The effects of cryopreservation and transfer on embryonic development in the common marmoset monkey, Callithrix jacchus

Embryos were collected at the 4-10-cell stage from the oviducts (Day 4; Day 1 = ovulation) or as morulae (Day 7) from the uterus of marmosets and frozen in 1.5 M-DMSO (Days 4 and 7) or 1.0 M-glycerol (Day 4 only), using a slow freezing and thawing technique. Of 22 Day-4 embryos frozen in DMSO, 18 were recovered and 16 of these were transferred to 10 synchronized recipients; 7 recipients became pregnant compared with all 7 control recipients receiving 10 unfrozen embryos. Fifteen frozen-thawed morulae were transferred to 9 Day-6 recipients; the pregnancy rate (55.6%) was lower than for control embryos (85.7%). Embryos frozen in glycerol suffered severe osmotic stress during glycerol addition and removal. Of 8 recipients, 3 (37.5%) became pregnant but only one fetus was carried to term. These results on embryo collection, freezing and transfer in the marmoset have important implications for developing improved methods for freezing human embryos and the breeding of endangered primates.     

Vitrification of rat embryos at various developmental stages

The effect of developmental stage on the survival of cryopreserved rat embryos was examined. Wistar rat embryos at various developmental stages were vitrified by a 1-step method with EFS40, an ethylene glycol-based solution, or by a 2-step method with EFS20 and EFS40. After warming, the survival of the embryos was assessed by their morphology, their ability to develop to blastocysts (or expanded blastocysts for blastocysts) in culture, or their ability to develop to term after transfer. Most (91-100%) of the embryos recovered after vitrification were morphologically normal in all developmental stages. However, the developmental ability of 1-cell embryos was quite low; exposing them to EFS40 for just 0.5 min decreased the in vitro survival rate from 76 to 9%. The survival rates of 2-cell embryos and blastocysts, both in vitro and in vivo, were significantly higher with a 2-step vitrification process than with a 1-step vitrification process. Very high in vitro survival rates (94-100%) were obtained in 4- to 8-cell embryos and morulae in the 1-step method. Although survival rates in vivo of 4-cell (40%) and 8-cell (4%) embryos vitrified by the 1-step method were comparatively low, the values were similar to those obtained in non-vitrified fresh embryos. When morulae vitrified by the 1-step method were transferred to recipients, the in vivo survival rate (61%) was high, and not significantly different from that of fresh embryos (70%). These results show that rat embryos at the 2-cell to blastocyst stages can be vitrified with EFS40, and that the morula stage is the most feasible stage for embryo cryopreservation in this species.     

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%.     

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.     

Vitrification of mouse oocytes and embryos at various stages of development in an ethylene glycol-based solution by a simple method

Mouse oocytes and embryos at various developmental stages were exposed directly to an ethylene glycol-based vitrification solution (EFS) for 2 or 5 minutes at 20 degrees C. They were then vitrified at -196 degrees C and were warmed rapidly. At the germinal vesicle stage, the proportion of morphologically normal oocytes was 36 to 39% if they had cumulus cells, whereas in cumulus-removed immature oocytes and in ovulated oocytes it was only 2 to 4%. This low survival was attributed to the harmful action of ethylene glycol. After fertilization, on the other hand, the post-warming survival rate of 1-cell zygotes, as assessed by cleavage to the 2-cell stage, increased markedly (62%). As the developmental stage proceeded, higher proportions of vitrified embryos developed to expanded blastocysts; the rates increased up to 77 and 80% in 2-cell and 4-cell embryos, respectively. For embryos at the 8-cell, morula and early blastocyst stages, the proportion of embryos developed after vitrification (90 to 95%) was not significantly different from that of the untreated embryos (95 to 100%) when the period of exposure to EFS solution was 2 minutes. As the blastocoel began to enlarge, however, survival began to decrease again, with rates of 79 and 57% in blastocysts and expanded blastocysts, respectively. After the cryopreserved 2-cell, 4-cell and 8-cell embryos as well as morulae and blastocysts were transferred to recipients, 43 to 57% of the recipients became pregnant, and 48 to 60% of these various stage embryos developed into live young.     

