Project description:Exostosin 1 (Ext1) is a glycosyltransferase involved in the biosynthesis of the extracellular matrix Heparan Sulfate Proteoglycan (HSPG). Knockdown of Ext1 caused gastrulation defects and formation of an abnormal body axis. Since ext1 has been implicated as an indirect contributor to multiple signaling pathways in vertebrate development, microarray was used to identify genes expressed in gastrulae that would be affected by a reduction in ext1 expression. Microarray-based comparisons of gene expression in control vs. Ext1 MO embryos showed that Ext1 is involved in regulating genes that are related to metabolic process, development and signaling pathways. Half of the hits from the microarray are uncharacterized genes. Approximately forty-five percent of genes are related to metabolic process and thirty percent of genes are belonged to signaling and developmental process categories. Ten percent of each up-regulated and down-regulated gene set is predicted to function in establishment of localization by GO, which is consistent with EXT1 being involved in the movement of extracellular substances. The transcription factors or signaling protein, Isl1, Pitx2, TBX5A, Wnt5A, Wnt7A, WT1, Pax3, Wnt1, and Xbra were identified as Ext1 regulated genes. This analysis investigating the role of Ext1 during gastrulation and provide the information that EXT1 plays an important role in Xenopus early development. Exostosin 1 (EXT1) is a glycosyltransferase involved in the biosynthesis of the extracellular matrix Heparan Sulfate Proteoglycan (HSPG). Knockdown of EXT1 caused gastrulation defects and formation of an abnormal body axis. Since ext1 has been implicated as an indirect contributor to multiple signaling pathways in vertebrate development, microarray was used to identify genes expressed in gastrulae that would be affected by a reduction in ext1 expression. Microarray-based comparisons of gene expression in control vs. EXT1 MO embryos showed that EXT1 is involved in regulating genes that are related to metabolic process, development and signaling pathways. Half of the hits from the microarray are uncharacterized genes. Approximately forty-five percent of genes are related to metabolic process and thirty percent of genes are belonged to signaling and developmental process categories. Ten percent of each up-regulated and down-regulated gene set is predicted to function in establishment of localization by GO, which is consistent with EXT1 being involved in the movement of extracellular substances. The transcription factors or signaling protein, Isl1, Pitx2, TBX5A, Wnt5A, Wnt7A, WT1, Pax3, Wnt1, and Xbra were identified as EXT1 regulated genes. This analysis investigating the role of EXT1 during gastrulation and provide the information that EXT1 plays an important role in Xenopus early development.

Project description:Experiment consisted of MO knockdown of emc1 in Xenopus and comparison of proteome in emc1 depleted stage 24 embryos vs MO control injected embryos.

Project description:The vertebrate body plan is established through inductive signaling during gastrulation via a signaling center, which is called the Spemann-Mangold organizer (SMO) in the developmental model Xenopus laevis, the South African Clawed Frog. Here, we performed a multiplexed quantitative proteomic screen of the SMO in contrast with the rest of the embryo (RE). Wild-type embryos were cultured to the 32-cell stage, where precursor cells of the SMO were injected with a fluorescent lineage tracing dye. These experimental embryos were cultured to stage 10 (beginning of gastrulation), whence the fluorescently labelled cells were dissected. The proteome of the SMO and the RE were quantified using multiplexing quantification. The tissue samples were processed using a bottom-up proteomic workflow and analyzed using LC-MS3. The resulting data revealed an upregulation of oxidative phosphorylation (OXPHOS) in the SMO tissues.

Project description:Left-right axis determination is a fundamental and conserved developmental process, with consequences for human pathology. At the molecular level, this process requires at least two centers of nodal-type TGFbeta signals: the first center, containing nodal/Xn; Microarrays were used to determine differences in gene expression in posterior mesoderm of Xenopus embryos. We compared controls and Derriere depleted embryos. Experiment Overall Design: Microarrays were used to determine differences in gene expression in posterior mesoderm of Xenopus embryos. We compared controls and embryos depleted of Derriere protein using MO oligonucleotides.

