转人t-PA指形区缺失基因的山羊体细胞核移植及其继代核移植

为了探索转基因体细胞核经连续核移植后的发育潜力,以转人组织型纤溶酶原激活剂(t-PA)指形区缺失基因的山羊胎儿成纤维细胞为核供体,MII期的卵母细胞质为核受体,利用胞质内注射法构建原代核移胚胎(G0),并进行了原代核移植胚胎的继代核移植研究。比较原代和继代核移植胚胎在体外发育能力上的差异;在G1、G2代核移植试验过程中,比较了供体胚胎细胞的发育阶段对核移植胚胎体外发育的影响。结果表明,原代核移植胚胎的卵裂率(76.45%±1.17%)与继代核移植胚胎的卵裂率(72.18%±1.97%,76.05%±2.38%,75.99%±2.84%)无显著性差异(P>0.05)。但原代核移植胚胎的桑葚胚率(47.20%±2.93%)、囊胚率(11.00%±1.42%)显著高于G1、G2、G3代核核移植胚胎的桑葚胚率(34.99%±2.66%,28.23%±2.00%,23.34%±1.99%)、囊胚率(3.87%±0.67%,2.08%±1.66%,0);在G1、G2中,当用16-细胞期核移植胚胎作为核供体时的桑葚胚率(29.57%±1.53%,24.43%±1.87%)、囊胚率(1.96%±1.31%,2.01%±1.34%)低于用32~64-细胞时期的核移植胚胎的桑葚胚率(34.32%±1.31%,29.76%±1.66%)、囊胚率(3.86%±1.03%,3.48%±0.34%),但无显著性差异(P>0.05)。由此得出结论:转基因体细胞核移植胚胎不宜进行多代克隆;胞质内注射法构建核移植胚胎,用32~64-细胞期的胚胎作为核供体构建的核移植胚胎的体外发育率高于用16-细胞期的胚胎作为核供体构建的核移植胚胎的体外发育率。     

Nuclear transfer in cattle using in vivo-derived vs. in vitro-produced donor embryos: Effect of developmental stage

To determine the best developmental stage of donor embryos for yielding the highest number of clones per embryo, we compared the efficiencies of nuclear transfer when using blastomeres from morulae or morulae at cavitation, or when using inner-cell-mass cells of blastocysts as nuclear donors. This comparison was done both on in vivo-derived and in vitro-produced donor embryos. In experiment 1, with in vivo-derived donor embryos, nuclei from morulae at cavitation supported the development of nuclear transfer embryos to the blastocyst stage (36%) at a rate similar to that of nuclei from morulae (27%), blastomeres from morulae at cavitation being superior (P < 0.05) to inner-cell-mass cells from blastocysts (21%). The number of blastocysts per donor embryo was significantly (P < 0.05) higher when using nuclei from morulae at cavitation (15.7 ± 4.1) rather than nuclei from morulae (9.8 ± 5.5) or blastocysts (6.3 ± 3.3). With in vitro-produced donor embryos (experiment 2), nuclei from morulae yielded slightly more blastocysts (32%) than nuclei from morulae at cavitation (29%), both stages being superior to nuclei from blastocysts (15% development to the blastocyst stage). Morulae at cavitation yielded a higher number of cloned blastocysts per donor embryo (11.5 ± 5.9) than did morulae (9.3 ± 3.2) and blastocysts (3.3 ± 1.4). Transfer of cloned embryos originating from in vivo-derived morulae, morulae at cavitation, and blastocysts resulted in four pregnancies (10%), three pregnancies (7%), and one (17%) pregnancy on day 45. The corresponding numbers of calves born were 3 (4%), 3 (7%), and 0, respectively. After transfer of blastocysts derived from in vitro nuclear donor morulae (n = 16) and morulae at cavitation (n = 7), two (20%) and two (50%) recipients, respectively, were pregnant on day 45. However, transfer of seven cloned embryos from in vitro donor blastocysts to three recipients did not result in a pregnancy. Using in vitro-produced donor embryos, calves were only obtained from morula-stage donors (13%). Our results indicate that the developmental stage of donor embryos affects the efficiency of nuclear transfer, with morulae at cavitation yielding a high number of cloned blastocysts. © 1996 Wiley-Liss, Inc.     

