Successful nonsurgical deep uterine embryo transfer in pigs.

At present, it is possible to transfer pig embryos directly into the uterine body of sows by nonsurgical procedures. The aim of this study was to develop a procedure for nonsurgical embryo transfer (ET) into the upper part of one uterine horn in gilts and sows. In experiment 1, 29 gilts and 43 sows were used. Intrauterine insertions took place for each female at days 4-6 of the estrous cycle (D0 = onset of estrus). An artificial insemination (AI) spirette was inserted into the cervix to assist with the guidance of a modified flexible catheter originally developed for deep intrauterine insemination in pigs. The flexible catheter length inserted anterior to the inserted AI spirette was 43.0 +/- 1.7 cm. The time required to complete the procedure was affected by the type of female (P < 0.001) and by the difficulties encountered for inserting the catheter (P < 0.001). However, when no or minor difficulties were encountered during the insertion of the catheter (in approximately 70 and 80% of gilts and sows, respectively), the time required to complete the procedure did not differ between gilts (2.5 +/- 0.1 min) and sows (2.3 +/- 0.1 min). In experiment 2, 24 to 31 fresh morulae and/or blastocysts were transferred to each of 24 recipients. Seventeen animals (70.8%) farrowed an average of 6.9 +/- 0.7 piglets, of which 0.6 +/- 0.3 piglets were born dead. In conclusion, the procedure described in this study offers new possibilities to transfer embryos nonsurgically to the uterine horn of pigs.

Mosaic gene expression in nuclear transfer-derived embryos and the production of cloned transgenic pigs from ear-derived fibroblasts.

Genetically modified domestic animals have many potential applications ranging from basic research to production agriculture. One of the goals in transgenic animal production schemes is to reliably predict the expression pattern of the foreign gene. Establishing a method to screen genetically modified embryos for transgene expression before transfer to surrogates may improve the likelihood of producing offspring with the desired expression pattern. In order to determine how transgene expression may be regulated in the early embryo, we generated porcine embryos from two distinct genetically modified cell lines by using the nuclear transfer (NT) technique. Both cell lines expressed the enhanced green fluorescent protein (eGFP); the first was a fibroblast cell line derived from the skin of a newborn pig that expressed eGFP, whereas the second was a fetal derived fibroblast cell line into which the eGFP gene was introduced by a retroviral vector. The reconstructed embryos were activated by electrical pulses and cultured in NCSU23. Although the in vitro developmental ability of each group of NT embryos was not different, the eGFP expression pattern was different. All embryos produced from the transduced fetal cell line fluoresced, but only 26% of the embryos generated from the newborn cell line fluoresced, and among those that did express eGFP, more than half had a mosaic expression pattern. This was unexpected because the fetal cell line was not clonally selected, and each cell had potentially different sites of integration. Embryos generated from the newborn cell line were surgically transferred to five surrogate gilts. One gilt delivered four female piglets, all of which expressed eGFP, and all had microsatellites identical to the donor. Here we demonstrate that transgene expression in all the blastomeres of an NT embryo is not uniform. In addition, transgene expression in a genetically manipulated embryo may not be an accurate indicator of expression in the resulting offspring.