Transfer of vitrified blastocysts from one or two superovulated Large White Hyperprolific donors to Meishan recipients: reproductive parameters at Day 30 of pregnancy

The present study was designed to determine the effect of pooling embryos from two donors on the reproductive success of transfer of vitrified/warmed porcine blastocysts. Intact blastocysts were collected from superovulated Large White Hyperprolific gilts (n = 24) on Days 5-5.5 after artificial insemination. Embryos were recovered by flushing the uterine horns, and unhatched blastocysts were selected. Vitrification and warming were performed as described by Berthelot et al. [Cryobiology 41(2000) 116]. To evaluate in vitro development, 37 vitrified/warmed blastocysts were cultured, non-vitrified embryos (n = 48) were used as controls. Embryo transfers were conducted in asynchronous (-24 h) Meishan gilts (n = 20). Twenty vitrified/warmed blastocysts were surgically transferred into one uterine horn. Ten recipients received embryos from one donor (Group 1) and the other 10 transfers were performed with mixed embryos from two donors (Group 2). Pregnancy was assessed ultrasonographically at Day 25 after estrus and recipients were slaughtered at Day 30 after transfer. In vitro survival rate of the vitrified/warmed blastocysts was lower (P < 0.01) than that from control embryos (73.0% versus 93.7%). The pregnancy rate for Group 1 (70%) was not different (P > 0.05) than that from Group 2 (90%). No significant differences were detected between Groups 1 and 2 for in vivo embryo development (number fetuses/transferred embryos in pregnant recipients) or in vivo embryo survival (number viable fetuses/transferred embryos in pregnant recipients). However, the in vivo efficiency (number viable fetuses/total transferred embryos) was higher (P < 0.05) when transfers were performed with embryos from two donors (19.5% versus 30.5%). These results indicate that pooling embryos from two donors increases the in vivo efficiency after transfer of vitrified/warmed porcine blastocysts.     

Direct transfer of vitrified rabbit embryos

In this study we looked at the feasibility of transferring vitrified rabbit embryos directly into recipient does. Compacted morulae were vitrified in a solution of 20% ethylene glycol and 20% dimethyl sulfoxide. After thawing, and without step-wise diluted solution, the vitrified embryos were transferred into the recipient's uterine horns. Survival rate at birth differed from fresh rabbit embryos (40% vs 55%, P < 0.05). However, the percentage of does that delivered (94%) and the survival rate suggested this method is suitable for both storage and simple transfer of rabbit morulae.     

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.     

Establishment of pregnancies after serial dilution or direct transfer by vitrified equine embryos

Experiments were conducted to determine viability of equine embryos in vivo after vitrification. In a preliminary study (Experiment 1), embryos were exposed in three steps to vitrification solutions containing increasing concentrations of ethylene glycol and glycerol (EG/G); the final vitrification solution was 3.4 M glycerol + 4.6 M ethylene glycol in a base medium of phosphate-buffered saline. Embryos were warmed in a two-step dilution and transferred into uteri of recipients. No pregnancies were observed after transfer of blastocysts >300 microm (n = 3). Transfer of morulae or blastocysts < or = 300 microm resulted in four embryonic vesicles (4/6, 67%). In a second experiment, embryo recovery per ovulation was similar for collections on Day 6(28/36, 78%) versus Days 7 and 8(30/48, 62%). Embryos < or = 300 and >300 microm were vitrified, thawed and transferred as in Experiment 1. Some embryos < or = 300 microm were also transferred using a direct-transfer procedure (DT). Embryo development rates to Day 16 were not different for embryos < or = 300 microm that were treated as in Experiment 1(10/22, 46%) or transferred by DT (16/26, 62%). Embryos > 300 microm (n = 19) did not produce embryonic vesicles.     

