Gonadotropin effects on chromosomal normality of hamster preimplantation embryos

Induction of ovulation with pregnant mare's serum (PMS) and the timing of human chorionic gonadotropin (hCG) injection on chromosomal normality were examined in preimplantation hamster embryos. Two separate experimental trials were done. The first compared superovulation (SO, PMS on Day 1 of the cycle followed by hCG on Day 4) to natural ovulation. Natural mating was used. In the second series of trials, precocious superovulation (PSO, PMS on Day 1 followed by hCG on Day 3) was used. Since there is poor sperm transport in PSO females, direct uterine artificial insemination (AI) was used to achieve fertilization. The control animals in the second series of trials were naturally ovulating females subjected to the artificial insemination procedure. Of 785 embryos analyzed in the SO group, 9 (1.1%) were aneuploid (5 hyperploidy and 4 hypoploidy) and 8 (1.0%) showed triploidy. In the PSO group, artificial insemination resulted in a normal development rate of 85.5% up to the 2-cell stage. A total of 2.6% karyotypically abnormal embryos, consisting of 5 (1.1%) aneuploid and 7 (1.5%) polyploid, were found among 460 embryos examined in PSO females. No significant difference in the incidence of chromosomal abnormalities was observed between the stages of development. The overall incidence of chromosomal imbalance in hormonally treated females was not significantly different from that in controls (2.2% in SO cycles vs. 1.2% in natural cycles, 2.6% in PSO with AI vs. 2.4% in natural cycles with AI). These results indicate that PMS-hCG treatment has no adverse effect on the chromosomal integrity of hamster preimplantation embryos.     

Heat shock-induced apoptosis in preimplantation bovine embryos is a developmentally regulated phenomenon

Apoptosis is a form of cell death that can function to eliminate cells damaged by environmental stress. One stress that can compromise embryonic development is elevated temperature (i.e., heat shock). For the current studies, we hypothesized that heat shock induces apoptosis in bovine embryos in a developmentally regulated manner. Studies were performed to 1) determine whether heat shock can induce apoptosis in preimplantation embryos, 2) test whether heat-induced apoptosis is developmentally regulated, 3) evaluate whether heat shock-induced changes in caspase activity parallel patterns of apoptosis, and 4) ascertain whether exposure to a mild heat shock can protect embryos from heat-induced apoptosis. As determined by TUNEL reaction, exposure of bovine embryos > or =16 cells on Day 5 after insemination to 41 or 42 degrees C for 9 h increased the percentage of cells undergoing apoptosis. In addition, there was a duration-dependent increase in the proportion of blastomeres that were apoptotic when embryos were exposed to temperatures of 40 or 41 degrees C, which are more characteristic of temperatures experienced by heat-stressed cows. Heat shock also increased caspase activity in Day 5 embryos. However, heat shock did not induce apoptosis in 2- or 4-cell embryos, nor did it increase caspase activity in 2-cell embryos. The apoptotic response of 8- to 16-cell-stage bovine embryos to heat shock depended upon the day after insemination that heat shock occurred. When 8- to 16-cell embryos were collected on Day 3 after insemination, heat shock of 41 degrees C for 9 h did not induce apoptosis. In contrast, when 8- to 16-cell embryos were collected on Day 4 after insemination and exposed to heat shock, there was an increase in the percentage of cells undergoing apoptosis. Exposure of 8- to 16-cell embryos at Day 4 to a mild heat shock of 40 degrees C for 80 min blocked the apoptotic response to a subsequent, more-severe heat shock of 41 degrees C for 9 h. In conclusion, apoptosis is a developmentally acquired phenomenon that occurs in embryos exposed to elevated temperature, and it can be prevented by induced thermotolerance.     

Intrabursal transfer of spermatozoa (ITS): a new route for artificial insemination of mice.

