Hematopoietic deficiencies and core binding factor expression in murine Ts16, an animal model for Down syndrome.

Patients with Down syndrome (DS, Trisomy 21) suffer from hematopoietic abnormalities, including an increased risk to develop leukemia. Overexpression of chromosome 21-encoded genes thus leads to hematopoietic deficiencies. Of the genes found within the DS chromosomal region, core binding factor alpha (CBFA) is a candidate whose overexpression could affect hematopoietic development. To learn more about the pathogenesis of hematological diseases in DS, we studied hematopoietic precursor cells in Ts16 mice, an animal model for DS. We found reduced proportions of B lymphoid and myeloid cells in the liver and spleen, whereas the proportion of developing thymocyte populations and that of the erythroid cells in liver and spleen were increased. Furthermore, when analyzing the expression of Cbfa2 in both whole fetuses and isolated thymuses, we found no significant differences in the absolute amount of Cbfa2 mRNA or in the ratio of the isoforms Cbfa2.1 and Cbfa2.2 between Ts16 and diploid samples. Thus, a disequilibrium of Cbfa2 expression and a dysregulation of the two Cbfa2 mRNA species as a cause for the abnormalities in Ts16 fetuses in general and the deficient Ts16 thymocyte development in particular appears unlikely.

Self renewal of embryonic stem cells in the absence of feeder cells and exogenous leukaemia inhibitory factor.

To evaluate the role of leukaemia inhibitory factor (LIF) for maintaining pluripotent embryonic stem (ES) cells in culture, we established several exogenous LIF-independent ES cell lines by continuous passaging in culture. The newly established ES cells, Kli and CBli, sustained their growth and remained undifferentiated in LIF-deficient medium. Analysis of chimaeric animals, produced with the beta-galactosidase transgenic Kli ES cells, revealed that LIF-independent ES cells can contribute to all embryonic germ layers. There was no detectable LIF protein in ES cell conditioned medium, and no upregulation of LIF mRNA was found. The addition of neutralising anti-LIF antibodies was not sufficient to abrogate the self renewal of the Kli ES cells. These studies suggest that the signalling pathway involving diffusible LIF can be bypassed for maintaining the pluripotency in culture, and indicate a considerable heterogeneity in growth factor dependence and differentiation of different ES cells.

Unrestricted lineage differentiation of parthenogenetic ES cells.

The developmental potential of parthenogenetic embryonic stem (P-ES) cells was studied in teratomas and mouse chimaeras. Teratomas derived from P-ES cells contained a mixture of tissue types with variable proportions of specific tissues. Three of the eight P-ES cell lines analysed showed high proportions of striated muscle in teratomas, similar to teratomas from normal embryos or ES cell lines derived from fertilised embryos (F-ES cells). Our study also revealed that one P-ES cell line showed little lineage restriction in injection chimaeras. Descendants of the P-ES cells contributed to most tissues of chimaeric fetuses in patterns similar to F-ES cells. Normal colonisation of muscle, liver and pancreas was found in adult chimaeras. P-ES cells also showed similar haematopoietic differentiation and maturation as F-ES cells. However, extensive P-ES cell contribution was associated with a reduction in body size. These findings suggest that, while P-ES cells display more extensive developmental potential than the cells of parthenogenetic embryos from which they were derived, they only retained properties related to the presence of the maternal genome. To elucidate the molecular basis for the lack of lineage restriction during in vivo differentiation, the expression of four imprinted genes, H19, Igf2r, Igf2 and Snrpn was compared among five P-ES and two F-ES cell lines. Expression levels of these genes varied among the different ES cell lines, both in undifferentiated ES cells and in embryoid bodies.

Estimation of the number of hematopoietic precursor cells during fetal mouse development by covariance analysis.

