Project description:Oxygen is vital for the development and survival of mammals. In response to hypoxia, the brain initiates numerous adaptive responses at the organ level as well as at the molecular and cellular level, including the alteration of gene expression. Astrocytes play critical roles in the proper functioning of the brain, thus the manner in which astrocytes respond to hypoxia is likely important in determining the outcome of brain hypoxia. We used microarray gene expression profiling and data analysis algorithms to identify and analyze hypoxia-responsive genes in primary human astrocytes. We also compared the gene expression patterns in astrocytes with those in human HeLa cells and pulmonary artery endothelial cells (ECs). Remarkably, in astrocytes, 5 times as many genes were up-regulated as down-regulated, whereas in HeLa and pulmonary ECs, as many or more genes were down-regulated as up-regulated. More genes encoding hypoxia-inducible functions, such as glycolytic enzymes and angiogenic growth factors, were strongly induced in astrocytes compared to HeLa cells. The extent of induction was also greater than in HeLa cells. Further, gene ontology and computational algorithms revealed that many target genes of the EGF and insulin signaling pathways and the transcriptional regulators Myc, Jun and p53 were selectively altered by hypoxia in astrocytes and HeLa cells to a varying degree. These results provide a global view of the signaling and regulatory network mediating oxygen regulation in astrocytes, in comparison with that in HeLa cells. Experiment Overall Design: Gene expression profiles of three independent batches of astrocytes grown under normoxia were compared to gene expression profiles of three independent batches of astrocytes grown under 1% oxygen for 24 hours. Affymetrix U133 plus 2.0 microarrays were used.

Project description:Oxygen is vital for the development and survival of mammals. In response to hypoxia, the brain initiates numerous adaptive responses at the organ level as well as at the molecular and cellular level, including the alteration of gene expression. Astrocytes play critical roles in the proper functioning of the brain, thus the manner in which astrocytes respond to hypoxia is likely important in determining the outcome of brain hypoxia. We used microarray gene expression profiling and data analysis algorithms to identify and analyze hypoxia-responsive genes in primary human astrocytes. We also compared the gene expression patterns in astrocytes with those in human HeLa cells and pulmonary artery endothelial cells (ECs). Remarkably, in astrocytes, 5 times as many genes were up-regulated as down-regulated, whereas in HeLa and pulmonary ECs, as many or more genes were down-regulated as up-regulated. More genes encoding hypoxia-inducible functions, such as glycolytic enzymes and angiogenic growth factors, were strongly induced in astrocytes compared to HeLa cells. The extent of induction was also greater than in HeLa cells. Further, gene ontology and computational algorithms revealed that many target genes of the EGF and insulin signaling pathways and the transcriptional regulators Myc, Jun and p53 were selectively altered by hypoxia in astrocytes and HeLa cells to a varying degree. These results provide a global view of the signaling and regulatory network mediating oxygen regulation in astrocytes, in comparison with that in HeLa cells. Experiment Overall Design: Gene expression profiles of three independent batches of HeLa cells grown under normoxia were compared to gene expression profiles of three independent batches of HeLa cells grown under 1% oxygen for 24 hours. Affymetrix U133 plus 2.0 microarrays were used.

Project description:Oxygen is vital for the development and survival of mammals. In response to hypoxia, the brain initiates numerous adaptive responses at the organ level as well as at the molecular and cellular level, including the alteration of gene expression. Astrocytes play critical roles in the proper functioning of the brain, thus the manner in which astrocytes respond to hypoxia is likely important in determining the outcome of brain hypoxia. We used microarray gene expression profiling and data analysis algorithms to identify and analyze hypoxia-responsive genes in primary human astrocytes. We also compared the gene expression patterns in astrocytes with those in human HeLa cells and pulmonary artery endothelial cells (ECs). Remarkably, in astrocytes, 5 times as many genes were up-regulated as down-regulated, whereas in HeLa and pulmonary ECs, as many or more genes were down-regulated as up-regulated. More genes encoding hypoxia-inducible functions, such as glycolytic enzymes and angiogenic growth factors, were strongly induced in astrocytes compared to HeLa cells. The extent of induction was also greater than in HeLa cells. Further, gene ontology and computational algorithms revealed that many target genes of the EGF and insulin signaling pathways and the transcriptional regulators Myc, Jun and p53 were selectively altered by hypoxia in astrocytes and HeLa cells to a varying degree. These results provide a global view of the signaling and regulatory network mediating oxygen regulation in astrocytes, in comparison with that in HeLa cells. Keywords: response to hypoxia

