Embryonic stem cell differentiation system for evaluating gene functions involved in physiological megakaryocytic differentiation.

Megakaryocytic differentiation is accompanied by marked morphological changes induced by endomitosis and proplatelet formation. Molecular mechanisms underlying this unique cell differentiation process have been investigated by gain/loss-of-function studies using leukemic cell lines. However, these cell lines cannot completely mimic physiological megakaryocytic differentiation, including the morphological changes, and sometimes lead to contradictory results between cell lines. The goal of this study was to establish a novel cell differentiation system that completely mimics physiological megakaryocytic differentiation for analyzing gene function. To that end, we used homologous recombination to prepare an embryonic stem (ES) cell line containing a GFP-transgene driven by the PF4 promoter at the Hprt locus. Differentiation of these cells resulted in megakaryocytes and proplatelets, suggesting physiological megakaryocytic differentiation. However, the number of GFP-expressing cells was low (1.7% GFP(+) cells among CD41(+) cells). Insertion of full-length or small core ß-globin insulators on either side of the transgene significantly increased the number of GFP-expressing cells (∼60% GFP(+) cells among CD41(+) cells), and GFP-expression was specifically observed in megakaryocytic cells. Similar results were obtained with other ES cells containing a GPIIb-GFP transgene. Altogether, we have succeeded in efficiently expressing exogenous genes specifically in differentiating megakaryocytes and in establishing a novel ES cell differentiation system for analyzing gene function involved in physiological megakaryocytic differentiation.

A GABP-binding element in the Robo4 promoter is necessary for endothelial expression in vivo.

We recently demonstrated that the 3-kb 5'-flanking region of the human ROBO4 gene directs endothelial cell-specific expression in vitro and in vivo. Moreover, a GA-binding protein (GABP)-binding motif at -119 was necessary for mediating promoter activity in vitro. The goal of the present study was to confirm the functional relevance of the -119 GABP-binding site in vivo. To that end, the Hprt locus of mice was targeted with a Robo4-LacZ transgenic cassette in which the GABP site was mutated. In other studies, the GABP mutation was introduced into the endogenous mouse Robo4 locus in which LacZ was knocked-in. Compared with their respective controls, the mutant promoters displayed a significant reduction in activity in embryoid bodies, embryos, and adult animals. Together, these data provide strong support for the role of the GABP-binding motif in mediating Robo4 expression in the intact endothelium.

A three-kilobase fragment of the human Robo4 promoter directs cell type-specific expression in endothelium.

Robo4, a member of the roundabout family, is expressed exclusively in endothelial cells and has been implicated in endothelial cell migration and angiogenesis. Here we report the cloning and characterization of the human Robo4 promoter. The 3-kb 5'-flanking region directs endothelial cell-specific expression in vitro. Deletion and mutation analyses revealed the functional importance of two 12-bp palindromic DNA sequences at -2528 and -2941, 2 SP1 consensus motifs at -42 and -153, and an ETS consensus motif at -119. In electrophoretic mobility shift assays using supershifting antibodies, the SP1 motifs bound SP1 protein, whereas the ETS site bound a heterodimeric member of the ETS family, GA binding protein (GABP). These DNA-protein interactions were confirmed by chromatin immunoprecipitation assays. Transfection of primary human endothelial cells with small interfering RNA against GABP and SP1 resulted in a significant (approximately 50%) reduction in endogenous Robo4 mRNA expression. The 3-kb Robo4 promoter was coupled to LacZ, and the resulting cassette was introduced into the Hprt locus of mice by homologous recombination. Reporter gene activity was observed in the vasculature of adult organs (particularly in microvessels), tumor xenografts, and embryos, where it colocalized with the endothelial cell-specific marker CD31. LacZ mRNA levels in adult tissues and tumors correlated with mRNA levels for endogenous Robo4, CD31, and vascular endothelial cadherin. Moreover, the pattern of reporter gene expression was similar to that observed in mice in which LacZ was knocked into the endogenous Robo4 locus. Together, these data suggest that 3-kb upstream promoter of human Robo4 contains information for cell type-specific expression in the intact endothelium.