Preimplantation genetic diagnosis.

Preimplantation genetic diagnosis (PGD) has now been used in human fertility centers for a decade. To this end, diagnostic analysis is conducted on polar bodies or single blastomeres from biopsied embryos before the embryos are transferred, allowing the selection of normal embryos before a pregnancy has been established. Advances in technology available for PGD are described, including fluorescent in situ hybridization (FISH), interphase chromosome conversion, comparative genomic hybridization (CGH), fluorescent polymerase chain reaction (PCR), multiplex PCR, and whole genome amplification. These techniques support the diagnosis of a number of diseases at the single-cell level.

Cryopreservation of ovarian tissue: banking reproductive potential for the future.

Cryopreservation of ovarian tissue is a technology that holds promise for banking reproductive potential for the future. It may be apropos for cancer survivors who have undergone treatment with sterility-inducing chemotherapy. Although there is some evidence suggesting cellular and molecular injury with the freezing and thawing process, there are examples in both animals and humans that transplantation of cryopreserved ovarian tissue can effectively bank reproductive potential for the future. This technology may ultimately have applications for in vitro fertilization, and preventing natural or iatrogenic menopause.

Nuclear transfer in the rhesus monkey: practical and basic implications.

In early 1997, the birth of a lamb after transfer of the nucleus from an adult mammary gland cell into an enucleated oocyte, along with the production of rhesus monkeys by nuclear transfer of embryonic cells, marked a reemergence of the field of mammalian cloning. Clonally derived rhesus monkeys would be invaluable in biomedical research, and the commercial interests in transgenic sheep and cattle propagated by cloning are substantial. Nuclear transfer technology is under consideration in human in vitro fertilization clinics to overcome infertility secondary to advanced maternal age or mitochondrial-based genetic disease. Nuclear transfer involves preparing a cytoplast as a recipient cell, in most cases a mature metaphase II oocyte from which the chromosomes have been removed. A donor nucleus cell is then placed between the zona and the cytoplast, and fusion, as well as cytoplast activation, is initiated by electrical stimulation. Successful reprogramming of the donor cell nucleus by the cytoplast is critical--a step that may be influenced by cell cycle stage. Embryos produced by nuclear transfer are cultured in vitro for several cell divisions before cryopreservation or transfer to the oviduct or uterus of a host mother. The efficiency of producing live young by nuclear transfer in domestic species is low, with a high frequency of developmental abnormalities in both preterm and term animals. However, a number of pregnancies have now been established using fetal cells as the source of donor nuclei. The use of cell lines not only allows large clone sizes but also supports the ability to genetically manipulate cells in vitro before nuclear transfer. Ongoing research focused on the production of clonally derived rhesus monkeys using fetal fibroblasts and embryonic stem cells as the source of donor nuclei will be reviewed.

Nuclear transplantation of ectodermal cells in pig oocytes: ultrastructure and radiography.

This study investigated the changes in nucleolar fine structure and the synthesis of both heterogeneous nuclear RNA (hnRNA) and ribosomal RNA (rRNA) in pig reconstructed embryos obtained by electrofusion of a single pig ectodermal cell to an enucleated metaphase-II oocyte. The nucleolar morphological changes and the pattern of transcription were examined in the ectodermal cells before fusion and in the nuclear transfer reconstructed embryos 16-18 hr after fusion. Before fusion the ectodermal cells exhibited a reticulated nucleolus with active RNA synthesis. In the reconstructed embryos, modifications of the nucleolar structure were observed, as assessed by the presence of either round-shaped, compact, dense nucleolar precursor bodies, or reticulated nucleoli. However, in both cases there was no RNA synthesis. Blebbing activity of the nuclear envelope was not observed. These results indicate that the nucleus of pig ectodermal cells exhibited either a complete or an incomplete remodelling when transferred to an enucleated metaphase-II oocyte, with no detectable RNA synthesis. Cell-cycle synchronization of ectodermal cell donor nuclei may play an important role in nuclear reprogramming after fusion.

Nuclear transplantation in pigs: M-phase karyoplast to M-phase cytoplast fusion.

Porcine embryonic fibroblasts in M-phase were isolated from confluent cultures by selective detachment and fused to homologous metaphase II enucleated oocytes. The fusion products were analysed by light and electron microscopy (EM). The fusion treatment, per se, did not induce the disappearance of the maturation promoting factor (MPF) in the cloned embryos and the transferred chromatin remained condensed for up to 10 h. Spontaneous decondensation started after this time and, at about 20 h post-induction of fusion, a single large nucleus was present in the cytoplasm. The prolonged exposure of introduced chromatin to MPF resulted in a total morphological remodelling as assessed by the nucleolar morphology observed by EM in all the specimens.

