Project description:A balance between cell survival and apoptosis is essential for animal development. Although proper development involves multiple interactions between germ layers, little is known about the intercellular and intertissue signaling pathways that promote cell survival in neighboring or distant germ layers . We show that serum- and glucocorticoid-inducible kinase 1 (SGK1) promoted ectodermal cell survival during early Xenopus embryogenesis through a non-cell-autonomous mechanism. Dorsal depletion of SGK1 in Xenopus embryos resulted in shortened axes and reduced head structures with defective eyes, and ventral depletion led to defective tail morphologies. Although the gene encoding SGK1 was mainly expressed in the endoderm and dorsal mesoderm, knockdown of SGK1 caused excessive apoptosis in the ectoderm. SGK1-depleted ectodermal explants showed little or no apoptosis, suggesting non-cell-autonomous effects of SGK1 on ectodermal cells. Microarray analysis revealed that SGK1 knockdown increased the expression of genes encoding FADD and caspase-10, components of the death-inducing signaling complex (DISC). Inhibition of DISC function suppressed excessive apoptosis in SGK1-knockdown embryos. SGK1 acted through the transcription factor nuclear factor kappaB to stimulate production of bone morphogenetic protein 7 (BMP7), and overexpression of BMP7 in SGK1-knockdown embryos reduced the abundance of DISC components. We show that phosphoinositide 3-kinase (PI3K) functioned upstream of SGK1, thus revealing an endodermal and mesodermal pathway from PI3K to SGK1 to NF-kappaB that produces BMP7, which provides a survival signal to the ectoderm by decreasing DISC function.

Project description:The Xenopus POU class V transcription factor XOct-25 has been shown to inhibit BMP-dependent epidermal differentiation and promote neural induction in the ectoderm during early embryogenesis. In order to identify genes that act downstream of XOct-25, transcriptional profile of Xenopus ectodermal cells overexpressing XOct-25 was compared with control cells by using a DNA microarray method. Two independent experiments. Each experiment contains ectodermal cells overexpressing XOct-25 and corresponding control cells. Xenopus embryos were injected at the 8-cell stage with mRNA encoding GR-XOct-25, a hormone-inducible version of XOct-25. Explants from stage 9 embryos were treated with or without dexamethazone (DEX) until the sibling embryos reached stage 10.5, when they were used for RNA extraction. The explants cultured without DEX was used as a control sample. biological replicates: Sample name XOct-exp 1, Sample name XOct-exp 2

Project description:Sox9 acts together with Sox5 or Sox6 as a master regulator for chondrocyte differentiation; however, how these transcription factors functionally interact and collaborate to regulate chondrogenesis remains unclear. Here we show that the protein kinase MLTK plays an essential role in the onset of chondrogenesis through triggering the induction of Sox6 by Sox9. Knockdown of MLTK in Xenopus embryos results in drastic loss of craniofacial cartilages without defects in neural crest formation. We also find that Sox6 is specifically induced during craniofacial chondrogenesis and this induction is inhibited by MLTK knockdown. Remarkably, Sox6-knockdown embryos display essentially the same phenotype as the MLTK-knockdown embryos; the drastic loss of cartilages and the marked down-regulation of genes involved in chondrogenesis. Microarray analysis reveals a remarkable similarity between Sox6-depleted and MLTK-depleted embryos in their gene expression pattern. Moreover, we find that ectopic expression of MLTK can induce Sox6 expression in a Sox9-dependent manner. These results identify a novel, key regulator for chondrogenesis. We used microarrays to describe the genome-wide gene expression profiles of xMLTK-depleted and xSox6-depleted embryos. CoMO, xMLTK-MO, or xSox6-MO was injected into the animal pole of all blastomeres (10 ng/cell) at the four-cell stage. The heads of embryos were cut out and harvested at 72 hours after fertilization (corresponding to about stage 41). Total RNA was extracted using TRIsol reagent, treated with DNase (TURBO DNase, Ambion), and then purified using RNeasy Mini Kit (QIAGEN) according to the manufacturerM-bM-^@M-^Ys instruction. The quality of total RNA was assessed using the Agilent 2100 BioAnalyzer. Reverse transcription to synthesize first-strand cDNA, second-strand cDNA synthesis, in vitro transcription to synthesize Biotin-modified aRNA, aRNA purification and fragmentation of the labeled aRNA were performed using the GeneChip 3M-bM-^@M-^Y IVT Express Kit and hybridization to the Affymetrix GeneChip Xenopus laevis Genome 2.0 Array was performed using the GeneChip Hybridization Wash and Stain Kit according to the manufacturerM-bM-^@M-^Ys instruction. Hybridized arrays were scanned using an Affymetrix GeneChip Scanner. Scanned Chip images were analyzed with GeneChip operating Software v.1.4 (GCOS) and GeneSpring GX 11.0.2. (Agilent technologies).

