Project description:Diabetes mellitus in early pregnancy is a non–genetic maternal risk factor for neural tube defects, which are associated with dysregulated gene expression and disruption of cellular behaviors. However, the key molecules linking high glucose metabolism to gene dysregulation remain unclear. Here, we report elevation of ATP citrate lyase (ACL), a metabolic enzyme of the glucose–related tricarboxylic acid cycle in brains of DM–induced mouse embryos with neural tube defects. Consistent with high glucose exposure, manipulation of ACL expression controlled the levels of acetyl-CoA and subsequent lysine 27 acetylation of histone H3 (H3K27ac). Inhibition of ACL activity significantly ameliorated diabetes mellitus–induced exencephaly in mouse embryos. Combinational analysis of H3K27ac ChIP-seq and RNA-seq data revealed a genome–wide synergistic dysregulation of 566 genes, among which the most highly upregulated gene was Txnip, which encodes a thioredoxin–interacting protein. Manipulation of ACL expression disrupted the levels of TXNIP protein, subsequent phosphorylation of apoptosis signal–regulating kinase 1 (ASK1) and neuroepithelial apoptosis. Such pathogenic pathway involving high glucose–induced ACL–H3K27ac, increased–TXNIP upregulation and excessive apoptosis was validated in human embryonic brain tissue affected by neural tube defects. Our study uncovers an intermediary role of ACL in linking high glucose metabolism to epigenetic alterations and neural tube defect formation.

Project description:Exposure to ionizing radiation around the time of neural tube closure results in a number of developmental defects, including neural tube defects (e.g. exencephaly, cleft palate) and eye defects (e.g. microphtalmos, anaphtalmos). These defects result from perturbed neural tube closure and development of the presumptive eye. In order to better understand the underlying molecular mechanisms, gene expression profiling was performed in heads of mouse embryos at embryonic day 9, after they had been irradiated at embryonic day 7.5 with 1 Gy of X-rays. Non-irradiated mice served as controls for differential gene expression.

Project description:CRISPR/Cas9-mediated gene-editing allows manipulation of a gene of interest in its own chromosomal context. When applied to the analysis of protein interaction, and in contrast to an exogenous expression of a protein, these can be studied maintaining physiological stochiometries, topology and context. We have used CRISPR/Cas9-mediated recombination to Cluap1/ IFT38, a component of the intraflagellar transport complex B (IFT-B). Cluap1 has been implicated in human development as well as in cancer progression. Cluap1 loss of function results in early developmental defects with neural tube closure, sonic hedgehog signaling and left-right defects. Herein, we generated an endogenously tagged Cluap1 for protein complex analysis which was then correlated to the corresponding interactome determined by ectopic expression.

Project description:Background The vitamin A derivative, retinoic acid (RA), is a potent teratogenic agent that induces a variety of congenital abnormalities including neural tube defects. The embryopathology of RA has been extensively investigated and retinol receptors play important roles during organogenesis, development and neural tube closure. Still, the mechanisms by which RA influences these processes are not completely understood. Methods We used a custom-made mouse genome 32K oligonucleotide microarray to determine the gene expression profiles of mouse embryo spinal cord samples that had been exposed to vehicle or RA. Then, we performed a GSEA (gene set enrichment analysis) on the gene expression data by searching MSigDB (v2.5) c2 gene sets (canonical pathways) and c5 gene sets (curated GO terms), with set size restraints on the range to avoid over-narrow or over-broad categories. Results Using microarray technology, the present study identifies 85 genes in the spinal cord that exhibit at least a 1.5-fold change between control samples and samples with spina bifida aperta. A gene set enrichment analysis showed that maternal exposure to RA induced spinal bifida that were associated with altered expression of genes involved in pro- or anti-apoptosis, cell proliferation, migration, cytoskeleton components, and cell or focal adhesion, indicating that defective functions of these cell components and biological processes preceded the abnormal development of neural tube. Conclusions Maternal exposure to RA induced spinal bifida that were associated with altered expression of genes involved in pro- or anti-apoptosis, cell proliferation, migration, cytoskeleton components, and cell or focal adhesion. As shown in previous reports, defective functions of these cell components and biological processes preceded the abnormal development of the neural tube. Our study will help the understanding of the etiology and pathology of spinal bifida. However, it should be noted that the changes in gene expression induced by RA exposure may not be an effect on events other than neural tube closure; further study is required to fully understand the molecular mechanisms and consequence of neural tube defects in embryos exposed to RA. Our study provides a global analysis of gene expression patterns in spina bifida and will help the understanding of the etiology and pathology of neural tube defects. We assessed the changes in gene expression that coincide with spina bifida in RA-treated mouse fetuses. After generating an independent list of regulated genes, we analyzed samples by gene set enrichment analysis to expand our results. A pool of spinal cord tissue from spina bifida fetuses whose mothers were exposed to RA was compared to a pool of spinal cord tissue from fetuses whose mothers were exposed to olive oil vehicle. Three replicates each.