Viability of mouse half-embryos in vitro and in vivo

Mouse embryos at the 2-, 4-, 8-cell, and morula stage were divided in half by using microsurgical procedures and were either grown in vitro up to the blastocyst stage or transferred at the late morula stage into the uteri of pseudopregnant recipients. A relatively high percentage of the half embryos from 2-cell (70%), 4-cell (75%), 8-cell (93%), or morula stage embryos (75%) developed into blastocysts in vitro. However, the overall development in vivo of half embryos was low, as 3%, 13%, 8%, and 1% of half embryos from the 2-cell, 4-cell, 8-cell, and morula stages, respectively, developed into live fetuses. Embryos which were divided in half at different stages developed at different rates in vitro. This determined the stage of embryonic development at the time of transfer, which might have interacted with the stage of pseudopregnancy of the recipients to influence embryo survival in vivo.     

Early embryonic development and in vitro culture of in vivo produced embryos in the farmed European polecat (Mustela putorius)

Early embryonic development and in vitro culture of in vivo produced embryos in the farmed European polecat (Mustela putorius) was investigated as a part of an ex situ conservation program of the endangered European mink (Mustela lutreola), using the European polecat as a model species. The oestrus cycles of 34 yearling polecat females were monitored by visual examination of the vulval swelling and, to induce ovulation, the females were mated once daily on two consecutive days. Sixteen yearling males were used for mating. The females were humanely killed 3-14 days after the first mating and the uteri and oviducts were collected for embryo recovery. Uterine and oviductal flushings yielded a total number of 295 embryos, representing developmental stages from the 1-cell stage to large expanded and hatched blastocysts. On Day 3 after the first mating, only 1-16-cell stage embryos were recovered. Between Days 4 and 6 after the first mating, 1-16-cell stage embryos and morulae were found. The first blastocysts were recovered on Day 7 after the first mating. The first implanted blastocysts were detected on Day 11 after the first mating. A total number of 85 embryos were in vitro cultured after recovery. Blastocyst production rates for in vitro cultured 1-16-cell stage embryos and for morulae/compact morulae were 68 and 84%, respectively. For all cultured embryos, the hatching rate was 15%. The in vitro culture requirements for the preimplantation embryos of the farmed European polecat remain to be determined before further utilization of the technique.     

Effect of asynchronous superinduction on embryo survival and range of blastocyst development in swine

The importance of uniform development of blastocysts was examined by comparing the effects of asynchronous superinduction (Day 6 embryos into Day 7 pregnant recipients and Day 7 embryos into Day 6 pregnant recipients) on the range of embryo development at Days 12 and 13 to subsequent survival to Day 30. Twenty gilts were used to produce five Day 7 recipients that received Day 6 embryos and five Day 6 recipients that received Day 7 embryos. Embryos from the Day 7 and Day 6 recipients were examined 6 days later. Recovered embryos ranged morphologically from spherical to filamentous blastocysts. This range of embryos was within the limits of that previously observed for naturally mated sows. However, recovered blastocysts from the Day 6 embryos transferred into Day 7 recipients were morphologically more variable and proportionately less developed than the blastocysts from the Day 7 embryos transferred into Day 6 recipients. Forty additional gilts were subsequently utilized to generate 20 recipients (10 recipients per transfer group) that were examined on Day 30. More Day 7 embryos transferred into Day 6 recipients survived (p less than 0.05) than Day 6 embryos transferred into Day 7 recipients. These experiments suggested that greater variation in early development of embryos, within litters, subsequently resulted in greater mortality of embryos.     