Artificial insemination (AI) by direct injection of epididymal spermatozoa into the reproductive tract of females is simpler and more convenient than in vitro fertilization (IVF) and subsequent transfer of fertilized eggs to recipient oviducts for simultaneous acquisition of a large number of pups. Introduction of epididymal spermatozoa into oviducts via the oviductal wall or via vaginal and intrauterine routes is currently the most commonly used method for AI in mice. In this study, we explored another route for AI of the mouse and found that transfer of spermatozoa into a space near the infundibulum between the ovary and ovarian bursa enables in vivo fertilization of ovulated oocytes at the ampulla. When 1 microL of a sperm suspension containing 1 x 10(4) spermatozoa freshly isolated from B6C3F1 males was intrabursally injected into superovulated B6C3F1 females on E (embryonic day) 0.4 (10:00 AM), 5 of 7 females yielded 2-cell embryos with rates of efficiency ranging from 4 to 21% (11% on average), which were much lower than those (91% on average) for embryos obtained by natural mating. All the 2-cell embryos derived from injection of sperm developed in vitro to hatched blastocysts. Similar results were obtained from injection of 1 microL of sperm suspension containing 1 x 10(3) spermatozoa, although in vivo fertilizing ability was slightly improved (28% on average). When 1 microL of sperm suspension containing 1 x 10(4) spermatozoa was injected intrabursally into superovulated females that had been mated with vasectomized males, 6 of 10 mice (60%) yielded 19 normal mid-gestational fetuses with an average litter size of 3.2, which was much lower than that (14.5) for embryos obtained by natural mating. Although the present findings appear to be preliminary, this technique, based on the intrabursal transfer of spermatozoa, will be of practical use for AI in mice, particularly for transgenic and mutant mice that are often difficult to breed.     

Intrauterine transfer of early canine embryos

The success rate of in vitro fertilization (IVF) in dogs is low and only early embryos have been obtained. In the present study, we investigated the use of intrauterine transfer of early-stage canine embryos to obtain pups. Twenty-three female dogs, in which the date of ovulation (based on plasma progesterone concentrations) differed by +/-1 day, were used (10 donors and 13 recipients). The uterine tube was extirpated under general anesthesia 1-4 days after mating (5-7 days after ovulation), and descending perfusion was done to collect embryos. Embryos were examined and transferred into the uterine horn of a recipient, ipsilateral to the ovary with the most corpora lutea. Pregnancy was established in one of eight bitches that received early embryos (zygote to 4-cell embryos); she received two zygotes and one 2-cell embryo and delivered two puppies. Although intrauterine transfer of early embryos (zygote to 4-cell embryos) was difficult, pregnancy was achieved, suggesting that uterine tube transfer is appropriate for these early-stage embryos.     

Effect of blastomere sex and fluorescent labelling on the development of bovine chimeric embryos reconstituted at the four-cell stage

The development rate of bovine chimeric embryos reconstituted at the 4-cell stage is relatively low. If chimerism is to be used as an approach in producing transgenic livestock, it is important to investigate whether this rate is affected by the sex of the blastomeres being combined and if all blastomeres survive equally well. In Experiment 1, blastomeres from 4-cell stage embryos were inserted into surrogate zonae pellucidae either in pairs to reconstitute 4-cell chimeras, or as the original sets of four to make handled controls. The development of chimeras with one pair of blastomeres labelled with PKH26-GL was also investigated. The rate of development into blastocysts was similar in chimeras with unlabelled blastomeres (23%) and in those in which one pair of blastomeres was labelled (26%) and was lower (P < 0.001) than in the handled and IVF control groups (43 and 58%, respectively). Labelled cells were distributed approximately evenly between ICM and trophoblast. In Experiment 2, the effect of sex differences between pairs of blastomeres in chimeras was investigated; chimeras were reconstituted from pairs of blastomeres taken from 4-cell embryos in which the remaining pair was sexed by PCR. No significant differences according to the sex of constituent blastomeres were detectable (mixed sex, 27%; males, 24%; females, 21%; P > 0.05). These results suggest that, in addition to the negative effects of micromanipulation, factors other than the sex of the blastomeres are involved in the reduced rate of development of chimeric bovine embryos. They also confirm the usefulness of PKH26-GL labelling for tracking the progeny of cleaving bovine blastomeres at least to the blastocyst stage.     

Fertilization of Chinese hamster ova in vitro and in vivo and their subsequent development in culture

Oocytes from superovulated Chinese hamsters can be fertilized in vitro using the culture medium BWW (70% of 112 ova) or a modified BWW designated as MBWW (76% of 122 ova) when either medium is supplemented with 4 mg/ml of bovine serum albumin. Ova fertilized in vitro will also cleave to the 2-cell stage in either medium (52% in BWW, 87% in MBWW), but fail to develop any further in culture. Oocytes fertilized in vivo and recovered at the late 2-cell or early 4-cell stages from females on Day 3 of pregnancy have the capacity to develop into expanded blastocysts in MBWW. When early embryos that developed into morulae and early blastocyts in culture were transferred to surrogate females, eight normal young were born.     

