J.R. Dobrinsky

Somatic cell nuclear transfer in the pig: Control of pronuclear formation and integration with improved methods for activation and maintenance of pregnancy

Abstract To clone a pig from somatic cells, we first validated an electrical activation method for use on ovulated oocytes. We then evaluated delayed versus simultaneous activation (DA vs. SA) strategies, the use of 2 nuclear donor cells, and the use of cytoskeletal inhibitors during nuclear transfer. Using enucleated ovulated oocytes as cytoplasts for fetal fibroblast nuclei and transferring cloned embryos into a recipient within 2 h of activation, a 2-h delay between electrical fusion and activation yielded blastocysts more reliably and with a higher nuclear count than did SA. Comparable rates of development using DA were obtained following culture of embryos cloned from ovulated or in vitro-matured cytoplasts and fibroblast or cumulus nuclei. Treatment of cloned embryos with cytochalasin B (CB) postfusion and for 6 h after DA had no impact on blastocyst development as compared with CB treatment postfusion only. Inclusion of a microtubule inhibitor such as nocodozole with CB before and after DA improved nuclear retention and favored the formation of single pronuclei in experiments using a membrane dye to reliably monitor fusion. However, no improvement in blastocyst development was observed. Using fetal fibroblasts as nuclear donor cells, a live cloned piglet was produced in a pregnancy that was maintained by cotransfer of parthenogenetic embryos.

Birth of Piglets After Transfer of Embryos Cryopreserved by Cytoskeletal Stabilization and Vitrification

Abstract Pig embryos suffer severe sensitivity to hypothermic conditions, which limits their ability to withstand conventional cryopreservation. Research has focused on high lipid content of pig embryos and its role in hypothermic sensitivity, while little research has been conducted on structural damage. Documenting cytoskeletal disruption provides information on embryonic sensitivity and cellular response to cryopreservation. The objectives of this study were to document microfilament (MF) alterations during swine embryo vitrification, to utilize an MF inhibitor during cryopreservation to stabilize MF, and to determine the developmental competence of cytoskeletal-stabilized and vitrified pig embryos. Vitrified morulae/early blastocysts displayed MF disruptions and lacked developmental competence after cryopreservation; hatched blastocysts displayed variable MF disruption and developmental competence. Cytochalasin-b did not improve morula/early blastocyst viability after vitrification; however, it significantly (P < 0.05) improved survival and development of expanded and hatched blastocysts. After embryo transfer, we achieved pregnancy rates of almost 60%, and litter sizes improved from 5 to 7.25 piglets per litter. This study shows that the pig embryo cytoskeleton can be affected by vitrification and that MF depolymerization prior to vitrification improves blastocyst developmental competence after cryopreservation. After transfer, vitrified embryos can produce live, healthy piglets that grow normally and when mature are of excellent fecundity.

Advancements in cryopreservation of domestic animal embryos.

The development of embryo freezing technologies revolutionized cattle breeding. Since then, advancements in cryobiology, cell biology, and domestic animal embryology have enabled the development of embryo preservation methodologies for our other domestic animal species, including sheep and goats. Recently, technologies have been developed to cryopreserve pig embryos, notorious for their extreme sensitivity to cooling; horse embryo cryopreservation is in its infancy. While cryopreservation can enhance the utilization of in vitro embryo production technologies, cryosurvival of in vitro-produced (IVP) or micromanipulated embryos is less than that of in vivo-derived embryos. This review outlines recent efforts in livestock embryo cryopreservation. In the near future, use of preserved embryos could be a routine breeding alternative for all livestock producers providing 1) preservation methods for maternal germplasm, 2) global genetic transport, 3) increased selection pressure within herds, 4) breeding line regeneration or proliferation, and 5) methodology for genetic rescue.