Characterization of embryos derived from calf oocytes: kinetics of cleavage, cell allocation to inner cell mass, and trophectoderm and lipid metabolism

Embryos derived from calf oocytes were compared with adult cow oocyte-derived embryos (1) by studying the kinetics of embryo development using time-lapse cinematography (2) by evaluating the ratio between inner cell mass (ICM) and trophectoderm (TE) cells in blastocysts (3) by measuring the triglyceride content of the blastocysts. The rate of calf oocyte-derived embryos reaching the blastocyst stage was reduced (26 vs. 46% for adult derived embryos). Calf oocyte-derived embryos preferably arrested their development before the 9-cell stage. Those that developed into blastocysts had cleaved earlier to reach the 2-cell or 3-cell stages than embryos that arrested before the 9-cell stage. The 9-cell stage tended to appear later in calf oocyte-derived embryo that reached the blastocyst stage than in adult-derived embryos. This difference became significant at the morula stage. Accordingly, the fourth cell cycle duration was longer for calf oocyte-derived embryos. Day 8 blastocysts from both sources had similar total cell numbers (calf: 89 +/- 20; cow: 100 +/- 30) and cell distribution between TE and ICM. The triglyceride content of day 7 blastocysts was similar for both sources (64 +/- 15 vs. 65 +/- 6 ng/embryo, respectively). In conclusion, calf oocyte-derived embryos are characterized by a higher rate of developmental arrest before the 9-cell stage and by a longer lag phase preceding the major onset of embryonic genome expression. These changes might be related to insufficient "capacitation" of the calf oocyte during follicular growth. Despite these differences, modifications in the quality of the resulting blastocysts were not detected.     

Morphologic evaluation and actin filament distribution in porcine embryos produced in vitro and in vivo

Porcine embryos produced in vitro have a small number of cells and low viability. The present study was conducted to examine the morphological characteristics and the relationship between actin filament organization and morphology of porcine embryos produced in vitro and in vivo. In vitro-derived embryos were produced by in vitro maturation, in vitro fertilization (IVF), and in vitro development. In vivo-derived embryos were collected from inseminated gilts on Days 2-6 after estrus. In experiment 1, in vitro-derived embryos (相似文献   

Pregnancies and live birth from in vitro fertilization of calf oocytes collected by laparoscopic follicular aspiration

Oocytes were recovered by laparoscopic aspiration from 3- to 8-week-old calves treated with follicle-stimulating hormone (FSH) followed by human chorionic gonadotropin (hCG) to induce follicular growth and oocyte maturation in vivo. Most of the recovered oocytes either had resumed meiotic maturation at the time of aspiration or were competent to undergo maturation during subsequent culture in vitro. Oocytes matured in vivo following FSH and hCG treatment underwent in vitro fertilization (70%) at rates not significantly different from those of control oocytes recovered from adult cow ovaries at abattoirs and matured in vitro (75%). Calf oocytes that were immature at aspiration exhibited lower fertilization rates after in vitro maturation (36%) but their rate of development to morulae and blastocysts did not differ from that of mature oocytes at aspiration. A total of 91% of the zygotes produced from calf oocytes developed to morula and 27% to blastocyst stages during 6 days of culture. The proportion developing to morulae was significantly higher (P<0.05) than that observed for zygotes resulting from in vitro maturation and fertilization of oocytes recovered from cow ovaries obtained at an abattoir and processed concomitantly (59% to morulae and 18% to blastocysts). Morulae or blastocysts developed from oocytes from 5 to 6-week-old calves, when transferred to synchronized recipient heifers, resulted in 2 confirmed pregnancies, one of which produced a single full-term live calf. The ability to produce embryos from oocytes recovered from newborn or prepubertal calves offers the potential for markedly reducing the generation interval in cattle, thereby substantially accelerating the rate of genetic gain that can be achieved through embryo transfer.     