Birth of piglets after OPS vitrification and transfer of compacted morula stage embryos with intact zona pellucida

In swine, five to six days post-insemination, morulae and blastocysts are collected together after uterine flushing. The purpose of this study was to vitrify zona pellucida-intact morulae with Open Pulled Straw (OPS) technology and obtain piglets after transfer. Morulae (200) were vitrified after a two-step equilibration in ethylene glycol, dimethyl sulfoxide and sucrose in Hepes-buffered TCM199 + 20% NBCS medium (TCM). 2-6 morulae were loaded into OPS and plunged into liquid nitrogen. At embryo warming, a three-step dilution with decreasing concentrations of sucrose was applied. In each of 10 recipients, 20 morulae were transferred surgically. Day 25, gestation rate and the farrowing rate were 80% and 70%, respectively. The pregnant recipients farrowed from 1 to 8 piglets and the survival of total transferred embryos was 13%. Although survival rates are still compromised, OPS technology is therefore appropriate to cryopreserve porcine morulae with intact zona pellucida.     

Development and survival after transfer of cow embryos cultured from 1-2-cells to morulae or blastocysts in rabbit oviducts or in a simple medium with bovine oviduct epithelial cells

This study compares development of bovine 1-2-cell embryos in bovine oviduct epithelial cell co-culture (Group EC) with a glucose- and serum-free simple medium (CZB), or after surgical transfer to ligated oviducts of rabbits (Group RO). Embryos were surgically collected from superovulated donor cows 40-48 h after the beginning of oestrus and randomly distributed between the two groups. Embryos were cultured or incubated for 5 days. In Exp. 1, embryo quality scores and total numbers of cells in the two groups were compared. In Exp. 2, pairs of similarly treated morulae were transferred to each of 10 or 12 recipients in the Groups RO and EC, respectively. Total cell counts per embryo in both groups averaged 52 (P greater than 0.05), and the in-vitro culture system was equivalent to the rabbit oviducts in promoting embryo development for all characteristics measured. Embryo survival, as determined by ultrasound between Days 39 and 43 after oestrus, in 13 ideal recipients was 57% for embryos in Group EC and 58% for embryos Group RO. None of the 9 less desirable recipients was pregnant for either group. These results establish that cattle zygotes can develop to morulae in culture with bovine oviduct epithelial cells in a simple medium and can produce normal pregnancy rates.     

Increased mortality during early embryonic development after in-vitro fertilization of rat oocytes

Immature female rats (60-65 g) were injected with 4 i.u. PMSG on Day -2, and allocated to 3 groups. For Groups I and II, unmated donors were killed 67-69 h after PMSG injection, shortly after the expected time of ovulation. Oocytes were recovered from the oviducts and transferred immediately into the oviduct of mated recipients (Group I) whose ipsilateral ovary had been exposed by peeling back the bursa, preventing endogenous oocytes from entering the oviduct, or were fertilized in vitro (Group II) and were transferred 16-18 h later. Rats in Group III were allowed to mate and half were killed 6 h after mating. The fertilized oocytes were then incubated for 10-12 h until transfer. The remaining rats in Group III were killed 16-18 h after mating and fertilized oocytes were collected and transferred immediately. Recipient rats were killed on Days 2, 5, 8 and 20. Zygotes resulting from in-vitro fertilization (Group II) were as able as those fertilized in donors (Group III) or recipients (Group I) to develop to the 2-cell stage, but underwent significantly greater embryonic loss beyond this stage of development. There was a slower rate of development of such oocytes to the blastocyst stage (Day 5) and a lower mean weight of implantation sites (Day 8). Transfer of zygotes after in-vitro fertilization resulted in a loss of 35% of the embryos at the time of implantation. These results suggest that in-vitro fertilization of rat oocytes leads to defects in the embryos causing a delay in early embryo development and a large number of implantation losses.     

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.     

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.     

