologically similar to that at MII. Thus, the chromosome decondensation induced by protein synthesis inhibition at MI was reversible. Oocytes treated at MII, several hours after first polar body formation, also underwent chromosome decondensation to form a nucleus. In the continuous presence of puromycin, the chromosomes remained decondensed, but neither DNA synthesis nor mitosis occurred. However, following puromycin withdrawal, these occytes synthesised DNA and underwent mitosis. Thus, protein synthesis inhibition at MII, by parthenogenetically activating the oocytes, caused irreversible chromosome decondensation. Based on these observations, we discussed the roles of protein synthesis in the regulation of oocyte chromosome behaviour during meiotic maturation.     

Three Phases of Cortical Maturation during Meiosis Reinitiation in Starfish Oocytes

Oocytes of the starfish, Asterina pectinifera , respond differently to calcium ionophore A23187 depending upon their stage of maturation. Oocytes not-treated with 1-methyladenine (1-MA) formed only a partial fertilization envelope (FE) in response to A23187. Those treated with 1-MA formed no FE if the ionophore was introduced to them before germinal vesicle breakdown (GVBD), in contrast with which they did fully elevate the FE if it was introduced after GVBD. Similar stage-dependent results were obtained if the intracellular concentration of calcium was increased by microinjection of calcium-EGTA buffers. In good accordance with the FE formation, a stage-dependent protease release from oocytes by the ionophore was observed.
It is concluded from these results that, in starfish oocytes, their ability to undergo the exocytosis of cortical granules in response to an increase in intracellular calcium greatly changes along the way of maturation.     

Optimisation of porcine oocyte activation following nuclear transfer

Experiments were conducted to examine the effects of (a) different activation methods, (b) incubation time in calcium-free medium and (c) bisbenzimide staining on the activation and subsequent development of pig oocytes. Oocytes were matured in vitro and activated by one of the following methods: combined thimerosal/dithiothreitol (DTT) treatment, calcium ionophore A23187 treatment followed by incubation in the presence of 6-dimethylaminopurine (6-DMAP), electroporation, and electroporation followed by incubation with cytochalasin B. There were no significant differences in the activation rate (ranging from 70.0% to 88.3%) and the percentage of cleaved embryos after activation (ranging between 48.8% and 58.8%) among the four treatment groups (p < 0.05). The rate of development of the blastocyst stage in oocytes activated by thimerosal/DTT (10.0%) or electroporation followed by cytochalasin B treatment (12.3%) was significantly higher (p < 0.05) than in the group activated with A23187/6-DMAP (2.5%). Both the activation rate and the rate of blastocyst formation in oocytes that were incubated in Ca(2+)-free medium for 8 h before thimerosal/DTT activation were significantly lower (p < 0.05) than in those incubated for 0, 1 or 4 h. Intracellular Ca2+ measurements revealed that the Ca2+ homeostasis in these oocytes were severely altered. Staining of oocytes with 5 micrograms/ml bisbenzimide for 2 h decreased the quality of blastocysts and increased the rate of degenerated embryos at day 6. Two activation protocols (thimerosal/DTT and electroproation) were used for activation after nuclear transfer; the rate of nuclear formation did not differ in the oocytes activated by the two different methods.     

In vitro fertilization of in vitro-matured equine oocytes: effect of maturation medium,duration of maturation,and sperm calcium ionophore treatment,and comparison with rates of fertilization in vivo after oviductal transfer

