In eukaryotes, the ability of DNA-binding proteins to act as transcriptional repressors often requires that they recruit accessory proteins, known as corepressors, which provide the activity responsible for silencing transcription. Several of these factors have been identified, including the Groucho (Gro) and Atrophin (Atro) proteins in Drosophila. Here we demonstrate strong genetic interactions between gro and Atro and also with mutations in a third gene, scribbler (sbb), which encodes a nuclear protein of unknown function. We show that mutations in Atro and Sbb have similar phenotypes, including upregulation of the same genes in imaginal discs, which suggests that Sbb cooperates with Atro to provide repressive activity. Comparison of gro and Atro/sbb mutant phenotypes suggests that they do not function together, but instead that they may interact with the same transcription factors, including Engrailed and C15, to provide these proteins with maximal repressive activity.
To study paraxial mesoderm formation in the mouse, transgenic lines that can be used to either selectively delete or express genes of interest in the paraxial mesoderm are required. We have generated a transgenic mouse line that expresses Cre recombinase in the paraxial mesoderm (PAM) beginning at e7.5. A lacZ Cre recombinase reporter line showed that in addition to PAM and its derivatives, lateral plate and intermediate mesoderm derivatives were also exposed to Cre activity, while the node, notochord, and cardiac mesoderm were not. We further demonstrate that 70-75% of the fibroblasts generated from Dll1-msd Cre, ROSA26-rtTA embryos possess Cre recombinase activity. These mice can therefore be used in combination with tet-responsive transgenic lines to generate mesoderm-derived embryonic fibroblasts that inducibly express a gene of interest.
Members of the T-box family of transcription factors play essential roles in cell type specification, differentiation, and proliferation during embryonic development. All T-box family members share a common DNA binding domain - the T-domain - and can therefore recognize similar sequences. Consequently, T-box proteins that are co-expressed during development have the potential to compete for binding at downstream targets. In the mouse, Tbx6 is expressed in the primitive streak and presomitic mesoderm, and is sharply down-regulated upon segmentation of the paraxial mesoderm. We sought to determine the phenotypic and molecular consequences of ectopically expressing Tbx6 within the segmented paraxial mesoderm and its derivatives using a 3-component transgenic system. The vertebral column, ribs, and appendicular skeleton were all affected in these embryos, which resembled Tbx18 and Tbx15 null embryos. We hypothesize that these phenotypes result from competition between the ectopically expressed Tbx6 and the endogenously expressed Tbx18 and Tbx15 at the binding sites of target genes. In vitro luciferase transcriptional assays provide further support for this hypothesis.
Human embryonic stem cells (hESCs) have the capacity to self-renew and to differentiate into all components of the embryonic germ layers (ectoderm, mesoderm, endoderm) and subsequently all cell types that comprise human tissues. HESCs can potentially provide an extraordinary source of cells for tissue engineering and great insight into early embryonic development. Much attention has been given to the possibility that hESCs and their derivatives may someday play major roles in the study of the development, disease therapeutics, and repair of injuries to the central and peripheral nervous systems. This tantalizing promise will be realized only when we understand fundamental biological questions about stem cell growth and development into distinct tissue types. In vitro, differentiation of hESCs into neurons proceeds as a multistep process that in many ways recapitulates development of embryonic neurons. We have found in vitro conditions that promote differentiation of stem cells into neuronal precursor or neuronal progenitor cells. Specifically, we have investigated the ability of two federally approved hESC lines, HSF-6 and H7, to form embryonic and mature neuronal cells in culture. Undifferentiated hESCs stain positively for markers of undifferentiated/pluripotent hESCs including surface glycoproteins, SSEA-3 and 4, and transcription factors Oct-3/4 and Nanog. Using reduced numbers of mouse embryonic fibroblasts as feeder substrates, these markers of pluripotency are lost quickly and replaced by primarily neuroglial phenotypes with only a few cells representing other embryonic germ layer types remaining. Within the first 2 weeks of co-culture with reduced MEFs, the undifferentiated hESCs show progression from neuroectodermal to neural stem cell to maturing and migrating neurons to mature neurons in a stepwise fashion that is dependent on both the type of hESCs and the density of MEFs. In this chapter, we provide the methods for culturing pluripotent hESCs and MEFs, differentiating hESCs using reduced density MEFs, and phenotypic analyses of this culture system.
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