Project description:Gene expression was measured using microarrays in 8 hour postfertilization embryos, comparing control versus ethanol-treated (2 to 8 hours postfertilization) embryos. This experiment was performed to determine the gene expression changes that occur in response to ethanol treatment as a model of fetal alcohol spectrum disorder. Fetal alcohol spectrum disorder (FASD) occurs when pregnant mothers consume alcohol, causing embryonic ethanol exposure and characteristic birth defects that include craniofacial, neural and cardiac defects. Gastrulation is a particularly sensitive developmental stage for teratogen exposure, and zebrafish is an outstanding model to study gastrulation and FASD. Epiboly (spreading blastomere cells over the yolk cell), prechordal plate migration and convergence/extension cell movements are sensitive to early ethanol exposure. Here, experiments are presented to characterize mechanisms of ethanol toxicity on epiboly and gastrulation. Epiboly mechanisms include blastomere radial intercalation cell movements and yolk cell microtubule cytoskeleton pulling the embryo to the vegetal pole. Both of these processes were disrupted by ethanol exposure. Ethanol effects on cell migration also indicated that cell adhesion was affected, which was confirmed by cell aggregation assays. E-cadherin cell adhesion molecule expression and distribution, which control epiboly and gastrulation, were not affected. Gene expression microarray analysis was used to identify potential causative factors for early development defects, and expression of the cell adhesion molecule protocadherin-18a (pcdh18a), which controls epiboly, was significantly reduced in ethanol-exposed embryos. Injecting pcdh18a synthetic mRNA in ethanol-treated embryos partially rescued epiboly cell movements, including enveloping layer cell shape changes. Together, data show that epiboly and gastrulation defects induced by ethanol are multifactorial, and include yolk cell (extraembryonic tissue) microtubule cytoskeleton disruption and blastomere adhesion defects, in part caused by reduced pcdh18a expression. Control vs. ethanol-treated zebrafish embryos that were treated from 2 to 8 hours postfertilization. Total RNA from control and ethanol-treated embryos were harvested at 8 hours postfertilization.

Project description:Ethanol exposure disrupts extraembryonic microtubule cytoskeleton and embryonic blastomere cell adhesion, producing epiboly and gastrulation defects

Project description:Transcriptional profiling of Mtx2 morphants at 30% epiboly stage, shield stage and tailbud stage of embryonic development: Coordinated cell movements of gastrulation reshape the uniform blastula into a structured gastrula with three fundamental axes and an internal germ layer of mesoderm. Genetic regulation of the forces which drive gastrulation is incompletely understood. We employed a microarray screen in zebrafish for genes which participate in epibloy, and identified many with biochemical roles in endocytosis, microtubule remodeling, cell adhesion and transcription.

Project description:Ethanol exposure during prenatal development causes fetal alcohol spectrum disorder (FASD), the most frequent preventable birth defect and neurodevelopmental disability syndrome. The molecular targets of ethanol toxicity during development are poorly understood. Developmental stages surrounding gastrulation are very sensitive to ethanol exposure. To understand the effects of ethanol on early transcripts during embryogenesis, we treated zebrafish embryos with ethanol during pre-gastrulation period and examined the transcripts by Affymetrix GeneChip microarray before gastrulation. We identified 521 significantly dysregulated genes, including 61 transcription factors in ethanol-exposed embryos. Sox2, the key regulator of pluripotency and early development was significantly reduced. Functional annotation analysis showed enrichment in transcription regulation, embryonic axes patterning, and signaling pathways, including Wnt, Notch and retinoic acid. We identified all potential genomic targets of 25 dysregulated transcription factors and compared their interactions with the ethanol-dysregulated genes. This analysis predicted that Sox2 targeted a large number of ethanol-dysregulated genes. A gene regulatory network analysis showed that many of the dysregulated genes are targeted by multiple transcription factors. Injection of sox2 mRNA partially rescued ethanol-induced gene expression, epiboly and gastrulation defects. Additional studies of this ethanol dysregulated network may identify therapeutic targets that coordinately regulate early development.

Project description:The glucose-sensing Mondo pathway regulates expression of metabolic genes in mammals. Here, we have revealed an unexpected role of this pathway in vertebrate embryonic development. We characterized Mondo pathway function in the zebrafish and showed that knock-down of mondoa impaired the early morphogenetic movement of epiboly in zebrafish embryos. Expression of nsdhl , an enzyme of cholesterol and pregnenolone synthesis, was strongly reduced in these embryos. Loss of Nsdhl function likewise impaired epiboly and led to microtubule cytoskeleton defects in the embryo, similar to MondoA loss of function. Both epiboly and microtubule cytoskeleton defects were partially restored by pregnenolone treatment. Gene disruption of mondoa perturbed epiboly with only partial penetrance, likely due to compensatory changes in the expression of cholesterol/steroid metabolism genes. Collectively, our results show a novel role for MondoA in the regulation of early vertebrate development, connecting glucose, cholesterol and steroid hormone metabolism with early embryonic cell movements.