Differentiation of hematopoietic precursor cells results in the formation of clonally related descendent cells. Using the mosaic expression of beta-galactosidase in female mouse fetuses heterozygous for an X-linked lacZ transgene, we analyzed the clonal relationship of the hematopoietic progeny. The proportion of beta-galactosidase positive cells for different T- and B-lymphoid and myeloid cell populations was determined at different stages of fetal development. We found excellent correlations of the proportion of beta-galactosidase expressing cells for all hematopoietic lineages confirming that they share a common ancestry. Therefore, it was possible to estimate the number of common precursor cells (PC) based on binomial distribution and covariance analysis of pairs of different hematopoietic cell populations. Our results obtained from hematopoietic cells at 15.5 to 18.5 days of gestation indicated the presence of 15 to 18 lymphoid and 18 to 22 myeloid/lymphoid specific precursor cells. Statistical analysis of the precursor cell numbers showed a trend of increasing numbers that was highly significant. The precursor cell number was inversely related to maturity of the cell populations analyzed; ie, the lowest number of lymphoid and lymphoid/myeloid precursors was calculated when the most mature CD3+ T-cell population was used for comparison. Determination of PC numbers can therefore be used to assess the relative maturity and developmental potential of individual cell populations.

Defective chorioallantoic fusion in mid-gestation lethality of parthenogenone<-->tetraploid chimeras.

Previous studies of parthenogenetic embryos revealed severe perturbations of both embryonic and extraembryonic tissue lineages during postimplantation development. The majority of pure parthenogenetic concepti have no recognizable axis and exhibit preferential terminal differentiation of their trophectoderm and primitive endoderm. To further define the role of the extraembryonic lineages in parthenogenetic development, we provided them with zygote-derived extraembryonic tissues by aggregating them with fertilized tetraploid embryos. On Day 12 of combined in vitro and in vivo development, most of the embryos proper in these chimeras were entirely derived parthenogenetically, whereas their trophectoderm and primitive endoderm tissues were derived from the tetraploid component. No Igf2 expression was detected in the parthenogenetic embryo proper, indicating that imprinting was manifested in such chimeras. Typical development of the parthenogenetic embryo proper was markedly improved in comparison with pure parthenogenetic concepti, with such chimeras attaining an average of 23 somites (range, 10 to 35). However, most of the chimeras died abruptly at Day 13, and all were being resorbed at Day 14 of development. The gross normality of axial structures and organ development suggests that a major cause of failure of these chimeric parthenogenones to survive beyond mid-gestation was due to defective chorioallantoic fusion. Our results indicate that the severe perturbation of axial development seen in most pure parthenogenetic concepti is a secondary consequence of the effects of parthenogenesis on the trophectoderm and primitive endoderm lineages. Moreover, the mid-gestation death of parthenogenetic embryos proper despite the presence of zygote-derived tetraploid tissues implicates extraembryonic mesoderm in manifesting the effects of genomic imprinting.

The development of haematopoietic cells is biased in embryonic stem cell chimaeras.

The haematopoietic development of embryonic stem (ES) cell injection chimaeras was analysed using beta-galactosidase expression from an X-linked transgene as a marker to distinguish the ES-derived cell population from the host cells. The number of cells in the different haematopoietic cell subpopulations was determined by flow cytometry. When the proportions of ES-derived cells in the antigen-positive lineages were compared to the ES cell contribution to all cells in teh organs, we found an unexpected bias in the haematopoietic differentiation of ES-derived cells. ES descendants were overrepresented in the bone marrow B lymphoid cell population and the splenic myeloid cells but were underrepresented in the CD4-positive T lymphoid cells in the spleen. These results were obtained by comparison with control female animals that were X chromosome mosaic for beta-galactosidase expression. These findings of uneven contribution to haematopoietic development by ES cells indicate that the commitment of ES cell descendants may be different from that of the host cells.

Simultaneous detection of beta-galactosidase activity and surface antigen expression in viable haematopoietic cells.