Endoscopic embryo collection and embryo transfer into the oviduct and the uterus of pigs

We describe the first complete embryo transfer program, including flushing of embryos from the oviducts via the uterine horns, transfer of embryos into the Fallopian tubes or the uterine horns and recording of the number of piglets born live. The described procedure is minimally invasive and allows the use of pigs simultaneously for embryo collection and production of normal pregnancies. A 30 degrees forward oblique endoscope provided optimal visualization of the reproductive organs and free access to the organs for embryo flushing and transfer. In contrast to surgical and nonsurgical methods, endoscopy allows to pre-examine the genital tract for reproductive abnormalities and successful ovulation. A total of 95 prepuberal gilts or cyclic sows were used in this trial. Embryos or oocytes were collected from hormonally treated pigs via endoscopy(n = 17) on Day 3 and via laparotomy or post mortem after slaughter (control group, n = 38) on Day 3 and 6 after insemination. One (unilateral collection, n = 7) or both oviducts (bilateral collection, n = 10) were flushed endoscopically. We recovered 114 (average 16/pig) and 279 (average 28/pig) oocytes or embryos with fertilization rates of 89% and 72%, respectively. In the control group 834 oocytes or embryos were collected at Day 3 and 6 after insemination (fertilization rate 64%, total 534 embryos, 33 at 2-, 367 at 4-, 2 at 8-cell stage, 24 morulae and 108 blastocysts). Of 836 embryos recovered by endoscopy, surgery or slaughter 528 Day 3 embryos at 2- to 4-cell stage were transferred into (one) oviducts (n = 27 pigs, about 20/pig) resulting in 9 pregnant pigs diagnosed at Day 28 by sonography. Of the 9, 8 carried a total of 49 piglets to term. A total of 195 Day 6 embryos were transferred into uterine horns (n = 12 pigs, about 16/pig), resulting in 5 pregnant pigs carrying a total of 38 offspring to term. The use of endoscopy in assisted reproduction of pigs has the advantages of allowing easy access to the ovary, oviduct and uterus, clear view of the organ manipulation without exposure and exteriorization of viscera during surgery.     

In vitro development up to hatching of bovine in vitro-matured and fertilized oocytes with or without support from somatic cells

To verify the importance of somatic cells upon in vitro embryo development, in vitro-matured (IVM) and -fertilized (IVF) bovine oocytes were cultured in TCM 199 supplemented with estrous cow serum (10% v/v) and 0.25 mM sodium pyruvate (ECSTCM) under the following treatments: 1) ECSTCM alone; 2) together with bovine oviduct epithelial cells (BOEC); 3) with cumulus cells (CC); 4) in fresh BOEC conditioned ECSTCM; or 5) in frozen-thawed BOEC conditioned ECSTCM. Culturing zygotes encased in cumulus cells significantly reduced the cleavage rate (P<0.05). There was no difference between culture systems in the proportions of embryo development through the 8-cell stage (P=0.42) up to the morula/blastocyst stages (P=0.50) at Day 7 post insemination. However, co-culture with BOEC yielded the highest percentage (21.2% of zygotes; P<0.05) of quality Grade-1 and Grade-2 embryos with the number of blastomeres per embryo (114.4) comparable to that of 7-day-old in vivo-developed embryos of similar grades (102.5), and higher (P<0.05) than those of the other treatments. The ratio of blastocysts to total morulae/blastocysts obtained from frozen-thawed conditioned medium was lower (P<0.05) than that from ECSTCM or after co-culture with BOEC at Day 7 post insemination. On average, 7.5 to 17.5% of the zygotes developed to blastocyst, expanded blastocyst and hatched blastocyst stages by Day 10 post insemination, depending upon the culture system. The difference between treatments, however, was not significant (P=0.68). The results indicate that chronological development up to hatching of bovine IVM-IVF embryos is not favored by somatic cells; however, the presence of viable oviduct epithelial cells in culture significantly improves the quality of 7-day-old embryos.     