Three experiments were conducted to evaluate the effect of oocyte and sperm treatments on rates of in vitro fertilization (IVF) in the horse and to determine the capacity of in vitro-matured horse oocytes to be fertilized in vivo. There was no effect of duration of oocyte maturation (24 vs. 42 h) or calcium ionophore concentration during sperm capacitation (3 microM vs. 7.14 microM) on in vitro fertilization rates. Oocytes matured in 100% follicular fluid had significantly higher fertilization (13% to 24%) than did oocytes matured in maturation medium or in 20% follicular fluid (0% to 12%; P < 0.05). There was no significant difference in fertilization rate among 3 sperm treatments utilizing 7.14 microM calcium ionophore (12% to 21%). Of in vitro-matured oocytes recovered 40-44 h after transfer to the oviducts of inseminated mares, 77% showed normal fertilization (2 pronuclei to normal cleavage). Cleavage to 2 or more cells was seen in 22% of oocytes matured in follicular fluid and 63% of oocytes matured in maturation medium; this difference was significant (P < 0.05). We conclude that in vitro-matured horse oocytes are capable of being fertilized at high rates in the appropriate environment and that in vitro maturation of oocytes in follicular fluid increases fertilization rate in vitro but reduces embryo development after fertilization in vivo. Further work is needed to determine the optimum environment for sperm capacitation and IVF in the horse.     

DFP-sensitive multicatalytic protease complexes (proteasomes) involved in the control of oocyte maturation in the toad,Bufo japonicus

The inhibition of progesterone-induced oocyte maturation by diisopropylfluorophosphate (DFP), a typical serine protease inhibitor, was investigated in oocytes of the Japanese toad Bufo japonicus for the first time. Oocytes to which DFP was externally applied did not undergo germinal vesicle breakdown (GVBD), which is an early signal of oocyte maturation, in response to progesterone. The more inhibitory period was found to be 0–0.5 GVBD₅₀ on a relative time scale [when the time at which 50% of the oocytes had completed GVBD (GVBD₅₀) was set at 1.0], namely, before the beginning of GVBD. DFP-sensitive proteases, which seem to be multifunctional nonlysosomal protease complexes (proteasomes), may already be present in the cytosol of premature oocytes. Peptide hydrolyzing activity, as reflected by proteasome activity, was found to be regulated before and after GVBD. In addition, immunoblotting regarding the native electrophoretic protein profile of the proteasomes throughout the maturational process demonstrated that they undergo alterations in mobility dependent upon the maturational process. These findings raise the possibility that the activities of some endogenous DFP-sensitive proteasomes play distinct, essential roles in oocyte maturation triggered by progesterone in Bufo. © 1994 Wiley-Liss, Inc.     

RNA synthesis in the ovary and oocytes of the starfish

Qualitative studies on the in vitro uptake and incorporation of tritiated uridine into RNA of the somatic and germinal elements of the starfish ovary were carried out prior to and during hormone-induced oocyte maturation and spawning.Autoradiography of nonhormone-treated ovaries indicated that the outer ovarian wall contained the highest concentration of label, with lesser amounts in the follicle cells and least in the oocytes. Oocytes and follicle cells localized at the periphery of the ovary were labeled first, and both cells became progressively labeled throughout the ovary with time; the label first appeared localized in the nucleolus of the oocyte.Sucrose gradient analysis of the separated cellular components of prelabeled hormone-treated ovaries indicated that RNA synthesis occurred in all segments of the ovary and that the spawned oocyte fraction was the least active. Synthesis of ribosomal RNA was detectable after a lag period of approximately 4 hr. Oocytes incubated in ³H-uridine during and subsequent to 1-methyladenine-induced spawning and maturation synthesized 15–19 S and low molecular weight RNA but not ribosomal RNA. Synthesis of the 15–19 S RNA was inhibited with ethidium bromide and to a limited extent by actinomycin D. Isolated mitochondrial fractions contained most of the labeled 15–19 S RNA. These data suggest the mitochondrial origin of most, if not all, of this intermediate-weight RNA. On the basis of these studies, it appears that starfish oocytes and follicle cells are metabolically active at the transitional period from growth to maturational stages in oocytes. Synthesis of RNA furthermore apparently continues in the cytoplasm subsequent to germinal vesicle breakdown and spawning.     

