Status of genomic imprinting in epigenetically distinct pluripotent stem cells.

Mouse epiblast stem cells (EpiSCs) derived from postimplantation embryos are developmentally and functionally different from embryonic stem cells (ESCs) generated from blastocysts. EpiSCs require Activin A and FGF2 signaling for self-renewal, similar to human ESCs (hESCs), while mouse ESCs require LIF and BMP4. Unlike ESCs, EpiSCs have undergone X-inactivation, similar to the tendency of hESCs. The shared self-renewal and X-inactivation properties of EpiSCs and hESCs suggest that they have an epigenetic state distinct from ESCs. This hypothesis predicts that EpiSCs would have monoallelic expression of most imprinted genes, like that observed in hESCs. Here, we confirm this prediction. By contrast, we find that mouse induced pluripotent stem cells (iPSCs) tend to lose imprinting similar to mouse ESCs. These findings reveal that iPSCs have an epigenetic status associated with their pluripotent state rather than their developmental origin. Our results also reinforce the view that hESCs and EpiSCs are in vitro counterparts, sharing an epigenetic status distinct from ESCs and iPSCs.

Nuclear transfer-derived epiblast stem cells are transcriptionally and epigenetically distinguishable from their fertilized-derived counterparts.

Mouse embryonic pluripotent stem cells can be obtained from the inner cell mass at the blastocyst stage (embryonic stem cells, ESCs) or from the late epiblast of postimplantation embryos (epiblast stem cells, EpiSCs). During normal development, the transition between these two stages is marked by major epigenetic and transcriptional changes including DNA de novo methylation. These modifications represent an epigenetic mark conserved in ESCs and EpiSCs. Pluripotent ESCs derived from blastocysts generated by nuclear transfer (NT) have been shown to be correctly reprogrammed. However, NT embryos frequently undergo abnormal development. In the present study, we have examined whether pluripotent cells could be derived from the epiblast of postimplantation NT embryos and whether the reprogramming process would affect the epigenetic changes occurring at this stage, which could explain abnormal development of NT embryos. We showed that EpiSCs could be derived with the same efficiency from NT embryos and from their fertilized counterparts. However, gene expression profile analyses showed divergence between fertilized- and nuclear transfer-EpiSCs with a surprising bias in the distribution of the differentially expressed genes, 30% of them being localized on chromosome 11. A majority of these genes were downregulated in NT-EpiSCs and imprinted genes represented a significant fraction of them. Notably, analysis of the epigenetic status of a downregulated imprinted gene in NT-EpiSCs revealed complete methylation of the two alleles. Therefore, EpiSCs derived from NT embryos appear to be incorrectly reprogrammed, indicating that abnormal epigenetic marks are imposed on cells in NT embryos during the transition from early to late epiblast.

Derivation of pluripotent epiblast stem cells from mammalian embryos.

Although the first mouse embryonic stem (ES) cell lines were derived 25 years ago using feeder-layer-based blastocyst cultures, subsequent efforts to extend the approach to other mammals, including both laboratory and domestic species, have been relatively unsuccessful. The most notable exceptions were the derivation of non-human primate ES cell lines followed shortly thereafter by their derivation of human ES cells. Despite the apparent common origin and the similar pluripotency of mouse and human embryonic stem cells, recent studies have revealed that they use different signalling pathways to maintain their pluripotent status. Mouse ES cells depend on leukaemia inhibitory factor and bone morphogenetic protein, whereas their human counterparts rely on activin (INHBA)/nodal (NODAL) and fibroblast growth factor (FGF). Here we show that pluripotent stem cells can be derived from the late epiblast layer of post-implantation mouse and rat embryos using chemically defined, activin-containing culture medium that is sufficient for long-term maintenance of human embryonic stem cells. Our results demonstrate that activin/Nodal signalling has an evolutionarily conserved role in the derivation and the maintenance of pluripotency in these novel stem cells. Epiblast stem cells provide a valuable experimental system for determining whether distinctions between mouse and human embryonic stem cells reflect species differences or diverse temporal origins.

Evidence of macrophage receptors capable of direct recognition of xenogeneic epitopes without opsonization.

BACKGROUND: We have previously demonstrated that porcine livers perfused with human blood remove most of the erythrocytes from three units of human blood over the course of a 72-h extracorporeal perfusion. Red blood cell loss did not appear to involve classical complement pathway-mediated hemolysis, but instead resulted from porcine Kupffer cell phagocytosis. METHODS: We developed a method incorporating collagenase digestion and metrizamide separation to isolate and maintain porcine Kupffer cells in primary culture. An in vitro rosetting assay was used to assess the binding of human and porcine erythrocytes to porcine Kupffer cells. Immunohistochemistry was used to confirm the presence of porcine macrophages. The rosetting assay was quantified using 51Cr-labeling of erythrocytes to assay for both rosette formation and phagocytosis. RESULTS: Porcine Kupffer cells were successfully isolated and maintained in primary culture. The presence of porcine macrophages was confirmed using the monoclonal antibody 74-22-15A. Human, but not porcine, erythrocytes were bound in an in vitro rosetting assay as confirmed by immunohistochemistry, electron microscopy and 51Cr-quantitation. Porcine Kupffer cells bound human erythrocytes regardless of the presence of opsonizing antibody. Approximately 70% of the isolated porcine Kupffer cells demonstrated the capacity to bind non-opsonized human erythrocytes. Phagocytosis was not observed. CONCLUSIONS: Using primary porcine Kupffer cell cultures, we have demonstrated that a subpopulation of porcine macrophages has the ability to recognize specifically xenogeneic human erythrocyte epitopes without the need for prior opsonization. The possibility is discussed that lectin-mediated carbohydrate binding plays a role in the cellular and humoral recognition and rejection of xenografts.