Cleavage beyond the block stage and survival after transfer of early bovine embryos cultured with trophoblastic vesicles

Early bovine embryos (1- to 8-cell stages) were recovered from superovulated heifers at slaughter on Days 2 or 3. Embryos were cultured for 3-4 days in Medium B2 supplemented with 15% (v/v) fetal calf serum in the absence (B2SS, 106 embryos) or presence of trophoblastic vesicles (B2SS + TV, 190 embryos). At the end of culture, there were more (P less than 0.001) morulae (greater than or equal to 16 cells) in B2SS X TV (46%) than in B2SS alone (18%) irrespective of the initial cell stage. More 8-cell embryos reached the 16-cell stage than did embryos with less than 8 cells (30% vs 15% in B2SS, P greater than 0.05; 70% vs 41% in B2SS + TV, P less than 0.005). After culture, 102 morulae were transferred non-surgically to temporary recipient heifers (84 embryos cultured in B2SS + TV and 18 in B2SS). After 2 or 3 days, 14 out of 58 embryos from the B2SS + TV group and 3 out of 10 embryos from the B2SS group were recovered as blastocysts. Most blastocysts were deep-frozen and stored for several weeks. After thawing, 10 apparently normal embryos from the B2SS + TV group were transferred non-surgically into 10 recipient heifers. Four pregnancies were induced, but only one embryo survived to term (birth of a normal male calf). It is concluded that trophoblastic vesicles release one or several unknown compound(s) normally present in vivo, promoting the cleavage of early bovine embryos.     

Decreased embryonic survival of in-vitro fertilized oocytes in rats is due to retardation of preimplantation development

Immature female rats (60-65 g) were injected with 4 i.u. PMSG on Day -2 and allocated to 3 groups. On the evening of Day 0, rats in Groups I and II were allowed to mate. Embryos were collected on Day 4 (Group I, control morulae) or Day 5 (Group II, control blastocysts) and were transferred into the oviduct or uterine horn of Day-4 pregnant recipient rats. On the transfer side of the recipients, the bursa had been peeled from around the ovary to prevent endogenous oocytes from entering the oviduct. For Group III, unmated donors were killed 65-67 h after PMSG injection. Ovulated oocytes recovered from the oviducts were fertilized in vitro and transferred 16-18 h later. Embryos developing from in-vitro fertilized (IVF) oocytes were recovered on Day 5, separated into morulae (Group IIIm) and blastocysts (Group IIIb) and transferred into Day-4 pregnant recipients similar to control embryos. Some embryos from each group were used to determine the mean number of cells/embryo. Embryo recipients were killed on Day 20. After transfer, the development of IVF oocytes was retarded compared to control embryos. IVF morulae contained significantly fewer cells/embryo than did control morulae but were able to implant and grow to fetuses, in proportions similar to controls, if transferred into the oviduct of the recipients. These results suggest that the developmental potential of rat oocytes fertilized in vitro is limited due to asynchrony between the embryo and the uterine environment at the time of implantation, rather than possible defects incurred by the oocyte during the fertilization procedure.     

Pronuclear visibility, development and transgene expression in IVM/IVF-derived porcine embryos

A total of 1550 zygotes was used to assess the timing of pronuclear visibility, embryo development following DNA microinjection, and transgene expression in IVM/IVF-generated porcine embryos. After centrifugation, pronuclei could be seen in 61.6% of zygotes. In 55.3% of these only 1 pronucleus was visible. Pronuclear visibility was highest at 20 h post-insemination. Zygotes were microinjected with 1 of 2 LacZ gene constructs driven by either the SV40 early promoter (pSVON) or the human cytoplasmic beta actin promoter (pbActinLacZ). Development and transgene expression were assessed after either 48 h or 7 d in culture. After 48 h, significantly more zygotes with a single visible pronucleus developed to the 8-cell stage than zygotes in which no pronucleus had been seen (43.0 vs 24.8%), while those with 2 pronuclei were intermediate (31.4%). After 7 d, no difference in development to the morula stage was observed between noninjected control embryos (25.5%) and embryos with 1 (21.0%) or 2 pronuclei (22.5%); however, the proportion of embryos reaching the morula stage in the nonpronuclear group was significantly reduced (9.1%). After 48 h in culture, transgene expression was significantly higher in embryos with 2 pronuclei at the time of injection than in those with 1 (36.4 vs 17.9%). After 7 d in culture, 41.5% of morulae derived from zygotes with 2 pronuclei and 29.97% of thsoe derived from zygotes with 1 pronucleus showed signs of transgene expression. At this stage, significantly more morulae expressed the pbActinLacZ than the pSVON transgene (43.8 vs 25.8%). More than 80% of putative transgenic morulae or blastocysts showed evidence of mosaicism. These results demonstrate that IVM/IVF porcine embryos are able to develop in culture and express a microinjected transgene.     