Project description:Transcriptional targets of neurogenin (Ngnr1) were identified by over-expression of an inducible form of neurogenin in Xenopus ectodermal explants. The effects of co-expressing the nucleoprotein geminin on Ngnr1-dependent target gene transactivation were defined. Regulating the transition from lineage-restricted progenitors to terminally differentiated cells is a central aspect of nervous system development. Here, we investigated the role of the nucleoprotein geminin in regulating neurogenesis at a mechanistic level during both Xenopus primary neurogenesis and mammalian neuronal differentiation in vitro. The latter work utilized both neural cells derived from embryonic stem and embryonal carcinoma cells in vitro and neural stem cells from mouse forebrain. In all of these contexts, geminin antagonized the ability of neural bHLH transcription factors to activate transcriptional programs promoting neurogenesis. Furthermore, geminin promoted a bivalent chromatin state, characterized by the presence of both activating and repressive histone modifications, at genes encoding transcription factors that promote neurogenesis. This epigenetic state restrains the expression of genes that regulate commitment of undifferentiated stem and neuronal precursor cells to neuronal lineages. Geminin is highly expressed in undifferentiated neuronal precursor cells but is downregulated prior to differentiation. Therefore, these data support a model whereby geminin promotes the neuronal precursor cell state by modulating both the epigenetic status and expression of genes encoding neurogenesis-promoting factors. Additional developmental signals acting in these cells can then control their transition toward terminal neuronal or glial differentiation during mammalian neurogenesis. A dexamethasone-inducible (GR ligand binding domain fused) form of Xenopus neurogenin-related 1, NgnrGR, was over-expressed in Xenopus embryonic ectodermal explants, in the presence or absence of over-expressed geminin. Induction of Ngnr1 activity was used to define direct targets as previously described (EMBO J. 26(24): 5093-5108). The ability of geminin to suppress Ngnr1-dependent transactivation of its target gene programs was determined.

Project description:Post-translational modifications (PTMs) of histones exert fundamental roles in regulating gene expression. During development, groups of PTMs are constrained by unknown mechanisms into combinatorial patterns, which facilitate transitions from uncommitted embryonic cells into differentiated somatic cell lineages. Repressive histone modifications such as H3K9me3 or H3K27me3 have been investigated in detail, but the role of H4K20me3 in development is currently unknown. Here we show that Xenopus laevis Suv4-20h1 and h2 histone methyltransferases (HMTases) are essential for induction and differentiation of the neuroectoderm. Morpholino-mediated knockdown of the two HMTases leads to a selective and specific downregulation of genes controlling neural induction, thereby effectively blocking differentiation of the neuroectoderm. Global transcriptome analysis supports the notion that these effects arise from the transcriptional deregulation of specific genes rather than widespread, pleiotropic effects. Interestingly, morphant embryos fail to repress the Oct4-related Xenopus gene Oct-25. We validate Oct-25 as direct target of xSu4-20h enzyme-mediated gene repression, showing by chromatin immunoprecipitaton that it is decorated with the H4K20me3 mark downstream of the promoter in normal, but not in double-morphant, embryos. Since knockdown of Oct-25 protein significantly rescues the neural differentiation defect in xSuv4-20h double-morphant embryos, we conclude that the epistatic relationship between Suv4- 20h enzymes and Oct-25 controls the transit from pluripotent to differentiation-competent neural cells. Consistent with these results in Xenopus, murine Suv4-20h1/h2 double-knockout embryonic stem (DKO ES) cells exhibit increased Oct4 protein levels before and during EB formation, and reveal a compromised and biased capacity for in vitro differentiation, when compared to normal ES cells. Together, these results suggest a regulatory mechanism, conserved between amphibian and mammals, in which H4K20me3-dependent restriction of specific POU-V genes directs cell fate decisions, when embryonic cells exit the pluripotent state. Total RNA samples from Xenopus laevis embryos. Transcript levels were analyzed after injection of control or Suv420 morpholinos into blastomeres.

Project description:Variation in gene expression is known to be important for morphological evolution, however little is known about its general propensity. Here we examine a pair of frogs M-bM-^@M-^S Xenopus laevis and Xenopus tropicalis M-bM-^@M-^S with highly similar embryology, and ask how their transcriptomes compare. Despite separation for over ~30-90 million years we found a strong conservation in gene expression in the vast majority of the expressed orthologs. There were a significant number of changes in the level of expression of genes. Changes in timing of expression, heterochrony, were much less common, and were often found in genes and pathways that reflect responses to selective features of the environment. Differences in gene expression levels were concentrated in the earliest embryonic stages. We propose that different evolutionary rates across developmental stages may be explained by the stabilization of cell fate determination pathways in later stages. 96 microarrays, across developmental stages in Xenopus laevis and Xenopus tropicalis in wildtype embryos. For each of the two timecourse indepenent triplicates (clutches) were generated.