PRODUCTION OF PIGLETS PRESELECTED FOR SEX FOLLOWING IN VITRO FERTILIZATION WITH X AND Y CHROMOSOME-BEARING SPERMATOZOA SORTED BY FLOW CYTOMETRY

In vivo-matured porcine oocytes were fertilized in vitro with X and Y chromosome-bearing spermatozoa, and sorted for sex on the basis of DNA content by flow cytometry. Developmental competence of the sexed embryos was determined through established pregnancies after embryo transfer. Spermatozoa were stained with Hoechst 33342 and sorted using a flow cytometry cell sorter. Purity of sorting was 83% for Y spermatozoa and 92% for X spermatozoa. A total of 387 mature cumulus-oocyte-complexes (COC) was collected from 18 superovulated prepuberal gilts shortly before ovulation. In vitro fertilization with sorted spermatozoa was performed in 4 replicates. After 18 h of sperm- oocyte co-culture at 39 degrees C, the zygotes were placed into culture medium (NCSU-23) for another 24 h. The average cleavage rate was 56.2%. Ninety-two embryos produced from X-sorted sperm cells were transferred surgically into the uterus of 2 recipients. Two gilts farrowed and delivered 6 and 4 healthy female piglets, respectively. Additionally, 2 gilts were inseminated intratubally via surgical laparotomy with either X or Y sorted spermatozoa (2 x 10(5)) per oviduct. The 2 sows farrowed producing 15 piglets. Thirteen of the 15 piglets were of the predicted gender (85%).

In vitro production of pig embryos: Comparisons of culture media and boars

The utilization of in vitro produced pig embryos for commercial production or research is dependent upon the development of improved methodology. Our objective was to establish a consistent in vitro embryo production (IVP) system and subsequently utilize the procedures to evaluate culture system components and boar effects. To summarize the IVP system, 403 inseminated oocytes from a total of 2243 were analyzed across 17 replicates for maturation and fertilization efficiency, while 1838 zygotes were cultured in 26 replicates for developmental data. Penetration, cleavage and blastocyst development rates were determined at 18, 44 and either 144 or 168 h post insemination, respectively. Monospermic penetration averaged 31.8+/-7.3% while polyspermy was 30.8+/-17.2%. Cleavage rate was 44.9+/-16.1%, with 21.8+/-7.5% of fertilized oocytes and 51.9+/-15.9% of cleaved embryos developing to blastocysts. For culture medium comparison, fertilized oocytes were cultured in either BECM-6, BECM-7, NCSU-23 or NCSU-23aa and supplemented on Day 5 post insemination (pi) with 10% FCS. These treatments resulted in 4.0, 4.9, 19.8 and 13.6% (+/-3.2%) blastocysts by Day 7 pi, with an average cell number of 44.4+/-9.0, 65.1+/-8.2, 61.3+/-4.5 and 64.4+/-4.8, respectively. These IVP procedures consistently produced zygotes from semen of several different boars, capable of forming blastocysts in vitro. Comparison of developmental rates among the boars indicated that this system is variable among boars but not strictly boar-dependent. Culture media comparisons suggest that NCSU-23 yielded a higher percentage of blastocysts than the other media in this IVP system.

Improvement of an Electrical Activation Protocol for Porcine Oocytes

Abstract Factors influencing pig oocyte activation by electrical stimulation were evaluated by their effect on the development of parthenogenetic embryos to the blastocyst stage to establish an effective activation protocol for pig nuclear transfer. This evaluation included 1) a comparison of the effect of epidermal growth factor and amino acids in maturation medium, 2) an investigation of interactions among oocyte age, applied voltage field strength, electrical pulse number, and pulse duration, and 3) a karyotype analysis of the parthenogenetic blastocysts yielded by an optimized protocol based on an in vitro system of oocyte maturation and embryo culture. In the first study, addition of amino acids in maturation medium was beneficial for the developmental competence of activated oocytes. In the second study, the developmental response of activated oocytes was dependent on interactions between oocyte age at activation and applied voltage field strength, voltage field strength and pulse number, and pulse number and duration. The formation of parthenogenetic blastocysts was optimal when activation was at 44 h of maturation using three 80-μsec consecutive pulses of 1.0 kV/cm DC. Approximately 84% of parthenogenetic blastocysts yielded by this protocol were diploid, implying a potential for further in vivo development.

Dual labeling of the cytoskeleton and DNA strand breaks in porcine embryos produced in vivo and in vitro.

