Production of monozygotic twin calves using the blastomere separation technique and Well of the Well culture system

The present study was conducted to establish a simple and efficient method of producing monozygotic twin calves using the blastomere separation technique. To produce monozygotic twin embryos from zona-free two- and eight-cell embryos, blastomeres were separated mechanically by pipetting to form two demi-embryos; each single blastomere from the two-cell embryo and tetra-blastomeres from the eight-cell embryo were cultured in vitro using the Well of the Well culture system (WOW). This culture system supported the successful arrangement of blastomeres, resulting in their subsequent aggregation to form a demi-embryo developing to the blastocyst stage without a zona pellucida. There was no significant difference in the development to the blastocyst stage between blastomeres separated from eight-cell (72.0%) and two-cell (62.0%) embryos. The production rates of the monozygotic pair blastocysts and transferable paired blastocysts for demi-embryos obtained from eight-cell embryos (64.0 and 45.0%, respectively) were higher than those for demi-embryos obtained from two-cell embryos (49.0 and 31.0%, P<0.05). The separated demi-embryos obtained from eight-cell embryos produced by IVM/IVF of oocytes collected by ovum pick-up (OPU) from elite cows and cultured in wells tended to have a higher pregnancy rate (78.9% vs. 57.1%) and similar monozygotic twinning rate (40.0% vs. 33.3%) compared with monozygotic twin blastocysts obtained by the conventional bisection of in vivo derived blastocysts. In conclusion, producing twins by separation of blastomeres in OPU-IVF embryos, followed by the WOW culture system, yielded viable monozygotic demi-embryos, resulting in high rates of pregnancy and twinning rates after embryo transfer.     

Embryo cloning in sheep: work in progress

We summarize here the procedures for nuclear transfer using S-phase cytoplasts and describe a new method for avoiding loss of reconstructed embryos from the oviducts during in vivo culture. We obtained 2 clones of 5 genetically identical animals following the transfer of blastomeres from 16-cell embryos into enucleated preactivated cytoplasts. Metaphase II oocytes and embryos were surgically collected from superovulated Sarda breed ewes 54 and 120 h after sponge removal, respectively. Oocytes were exposed for 15 min to 5 mug/ml of Hoechst 33342 and were micromanipulated at room temperature. Efficiency in embryo reconstruction was 100% for enucleation and 98% for fusion. Embryos were embedded in agar as separate clones and transferred into the oviducts of temporary recipients. The fimbriae were closed with glass-nylon made filters. Embryo recovery from the temporary recipients was 97.3%, with a cleavage rate of 81.4%; development to morula-blastocyst stage was 70.6%. A total of 29 Grade 1 blastocysts corresponding to 5 clones were transferred into 13 naturally synchronous ewes, and scanning was performed at 30 and 90 d. Ten ewes were pregnant at the first scanning and nine at the second for a final pregnancy rate of 71.4%; the survival rate at term was 48%. Overall, we obtained 4 clones of identical lambs: two sets of 5 (one male set and one female set) and two sets of twins (both sets male). Pregnancy length in recipients carrying clones was longer than the standard period in Sarda breed (153 vs 150 d, respectively). Weight at birth was higher for male lambs obtained from nuclear transfer than for normal males (4.1 vs 3.6 kg), while the weight for females was normal.     

Development of single blastomeres from four- and eight-cell mouse embryos fused into the enucleated half of a two-cell embryo

Single blastomeres from four- and eight-cell mouse embryos were fused into the enucleated halves of two-cell embryos, and the ability of these reconstituted embryos to develop in vitro and in vivo was examined. The proportion of these reconstituted embryos developing to blastocysts was 74% (60/81) when four-cell embryo blastomeres were used as nuclei donors and 31% (57/182) when eight-cell embryo blastomeres were used. Eight complete sets of the quadruplet-reconstituted embryos developed to blastocysts, and five live young (9%, 5/57) were obtained after transfer; however, none of the live young were clones. Although when using blastomeres from eight-cell embryos no complete set of eight developed to blastocysts, sextuplets were obtained. The blastocysts, however, failed to produce live young after transfer. In assessing the outgrowths, it was found that 43% of those derived from reconstituted embryos using blastomeres from four-cell embryos had an inner cell mass (ICM); however, outgrowths derived from reconstituted embryos using blastomeres from eight-cell embryos lacked an ICM. These results suggest that the genomes of four- and eight-cell nuclei introduced into the enucleated halves of two-cell embryos are reversed to support the development of the reconstituted embryo.     