Developmental capacity of bovine oocytes collected from ovaries of individual heifers and fertilized in vitro

Bovine follicular oocytes from individual heifers (n=49) were separately matured, fertilized with frozen-thawed spermatozoa and cultured with cumulus cells. Although there were great variations in the number (mean+/-SD=19.1+/-11.9) of oocytes collected from individual heifers and the percentages of the oocytes cleaved 48 hours after insemination (mean+/-SD=69.5+/-18.4) and developed to the morula stage 7 days after insemination (mean+/-SD=10.9+/-10.9), there were significant correlations between the numbers of oocytes collected and cleaved (the correlation coefficient: r= 0.9336) or developed to morula stage (r=0.6633), indicating that oocytes from different heifers have the same developmental ability after in vitro fertilization. Ten morulae and 12 blastocysts which were obtained 7 and 8 days after insemination were transferred, one by one, to each uterine horn of 11 recipients. At Day 60 of pregnancy, 8 (80%) fetuses were identified in 4 (80%) of 5 recipients into which 10 embryos were transferred at Day -1 of synchrony. However, only 3 (25%) fetuses were identified in 2 (40%) of 6 recipients into which 12 embryos were transferred at Day 0 or +1 of synchrony.     

Fusion of Spermatozoa with Embryonic Cells and Somatic Cells in the Sea Urchin

Spermatozoa can enter the separated blastomeres of 8- and 16-cell stage embryos, the cells of blastulae and even somatic cells of the oesophagus wall of an adult sea urchin, under certain conditions. In the presence of egg jelly solution, the rate of entrance of spermatozoa is remarkably increased. In the case of the blastomere of 8-cell stage embryos, characteristic cytoplasmic protrusions are formed at the sites of sperm entry, in succession to the formation of the cytoplasmic bulge. These protrusions elongate until 4 min after insemination, and then they retract gradually. The nucleus of penetrated sperm swells and decondenses to form a pronucleus. In most cases, the pronucleus seems to fuse with the preexisting diploid nucleus of the blastomere. When the dissociated oesophagus cells were inseminated, a certain type of the cells was found to fuse with spermatozoa, although the percentage of fused cells was very low.     

In vivo development of vitrified rat embryos: effects of timing and sites of transfer to recipient females

In cryopreserved rat embryos, survival rates obtained in vitro are not always consistent with the rates obtained in vivo. To determine the optimal conditions for in vivo development to term, rat embryos at the 4-cell, 8-cell, and morula stages were vitrified in EFS40 by a one-step method and transferred into oviducts or uterine horns of recipients at various times during pseudopregnancy. Vitrified and fresh 4-cell embryos only developed after transfer into oviducts of asynchronous recipients on Days -1 to -2 of synchrony (i.e., at a point in pseudopregnancy 1-2 days earlier than the embryos). Approximately half the vitrified embryos transferred into oviducts on Day -1 developed to term, but only a minority of embryos, whether vitrified (10%-34%) or fresh (24%-33%), transferred at later times did so, suggesting that this may not be the most suitable stage for cryopreservation. Very few 8-cell embryos, either vitrified or fresh, developed when transferred into oviducts on Day 0 to -0.5. However, when transferred into uterine horns, high proportions of vitrified 8-cell embryos ( approximately 63%) developed to term in reasonably synchronous recipients (Day 0 to -0.5) but not in more asynchronous ones (6%; Day -1). A majority of vitrified morulae also developed to term (52%-68%) in a wider range of recipients (Days 0 to -1), the greatest success occurring in recipients on Day -0.5. Similar proportions of vitrified and fresh 4-cell embryos, 8-cell embryos, and morulae developed to term when appropriate synchronization existed between embryo and recipient. Thus, vitrification of preimplantation-stage rat embryos does not appear to impair their developmental potential in vivo.     

Cryopreservation of mouse spermatozoa]

The spermatozoa of cauda epididymis of mature mice were suspended in 3% skim milk in distilled water supplemented with 12, 15, 18 or 21% (W/V) raffinose. The suspension of spermatozoa were frozen in liquid nitrogen gas for 10 min, then stored in liquid nitrogen (-196 degrees C). The frozen suspensions of spermatozoa were thawed by rapid warming in water bath at room temperature. For removing the cryopreservative solution, a pair of syringes connected with a three stop cock and a filter unit (pore size 0.45 mu) were used. Highest sperm motility was obtained after 1 hr of thawing from the cryopreservative solution containing 18% raffinose and 3% skim milk. These cryopreserved spermatozoa were used for fertilization in vitro. The proportion of pronuclear oocytes was 35.9% (74/206) 6 hr after insemination, and the proportion of 2-cell embryos was 33.6% (42/125) 28 hr after insemination. All 2-cell embryos were transferred to the oviducts of pseudopregnant recipients and 45.2% (19/42) developed to normal young.     