The quantitation of intracellular beta-galactosidase activity has been described for viable cells. By using the fluorogenic substrate fluorescein-di-beta-D-galactopyranoside (FDG) in conjunction with flow cytometry, the proportion of positive cells as well as the level of expression can be determined. In this paper we describe beta-galactosidase expression in lymphoid and myeloid cells from transgenic mice that widely express beta-galactosidase from an inserted lacZ transgene. Both foetal and adult haematopoietic tissues are able to express beta-galactosidase. The intracellular fluorescence reflecting beta-galactosidase activity can be readily combined with fluorescently labelled antibodies against cell surface antigens. Thus, beta-galactosidase can be used as a marker in transplantation experiments to study the development of lymphoid and myeloid precursor cells.

Abnormal development of embryonic and extraembryonic cell lineages in parthenogenetic mouse embryos.

Parthenogetically activated, diploid mouse oocytes can develop to midgestation stages in utero. However, even these advanced parthenogenones appear to die because of much reduced trophoblast and yolk sac development. Previous studies have compared the general features of parthenogenetic and androgenetic development and determined the fate of uniparental cells in chimeras with normal embryos. These studies led to the concept of genomic imprinting as the cause for developmental failure when either the maternal or the paternal genome is duplicated, with the corresponding deficiency of the other. Genomic imprinting appears to arise during gametogenesis and to act through dosage effects in a set of imprinted genes, whose expression depends on their parental origin. In this study we undertook a more detailed morphological analysis of parthenogenetic development in the mouse and established a classification system to quantify the developmental extent of parthenogenones. We found that the failure of parthenogenones occurred at different times during early postimplantation development, generating a spectrum of concepti which had developed to different extents, with only a small fraction of the embryos reaching advanced somite stages. In all parthenogenones differentiation and proliferation of the trophectoderm and primitive endoderm lineages (both extraembryonic) was abnormal, and in all, even the best-developed parthenogenones, we observed similar deficiencies in the embryonic lineages, especially the mesoderm. Common to all abnormally developed lineages was that the proportion of undifferentiated precursor cells was much reduced, while their differentiated descendants were relatively abundant. We propose, therefore, that the failure of parthenogenones to develop to term is due to abnormal regulation of differentiation and proliferation in both embryonic and extraembryonic lineages. In this hypothesis, the apparent tissue specific defects observed in parthenogenones arise as a consequence of the functional importance of certain tissues (like the trophoblast) early in development. The spectrum of parthenogenones thus appears to reflect critical events in early development, whose regulation are affected by genomic imprinting.

Insulin-like growth factor II acts through an endogenous growth pathway regulated by imprinting in early mouse embryos.

We present evidence that insulin-like growth factor II (IGF-II) mediates growth in early mouse embryos and forms a pathway in which imprinted genes influence development during preimplantation stages. mRNA and protein for IGF-II were expressed in preimplantation mouse embryos, but the related factors IGF-I and insulin were not. IGF-I and insulin receptors and the IGF-II/mannose-6-phosphate receptor were expressed. Exogenous IGF-II or IGF-I increased the cell number in cultured blastocysts, but a mutant form of IGF-II that strongly binds only the IGF-II receptor did not. Reduction of IGF-II expression by antisense IGF-II oligonucleotides decreased the rate of progression to the blastocyst stage and decreased the cell number in blastocysts. Preimplantation parthenogenetic mouse embryos expressed mRNA for the IGF-II receptor but not for either IGF-II ligand or the IGF-I receptor, indicating that the latter genes are not expressed when inherited maternally. These data imply that some growth factors and receptors, regulated by genomic imprinting, may control cell proliferation from the earliest stages of embryonic development.

Distribution of 5-methylcytosine in the DNA of somatic and germline cells from bovine tissues.

Genomic DNA of calf thymus contains 1.5 times as much 5-methylcytosine as similar sperm DNA, but the major EcoRI repeat fragment from satellite I of thymus contains ten times as much 5-methylcytosine as the corresponding fragment from sperm DNA. Restriction enzyme analyses of the total DNA and the satellite I fragment show that three HpaII sites in the fragment are completely unmethylated in sperm but fully methylated in thymus DNA. Under-methylation of many sites in the satellite DNAs can probably account for the lower level of methylation of sperm DNA rather than hemimethylation as previously suggested. These results are also discussed in relation to maintenance and de novo (initiation-type) methylases.