Project description:RNA-sequencing profiling analysis was performed on TS23 humerus tissue from muscle-less mutant (splotch-delayed) mice and compared to control littermates. The purpose of this profiling analysis was to identify differentially expressed genes between muscle-less and control embryonic (TS23) humerus tissue, in order to determine mechanosensitive genes that impact skeletal development.

Project description:Microarray profiling analysis was performed on TS23 humerus tissue from muscle-less mutant (splotch-delayed) mice and compared to control littermates. The purpose of this profiling analysis was to identify differentially expressed genes between muscle-less and control embryonic (TS23) humerus tissue, in order to determine mechanosensitive genes that impact skeletal development.

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 SubSeries listed below.

Project description:Gene transfer of distinct cocktails of transcription factors enables the targeted modification of cell fate. Reprogramming somatic cells to induced pluripotent stem cells (iPSCs) via ectopic expression of the transcription factors Oct4, Sox2, Klf4 and c-Myc allows creation of pluripotent cells with the potential to differentiate into any cell type of the body. To achieve a high degree of biosafety for future application of converted cells, technologies are required to express the required transcription factors without affecting the target cell genome. Retroviral vectors are widely employed gene transfer vehicles and can be converted into transient gene delivery vehicles by mutation of the viral integrase, thus avoiding risks associated with retroviral integration. We improved the retroviral episome transfer system by identifying the most suitable vector architecture, by enhancing episomal expression and by tuning the activity of the transcription factor Oct4. Repeated episomal transductions allowed establishment of stable, fully reversible expression levels over time. Providing proof-of-principle in the reprogramming context, we were able to generate human iPSCs following retroviral episomal transfer of Oct4 in fibroblasts stably expressing Klf4, Sox2 and c-Myc, with a high percentage of clones not carrying residually integrated vector copies. RNA obtained from human embryonic stem cells, fibroblasts and induced pluripotent stem cell lines reprogrammed with the mentioned reprogramming protocol

Project description:Forced expression of pro-neural transcription factors was shown to mediate direct neuronal conversion of human fibroblasts. Since neurons are postmitotic, the conversion efficiency represents an important parameter. Here we present a minimalist approach combining two factor neuronal programming with small molecule-based inhibition of GSK3ß and SMAD signaling, which gives rise to functional neuron-like cells (iNs) of various neurotransmitter phenotypes with an overall yield of up to >200% and a final neuronal purity of up to >80%. Timcourse of reprogramming of fibroblasts towards an neuronal phenotype in two independent fibroblast lines

Project description:RNA-sequencing DE Spd (humerus)

Project description:LCM-RNA-Seq data obtained from chick HH36 chondrocytes and osteoblasts at different stages of differentiation -immature chondrocytes and mature (hypertrophic) chondrocytes- isolated from the head (ceratobranchial) and limb (humerus).

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:Analysis of available RNA crystal structures has allowed us to identify a new family of RNA arrangements that we call double twist-joints, or DTJs. Each DTJ is composed of a double helix that contains two bulges incorporated into different strands and separated from each other by 2 or 3 bp. At each bulge, the double helix is over-twisted, while the unpaired nucleotides of both bulges form a complex network of stacking and hydrogen-bonding with nucleotides of helical regions. In total, we identified 14 DTJ cases, which can be combined in three groups based on common structural characteristics. One DTJ is found in a functional center of the ribosome, another DTJ mediates binding of the pre-tRNA to the RNase P, and two more DTJs form the sensing domains in the glycine riboswitch.

Project description:RNA samples were isolated shaft of the humerus bone of E16.5 embryos. A total of six, three ctrl & three test samples were used. RNASeq analyses were conducted to identify the differentially expressed genes upon Stat3 loss of function during long bone development. Total RNA was isolated from the long bone of E16.5 embryos of the indicated genotypes.