Differentiating mouse embryonic stem cells express markers of human endometrium.

BACKGROUND: Modeling early endometrial differentiation is a crucial step towards understanding the divergent pathways between normal and ectopic endometrial development as seen in endometriosis. METHODS: To investigate these pathways, mouse embryonic stem cells (mESCs) and embryoid bodies (EBs) were differentiated in standard EB medium (EBM). Immunofluorescence (IF) staining and reverse-transcription polymerase chain reaction (RT-PCR) were used to detect expression of human endometrial cell markers on differentiating cells, which were sorted into distinct populations using fluorescence-activated cell sorting (FACS). RESULTS: A subpopulation (50%) of early differentiating mESCs expressed both glandular (CD9) and stromal (CD13) markers of human endometrium, suggestive of a novel endometrial precursor cell population. We further isolated a small population of endometrial mesenchymal stem cells, CD45-/CD146+/PDGFR-ß+, from differentiating EBs, representing 0.7% of total cells. Finally, quantitative PCR demonstrated significantly amplified expression of transcription factors Hoxa10 and Foxa2 in CD13+ EBs isolated by FACS (p = 0.03). CONCLUSIONS: These findings demonstrate that mESCs have the capacity to express human endometrial cell markers and demonstrate potential differentiation pathways of endometrial precursor and mesenchymal stem cells, providing an in vitro system to model early endometrial tissue development. This model represents a key step in elucidating the mechanisms of ectopic endometrial tissue growth. Such a system could enable the development of strategies to prevent endometriosis and identify approaches for non-invasive monitoring of disease progression.

Disruption of local retinoid-mediated gene expression accompanies abnormal development in the mammalian olfactory pathway.

We have evaluated the role of retinoid signaling in the early development of the olfactory epithelium and olfactory bulb. When retinoid-mediated gene expression is blocked briefly in mouse embryos at midgestation with citral (a general alcohol dehydrogenase antagonist that is thought to interfere with retinoid synthesis), the spectrum of morphogenetic abnormalities includes disruption of olfactory pathway development. It is difficult, however, to assess the specificity of this pharmacological manipulation, insofar as it also compromises several other aspects of central nervous system development. In homozygous Pax6 mutant mice (small eye: Pax6(Sey-Neu)), there is a more discrete lesion to the olfactory pathway: The epithelium and bulb cannot be recognized at any time during development, whereas other forebrain subdivisions can still be recognized. This loss of the entire primary olfactory pathway is accompanied by a failure of retinoid-mediated gene expression limited to the frontonasal region and forebrain. Retinoid receptors are expressed in the forebrain of Pax6(Sey-Neu)/Pax6(Sey-Neu) embryos, and the mutant forebrain remains responsive to exogenous retinoic acid. However, in Pax6(Sey-Neu)/ Pax6(Sey-Neu) embryos, retinoic acid (RA) is not produced by the frontonasal mesenchyme, which normally provides local retinoid signals to the placode and forebrain. Together, these results suggest that local retinoid signaling is essential for the normal development of the mammalian olfactory pathway.

Transforming growth factor-beta-3 is mitogenic for rat retinal progenitor cells in vitro.

Recent data indicate that the process of neurogenesis in the mammalian central nervous system (CNS) may be regulated by peptide growth factors, such as epidermal growth factor, transforming growth factor-alpha, and acidic or basic fibroblast growth factor. We have investigated whether members of the transforming growth factor-beta (TGF beta) family also play a role in this process and have found that TGF beta-3 is mitogenic for embryonic rat retinal cells in vitro. We also show that TGF beta-3 stimulates production of retinal amacrine cells while photoreceptor production remains unchanged. These data demonstrate that TGF beta-3 can regulate cell proliferation in the CNS during development and can also influence commitment or differentiation, or both, of neural progenitor cells to particular retinal fates.

EGF and TGF-alpha stimulate retinal neuroepithelial cell proliferation in vitro.

Peptide growth factors have been shown to have diverse effects on cells of the CNS, such as promoting neuronal survival, neurite outgrowth, and several other aspects of neuronal differentiation. In addition, some of these factors have been shown to be mitogenic for particular classes of glial cells within the brain and optic nerve, and recently two peptide growth factors, fibroblast growth factor and nerve growth factor, have been shown to have mitogenic activity on the CNS neuronal progenitors. We now report that two members of another peptide growth factor, epidermal growth factor and transforming growth factor-alpha, are mitogenic for retinal neuroepithelial cells in primary cultures and provide evidence for the presence of both of these factors in normal developing rat retina.