Mouse singletons and twins developed from isolated diploid blastomeres supported with tetraploid blastomeres.

The aim of this study was to obtain mice, hopefully identical multiplets, from single diploid blastomeres isolated at the 4-cell stage, or from pairs of sister blastomeres isolated at the 8-cell stage. To this end isolated blastomeres were aggregated with one or two tetraploid carrier embryos produced by electrofusion of 2-cell embryos. Diploid embryos were albino and homozygous for the "a" allele of glucose-phosphate isomerase (GPI-1a1a) and tetraploid embryos were pigmented and GPI-1b1b. The aggregates were cultured in vitro up to the blastocyst stage. Each quartet (occasionally triplet or doublet) of chimaeric blastocysts was transplanted to the oviduct of a separate pseudopregnant recipient. Altogether 62 blastocysts were transplanted to 17 recipients. Eight full-term foetuses (two singletons and three pairs of twins) were rescued by Caesarian section on day 19, 20 or 21 of pregnancy. Three young (one singleton and twins) were successfully reared by foster mothers and proved to be normal and fertile females. All foetuses and animals were albino. In five individuals only the 1-A form of GPI (characteristic for 2n blastomere) was found. In one adult female traces of the 1-B form of GPI (characteristic for 4n carrier blastomeres) were detected in the heart and the lungs while 4 other organs contained only the 1-A form. These observations strongly suggest that the majority of foetuses/animals produced according to our experimental system are 'pure' diploids rather than 2n/4n chimaeras, and that the described method can be used in future to produce twins, triplets and quadruplets in the mouse. Our study confirms earlier work by Kelly (1975, 1977) that 'quarter' blastomeres of the mouse are still totipotent.     

Invitro uptake of estradiol and progesterone in the hamster uterus relative to the time of embryo transfer and stage of development

The normal time for cleavage to the 2- and 8-cell stages of development of naturally ovulated hamster embryos is 25–27.5 and 59–61 h respectively, after ovulation and mating. The corresponding values for PMS-hCG treated hamsters were 33–35.5 and 62–64 h respectively. When 2-cell embryos, obtained by this timing method, were transferred to the oviductal bursa on Day 2 of the cycle, and when 8-cell embryos were transferred to the uterus on Day 3 of the cycle, implantation rates of 61.5 and 64.0% respectively, were obtained. The current study was conducted to determine the effects of transfer on estradiol and progesterone uptake by the uterine tissue on Day 14 after mating. A 2-fold increase in estradiol uptake was observed in superovulated, nonpregnant uteri when compared with nonsuperovulated animals. This level was also significantly higher than with nonsuperovulated pregnant animals and of animals receiving 2-cell embryo transfers. Estradiol uptake increases of 3.2 and 1.2-fold were noted for animals receiving 8-cell embryo transfers in naturally and superovulated groups respectively. Superovulation resulted in increased progesterone uptake. Transfer of 2- and 8-cell embryos resulted in a 15.8 and 109.9% increase in progesterone uptake respectively in naturally ovulated hamsters. Similar values for superovulated hamsters were 16.2 and 87.6% respectively. The 8-cell embryos, however, were transferred about four hrs prior to the time for normal 8-cell cleavage and this, coupled with increased estradiol uptake by the embryos themselves, resulted in an elevated estradiol and progesterone uptake in the uterine tissue even when measured on Day 14 of pregnancy. The degree of increase was less with superovulated animals receiving 8-cell embryos, reflecting higher levels of estradiol and progesterone uptake in control tissues. This could account for the slight delay in development of superovulated embryos.     

