Nuclear and nucleolar reprogramming during the first cell cycle in bovine nuclear transfer embryos.

The immediate events of genomic reprogramming at somatic cell nuclear transfer (SCNT) are to high degree unknown. This study was designed to evaluate the nuclear and nucleolar changes during the first cell cycle. Bovine SCNT embryos were produced from starved bovine fibroblasts and fixed at 0.5, 1, 2, 3, 4, 8, 12, and 16 h postactivation (hpa). Parthenogenetic (PA) embryos were used as control. The SCNT and PA embryos were processed for lacmoid staining, autoradiography, transmission electron microscopy (TEM), and immunofluorescence localization of: upstream binding factor (UBF) and fibrillarin at 4 and 12 hpa. Likewise, starved and nonstarved fibroblasts were processed for autoradiography and TEM. The fibroblasts displayed strong transcriptional activity and active fibrillogranular nucleoli. None of the reconstructed embryos, however, displayed transcriptional activity. In conclusion, somatic cell nuclei introduced into enucleated oocytes displayed chromatin condensation, partial nuclear envelope breakdown, nucleolar desegregation and transcriptional quiescence already at 0.5 hpa. Somatic cell cytoplasm remained temporally attached to introduced nucleus and nucleolus was partially restored indicating somatic influence in the early SCNT phases. At 1-3 hpa, chromatin gradually decondensed toward the nucleus periphery and nuclear envelope reformed. From 4 hpa, the somatic cell nucleus gained a PN-like appearance and displayed NPBs suggesting ooplasmic control of development.

Attempts towards derivation and establishment of bovine embryonic stem cell-like cultures.

Current knowledge on the biology of mammalian embryonic stem cells (ESC) is stunningly sparse in light of their potential value in studies of development, functional genomics, generation of transgenic animals and human medicine. Despite many efforts to derive ESC from other mammalian species, ESC that retain their capacity for germ line transmission have only been verified in the mouse. However, the criterion of germ line transmission may not need to be fulfilled for exploitation of other abilities of these cells. Promising results with human ESC-like cells and adult stem cells have nourished great expectations for their potential use in regenerative medicine. However, such an application is far from reality and substantial research is required to elucidate aspects of the basic biology of pluripotent cells, as well as safety issues associated with the use of such cells in therapy. In this context, methods for the derivation, propagation and differentiation of ESC-like cultures from domestic animals would be highly desirable as biologically relevant models. Here, we review previously published efforts to establish bovine ESC-like cells and describe a procedure used in attempts to derive similar cells from bovine Day 12 embryos.

Effect of leukemia inhibitory factor (LIF) on in vitro produced bovine embryos and their outgrowth colonies.

In vitro produced (IVP) bovine embryos were subjected to in vitro culture with or without 1000 U/ml human recombinant leukemia inhibitory factor (LIF) added to the culture medium from Days 5 to 8 post insemination (p.i.). Resulting blastocysts were subsequently plated intact on mouse feeder cells in a medium with or without LIF. Significantly more embryos reached the hatched blastocyst stage, and the number of blastocysts with excellent morphology was significantly higher, when LIF was omitted. At Day 8 p.i., total cell count (TCC) and inner cell mass (ICM) cell count was significantly higher in embryos cultured without LIF. In embryos cultured with LIF, cytoplasmic vesicles and lipid droplets were abundant and a decreased expression of both Oct4 and laminin could be observed. Initial hypoblast formation was revealed in almost 1/3 of the LIF-cultured blastocysts whereas this feature was evident in 2/3 of the blastocysts cultured in the absence of LIF. Overall, almost 60% of the blastocysts cultured without LIF formed outgrowth colonies (OCs) when plated on feeders, whereas this phenomenon was only observed in 30% of the blastocysts cultured in the presence of LIF. A tendency for retaining a tightly packed central growth of putative ICM-derived cells was observed, when attachment to the feeder layer was initiated close to the embryonic pole of the blastocyst. At Day 8 of outgrowth culture, approximately 20% of the colonies contained a central core of putative ICM-derived cells appearing large enough for mechanical isolation and further subculture. Immunohistochemical labeling for Oct4 revealed staining of both trophectodermal and ICM-derived cells. The presence of LIF in the outgrowth culture medium did not have any apparent effect on the plating efficiency or colony type. In conclusion, LIF had an adverse effect on in vitro embryonic development when added to the culture medium in the period from Days 5 to 8 p.i., whereas it had no apparent effect on the OCs subsequently formed from such embryos.

[Therapeutic cloning. Biology, perspectives and alternatives]. / Terapeutisk kloning. Biologi, perspektiver og alternativer.

Certain diseases are caused by or cause irreversible loss of cells and may in the future be treated by cell-based therapies where spare cells are introduced into the body. Therapeutic cloning constitutes a scientifically and ethically challenging route to the generation of autologous patient specific spare cells: Stem cells for subsequent differentiation and transplantation are isolated from one week old embryos, which are produced by cloning by nuclear transfer from normal cells retrieved from a patient. Research in therapeutic cloning should be pursued in line with alternative strategies for obtaining stem cells. Finally, the molecular biology of cloning by nuclear transfer may hold the key to understanding trans-differentiation, which ultimately may allow for de-differentiation and subsequent re-differentiation of adult somatic cells for therapeutic purposes.