Initial culture behaviour of rat blastocysts on selected feeder cell lines.

To increase our understanding of rat embryos in culture and to attempt the isolation of blastocyst-derived cell lines, we examined the initial growth behaviour of rat blastocysts from four strains of rat on four different feeder cell layers. The feeders used were a continuous cell line of murine embryonic fibroblasts (STO), primary mouse (MEF) or primary rat (REF) embryonic fibroblasts, and a continuous cell line of rat uterine epithelial cells (RUCs). A medium that gave optimum plating efficiencies for murine ES cells was used in the rat embryo culture. Each culture system allowed hatching and attachment of the blastocysts, that is, the behaviour was similar on each feeder and each strain for the first 2 days in culture. Subsequently, there was a rapid differentiation of the Inner Cell Mass (ICM) cells on fibroblastic feeder cell layers (STO > MEF > REF), and this was generally complete after 3-6 days in primary culture. On RUCs, the ICM was found to increase in size without differentiation up to and including day 4 and in some cases longer. Embryo-derived cells were obtained by disaggregating and passaging ICMs on REF and RUC feeders. Rounded, refractile, and epithelial-like cells were isolated on REF and colonies of ES-like cells on the RUCs. The ES-like cells were positive for expression of alkaline phosphatase and stage-specific embryonic-antigen 1. This is an important first step towards the derivation and culture of pluripotent ES cells from the rat.

Chromosome condensation activity (CCA) in bisected C57BL/6JxCBA mouse oocytes.

Chromosome condensation activity (CCA) has been analysed in C57BL/6Jx CBA mouse oocytes bisected (i) shortly after germinal vesicle breakdown (GVBD), (ii) in metaphase I (MI) and (iii) in metaphase II (MII) into two equal halves (nucleated, enucleated) which were thereafter fused to S- or G2-phase 4-cell-stage mouse blastomeres. In nucleated halves, premature chromosome condensation (PCC) in transplanted nuclei was always induced irrespective of the cell cycle stage of the blastomere, whereas in enucleated halves only G2 nuclei underwent PCC after transplantation. Premature chromosome condensation in S-phase nuclei was induced only in enucleated halves produced shortly after GVBD. Although S-phase nuclei transplanted to MI or MII enucleated halves remained intact, their capacity to synthesize DNA was invariably suppressed. When spindles were destroyed by preincubation of the oocytes in colcemid before bisection, both nucleated and enucleated halves produced at MI or MII induced PCC of both G2- or S-phase nuclei. These results demonstrate that chromosome condensation activity in mammalian oocytes is compartmentalized rather than uniformly distributed across the cell, and that the enucleation of mammalian oocytes before nuclear transplantation may, under some conditions, influence the levels of CCA and subsequent response of introduced nuclei to cytoplasmic factors.

A reversible block at the G1/S border during cell cycle progression of mouse embryos.

Late 2-cell stage mouse embryos were cultured in M-199 plus 100 micrograms/ml Na pyruvate 25 micrograms/ml gentamycin and 0.3% BSA with or without mimosine (200 microM, 150 microM, 100 microM and 50 microM) for a short (4-5 h) or long (18-20 h) culture period; after drug removal subsequent embryo development was evaluated. Late 2-cell stage mouse embryos treated with mimosine were blocked at the 4-cell stage. Autoradiographic studies show that mimosine inhibits cell cycle progression in mouse embryos at the G1/S boundary. The onset of DNA replication occurs within 15 min of releasing the embryos from mimosine block. Embryos pretreated with mimosine at 200 microM and 150 microM for 4-5 h progress after 3-4 days in culture to hatched blastocyst (71% and 79%, respectively) compared with control (90%). However a longer pretreatment (18-20 h) with mimosine at 200 microM was significantly detrimental to the subsequent developmental progression to hatched blastocyst (2% vs 81%, p < or = 0.05); the proportion of degenerated embryos was significantly increased with mimosine at 200 microM and 150 microM compared with control (57% and 28% vs 4%, p < or = 0.05) after 3-4 days in culture. Preliminary studies with mimosine treatment at 100 microM and 50 microM for 18-20 h show that 70% and 37% of the embryos were blocked at 4-cell stage, respectively. These results indicate that mimosine inhibits cell cycle progress in mouse embryos at the G1/S border and thus induces a reversible arrest in a dose- and time-dependent manner.

