Ectoderm specification

In Xenopus laevis, the specification of the three germ layers (endoderm, mesoderm and ectoderm) occurs at the blastula stage. Great efforts have been made to determine the factors that specify the endoderm and mesoderm. On the other hand, only a few examples of genes that are required for ectoderm specification have been described in the last decade. The first molecule identified to be required for the specification of ectoderm was the ubiquitin ligase Ectodermin (Ecto, TIF1-γ, TRIM33); later, it was found that the deubiquitinating enzyme, FAM/USP9x, is able to overcome the effects of ubiquitination made by Ectodermin in Smad4 (Dupont et al., 2009). Two transcription factors have been proposed to control gene expression of ectodermal specific genes: POU91/Oct3/4 and FoxIe1/Xema. A new factor specific for the ectoderm, XFDL156, has shown to be essential for suppression of mesoderm differentiation from pluripotent cells.Ectoderm induction in early blastula in Xenopus embryo. In Xenopus laevis, the specification of the three germ layers (endoderm, mesoderm and ectoderm) occurs at the blastula stage. Great efforts have been made to determine the factors that specify the endoderm and mesoderm. On the other hand, only a few examples of genes that are required for ectoderm specification have been described in the last decade. The first molecule identified to be required for the specification of ectoderm was the ubiquitin ligase Ectodermin (Ecto, TIF1-γ, TRIM33); later, it was found that the deubiquitinating enzyme, FAM/USP9x, is able to overcome the effects of ubiquitination made by Ectodermin in Smad4 (Dupont et al., 2009). Two transcription factors have been proposed to control gene expression of ectodermal specific genes: POU91/Oct3/4 and FoxIe1/Xema. A new factor specific for the ectoderm, XFDL156, has shown to be essential for suppression of mesoderm differentiation from pluripotent cells. The protein Ectodermin, firstly identified in Xenopus embryos, promotes ectodermal fate and suppresses the mesoderm formation mediated by the signaling of Transforming Growth Factor β (TGFβ) and Bone Morphogenic Proteins (BMP), members of the TGFβ-superfamily. When the TGFβ ligands bind to TGFβ receptors, they cause the activation of the signal transducers R-Smads (Smad2, Smad3). Smad4 forms a complex with activated R-Smads and activates transcription of specific genes in response to TGFβ signal. The BMP pathway transmits its signals in a similar way but through other types of R-Smads (Smad1, Smad5 and Smad8). The transcription factor Smad4 is the only common mediator shared between both TGFβ and the BMP pathways. During ectoderm specification, the function of Smad4 is regulated by ubiquitination and deubiquitination made by Ectodermin and FAM (acronym of Fat acets in mammals) respectively. The ubiquitination state of Smad4 will determine if it is able to respond to signals derived from TGFβ and BMP. The equilibrium of the activity, localization and timing of TGFβ and BMP transducers, Smad4, FAM and of Ectodermin should be achieved in order to be able to modulate the gene expression of genes required for germ layer formation. A cDNA library from the blastula stage of a frog embryo was cloned into RNA expression plasmids to generate synthetic mRNA. The mRNA was then injected into several Xenopus embryos at a four-cell stage and looked in early blastula embryos for an expansion of the region of the ectodermal marker Sox2 and diminution of the expression of the mesodermal marker Xbra. Ectodermin was one out of 50 clones to present this phenotype when injected into embryos. The identification of FAM was done through a siRNA screen to find deubiquitinases that regulate the response to TGFβ. Ectodermin mRNA is maternally deposited in the animal pole of the egg. In the early blastula stage of the embryo, Ectodermin mRNA and protein forms a gradient that goes from the animal pole (highest concentration) down to the marginal zone (lowest concentration) to prevent TGFβ and nodal signals that induce mesoderm originating from the vegetal pole. Ectodermin mRNA is enriched in the dorsal side of the embryo, and at the end of this stage the expression gradually disappears. Smad4 is ubiquitinated by Ectodermin in the nucleus and exported