Production of identical twin and triplet mice by nuclear transplantation

Transplantation of a single nucleus from two- or four-cell embryos into one of the enucleated blastomeres of a two-cell embryo resulted in successful production of identical triplet and twin mice. The proportion of reconstituted embryos that developed in blastocysts was 71% (84/118) when four-cell embryos were used as donors of nuclei; 10 sets of quadruplet and nine sets each of triplet and twin blastocysts were obtained by this technique. After transfer to recipients, 30% (18/61) developed to term, and one set of identical triplet and four sets of identical twin mice were obtained. When two-cell embryos were used as donors of nuclei, 79 (95%) sets of twin embryos developed to blastocysts. Of 38 twin blastocysts transferred to recipients, 21 sets (55%) developed to term as identical twin mice. These results demonstrate that the enucleated two-cell embryo develops in vitro after transfer of a nucleus from a two- or four-cell embryo and the resultant blastocyst has high potential for development to term after transfer to a recipient.     

Production of monozygotic (identical) horse twins by embryo micromanipulation

The blastomeres of 192- to 8-cell embryos recovered surgically 1-3 days after ovulation from 23 Pony mares were mechanically separated and inserted, in various combinations, into evacuated pig zonae pellucidae to make 27 'half' and 17 'quarter' micromanipulated embryos. These were embedded in agar and cultured in vivo in the ligated oviducts of ewes for 3.5-5 days to allow development to the late morula/early blastocyst stage. Subsequent surgical or non-surgical transfer of 13 'half' and 17 'quarter' embryos to mares resulted in 10 established pregnancies, including 2 monozygotic pairs. Surgical transfer to mares that had not been recently used as donors of embryos was more successful (10/20) than surgical or non-surgical transfer to recently operated mares (0/10).     

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.     

Fetal development of mouse oocytes and zygotes cryopreserved in a nonconventional freezing medium

This study (1) analyzed fetal development of mouse embryos after oocyte cryopreservation in CJ2, a choline-based medium, (2) examined the effect of culture duration in vitro on subsequent fetal development, and (3) compared survival and fetal development of zygotes frozen in embryo transfer freeze medium (ETFM; sodium-based medium) or CJ2. Unfertilized oocytes and zygotes were cryopreserved using a slow-cooling protocol. After thawing, oocytes were inseminated after drilling a hole in their zona, cultured in vitro either to the two-cell or blastocyst stage, and transferred to the oviducts or uterine horns of recipient mice. In parallel experiments, frozen-thawed zygotes were similarly cultured and transferred. Implantation rates for transferred embryos were high (range 66-88%), regardless of whether they had been frozen as oocytes or zygotes and whether they had been transferred to the oviduct or uterus. However, fetal development was significantly higher when two-cell embryos were transferred. With blastocyst transfer, control embryos implanted and produced a greater proportion of fetuses than did oocytes frozen in CJ2, whereas transfer at the two-cell stage resulted in similar proportions of implantation sites and fetuses. Blastocyst transfer of zygotes cryopreserved in ETFM or CJ2 produced similar fetal development rates (23.6% vs 20.0%), but when frozen-thawed zygotes were transferred at the two-cell stage the fetal development rates were higher in the ETFM group (53.3%) than in the CJ2 group (32.0%). A high proportion (46.7%) of oocytes frozen in CJ2 in a nonprogrammable freezer and plunged at -20 degrees C developed into live offspring. This study shows that in the mouse (1) oocytes frozen in CJ2 can develop into viable fetuses, (2) prolonging culture in vitro has a detrimental effect on embryo transfer outcome, and (3) CJ2 offers no advantage for zygote cryopreservation.     

