Project description:Background: Spina bifida is one of the most common and life threatening human congenital defects. Despite considerable effort and investigations, the causes and mechanisms underlying this malformation remain poorly characterized. In order to better understand pathogenesis of this abnormality, we conducted a microarray study to compare gene expression profiles between two mouse models, CLX-Splotch and Fkbp8Gt(neo), that both have spina bifida. Results: To compare the gene expression profiles in these two mouse models we performed microarray analysis using Mouse Whole Genome CodeLink Bioarray. We compared the level of gene expression between wildtype and homozygous mutant embryos in Fkbp8Gt(neo) and CXL-Splotch separately. A total of 54 genes were determined to be differentially expressed (25 down, 29 up) in the posterior neural tube of Fkbp8Gt(neo) mice embryos; while 73 genes were differentially expressed (56 down, 17 up) in the CXL-Splotch mouse. The only two genes that showed decreased expression in both mutants were v-ski sarcoma viral oncogene homolog (Ski) and Zic1, a transcription factor member of the zinc finger family. Interestingly, when Gene Ontology (GO) analysis was performed on all of the differentially expressed genes, there was a striking enrichment of genes associated with mesoderm development and central nervous system development in CLX-Splotch, whereas in Fkbp8Gt(neo) genes involved in dorsal/ventral pattern formation, cell fate specification, and positive regulation of cell differentiation were distinguished. This SuperSeries is composed of the following subset Series: GSE25974: Gene expression-based analysis of neural tube closure for the posterior neuropore of Fkbp8 embryos at E9.5 GSE25975: Gene expression-based analysis of neural tube closure for the posterior neuropore of Splotch embryos at E9.5

Project description:Maternal diabetes is a teratogen that can lead to neural tube closure defects in the offspring. We therefore sought to compare gene expression profiles at the site of neural tube closure between stage-matched embryos from normal dams, and embryos from diabetic dams. Neurulation-stage mouse embryos at 8.5 days of gestation were used to prepare neural tissue at the anterior aspect of neural tube closure site 1. Tissue was procured from the open neural tube immediately anterior of the closure site, and from the closed neural tube immediately posterior to the closure site by laser microdissection. For each sample, 10 sections were pooled, total RNA was extracted, and 7 ng of total RNA were used for expression profiling by Tag sequencing using an Applied Biosystems SolidSAGE kit for library construction, and an AB SOLiD 5500 XL instrument for sequencing. Sequence reads were mapped to RefSeq RNA, and count data per gene were obtained using a modified version of the Applied Biosystems SOLiDâ?¢ SAGEâ?¢ Analysis Software. diabetic dam - closed neural tube // diabetic dam - open neural tube // normal dam - closed neural tube // normal dam - open neural tube

Project description:Neural tube closure defect

Project description:Maternal diabetes is a teratogen that can lead to neural tube closure defects in the offspring. We therefore sought to compare gene expression profiles at the site of neural tube closure between stage-matched embryos from normal dams, and embryos from diabetic dams. Neurulation-stage mouse embryos at 8.5 days of gestation were used to prepare neural tissue at the anterior aspect of neural tube closure site 1. Tissue was procured from the open neural tube immediately anterior of the closure site, and from the closed neural tube immediately posterior to the closure site by laser microdissection. For each sample, 10 sections were pooled, total RNA was extracted, and 7 ng of total RNA were used for expression profiling by Tag sequencing using an Applied Biosystems SolidSAGE kit for library construction, and an AB SOLiD 5500 XL instrument for sequencing. Sequence reads were mapped to RefSeq RNA, and count data per gene were obtained using a modified version of the Applied Biosystems SOLiD™ SAGE™ Analysis Software.

Project description:single-cell sequencing of the mouse cranial region at E8.25 (the start of neural tube closure, at E9.5 (the end of neural tube closure, and of a miR-302 knockout embryo at E9.5 (example of neural tube closure defrect).

Project description:Three wildtype and three nullizygous embryonic posterior neural tube tissues were collected at embryonic day 9.5 and the gene expression patterns were profiled on CodeLink Mouse Whole Genome Bioarrays.

Project description:Three wildtype and three nullizygous embryonic posterior neural tube tissues were collected at embryonic day 9.5 and the gene expression patterns were profiled on CodeLink Mouse Whole Genome Bioarrays.

Project description:Three wildtype and three nullizygous embryonic posterior neural tube tissues were collected at embryonic day 9.5 and the gene expression patterns were profiled on CodeLink Mouse Whole Genome Bioarrays. Wild type versus nullizygous Splotch embryonic tissues were compared individually and as separate groups to determine classifiers and differences in expression due to the nullizygous mutation.

Project description:Three wildtype and three nullizygous embryonic posterior neural tube tissues were collected at embryonic day 9.5 and the gene expression patterns were profiled on CodeLink Mouse Whole Genome Bioarrays. Wild type versus nullizygous Fkbp8 embryonic tissues were compared individually and as separate groups to determine classifiers and differences in expression due to the nullizygous mutation.

Project description:The process of neural tube closure is a highly complex morphogenetic event that results in the generation of the primordial central nervous system. During formation of the neural tube, the non-neural ectoderm separates from the neighboring neural ectoderm and forms a single layer epithelial sheet that overlies the closed neural tube. Previous work has shown that the non-neural ectoderm is necessary for proper cranial neural tube closure, however little is known about this cell population at the molecular level or how the non-neural ectoderm contributes to neural tube closure. In this study, we used a mouse genetic system to fluorescently label the non-neural ectoderm cells and FACS sorted these cells away from the other cell populations in the neural tube. We performed high throughput RNA-sequencing to identify the transcriptome of the non-neural ectoderm and compared the gene expression profile of non-neural ectoderm cells to the remaining population of cells within the neural tube in order to identify which genes are enriched within the non-neural ectoderm. This analysis provides a clue as to which underlying molecular processes may be important for non-neural ectoderm function during neural tube closure.