Survival of frozen-thawed sheep embryos cryopreserved at cleavage stages

This study evaluated the effect of freezing-thawing procedures on the viability of sheep embryos cryopreserved at various developmental stages. The survival rates of frozen-thawed embryos were compared with non-frozen counterparts. Embryos were recovered from the oviduct and uterus, at different days of the early luteal phase, and were classified at six different developmental stages: 2- to 4-cell (n = 72), 5- to 8-cell (n = 73), 9- to 12-cell (n = 70), early morulae (n = 42), morulae (n = 41), and blastocyst (n = 70). For each early cleavage stage and blastocysts, approximately half of the embryos, were frozen immediately by slow freezing with an ethylene glycol-based solution. The remaining embryos were cultured to the hatched blastocyst stage. All morulae and compact morulae were frozen after recovery with the same protocol. Cryoprotectants were removed using 1M sucrose solution, and then warmed the embryos were cultured to the hatched stage in a standardized in vitro culture. Embryo developmental stage had a significant effect on the ability to hatch following freezing (P<0.0001). The cryotolerance of the embryos fitted a regression (r2 = 0.908), increasing linearly from 2- to 4-cell embryos (17.1%) to morula stage (46.3%) and in a quadratic regression from the morula to the blastocyst stage (83.7%). Frozen early cleavage stage embryos had a significantly lower viability than their fresh counterparts (23.1 vs 83.1%; P<0.0001), with a similar rate of viability between fresh or frozen blastocysts (92.5 vs 83.7%). In conclusion, early sheep embryos are very sensitive to freezing per se and the survival rates following conventional freezing improve as embryo developmental stage progresses.     

Comparison of hybrid and purebred in vitro-derived cattle embryos during in vitro culture

Frozen-thawed spermatozoa collected from a beef bull (Japanese Black) were used for in vitro fertilization (IVF) of matured oocytes obtained from dairy (Holstein) and beef (Japanese Black) females. Embryos were examined for fertilization, cleavage rate, interval between insemination and blastocyst production (experiment I), total cell number per embryo and sex ratio during blastocyst formation (experiment II), and blastocyst production rate of zygotes that developed to 2-, 4-, and 8-cell stages at 48h post-fertilization (experiment III). Fertilized oocytes were cultured in vitro on a cumulus cell co-culture system. The fertilization and cleavage rate of oocytes groups were similar, however, the blastocyst production rate was greater (P<0.05) in hybrid than from purebred embryos (27% versus 20%). Development of blastocysts produced from hybrid embryos developed at a faster rate than blastocysts produced from the straightbred embryos. In hybrid embryos, blastocyst production was significantly greater on day 7 (56%) and gradually decreased from 20% on day 8 to 17% on day 9. In contrast, blastocyst production rate from the purebred embryos was lower on day 7 (17%), increasing on day 8 to 59% and then decreased on day 9 to 24%. The total number of cells per embryo and sex ratio of in vitro-produced blastocysts were not different between hybrid and purebred embryos. The number of blastocysts obtained from embryos at the 8-cell stage of development by 48h post-fertilization (94%) was greater (P<0.01) than the number of zygotes producing blastocysts that had developed to the 4-cell stage (4%) and the 2-cell stage (2%) during the same interval. These results show that the blastocyst production rate and developmental rate to the blastocyst stage were different between hybrid and purebred embryos, and that almost all of the in vitro-produced blastocysts were obtained from zygotes that had developed to the 8-cell stage 48h post-fertilization.     

Triglyceride content of bovine oocytes and early embryos

A microfluorescence technique was used to measure the triglyceride content of a minimum of two bovine oocytes or preimplantation embryos up to the hatched blastocyst stage. Embryos were produced in vitro from abattoir-derived ovaries and grown in medium containing synthetic oviductal fluid, amino acids and BSA (SOFaaBSA medium); 10% fetal calf serum was added to some of the embryos at the four-cell stage. Before maturation, the triglyceride content of oocytes was 59 +/- 1.37 ng and it decreased (P < 0.05) after maturation to 46 +/- 0.85 ng. A decrease in triglyceride content (P < 0.05) was also observed after fertilization with the formation of the two-cell embryo (34 +/- 1.80 ng). In the absence of serum, the triglyceride content remained relatively constant from the two-cell to the hatched blastocyst stage. The triglyceride content of blastocysts produced in vivo was similar (33 +/- 0.70 ng) to that of blastocysts produced in vitro in the absence of serum. In contrast, the triglyceride content of embryos grown with 10% fetal calf serum increased steadily from the 9-16-cell stage to a value in hatched blastocysts (62 +/- 1.14 ng) almost double that in serum-free conditions. These results indicate that triglyceride may act as energy source during bovine oocyte maturation and fertilization and that the presence of serum causes excessive synthesis or accumulation of triglyceride in early embryos.     