Project description:Identification of FOLR1-interacting proteins in Xenopus laevis embryos during neurulation.

Project description:Percellome analysis of whole Xenopus embryos at developmental stage 18 Xenopus embryos were treated with TTNPB (RAR-agonist), AGN193109 (RAR-antagonist), or Control Vehicle at Nieuwkoop and Faber Stage 7. Embryos were collected at stage 18, followed by RNA extraction, hybridization on Affymetrix microarrays, and Percellome analysis.

Project description:Analysis of epithelial explants injected with the intracellular domain of Notch (ICD) to block the formation of multi-ciliate and proton secreting cells or with dominant negative human Mastermind (HMM) or a DNA binding mutant of Mastermind (DBM) to induce the formation of ectopic multi-ciliate and proton secreting cells. Results show which genes are up or down-regulated when DBM/HMM are compared to ICD. Epithelial cells projecting hundreds of motile cilia are prominent in the respiratory system, brain ependyma and female reproductive tract where they generate a vigorous fluid flow along luminal surfaces. Despite their importance for organ function, how multiciliate cells arise developmentally in diverse epithelia is poorly understood. Notch signaling has been shown in a variety of tissues, including the Xenopus epithelium, to regulate the formation of multiciliate cell precursors. In order to identify early downstream targets of Notch signaling which contribute to multiciliate cell fate we blocked or activated Notch signaling in explants of Xenopus epithelium and looked at changes in gene expression to identify candidates that regulate multiciliate cell fate. Here we identify a novel coiled-coil protein, called multicilin (MCI), whose expression is Notch-regulated and restricted to epithelia where multiciliate cells forms in Xenopus embryos. Inhibiting MCI activity blocks the formation of multiciliate cell precursors while ectopic MCI activity is sufficient to induce multiciliate cell differentiation within epithelial progenitors. 2-cell stage Xenopus embryos were injected with synthetic mRNA encoding ICD, DBM or HMM. At stage 9/10 the presumptive ectoderm was cut off the embryo and cultured on a fibronectin coated coverslip. At stage 12 RNA was harvested from explants and used as the starting material for arrays.

Project description:Endogenous bioelectric signaling via changes in cellular resting potential (Vmem) is a key regulator of patterning during regeneration and embryogenesis in numerous model systems. Depolarization of Vmem has been functionally implicated in de-differentiation, tumorigenesis, anatomical re-specification, and appendage regeneration. However, no unbiased analyses have been performed to understand genome-wide transcriptional responses to Vmem change in vivo. Moreover, it is unknown which genes or gene networks represent conserved targets of bioelectrical signaling across different patterning contexts and species. Here, we use microarray analysis to comparatively analyze transcriptional responses to specific Vmem depolarization. We compare the response of the transcriptome during embryogenesis (Xenopus development), regeneration (Axolotl regeneration), and stem cell differentiation (human mesenchymal stem cells in culture) to identify common networks across model species that are associated with depolarization. Both sub-network enrichment and PANTHER analyses identified a number of key genetic modules as targets of Vmem change, and also revealed important (well-conserved) commonalities in bioelectric signal transduction, despite highly diverse experimental contexts and species. Depolarization regulates specific transcriptional networks across all three germ layers (ectoderm, mesoderm and endoderm) such as cell differentiation and apoptosis, and this information will be used for developing mechanistic models of bioelectric regulation of patterning. Moreover, our analysis reveals that Vmem change regulates transcripts related to important disease pathways such as cancer and neurodegeneration, which may represent novel targets for emerging electroceutical therapies. Xenopus laevis embryos were fertilized in vitro according to standard protocols (Sive 2000) in 0.1X Marc’s Modified Ringer’s (MMR; 10mM Na+, 0.2mM K+,10.5mM Cl, 0.2 mM Ca2+, pH 7.8). Intracellular ion concentrations in Xenopus embryo are: 21mM Na+, 90mM K+, 60mM Cl-, 0.5mM Ca2+ (Gillespie 1983). Xenopus embryos were housed at 14-18oC and staged according to Nieuwkoop and Faber (Nieuwkoop 1967). All experiments were approved by the Tufts University Animal Research Committee (M2014-79) in accordance with the guide for care and use of laboratory animals. Capped synthetic mRNAs generated using mMessage mMachine kit (Ambion) were dissolved in nuclease free water and injected into the embryos in 3% Ficoll using standard methods (Sive 2000). Each injection delivered between 1-2 nL or 1– 2 ng of mRNA (per blastomere) into the embryos, usually at 4-cell stage into the middle of the cell in the animal pole. Constructs used were: GlyR (Davies et al. 2003) and 666 chimera (Hough et al. 2000).