In vitro‐produced embryos exhibit decreased cell numbers, small inner cell masses and reduced pregnancy rates after transfer. Evaluation of intracellular components of in vitro‐produced or ‐manipulated embryos will lead to improved methodology for embryo production. Whole mount techniques were developed to utilize terminal deoxynucleotidyl‐transferase 3′ nick end labeling (TUNEL) to detect broken DNA. Subsequent labeling of either tubulin or actin filaments provides further evidence of cytological damage. Porcine embryos produced in vitro or in vivo were evaluated throughout the cleavage and preimplantation stages of development. Early cleavage stages up to the 8‐cell stage never contained TUNEL‐labeled nuclei. However, TUNEL labeling of in vitro‐produced morula revealed some blastomeres with broken DNA. Nearly all in vitro‐produced blastocysts displayed some TUNEL positive cells, whereas in vivo‐collected embryos at a similar stage displayed few, if any, TUNEL‐labeled nuclei. The ratio of TUNEL‐labeled DNA to total DNA area of in vitro‐derived blastocysts was significantly greater than their in vivo counterparts (P < 0.05). Microtubule and microfilament labeling identified blastomeres of unequal size and shape that were losing cellular integrity. These data suggest that the combination of these labeling techniques may be useful in evaluating cellular damage in embryos produced under in vitro conditions. Mol. Reprod. Dev. 51:59–65, 1998. Published 1998 Wiley‐Liss, Inc. This article is a US Government work and, as such, is in the public domain in the United States of America.

Cryopreservation of swine embryos: a chilly past with a vitrifying future

Since the development of embryo freezing technologies for cattle in the 1980s, advances in cryobiology, cell biology and embryology of domestic animals have enabled the development of embryo preservation methodology for the pig, notorious for extreme sensitivity to cooling. This review outlines recent efforts to understand the biology of pig embryos as related to their extreme sensitivity to cooling. Cellular analyses and molecular approaches are discussed that have enabled pig embryos to survive cryopreservation and after transfer develop into live offspring with normal fecundity at maturity. In the near future, use of preserved embryos will be a routine breeding alternative for swine producers, providing: preservation methods for maternal germplasm; global genetic transport; increased selection pressure within herds; breeding line regeneration or proliferation; and methodology for genetic resource rescue. It took almost 50 years after the first successful embryo transfer to develop embryo preservation in the pig. Nonetheless, by applying novel methods described herein, rapid progress has been achieved.

Porcine sperm viability, oocyte fertilization and embryo development after staining spermatozoa with SYBR-14

The objective of these experiments was to determine the efficacy of the new membrane permeant nucleic acid stain, SYBR-14, for assessing boar sperm viability and to determine its effect on fertilization and early embryonic development using the pig as a model. We examined the staining patterns of SYBR-14 and another vital stain, Hoechst 33342, both in combination with the dead cell stain, propidium iodide (PI), to quantify the proportion of living and dead spermatozoa in ejaculated and epididymal semen. Flow cytometry analyses of semen from 4 boars revealed significant differences among boars for the proportion of SYBR-14-stained spermatozoa in both epididymal and ejaculated samples, but not for Hoechst 33342 or PI stained spermatozoa. Gilts were inseminated with unstained spermatozoa or spermatozoa stained with 2 levels of SYBR-14 or 2 levels of the reference stain, Hoechst 33342. Embryos recovered at 42 to 48 h postinsemination were morphologically evaluated, and only 4 to 8-cell embryos were continued in culture. Overall, fluorescent staining of boar spermatozoa with SYBR-14 or Hoechst 33342 neither affected their ability to fertilize oocytes, nor the developmental competence of the resultant embryos.

In vitro and in vivo developmental competence of ovulated and in vitro matured porcine oocytes activated by electrical activation

The objective of this study was to evaluate the in vitro and in vivo developmental competence of parthenogenetic (parthenote) pig embryos derived from ovulated and in vitro matured (IVM) oocytes. A total of four experiments were carried out. These demonstrated that the mean blastocyst rates from stimulated ovulated and IVM pig oocytes were not significantly different (61% vs. 46%, p > 0.05) following in vitro culture. Both ovulated and IVM pig parthenotes were able to develop in vivo for 30 days. Parthenote fetuses collected 21 and 30 days post estrus were morphologically normal but significantly smaller and lighter than fertilized controls (p < 0.01). IVM pig parthenotes stopped development around 31 days post estrus.