Effect of reduced concentrations of glycerol and various macromolecules on the cryopreservation of mouse and cattle embryos

The effect of different macromolecules [bovine serum albumin (BSA), Pluronic F-68, (ET surfactant), or sodium hyaluronate (SH)] on postthaw survival of mouse morulae and in vivo- and in vitro-derived bovine blastocysts frozen in 10, 5, or 1% glycerol solutions was investigated. Embryos were equilibrated with cryoprotectant solution at 25 degrees C for 10 min, seeded at -5 degrees C, cooled at 0.5 degrees C/min to -35 degrees C, and plunged into liquid nitrogen. Embryos were thawed in a 35 degrees C water bath, glycerol was removed with 0.6 M sucrose at 25 degrees C for 5 min, and postthaw viability was evaluated after 1, 24, and 48 h in culture. The addition of BSA supplementation improved postthaw survival of mouse morulae frozen in 5% glycerol, but not in 10% glycerol. All three macromolecular supplements were effective in increasing survival of mouse morulae in 5% glycerol but only BSA and SH were effective in increasing postthaw survival of in vivo- and in vitro-derived bovine blastocysts. None of the macromolecular supplements improved postthaw survival of embryos frozen in 1% glycerol.     

Nonelectrophoretic PCR-sexing of bovine embryos in a commercial environment

Techniques for sex determination of bovine embryos have evolved from karyotyping of older preimplantation embryos some 25 years ago to the current variety of widely used polymerase chain reaction (PCR) protocols. Although highly accurate, most PCR protocols for sex determination have included an electrophoresis step. The present work is a retrospective study utilizing a unique PCR protocol to sex bovine embryos without use of electrophoresis in a commercial embryo transfer program. Both in vivo and in vitro-derived embryos were produced by conventional techniques and biopsied between 7 and 8 days of age with a steel blade attached to a mechanical micromanipulator. Males constituted 49.0% of 3964 in vivo and 53.0% of 1181 in vitro-derived embryos subjected to PCR. Based on ultrasound fetal sexing and on calvings, the accuracy of sex determination was 98.7% for male embryos and 94.4% for females, with no samples producing an undetermined outcome. Pregnancy rates following transfer of biopsied Grade 1 embryos were lower than control, intact embryos as follows: 8, 6 and 16% points for in vivo, in vitro and in vivo frozen embryos, respectively. Pregnancy rates were similar for all stages of in vivo-derived embryos, whereas the pregnancy rate was significantly lower for in vitro-derived morulae compared to all stages of blastocysts. The sex ratio was significantly skewed in favor of females among in vitro-derived morulae, and in favor of males among in vitro expanded blastocysts. The sex ratio of in vivo expanded blastocysts was significantly skewed in favor of female embryos. No seasonal variation in either pregnancy rate or sex ratio was detected. There was no evidence that DNA contamination influenced the PCR assay during the duration of the study. The assay was sensitive to single blastomeres from male embryos, whereas it was not sensitive to Percoll-centrifuged or accessory sperm cells.     

Blastocysts produced by nuclear transfer between chicken blastodermal cells and rabbit oocytes

Interspecies nuclear transfer (INT) has been used as an invaluable tool for studying nucleus-cytoplasm interactions; and it may also be a method for rescuing endangered species whose oocytes are difficult to obtain. In the present study, we investigated interaction of the chicken genome with the rabbit oocyte cytoplasm. When chicken blastodermal cells were transferred into the perivitelline space of rabbit oocytes, 79.3% of the couplets were fused and 9.7% of the fused embryos developed to the blastocyst stage. Both M199 and SOF medium were used for culturing chicken-rabbit cloned embryos; embryo development was arrested at the 8-cell stage obtained in SOF medium, while the rates of morulae and blastocysts were 12.1 and 9.7%, respectively, in M199 medium. Polymerase chain reaction (PCR) amplification of nuclear DNA and karyotype analyses confirmed that genetic material of morulae and blastocysts was derived from the chicken donor cells. Analysis mitochondrial constitution of the chicken-rabbit cloned embryos found that mitochondria, from both donor cells and enucleated oocytes, co-existed. Our results suggest that: (1) chicken genome can coordinate with rabbit oocyte cytoplasm in early embryo development; (2) there may be an 8- to 16-cell stage block for the chicken-rabbit cloned embryos when cultured in vitro; (3) mitochondrial DNA from the chicken donor cells was not eliminated until the blastocyst stage in the chicken-rabbit cloned embryos; (4) factors existing in ooplasm for somatic nucleus reprogramming may be highly conservative.     