Project description:The glucose-sensing Mondo pathway regulates expression of metabolic genes in mammals. Here, we have revealed an unexpected role of this pathway in vertebrate embryonic development. We characterized Mondo pathway function in the zebrafish and showed that knock-down of mondoa impaired the early morphogenetic movement of epiboly in zebrafish embryos. Expression of nsdhl , an enzyme of cholesterol and pregnenolone synthesis, was strongly reduced in these embryos. Loss of Nsdhl function likewise impaired epiboly and led to microtubule cytoskeleton defects in the embryo, similar to MondoA loss of function. Both epiboly and microtubule cytoskeleton defects were partially restored by pregnenolone treatment. Gene disruption of mondoa perturbed epiboly with only partial penetrance, likely due to compensatory changes in the expression of cholesterol/steroid metabolism genes. Collectively, our results show a novel role for MondoA in the regulation of early vertebrate development, connecting glucose, cholesterol and steroid hormone metabolism with early embryonic cell movements.

Project description:Coordinated cell movements of gastrulation reshape the uniform blastula into a structured gastrula with three fundamental axes and an internal germ layer of mesoderm. Genetic regulation of the forces which drive gastrulation is incompletely understood. We employed a microarray screen in zebrafish for genes which are dynamically expressed during embryonic development. In particular, we were interested in exploring genes that are expressed during the gastrulation.

Project description:Rudhira is essential for mouse developmental angiogenesis and tissue morphogenesis. Embryos lacking endothelial rudhira die at mid-gestation with vascular patterning defects. Rudhira mutant yolk sac endothelial cells show slow and random migration. So to identify key signaling pathways perturbed in the absence of rudhira, we undertook whole transcriptome based analysis of gene expression in rudhira null yolk sac and embryo. Transcriptome analysis shows that key mediators of angiogenesis, cell adhesion, migration and extracellular matrix degradation as well as several components of the TGFβ pathway are perturbed in rudhira null mutant yolk sacs at 9.5 dpc. We used two embryo samples ( 2E- wild type; 5E- rudhira mutant). Repetition was done on each sample. We used 4 yolk sac samples (3Y,4Y- wild type; 7Y,8Y-rudhira mutant) for the analysis. Repetition was done on each sample.

Project description:Rudhira is essential for mouse developmental angiogenesis and tissue morphogenesis. Embryos lacking endothelial rudhira die at mid-gestation with vascular patterning defects. Rudhira mutant yolk sac endothelial cells show slow and random migration. So to identify key signaling pathways perturbed in the absence of rudhira, we undertook whole transcriptome based analysis of gene expression in rudhira null yolk sac and embryo. Transcriptome analysis shows that key mediators of angiogenesis, cell adhesion, migration and extracellular matrix degradation as well as several components of the TGFβ pathway are perturbed in rudhira null mutant yolk sacs at 9.5 dpc.

Project description:Craniofacial and CNS malformations characteristic of Fetal Alcohol Syndrome are caused by alcohol exposure during gastrulation (embryonic day [E]7 in mice; 2nd – 3rd week of human pregnancy). Genetics are a known contributor to differences in alcohol sensitivity in humans, and between different animal model strains such as C57BL/6J and C57BL/6NHsd mice. To investigate how these two genetically similar mouse strains differ in alcohol sensitivity, we profiled gene expression at baseline (E7.0) and 6 or 12 hours after alcohol exposure (E7.25–E7.5) in gastrulation-stage embryos. Many of the baseline transcriptional differences across strains were associated with immune signaling, indicative of their molecular divergence. Alcohol exposure was associated with a more pronounced transcriptional effect in 6J than in 6N, matching the 6J’s increased sensitivity. Alcohol exposure upregulated pathways related to cell death, stress, and hypoxia, and downregulated proliferation and morphogenic pathways. Dysregulated genes were also associated with craniofacial and CNS defects, but only in the 6J embryos. These data demonstrate the genetic variation that can contribute to the effects of prenatal alcohol and identify impacted molecular pathways, including higher baseline expression of inflammatory signaling genes in 6J embryos that likely increases sensitivity to teratogens such as alcohol. Collectively, our data provide a valuable resource that not only enables the discovery of biomarkers pertinent to prenatal alcohol exposure, but also facilitates the transcriptional comparison of two genetically similar mouse strains at three finely resolved developmental timepoints. To this end, we developed a web-based interactive tool to aid in data exploration available at http://parnell-lab.med.unc.edu/Embryo-Transcriptomics/.