Full-term development of rat after transfer of nuclei from two-cell stage embryos

Cloning technology would allow targeted genetic alterations in the rat, a species which is yet unaccessible for such studies due to the lack of germline-competent embryonic stem cells. The present study was performed to examine the developmental ability of reconstructed rat embryos after transfer of nuclei from early preimplantation stages. We observed that single blastomeres from two-cell embryos and zygotes reconstructed by pronuclei exchange can develop in vitro until morula/blastocyst stage. When karyoplasts from blastomeres were used for the reconstruction of embryos, highest in vitro cleavage rates were obtained with nuclei in an early phase of the cell cycle transferred into enucleated preactivated oocytes or zygotes. However, further in vitro development of reconstructed embryos produced from blastomere nuclei was arrested at early cleavage stages under all conditions tested in this study. In contrast, immediate transfer to foster mothers of reconstructed embryos with nuclei from two-cell embryos at an early stage of the cell cycle in preactivated enucleated oocytes resulted in live newborn rats, with a general efficiency of 0.4%-2.2%. The genetic origin of the cloned offspring was verified by using donor nuclei from embryos of Black Hooded Wistar rats and transgenic rats carrying an ubiquitously expressed green fluorescent protein transgene. Thus, we report for the first time the production of live cloned rats using nuclei from two-cell embryos.     

Identical triplets and twins developed from isolated blastomeres of 8- and 16-cell mouse embryos supported with tetraploid blastomeres

We studied the developmental potential of single blastomeres from early cleavage mouse embryos. Eight- and sixteen-cell diploid mouse embryos were disaggregated and single blastomeres from eight-cell embryos or pairs of sister blastomeres from sixteen-cell embryos were aggregated with 4, 5 or 6 tetraploid blastomeres from 4-cell embryos. Each diploid donor embryo gave eight sister aggregates, which later were manipulated together as one group (set). The aggregates were cultured in vitro until the blastocyst stage, when they were transferred (in sets) to the oviducts of pseudopregnant recipients. Eighteen live foetuses or pups were obtained from the transfer (11.0% of transferred blastocysts) and out of those, eleven developed into fertile adults (one triplet, one pair of twins and four singletons). In all surviving adults, pups and living foetuses, only diploid cells were detected in their organs and tissues as shown by analysis of coat pigmentation and distribution of glucose phosphate isomerase isoforms. In order to explain the observed high rate of mortality of transferred blastocysts, in an accompanying experiment, the diploid and tetraploid blastomeres were labelled with different fluorochromes and then aggregated. These experiments showed the diploid cells to be present not only in the inner cell mass (ICM) but also in the trophectoderm. The low number of diploid cells and the predominance of tetraploid cells in the ICM of chimaeric blastocysts might have been responsible for high postimplantation mortality of our experimental embryos.     

Effect of various procedures on the viability of mouse embryos containing half the normal number of blastomeres

Half embryos produced from 8-cell or compacted stages were cultured in vitro for 1-2 days and transferred to oviducts or uteri of recipients at different stages of pseudopregnancy. The proportion of live fetuses was low (8-12%), except for one group (27%) in which half embryos were cultured in vitro for 1 day and transferred into oviducts on the 1st day of pregnancy. Monozygotic twin production rate, however, was low (1 out of 10) even in this group. Fetal weight on the 18th day of gestation was significantly lower after transfer of half embryos than after transfer of similarly treated but undivided embryos. Half embryos produced from the 2-cell stage were inserted into empty zonae, embedded in agar, cultured in ligated mouse oviducts for 2-4 days and transferred to oviducts of recipient females on the 1st day of pregnancy or pseudopregnancy. When twin embryos cultured for 2-3 days were transferred to pseudopregnant recipients together with control embryos, 4 sets of monozygotic twins and 5 singletons out of 10 sets of twin embryos were obtained on Days 18-19 of gestation, giving a survival rate of 65%.     