Cryopreservation of unfertilized rat oocytes by ultrarapid freezing]

Unfertilized rat oocytes were placed in a highly concentrated solution of cryoprotectant (DAP 224:2M dimethylsulphoxide, 2M acetamide, 4M propylene glycol in PB1) in 0.5 ml sampling tubes and then immediately immersed into liquid nitrogen; thawing was conducted in a 37 degrees C waterbath. After thawing, 630 out of 968 oocytes (65.1%) were morphologically normal. After insemination in vitro of cryopreserved oocytes, the proportion of pronuclear oocytes with spermatail (s), male (s) and female pronuclei (8-10 h post insemination), and 2-cell embryos with two identical blastomeres (28-30 h post insemination) was 60.8% (152/250) and 29.8% (39/131), respectively. One hundred and fifty oocytes that were judged as pronuclear oocytes under the inverted microscope 8-10 h after insemination were transferred to the oviducts of pseudopregnant recipients; 18.7% (28/150) of the oocytes developed to normal young.     

A timetable of embryonic development, and ovarian and uterine changes during pregnancy, in the stripe-faced dunnart, Sminthopsis macroura (Marsupialia: Dasyuridae)

Aged stages (63) were available for establishment of a timetable of embryonic development of the stripe-faced dunnart. On Day 0 oocytes reaching maturity were found in the ovary. Within +/- 24 h of time 0 (time of minimum morning weight) polymorphonuclear leucocytes appeared and spermatozoa were last detected in the urine of 70% of females. Embryos were collected at intervals during pregnancy by hemihysterectomy and the embryos in the contralateral uterus either were examined at a later stage of pregnancy or allowed to develop to term. Cleavage to the unilaminar blastocyst stage with around 32 cells took 3 days with a cleavage arrest of 24 h at the 4-cell stage. Expansion of the unilaminar blastocyst occurred over the next 3 days. Primitive endoderm cells appeared on Day 6, fully bilaminar blastocysts by the end of Day 7 and trilaminar blastocysts on Day 8. Shell loss and implantation of 13-15-somite stage embryos occurred on Day 8 and organogenesis over the next 2-3 days. The gestation period was 9.5-12.0 days with most births occurring between 10.5 and 11.0 days. Major steps in embryonic development were correlated with stages in the development of the corpora lutea, which were maximal in size, and possibly in secretory activity, when the embryos were at the bilaminar blastocyst stage. Regression commenced when the embryos were at the primitive streak stage. At the time the corpora lutea were maximal the uterine epithelium reached its greatest height and the endometrium was thick and folded. Later in pregnancy villous-like projections of the epithelium formed, and the luminal epithelial cells became rounded. Two cell populations, a tier of 8 smaller cells above the yolk mass and a tier of 8 larger cells around the sides of the yolk mass appeared at the 16-cell stage. From the 16-cell stage to the blastocyst stage, with 150-200 cells, two cell populations distinguished by size, cell cycle time, cytoplasmic appearance and position relative to the yolk mass were present. The two populations were indistinguishable in blastocysts with greater than 200 and less than 2000 cells. They reappeared in blastocysts with greater than 2000 cells, as the darker cells of the embryoblast, and as the paler cells of the trophoblast. The darker cells lay in the yolky hemisphere and the paler cells in the non-yolky hemisphere.     

Blastomeres of the mouse embryo lose totipotency after the fifth cleavage division: expression of Cdx2 and Oct4 and developmental potential of inner and outer blastomeres of 16- and 32-cell embryos

Sixteen inner or outer blastomeres from 16-cell embryos and 32 inner or outer blastomeres from 32-cell embryos (nascent blastocysts) were reaggregated and cultured in vitro. In 24 h old blastocysts developed from blastomeres derived from 16-cell embryos the expression of Cdx2 protein was upregulated in outer cells (new trophectoderm) of the inner cells-derived aggregates and downregulated in inner cells (new inner cell mass) of the external cells-derived aggregates. After transfer to pseudopregnant recipients blastocysts originating from both inner and outer blastomeres of 16-cell embryo developed into normal, fertile mice, but the implantation rate of embryos formed from inner cell aggregates was lower. The aggregates of external blastomeres derived from 32 cell embryo usually formed trophoblastic vesicles accompanied by vacuolated cells. In contrast, the aggregates of inner blastomeres quickly compacted but cavitation was delayed. Although in the latter embryos the Cdx2 protein appeared in the new trophectoderm within 24 h of in vitro culture, these embryos formed only very small outgrowths of Troma1-positive giant trophoblastic cells and none of these embryos was able to implant in recipient females. In separate experiment we have produced normal and fertile mice from 16- and 32-cell embryos that were first disaggregated, and then the sister outer and inner blastomeres were reaggregated at random. In blastocysts developed from aggregates, within 24 h of in vitro culture, the majority of inner and outer blastomeres located themselves in their original position (internally and externally), which implies that in these embryos development was regulated mainly by cell sorting.     