Project description:In this study we have examine the deposition of H3K4me1,H3K4Me3 and H3K27Ac and the Nodal transcription factor, Smad2/3, immediately following zygotic transcription and continuing through gastrulation. We profiled 4 histone modifications (H3K4Me3, H3K27Me3, H3K27AC, H3K4Me1) and one transcription factor smad2/3 (+ chromatin input) using ChIP-Seq, and expression profiles (3' RNA-Seq) for Xenopus tropicalis embryos stage8, stage9 and stage10.5. Furthermore, we have profile two histone modifications (H3K4Me1 and H3K27Ac) in absance of nodal signaling in stage9 Xenopus tropicalis embryos using ChIP-seq and 3-seq

Project description:Studies of the Xenopus organizer have laid the foundation for our understanding of the conserved signaling pathways that pattern vertebrate embryos during gastrulation. Here, we use this wealth of knowledge as leverage in the design and analysis of a genomic visualization of organizer-related gene transcription. Using ectopic expression of the two major activities of the organizer, BMP and Wnt inhibition, as well as endogenous tissues, we generate a focused set of samples that represent different aspects of organizer signaling. The genomic expression values of each sample are then measured with oligonucleotide arrays. From this data, genes regulated by organizer signaling are selected and then clustered by their patterns of regulation. A new GO biological process annotation of the Xenopus genome allows us to rapidly identify clusters that are highly enriched for known gastrula patterning genes. Within these clusters, we can predict the expression patterns of unknown genes with remarkable accuracy, leading to the discovery of new organizer-related gastrula stage expression patterns for 19 genes. Moreover, the patterns of gene response observed within these clusters allow us to parse apart the contributions of BMP and Wnt inhibition in organizer function. We find that the majority of gastrula patterning genes respond transcriptionally to these activities according to only a few stereotyped patterns, allowing us to describe suites of genes that are likely to share similar regulatory mechanisms. These suites of genes demonstrate a mechanism where BMP inhibition initiates the organizer program before gastrulation, and Wnt inhibition maintains and drives the organizer program during gastrulation. Keywords: development, organizer, noggin, dkk-1, xenopus, gastrulation

Project description:Studies of the Xenopus organizer have laid the foundation for our understanding of the conserved signaling pathways that pattern vertebrate embryos during gastrulation. Here, we use this wealth of knowledge as leverage in the design and analysis of a genomic visualization of organizer-related gene transcription. Using ectopic expression of the two major activities of the organizer, BMP and Wnt inhibition, as well as endogenous tissues, we generate a focused set of samples that represent different aspects of organizer signaling. The genomic expression values of each sample are then measured with oligonucleotide arrays. From this data, genes regulated by organizer signaling are selected and then clustered by their patterns of regulation. A new GO biological process annotation of the Xenopus genome allows us to rapidly identify clusters that are highly enriched for known gastrula patterning genes. Within these clusters, we can predict the expression patterns of unknown genes with remarkable accuracy, leading to the discovery of new organizer-related gastrula stage expression patterns for 19 genes. Moreover, the patterns of gene response observed within these clusters allow us to parse apart the contributions of BMP and Wnt inhibition in organizer function. We find that the majority of gastrula patterning genes respond transcriptionally to these activities according to only a few stereotyped patterns, allowing us to describe suites of genes that are likely to share similar regulatory mechanisms. These suites of genes demonstrate a mechanism where BMP inhibition initiates the organizer program before gastrulation, and Wnt inhibition maintains and drives the organizer program during gastrulation. Experiment Overall Design: In order to describe and separate the genomic expression changes induced by the two main organizing activities, BMP inhibition and Wnt inhibition, we created a panel of gastrula stage ventral tissues that ectopically overexpressed one or both of these activities, and compared these samples to endogenous dorsal and ventral gastrula stage tissue. Two well-studied organizer secreted factors, Noggin and Dickkopf-1 (Dkk-1), were used to ectopically inhibit BMP and Wnt signaling, respectively. Four different overexpression mixtures were injected ventrally into 4-cell embryos: noggin and eGFP (anti-BMP); noggin, dkk-1, and eGFP (anti-BMP and anti-Wnt); dkk-1 and eGFP (anti-Wnt); and eGFP alone. eGFP mRNA was used to trace targeting. Plasmid DNA was used for noggin and dkk-1 overexpression, instead of mRNA, in order to limit ectopic expression of these genes to post-MBT stages, more closely mimicking the endogenous regulation of these genes. The ventrally injected embryos were grown to early stage 10, sorted for appropriately targeted eGFP florescence, and then bisected between the dorsal and ventral halves at either stage 10 (early gastrula) or stage 11.5 (late gastrula). For the noggin and/or dkk-1 injected embryos, only the ventral halves of the embryos were saved, eliminating endogenous organizer tissues. For the embryos injected with only eGFP, both the ventral and dorsal halves were saved, creating separate ventral and dorsal control conditions. These five conditions were each generated twice at both stage 10 and 11.5, with each set of five samples coming from a single clutch of embryos, creating twenty total tissue samples from 4 different clutches. For each batch of injections some sorted embryos were allowed to develop through tailbud stages in order to validate the phenotypes induced by our constructs. Total RNA was then isolated from the twenty tissue samples and applied to Affymetrix oligonucleotide arrays.