Nuclear transfer of porcine embryos using cryopreserved delipated blastomeres as donor nuclei

Nuclear transfer protocol for the pig using cryopreserved delipated four- to eight-cell and morula stage embryos as nucleus donors was developed. Donor embryos, which had been delipated by micromanipulation following centrifugation for polarizing cytoplasmic lipid droplets, were cryopreserved with 1.5 M 1,2-propanediol and 0.1 M sucrose. Recipient cytoplasts were prepared from ovulated oocytes. Activation of oocytes could be induced more efficiently when electric stimulation was given 53 hr after the hCG injection or later (66–83%), compared with 52 hr or earlier (11–16%, P < 0.05), suggesting that aging after ovulation may be required for in vivo matured porcine oocytes to be activated by electric stimuli. Membrane fusion rates between donor blastomeres and enucleated oocytes were 88% (127/144) and 97% (56/58, P > 0.05) for the four- to eight-cell and morula stage embryos, respectively. In vitro developmental rates to the two-cell (53/100 vs. 35/65), four-cell (34/100 vs. 26/65), and morula stage (17/100 vs. 18/65) were the same between the nuclear transfer embryos with four- to eight-cell and morula nuclei. However, more embryos reconstituted with morula nuclei developed to blastocysts (15% vs. 6%, P < 0.05). These data demonstrated that blastomeres of cryopreserved, delipated porcine embryos can be used as donor nuclei for nuclear transfer. Frozen-thawed, delipated blastomeres can be efficiently isolated and fused, and therefore provide a useful source of donor nuclei. Mol. Reprod. Dev. 48:339–343, 1997. © 1997 Wiley-Liss, Inc.     

Nuclear transplantation of mouse fetal germ cells into enucleated two-cell embryos

Mouse fetal germ cells were fused with enucleated blastomeres of two-cell embryos. Donor germ cells were obtained from fetuses of albino CD-1 strain or pigmented F(1) (C57BL x CBA) female mice mated with the same strain males at 11.5 to 16.5 days post coitum. Recipient two-cell embryos, which were of a different strain from the donors, were obtained at 37 to 42 hours (Group 1), 42 to 47 hours (Group 2), and 47 to 52 hours (Group 3) after treatment with human chorionic gonadotropin (hCG). After removing the nucleus from one two-cell blastomere, a single germ cell was fused with the enucleated blastomere using the Sendai virus; the second blastomere was left intact. The reconstituted embryos were cultured for 3 days in vitro, to examine their developmental capacity. The fused blastomeres in Groups 1 and 2 did not divide, but a few transplanted blastomeres in Group 3 divided several times, and some of them developed into normal blastocysts. Most embryos developed into blastocysts from one blastomere, with an undivided blastomere remaining. Embryos developing into normal blastocysts or blastocysts with small blastomeres were transferred to the oviducts of Day-1 or the uteri of Day-3 pregnant albino CD-1 mice. None of the young showed any contribution of the germ cells, judging by the eye and coat colors and by the germ cells in the germ line following mating with albino mice. Possible reasons for failure of pluripotency of the germ cells are discussed here.     

Production of identical mouse twins and a triplet with predicted gender

The aim of this study was to develop a method to generate identical twins and triplets with predicted gender. As a first step toward that aim, single blastomeres obtained from EGFP expressing eight-cell stage embryos and either diploid or tetraploid host embryos were used to compose chimera. We could follow the fate of EGFP expressing diploid blastomere derived cells in 3.5- and 4.5-day-old chimera embryos in vitro. We found that the diploid blastomere-derived cells had significantly higher chance to contribute to the inner cell mass if tetraploid host embryos were applied. After that, we developed a quick and reliable multiplex PCR strategy for sex diagnosis from single blastomeres by simultaneous amplification of the homologous ZFX and ZFY genes. By composed chimeras using single blastomeres, derived from sexed eight-cell stage embryos and a tetraploid host embryo, we could get preplanned sex newborns, wholly derived from these blastomeres. Among these mice, identical twins and a triplet were identified by microsatellite analysis. Unlike clones produced by nuclear transfer, these mice are identical at both the nuclear as well as mitochondrial DNA level. Therefore, the tetraploid embryo complementation method to produce monozygotic twins and triplets could be a valuable tool both in biomedical and agricultural applications.     

