The murine blastocyst contains two nonoverlapping pools of progenitor cells: the embryonic component contributes to the fetus and generates embryonic stem cells in vitro, whereas the extraembryonic pool contributes to the placenta and generates trophoblast stem cells in vitro. The transcriptional repressor Foxd3 is required for maintenance of the epiblast and the in vitro establishment of embryonic stem cell lines. Here, we demonstrate that Foxd3 is also required in the trophoblast lineage. Trophoblast progenitors in Foxd3-/- embryos do not self-renew and are not multipotent, but instead give rise to an excess of trophoblast giant cells. Injection of Foxd3-/- blastocysts with wild type ES cells fails to rescue Foxd3-/- placentas and such chimeras die around 10 days of embryogenesis. These results indicate an essential role for Foxd3 in two nonoverlapping progenitor cell populations that require different secreted factors to maintain their multipotent properties in vitro and give rise to divergent tissues in vivo. Moreover, this provides support for the hypothesis that there are conserved molecular mechanisms for maintaining the self-renewing properties of diverse progenitor cell types.

Identification of multipotent cardiac progenitors has provided important insights into the mechanisms of myocardial lineage specification, yet has done little to clarify the origin of the endocardium. Despite its essential role in heart development, characterization of the endocardial lineage has been limited by the lack of specific markers of this early vascular subpopulation. To distinguish endocardium from other vasculature, we generated an NFATc1-nuc-LacZ BAC transgenic mouse line capable of labeling this specific endothelial subpopulation at the earliest stages of cardiac development. To further characterize endocardiogenesis, embryonic stem cells (ESCs) derived from NFATc1-nuc-LacZ blastocysts were utilized to demonstrate that endocardial differentiation in vitro recapitulates the close temporal-spatial relationship observed between myocardium and endocardium seen in vivo. Endocardium is specified as a cardiac cell lineage, independent from other vascular populations, responding to BMP and Wnt signals that enhance cardiomyocyte differentiation. Furthermore, a population of Flk1+ cardiovascular progenitors, distinct from hemangioblast precursors, represents a mesodermal precursor of the endocardial endothelium, as well as other cardiovascular lineages. Taken together, these studies emphasize that the endocardium is a unique cardiac lineage and provides further evidence that endocardium and myocardium are derived from a common precursor.