Pregnancy and fetal characteristics after transfer of vitrified in vivo and cloned bovine embryos

This study was conducted to examine pregnancy progression and fetal characteristics following transfer of vitrified bovine nuclear transfer versus in vivo-derived embryos. Nuclear transfer (NT) was conducted using cumulus cells collected from an elite Holstein-Friesian dairy cow. Expanding and hatching blastocysts on Day 7 were vitrified using liquid nitrogen surface vitrification. Day 7 in vivo embryos, produced using standard superovulation procedures applied to Holstein-Friesian heifers (n=6), were vitrified in the same way. Following warming, embryos were transferred to synchronized recipients (NT: n=65 recipients; Vivo: n=20 recipients). Pregnancies were monitored by ultrasound scanning on Days 25, 45 and 75 and a sample of animals were slaughtered at each time point to recover the fetus/placenta for further analyses. Significantly more animals remained pregnant after transfer of in vivo-derived embryos than NT embryos at all time points: Day 25 (95.0 versus 67.7%, P<0.05), Day 45 (92.8 versus 49.1%, P<0.01) and Day 75 (70.0 versus 20.8%, P<0.0). There was no significant difference (P=0.10) in the weight of the conceptus on Day 25 from NT transfers (1.14+/-0.23 g, n=8) versus in vivo transfers (0.75+/-0.19 g, n=8). On Day 45, there was no significant difference in the weight of either fetus (P=0.393) or membranes (P=0.167) between NT embryos (fetus: 2.76+/-0.40, n=12; membranes: 59.0+/-10.0, n=11) or in vivo-derived embryos (fetus: 2.60+/-0.15, n=6; membranes: 41.8+/-5.2, n=4). However, on Day 75 the weight of the fetus and several of the major organs were heavier from NT embryos. These data suggest that morphological abnormalities involving the fetus and the placenta of cloned pregnancies are manifested after Day 45.     

Cryopreservation of wild mouse spermatozoa

Spermatozoa of wild mice from China, Czechoslovakia, Denmark, India, Japan and Switzerland were frozen and stored at -196 degrees C. After thawing, intact oocytes were inseminated in vitro with relatively high motility frozen-thawed mouse spermatozoa from Czechoslovakia, Denmark and India, while oocytes with a partially dissected zona were inseminated with low motility frozen-thawed spermatozoa from China, Japan and Switzerland. Embryos developing to the 2-cell stage from oocytes fertilized with frozen-thawed spermatozoa were transferred to the oviducts of female recipients on the first day of pseudopregnancy (day when a vaginal plug was confirmed). Successful embryo development to the 2-cell stage was 46 to 67%. Offspring resulted from 17 to 51% of these transferred 2-cell embryos.     

Transgenic production from in vivo-derived embryos: effect on calf birth weight and sex ratio

We examined transgenic-cattle production by DNA microinjection into 1-, 2-, and 4-cell embryos, analyzing the impact on calf size and subsequent viability. Embryos were either collected at an abattoir by flushing oviducts from superovulated and artificially inseminated cows (in vivo-derived) or obtained by in vitro maturation and in vitro fertilization of oocytes aspirated from excised ovaries (in vitro-derived). A human serum albumin (hSA) milk-expression DNA construct was microinjected, either in one of the visible pronuclei of in vitro- and in vivo-derived 1-cell embryos or in the nuclei of two blastomeres of 2- and 4-cell in vivo-derived embryos. Microinjection-induced mortality (lysis and developmental block) was equivalent ( approximately 40%) for all microinjected embryos. Embryos were co-cultured with BRL cells in B-2 medium containing 10% fetal calf serum (FSC). Overall, embryo development to morulae/blastocysts was significantly greater for in vivo-derived ova (15.5%) than for in vitro-derived oocytes (9.3%). All morulae and blastocysts were transferred to synchronized recipient females on Days 6-8 post-fertilization. A total of 189 calves were delivered. Birth weights were significantly greater for calves generated from in vitro-derived oocytes compared with those generated from in vivo-derived oocytes. One transgenic bull calf was obtained from the microinjection of a 2-cell embryo. Fluorescence in situ hybridization (FISH) analysis of lymphocytes detected one transgenic integration site in all cells. Transmission frequency of the hSA transgene in embryos obtained through IVM/IVF/IVC utilizing the semen of the transgenic calf confirmed that it was not mosaic.