to the cytoplasm where it can be deubiquitinated by FAM; this way Smad4 can be recycled and be functional again. Although there is no expression profile of FAM in early embryos in Xenopus, in the zebra fish, FAM homolog is expressed ubiquitously at a two-cell stage but as development proceeds then its only expressed in the cephalic central nervous system. Ectodermin is a ubiquitin E3 ligase that inhibits the TGFβ and the BMP signaling pathways by inhibition of Smad4 via ubiquitination of Lysine 519 and also though direct binding to phospho-Smad2. Injection of Ecto mRNA in the marginal zone leads to an expansion of the early ectodermal marker, Sox2, and a reduction of mesodermal markers (Xbra, Eomes, Vent-1, Mix-1 and Mixer). The opposite happens in knockdown experiments of Ectodermin by using a morpholino strategy; embryos become more sensitive to Activin response, they show an increase and expansion of the expression of mesodermal specific genes and down-regulate the expression of neural plate and epidermis marker (Sox2 and cytokeratin respectively). In line with a RING-finger dependent ubiquitin-ligase activity of Ectodermin, an Ecto RING-finger mutant (C97A/C100A) is inactive in gain-of-function. Gain-of-function of FAM increases the responses from BMP and TGFβ and its loss-of-function by mutation in a critical residue for its activity caused inhibition of TGFβ response. The molecular function of human ectodermin to act as a negative regulator of Smad4 suggests that this specific function is conserved among the vertebrate lineage. The sequence identity between FAM homologs is higher than 90% when comparing the homologs of Xenopus, zebrafish, mouse, and human, suggesting that this might also be conserved among other organisms. Indeed, knockout gene inactivation in mouse embryos showed that the function of ectodermin as inhibitor of TGF-beta signaling is conserved. Embryos lacking of ectodermin show defective development of the anterior visceral endoderm (AVE), which is the first tissue that is induced by TGF-beta signals in mouse embryos; in accordance with loss of an inhibitor, ectodermin-/- embryos showed enlarged AVE induction. As the AVE is a natural source of secreted TGF-beta antagonists, this primary AVE expansion caused secondarily, at later stages, an inhibition of extracellular TGF-beta ligands, resulting in embryos lacking of mesoderm development. This model was confirmed by the finding that ectodermin-/- embryos were rescued to wild type (normal AVE, normal mesoderm development) by lowering the genetic dosage of the main TGF-beta ligand of the emrbyo, Nodal. Further supporting a role as TGF-beta inhibitor, tissue-selective deletion of ectodermin from the epiblast (from which the mesoderm, but not the AVE, derive) left the AVE untouched but caused this time an expansion of anterior mesodermal fates, indicative of increased responsiveness to TGF-beta signals. Collectively, these data confirmed with genetic tools a cell-autonomous role for ectodermin as inhibitor of Smad4 responses previously identified in Xenopus embryos and human cell lines. During early in development in Xenopus, the transcription factor FoxI1e/Xema activates epidermal differentiation and represses endoderm and mesoderm specific genes in animal caps (Suri et al., 2005). It is suggested that FoxI1e is active before the ectoderm differentiates into epidermis and the central nervous system. Mir et al., 2005 identified FoxI1e (Xema) by selecting genes that were down-regulated under mesoderm-inducing signals in the ectoderm compared to vegetal region of an early blastula embryo. Also, high expression of this gene was observed in animal caps in embryos that lack VegT compared to wild type. FoxI1e mRNA is expressed zygotically (stage 8.5) and reaches higher level of expression early in gastrulation and maintains that level in neurula, tailbud until early tadpole stages. FoxI1e has a peculiar mosaic expression pattern, it is expressed first in the dorsal ectoderm and while gastrula progresses, the expression goes through the ventral side and its expression is down-regulated in the dorsal side when the neural plate is forming. FoxI1e is dependent on BMP signals in the neurula stage, limiting the localization of FoxI1e to the ventral side of the ectoderm.