Effect of centchroman on tubal transport and preimplantation embryonic development in rats

A single oral administration of centchroman (1.25 mg/kg) to adult female rats within 24 h of mating induced slight acceleration in the rate of transport of embryos through the oviducts. The compound did not seem to produce any deleterious effect on preimplantation embryonic development since well organized and apparently normal embryos were collected from the genital tract up to Day 12 of pregnancy. The recovery rate of embryos from centchroman-treated rats was, however, significantly reduced after Day 4 of pregnancy. There was some stimulation in the rate of cleavage of embryos and morula to blastocyst transformation, but retardation in the shedding of the zona pellucida. The rate of blastocyst formation was not altered when 6-8-cell embryos collected from the oviducts of control rats were transferred to the uteri of control or centchroman-treated females. A delay in zona shedding was observed in the centchroman-treated recipients.     

Luteotrophic influence of early bovine embryos and the relationship between plasma progesterone concentrations and embryo survival

This study was carried out to evaluate the luteotrophic influence of early (before Day 7 as well as after Day 7; Day 0=estrus) bovine embryos and the relationship between plasma progesterone (P4) concentrations and embryo survival. Virgin Holstein dairy heifers (n=325) from a single herd were randomly allocated to be nonbred, bred by artificial insemination (AI) or by embryo transfer (ET). Bred heifers were either treated with 1500 IU human chorionic gonadotrophin (hCG) on Day 7 of the estrous cycle or received no hCG treatment. Plasma P4 concentrations on Days 0, 5, 7, 10, 13, 15, 17, 19 and 21 were similar in pregnant AI- and ET-bred heifers and, this was observed in both hCG-treated and untreated females. Nonbred, AI- and ET-bred nonpregnant heifers (both hCG-treated and untreated) presented similar plasma P4 concentrations. Plasma P4 concentrations of pregnant heifers significantly deviated from those of nonpregnant and nonbred heifers on Day 17. In hCG-treated heifers, plasma P4 concentrations and Day 28 pregnancy rate were significantly higher in females with an induced accessory corpus luteum (CL) than in those females without an induced accessory CL. Treatment with hCG, although inducing the formation of accessory CL and significantly increasing plasma P4 concentrations had no significant effect on Day 28 pregnancy rate. In conclusion, this study does not support the existence of any peripherally detectable luteotrophic influence from early embryos (Days 5-7). Plasma P4 was only significantly related to embryo survival on Day 17, the time of expected onset of luteolysis.     

Efficacy of TEPA as a “sperm label” for competitive fertilization studies in the rabbit

In this paper, the conditions necessary to use TEPA [tris (1-aziridinyl)] effectively as a label for spermatozoa in competitive fertilization are established. The fertilizing ability of rabbit spermatozoa treated with 0 and 0.8 mg TEPA/ml was compared at insemination doses of 1, 5, 20, and 40 × 10⁶ spermatozoa. Fertility was assessed by collecting ova from 64 does 48 to 52 h after insemination. TEPA blocked all but 4% of the ova from developing when 1 × 10⁶ spermatozoa were inseminated, but fertility was reduced. When 5 × 10⁶ spermatozoa were inseminated following treatment with 0, 0.6 or 1.2 mg of TEPA/ml, the fertility was 83, 74 and 50% (P<0.05), and the percentage of ova containing more than four blastomeres was 83, 11 and 5% (P<0.05), respectively. The 0.6% TEPA level was selected for a competitive fertilization trial. Equal numbers of sperm from pure Dutch-color and albino sires were combined so that either both types were untreated, only the ‘albino’ semen was treated, only the ‘Dutch’ semen was treated, or both were treated. Does were inseminated with 5 × 10⁶ sperm and allowed to kindle. The litter sizes were 5.6, 3.1, 2.7, and 0 young, and the proportion of Dutch-color progeny was 63, 97, 0 and 0%, respectively, confirming the effectiveness of TEPA as a “label”. Only one of 60 young born resulted from fertilization by a TEPA-treated spermatozoon, demonstrating that few embryos fully escape the TEPA block. Thus, the TEPA concentration and sperm numbers were established to use TEPA effectively as a label for spermatozoa in competitive fertilization studies.