In vivo survival of domestic cat oocytes after vitrification, intracytoplasmic sperm injection and embryo transfer

We evaluated: (1) cleavage rate after IVF or intracytoplasmic sperm injection (ICSI) of in vivo- and in vitro-matured oocytes after vitrification (experiment 1); and (2) fetal development after transfer of resultant ICSI-derived embryos into recipients (experiment 2). In vivo-matured cumulus-oocyte complexes (COCs) were recovered from gonadotropin-treated donors at 24 h after LH treatment. In vitro-matured oocytes were obtained by mincing ovaries (from local veterinary clinics) and placing COCs into maturation medium for 24 h. Mature oocytes were denuded and cryopreserved in a vitrification solution of 15% DMSO, 15% ethylene glycol, and 18% sucrose. In experiment 1, for both in vivo- and in vitro-matured oocytes, cleavage frequencies after IVF of control and vitrified oocytes and after ICSI of vitrified oocytes were not different (P > 0.05). After vitrification, blastocyst development occurred only in IVF-derived, in vitro-matured oocytes. In experiment 2, 18 presumptive zygotes and four two-cell embryos derived by ICSI of vitrified in vitro-matured oocytes and 19 presumptive zygotes produced from seven in vivo- and 12 in vitro-matured oocytes were transferred by laparoscopy into the oviducts of two recipients, respectively. On Day 21, there were three fetuses in one recipient and one fetus in the other. On Days 63 and 66 of gestation, four live kittens were born. In vivo viability of zygotes and/or embryos produced via ICSI of vitrified oocytes was established by birth of live kittens after transfer to recipients.     

Preimplantation development of rabbit embryos after transfer of embryonic nuclei into different cytoplasmic environment

The development of nuclear-transfer oocytes and zygotes was tested in the rabbit. Metaphase II oocytes and zygotes in the early pronuclear stage were treated with a cytoskeletal inhibitor (cytochalasin D), enucleated, and subsequently fused either with single blastomeres from eight- and 16-cell stages (oocytes and zygotes) or with pronuclei-containing karyoplasts (zygotes only). Also, nonenucleated zygotes were fused with 1/8 blastomeres. Fusion was performed by means of an electric field. Development of reconstituted embryos was monitored mainly in vitro, but a certain number of embryos developed from oocytes and zygotes receiving nuclei from eight-cell stages were also transferred into pseudopregnant does. Development of nuclear-transfer oocytes was distinctly better than that of nuclear-transfer zygotes, since 16.9% and 9.5% oocytes vs. 8.1% and 3.7% zygotes carrying eight- and 16-cell nuclei, respectively, developed to the blastocyst stage. Two advanced but already dead fetuses were found after transfer of 27 four-cell embryos obtained after fusion of oocytes with 1/8 blastomeres. No implantations were observed after transfer of 25 four-cell embryos developed from enucleated zygotes receiving eight-cell nuclei. These findings indicate that, in the rabbit, some nuclei from 16-cell embryos are still capable of promoting at least preimplantation development. Comparison between the developmental abilities of oocyte- and zygote-derived nuclear-transfer embryos also suggests that the cytoplasmic environment of recipient cell is more crucial for the development of reconstituted embryos than the stage of introduced nuclei (at least up to the 16-cell stage). The majority of pronuclear exchange embryos (69.9%) and 40% of nonenucleated zygotes receiving eight-cell nuclei were able to develop to the blastocyst stage. This latter observation indicates, similarly as with mouse, a supporting role of residual pronuclei for participation of an eight-cell nucleus in the development of reconstituted zygotes.     