Project description:Background The vitamin A derivative, retinoic acid (RA), is a potent teratogenic agent that induces a variety of congenital abnormalities including neural tube defects. The embryopathology of RA has been extensively investigated and retinol receptors play important roles during organogenesis, development and neural tube closure. Still, the mechanisms by which RA influences these processes are not completely understood. Methods We used a custom-made mouse genome 32K oligonucleotide microarray to determine the gene expression profiles of mouse embryo spinal cord samples that had been exposed to vehicle or RA. Then, we performed a GSEA (gene set enrichment analysis) on the gene expression data by searching MSigDB (v2.5) c2 gene sets (canonical pathways) and c5 gene sets (curated GO terms), with set size restraints on the range to avoid over-narrow or over-broad categories. Results Using microarray technology, the present study identifies 85 genes in the spinal cord that exhibit at least a 1.5-fold change between control samples and samples with spina bifida aperta. A gene set enrichment analysis showed that maternal exposure to RA induced spinal bifida that were associated with altered expression of genes involved in pro- or anti-apoptosis, cell proliferation, migration, cytoskeleton components, and cell or focal adhesion, indicating that defective functions of these cell components and biological processes preceded the abnormal development of neural tube. Conclusions Maternal exposure to RA induced spinal bifida that were associated with altered expression of genes involved in pro- or anti-apoptosis, cell proliferation, migration, cytoskeleton components, and cell or focal adhesion. As shown in previous reports, defective functions of these cell components and biological processes preceded the abnormal development of the neural tube. Our study will help the understanding of the etiology and pathology of spinal bifida. However, it should be noted that the changes in gene expression induced by RA exposure may not be an effect on events other than neural tube closure; further study is required to fully understand the molecular mechanisms and consequence of neural tube defects in embryos exposed to RA. Our study provides a global analysis of gene expression patterns in spina bifida and will help the understanding of the etiology and pathology of neural tube defects.

Project description:The MondoA transcription factor forms a heterocomplex with its obligate partner Mlx to regulate ~75% of glucose-dependent transcription. By mediating glucose-induced activation of thioredoxin-interacting protein (TXNIP), MondoA directly represses glucose uptake. Given the predominant role of MondoA in controlling glucose-dependent transcription and glucose uptake, we asked whether glutamine regulates MondoA activity. Expression profiles from glucose and glutamine starved BxPC-3 cells (-G-Q) were compared with those from cells grown in glucose only (+G-Q), glutamine only (-G+Q) or glucose plus glutamine (+G+Q). As expected, TXNIP expression was highly induced by glucose. However, the addition of glutamine repressed the glucose-dependent induction of TXNIP. We show that glutamine inhibits MondoA-dependent transcriptional activation of TXNIP by triggering the recruitment of a histone deacetylase-dependent corepressor to the amino terminus of MondoA. Consistent with the repression of TXNIP, glucose uptake is elevated in cells grown in the presence of glucose and glutamine. Finally, alpha-ketoglutarate, a tricarboxylic acid cycle intermediate, also blocks MondoA-dependent activation of TXNIP and stimulates glucose uptake. Together, these results suggest that glutamine-dependent mitochondrial anapleurosis stimulates glucose uptake by restricting TXNIP expression via MondoA:Mlx complexes. Four growth conditons; four biological replicates

Project description:The MondoA transcription factor forms a heterocomplex with its obligate partner Mlx to regulate ~75% of glucose-dependent transcription. By mediating glucose-induced activation of thioredoxin-interacting protein (TXNIP), MondoA directly represses glucose uptake. Given the predominant role of MondoA in controlling glucose-dependent transcription and glucose uptake, we asked whether glutamine regulates MondoA activity. Expression profiles from glucose and glutamine starved BxPC-3 cells (-G-Q) were compared with those from cells grown in glucose only (+G-Q), glutamine only (-G+Q) or glucose plus glutamine (+G+Q). As expected, TXNIP expression was highly induced by glucose. However, the addition of glutamine repressed the glucose-dependent induction of TXNIP. We show that glutamine inhibits MondoA-dependent transcriptional activation of TXNIP by triggering the recruitment of a histone deacetylase-dependent corepressor to the amino terminus of MondoA. Consistent with the repression of TXNIP, glucose uptake is elevated in cells grown in the presence of glucose and glutamine. Finally, alpha-ketoglutarate, a tricarboxylic acid cycle intermediate, also blocks MondoA-dependent activation of TXNIP and stimulates glucose uptake. Together, these results suggest that glutamine-dependent mitochondrial anapleurosis stimulates glucose uptake by restricting TXNIP expression via MondoA:Mlx complexes.

Project description:CIDR Genome-Wide Association Study of Neural Tube Defects

Project description:CIDR Genome-Wide Association Study of Neural Tube Defects

Project description:To better understand the role of Geminin during germ layer specification, we bred floxed Geminin mice to Mox2-Cre mice. Mutants (fl/fl; cre/o) had spinal neural tube defects with complete penetrance. We obtained neural tube and paraxial tissue by laser capture microdissection and analyzed total RNA by microarray. Spinal neural tube and paraxial tissue were obtained separately by laser capture microdissection from wild-type and mutant E10.5 embryos. There were 2 replicates of each sample.