A culture system for the development of the preimplantation rat embryo.

We describe a system for the culture of 1-cell rat embryos through to the blastocyst stage, using co-culture on specific feeder cell layers and particular defined media. We show that the use of rat uterine epithelial cells as a feeder layer, together with either M16M, CZB or HECM-1 media at 38.5 degrees C can improve the in vitro development of cultured rat embryos. There was considerable variation in the culture conditions, which were optimal for each strain of rat tested. We show that the 4 to 8-cell embryos are viable after reimplantation and that the second 4 to 8-cell block in the rat can be overcome using HECM-1 in a co-culture system, thus enabling the in vitro culture of rat embryos up to the blastocyst stage.

Movement characteristics and hyperactivation of human sperm on different epithelial cell monolayers.

Studies of sperm movement characteristics concern mainly sperm swimming between two glass surfaces (as in the Makler chamber). Using automated videomicrography, (CellSoft, Cryo Resources, New York, USA), we have analysed the movements of human sperm swimming on monolayers of different origins: monkey kidney (Vero) cells, bovine oviduct cells, and human endometrial cells. About 10(5) sperm were deposited upon preparations consisting of monocellular layers adhering to a coverglass, and placed in a deep slide-coverglass system. Experiments were first performed at room temperature then at 37 degrees C. At room temperature, motion characteristics on Vero cell layers (six samples) were not different from those measured in either the conditioned or corresponding non-conditioned media, except for the amplitude of lateral head displacement (ALH) which was significantly lower. Comparison of the three different cell monolayers showed no difference between them for the corresponding motion parameters. The data were dramatically different at 37 degrees C: sperm swimming on cell monolayers of genital origin (oviduct or endometrium) exhibited high rates of hyperactivation (HA: 36.7% and 38.6% respectively), which was significantly more than on either Vero cells (10.9%) or in a control medium (12.6%). Moreover, HA rates were significantly higher on genital cell monolayers than in the corresponding conditioned medium. Hyperactivated sperm exhibited lasting 'star-spin' trajectories rather than 'transitional phases'. It is concluded that passage of sperm on either oviduct or endometrial epithelial cell monolayers can induce sperm hyperactivation and improve their fertilizing capacity.

Co-culture of 1-cell mouse embryos on different cell supports.

The development of 1-cell mouse embryos in explanted oviducts, on mouse and bovine oviduct epithelial cells and on two established cell line supports is compared. The best rates of blastocyst formation were obtained using explanted oviducts; mouse and to a lesser extent, bovine oviduct epithelial cells allow good embryonic development, associated with high viability after transfer of the blastocysts obtained in co-culture. MDBK (from bovine kidney) and Vero (from Green monkey kidney) have been tested. MDBK allows high rates of blastocyst formation (67%) and the blastocysts obtained are viable. Vero does not allow the 2-cell block to be overcome. Maintenance of cell polarity for all the feeder layers did not improve embryo development. A preliminary study on the metabolic modifications induced by the feeder layers showed no modifications at all related to a decrease in glucose, an increase in lactate and early embryonic development. On the other hand, for the free amino acids, cellular supports with high embryotrophic activity seem to mimic tubal secretions, especially with a high level of glycine. Neither a genital tract origin, nor a hormonal contribution are strictly necessary for embryo co-culture, as already demonstrated by co-culture with trophoblastic tissue. Established cell lines, which are easy to handle and control, could be useful tools in embryo biotechnology.

Culture of epithelial cells derived from the oviduct of different species.

This study proposes a procedure for the isolation and culture of oviduct epithelial cells of several species. In-vitro culture on such a feeder seems to allow full embryonic development and viability. The inner linings of Fallopian tubes from mouse, rabbit, cow and human were trypsinized and the epithelial cells were enriched with Percoll gradient. Isolated cells, obtained in high yield with good viability, were maintained in monolayer culture in B2-Menezo medium supplemented with serum, which also supports early embryonic development in vitro. The plated primary cultures reached confluence within 8 days, producing a monolayer of cohesive polygonal cells. Associated with this large epithelial cell population, ciliated cells as well as polykaryotic cells and few fibroblastic nests were observed. After the first sub-culture, the ciliated cells disappeared and the epithelial cell monolayer grew rapidly to confluence within 3 days and displayed contact inhibition. No epithelial cell growth could be obtained in culture in the absence of serum. The addition of oestrogens had no effect on any of the cultured oviductal epithelial cells. A spontaneous alteration was observed in morphology and growth after several passages, the number of which depends mainly upon the species.