Precocious induction of activation responses in amphibian oocytes by divalent ionophore A23187

Temporal relationships between maturational events and the onset of activation in response to divalent ionophore and to pricking were examined following in vitro exposure of Rana pipiens oocytes to desoxycorticosterone acetate (DOCA). Activation was evaluated on the basis of vitelline envelope elevation and cortical granule breakdown. Ionophore-induced activation was first observed after 18 hr of DOCA incubation, coincident with the time of separation of the vitelline envelope from the oocyte surface and 2–3 hr after breakdown of the germinal vesicle. Activation in response to pricking was not observed until 30 hr of DOCA incubation. Neither ionophore treatment nor pricking resulted in activation of oocytes that had not been incubated with DOCA. These results indicate that oocytes can be activated many hours earlier than previously demonstrated. The time of onset of the capacity for activation appears to be related to germinal vesicle breakdown and vitelline envelope separation.     

Signaling pathways in ascidian oocyte maturation: effects of various inhibitors and activators on germinal vesicle breakdown

The Ascidiacea, the invertebrate chordates, includes three orders; the Stolidobranchia is the most complex. Until the present study, the onset of oocyte maturation (germinal vesicle breakdown) had been investigated in only a single pyurid (Halocynthia roretzi), in which germinal vesicle breakdown (GVBD) begins when the oocyte contacts seawater (SW); nothing was known about internal events. This study strongly suggests the importance of protein phosphorylation in this process. Herdmania pallida (Pyuridae) functions like H. roretzi; GVBD occurs in SW. Oocytes of Cnemidocarpa irene (Styelidae) do not spontaneously undergo GVBD in SW but must be activated. Herdmania oocytes are inhibited from GVBD by pH 4 SW and subsequently activated by mastoparan (G-protein activator), A23187 (Ca2+ ionophore) or dimethylbenzanthracene (tyrosine kinase activator). This requires maturation promoting factor (MPF) activity; cyclin-dependent kinase inhibitors roscovitine and olomoucine are inhibitory. It also entails dephosphorylation as demonstrated by the ability of the phosphatase inhibitor vitamin K3 to inhibit GVBD. GVBD is also inhibited by the tyrosine kinase inhibitors tyrphostin A23 and genistein, and LY-294002, a phosphatidylinositol-3-kinase inhibitor previously shown to inhibit starfish GVBD. LY-294002 inhibits strongly when activation is by mastoparan or ionophore but not when activated by dimethylbenzanthracene (DMBA). The DMBA is hypothesized to phosphorylate a phosphatase directly or indirectly causing secondary activation, bypassing inhibition.     

Response of porcine oocytes to electrical and chemical activation during maturation in vitro

These studies were conducted to examine activation of in vitro-matured porcine oocytes in response to an electrical stimulus or to an ionophore. Cumulus-enclosed porcine oocytes were incubated in maturation medium supplemented with either FSH and LH (MM:Exp.1) or pregnant mare serum gonadotropin (PMSG; MM-P: experiments 2-4) at 39 degrees C in 5% CO2:95% air with high humidity. In experiment 1, groups of oocytes were stripped of cumulus and then shampulsed (control) or electrically pulsed with a Zimmerman Cell Fusion unit at 24, 31, 41, 48, and 65 h of incubation. Control oocytes were exposed to the activation medium for 20 sec, whereas oocytes to be pulsed were subjected to a single activation pulse (120 V, 30 microseconds). Oocytes were cultured for an additional 24 h and then fixed and examined. For oocytes pulsed at 24, 31, 41, 48, and 65 h, the proportions which activated were 0, 0, 87, 88, and 83%, respectively. In experiment 2, oocytes were electrically or sham-pulsed with a BTX 200 Embryomanipulation System at 24, 30, and 40 h of incubation and respective proportions of oocytes activating were 27%, 39%, and 72%. In experiment 3, oocytes were subjected to 0, 1, or 2 activation pulses after 41 h of incubation in MM-P. Double-pulsing halved the proportion of activated oocytes (P less than .0001). In experiment 4, oocytes were subjected to 0, 25, 50, or 100 microM ionophore at 48 h of incubation. Proportions of oocytes activated by ionophore were greater than for control (P less than .05), but activation was not increased by increasing dose of ionophore.(ABSTRACT TRUNCATED AT 250 WORDS)