Co-culture of early cattle embryos to the blastocyst stage with oviducal tissue or in conditioned medium

In Exp. 1, 5-8-cell embryos from superovulated cattle were co-cultured with oviducal tissue suspended in Ham's F10 + 10% fetal calf serum (F10FCS) or in F10FCS alone. After 4 days, the proportion of embryos developing into compact morulae or blastocysts was greater (P less than 0.005) in co-culture (38/82; 46%) than in F10FCS (1/27; 4%). In Exp. 2, a solution of collagenase, trypsin, DNAse and EDTA was used to disperse oviducal tissue, which was then cultured in TCM199 + 10% fetal calf serum (M199FCS) to obtain monolayers. Embryos (1-8 cells) were then co-cultured with monolayers or in M199FCS alone. The proportion of embryos developing into compact morulae and blastocysts after 4-5 days was higher (P less than 0.005) in co-culture (15/34; 43%) than in M199FCS (1/37; 3%); mean numbers of cells/embryo were also higher (P less than 0.001) (27.70; range 2-82 in co-culture; 8.83; range 2-18 in M199FCS). In Exp. 3, embryos obtained from in-vitro maturation and fertilization were used to compare development between co-culture and medium conditioned by oviducal tissue. Initial cleavage rate (no. embryos greater than 1 cell/total) was 76% (611/807) and did not differ among treatments. After 5 days, the proportion cleaving to greater than 16 cells was higher (P less than 0.005) in co-culture (71/203; 35%) and conditioned medium (48/205; 23%) compared to M199FCS (14/203; 7%). Similarly, the proportion developing into compact morulae and blastocysts was greater (P less than 0.005) in co-culture (44/203; 22%) and conditioned medium (46/205; 22%) than in M199FCS (7/203; 3%).(ABSTRACT TRUNCATED AT 250 WORDS)     

The transition from maternal to zygotic control of development occurs during the 4-cell stage in the domestic pig, Sus scrofa: quantitative and qualitative aspects of protein synthesis

A study was conducted to identify the embryonic stage when the zygotic genome begins to direct development and to characterize protein synthesis in pig oocytes and embryos. Reproductive tracts of gilts were flushed to obtain unfertilized oocytes (UFO), zygotes (Z), 2-, 4-, and 8-cell embryos, compact morulae (M), initial blastocysts (IB), blastocysts (B), and hatched blastocysts (HB). Pig eggs and embryos were cultured in medium containing 1 microM L-[35S]methionine and evaluated for amino acid uptake, incorporation of the radiolabel into protein, and qualitative changes in protein profiles specific to each cleavage stage. Unfertilized oocytes sequestered 65.7 fmol methionine/4 h/embryo. Uptake of methionine decreased (p less than 0.05) from the Z (49.4), 2-cell (41.8), and 4-cell (37.6) embryonic stages to the M (8.97 fmol/4 h/embryo) stage. This downward trend was reversed at the IB, B, and HB stages when uptake increased to 37.3, 50.3, and 84.2 fmol/4 h/embryo, respectively. Incorporation of methionine into protein followed a similar pattern, being relatively higher in the UFO (21.0), Z (20.5), and 2-cell stages (16.0); decreased (p less than 0.05) at the 4-cell (6.67), 8-cell (6.84), and M (6.16) stages; and increased (p less than 0.05) at the IB (28.0), B (41.5), and HB (69.6 fmol/4 h/embryo) stages. Differences in protein profiles were observed for UFO, Z, 4-cell, and M stages using lysates of single embryos, one-dimensional SDS-PAGE, and fluorography.(ABSTRACT TRUNCATED AT 250 WORDS)