Intrafallopian transfer of gametes and early stage embryos for in vivo culture in cattle

It may be possible to avoid inadequate in vitro culture conditions by incubating gametes or embryos in the oviducts for a short time. Ideally, an optimized procedure should be devised, combining in vitro and in vivo systems, in order to achieve synchronization in cattle. We transferred gametes as well as embryos in various stages of development and placed them into the oviducts. Embryos were recovered on Day 7 by flushing of oviducts and uterine horns. Blastocyst rates were determined on Day 7 and on Day 8. Experimental designs included transfer of in vitro matured cumulus oocyte complexes into previously inseminated heifers (COCs group), transfer of in vitro matured COCs simultaneously with capacitated spermatozoa (GIFTs group), transfer of four to eight cell stage embryos developed in vitro after IVM/IVF (Cleaved Stages group) and a group of solely in vitro produced embryos (IVP control group). Our results indicate that in vivo culture of IVM/IVF embryos in the homologous bovine oviduct has a positive influence on subsequent pre-implantation development. In addition, we have evidence that in vitro maturation and in vivo fertilization cannot be synchronized.     

Studies on the Cytoplasmic Determinant for Muscle Cell Differentiation in Ascidian Embryos: An Attempt at Transplantation of the Myoplasm

The 8-cell stage embryos of the ascidian Halocynthia roretzi which had been prevented from undergoing further divisions by continuous treatment with cytochalasin B could develop histospecific muscle acetylcholinesterase in two blastomeres (B4.1 and B4.1 cells). If the cytoplasm of a B4.1 or B4.1 cell was transplanted by microinjection into either an A4.1 or A4.1 cell of recipient embryos and the transplanted embryos were permanently cleavage-arrested with cytochalasin B, a few eventually developed AChE in three blastomeres instead of in just the two blastomeres found in cleavage-arrested control embryos. Judging from the relative positions of the blastomeres, the third AChE-producing cells appeared to be the A4.1 or A4.1 cells injected with the cytoplasm of B4.1 or B4.1. Although the success rate was considerably low, this result might indicate the presence in the cytoplasm of a determinant for the muscle-specific enzyme development.     

Developmental capacity of rat embryos produced by in vivo or in vitro fertilization

This work compares the ability of rat zygotes fertilized in vitro or in vivo to develop into viable embryos. All oocytes were from adult cyclic females. After the first cleavage, the zygotes were transferred to oviducts of pseudopregnant recipients. Their fate was examined on day 13 at laparotomy and again on day 20. Ninety-five of 146 in vivo fertilized zygotes developed into normal sized 13-day fetuses and 72 (55%) to apparently normal near-term fetuses. Forty-six of 135 in vitro fertilized zygotes developed up to day 13, and 30 (24%) developed to term. It appears that the probability that in vitro fertilized rat zygotes will develop into viable embryos is about half the chance of in vivo fertilized zygotes. Since the two types of zygotes were morphologically identical, the morphological appearance of the two-cell stage is not an adequate criterion for judging developmental potential.     

Nuclear totipotency of cultured rabbit morulae to support full-term development following nuclear transfer.

The rabbit was used as a model for nuclear transfer. A critical step in nuclear transfer is oocyte activation, which was evaluated in this research. Optimal field strength of an electric stimulus for activation was examined. A significantly higher activation rate in all criteria tested was achieved when oocytes were activated electrically with a field strength of 2.4 kV/cm versus 1.2 or 1.8 kV/cm. Also, electrical stimulation with combined alternating current (AC) and direct current (DC) was superior to DC stimulation alone for activation. In another study involving 586 oocytes, exposure of oocytes to cytochalasin B for 1 h followed by activation with electrical stimulation significantly improved development of the oocytes to blastocyst stage compared to oocytes without cytochalasin B pre-exposure (38% vs 26%, p less than 0.05). Cytochalasin B exposure alone (control), however, had no effect on activation. Exposing oocytes to activation medium without electrical stimulation also activated some oocytes. In the nuclear transfer experiment, blastomeres from 8-cell embryos cultured for 20-24 h to the 32-64-cell stage were used as nuclear donor cells. Of 491 oocytes used, 459 (93%) survived the enucleation and fusion procedure, 370 (81%) fused, and 284 (77%) developed into 2-4-cell embryos. A total of 243 of these 2-4-cell embryos were transferred to 15 pseudopregnant recipients and produced 8 young (3%). Although the efficiency is low, this study demonstrated that rabbit morulae cultured for 20-24 h to the 32-64-cell stage as nuclear donors for transfer remain totipotent.