Project description:The aim of the approach was to use RNAseq analysis to identify genes expressed in Xenopus epicardium that were affected by embryonic depletion of the epicardial transcription factor Tcf21 compared to control-MO injected siblings. Both upregulated and downregulated genes were validated by RT-PCR and whole embryo in situ hybridization to validate gene expression and assess spatio-temporal distribution of genes of interest within the heart and epicardium. Approximately 70-100 stage 44-46 Xenopus laevis hearts were dissected to isolate total mRNA from which poly-adenylated RNA was extracted using the Illumina standard protocol. This experiment represents one replicate from pooled hearts. mRNA profiles of stage 44-45 Xenopus laevis sibling hearts from control or Tcf21-depleted embryos, were generated by deep sequencing using Illumina GAII.

Project description:The influence of the extracellular matrix (ECM) within the stem cell niche remains poorly understood. We found that Syndecan-4 (Sdc4) and Frizzled-7 (Fzd7) form a coreceptor complex in satellite cells and that binding of the ECM glycoprotein Fibronectin (FN) to Sdc4 stimulates the ability of Wnt7a to induce the symmetric expansion of satellite stem cells. Newly activated satellite cells dynamically remodel their niche via transient high-level expression of FN. Knockdown of FN in prospectively isolated satellite cells severely impaired their ability to repopulate the satellite cell niche. Conversely, in vivo overexpression of FN with Wnt7a dramatically stimulated the expansion of satellite stem cells in regenerating muscle. Therefore, activating satellite cells remodel their niche through autologous expression of FN that provides feedback to stimulate Wnt7a signaling through the Fzd7/Sdc4 coreceptor complex. Thus, FN and Wnt7a together regulate the homeostatic levels of satellite stem cells and satellite myogenic cells during regenerative myogenesis. The data set contains one microarray of pooled quiescent skeletal muscle satellite cells

Project description:A large number of congenital hearing loss cases have an unknown genetic etiology. So far, transcriptomic approaches have successfully identified many candidate regulators of otic development, little is known about the abundance of their protein products during the development of the inner eat. Herein we used a multiplexed quantitative mass spectrometry-based proteomic approach to determine temporal trends in protein abundances during inner ear (otic) development in Xenopus. Wild type Xenopus embryos were cultured to larval stages and their otic tissues were manually dissected at five stages that represent that represent key transitions in otic morphology. The samples were processed using a bottom-up proteomic workflow and analyzed using LC-MS3.The analysis revealed dynamic expression of proteins related to cytoskeletal regulation, integrin signaling, and the extracellular matrix as inner ear structures developed. We correlated the dynamically regulated proteins in our dataset with previously published putative downstream targets of syndromic hearing loss genes SIX1 and CHD7 to identify novel candidate genes for congenital hearing loss.