Project description:Oxygen is vital for the development and survival of mammals. In response to hypoxia, the brain initiates numerous adaptive responses at the organ level as well as at the molecular and cellular level, including the alteration of gene expression. Astrocytes play critical roles in the proper functioning of the brain, thus the manner in which astrocytes respond to hypoxia is likely important in determining the outcome of brain hypoxia. We used microarray gene expression profiling and data analysis algorithms to identify and analyze hypoxia-responsive genes in primary human astrocytes. We also compared the gene expression patterns in astrocytes with those in human HeLa cells and pulmonary artery endothelial cells (ECs). Remarkably, in astrocytes, 5 times as many genes were up-regulated as down-regulated, whereas in HeLa and pulmonary ECs, as many or more genes were down-regulated as up-regulated. More genes encoding hypoxia-inducible functions, such as glycolytic enzymes and angiogenic growth factors, were strongly induced in astrocytes compared to HeLa cells. The extent of induction was also greater than in HeLa cells. Further, gene ontology and computational algorithms revealed that many target genes of the EGF and insulin signaling pathways and the transcriptional regulators Myc, Jun and p53 were selectively altered by hypoxia in astrocytes and HeLa cells to a varying degree. These results provide a global view of the signaling and regulatory network mediating oxygen regulation in astrocytes, in comparison with that in HeLa cells. Keywords: response to hypoxia

Project description:To investigate the mechansims that underlie astrocyte dedifferentiation, we performed single cell RNA sequencing analysis of primary astrocytes isolated from adult mouse cortex after p53 loss and exposure to mitogens, EGF and and FGF. Primary astrocytes were isolated from cortices of 2-3month old inducible p53 knockout mice (GFAP-CreERT2;p53flox/flox;LSL-tdTomato) using Miltenyi Adult Brain Dissociation kit and ACSA-2 beads. Treatment with 4-hydroxytamoxifen (4OHT) induces p53 loss and tdTomato labelling in GFAP+ astrocytes. Astrocytes were treated with 4OHT in media supplemented with EGF and FGF to induce recombination and astrocyte dedifferentiation in vitro.

Project description:Primary cultures of astrocytes from rat optic nerve heads were treated with EGFR ligand, EGF. Two cell lines from two different rat donors were used. The sister cell cultures were set as control and EGF treated groups. Keywords: rat optic nerve head astrocytes

Project description:Neural stem cells, located in discrete niches in the adult brain, generate new neurons throughout life. These stem cells are specialized astrocytes, but astrocytes in other brain regions (parenchymal astrocytes) do not generate neurons under physiological conditions. After stroke, however, astrocytes in the mouse striatum undergo neurogenesis, triggered by decreased Notch signaling. Notch signaling can be experimentally depleted in mice by deleting the Notch-mediating transcription factor Rbpj. This dataset consists of single-cell RNA sequencing data of astrocytes isolated from the striatum (where astrocytes undergo neurogenesis in response to Rbpj deletion) or somatosensory cortex (where astrocytes don't complete neurogenesis in response to Rbpj deletion) of 4 mice. Cells were isolated from Cx30-CreER; R26-tdTomato; Rbpj(fl/fl) mice at three time points after tamoxifen-induced Rbpj deletion (2, 4, 8 weeks), and from Cx30-CreER; R26-tdTomato mice with intact Rbpj 3 days after tamoxifen. These time points span the transition from astrocyte through transit-amplifying cells to neuroblasts. The dataset contains 1) astrocytes from the striatum that initiate a neurogenic transcriptional program in response to Rbpj deletion and generate transit-amplifying cells and neuroblasts, and 2) astrocytes from the somatosensory cortex that initiate a neurogenic program in response to Rbpj deletion but fail to generate transit-amplifying cells or neuroblasts.

Project description:To investigate the mechansims that underly astrocyte dedifferentiation, we performed single cell RNA sequencing analysis of primary astrocytes after p53 loss and exposure to mitogens, EGF and and FGF. Primary astrocytes were isolated from postnatal day 3 inducible p53 knockout mice (GFAP-CreERT2;p53flox/flox;LSL-tdTomato), whereby treatment with 4-hydroxytamoxifen (4OHT) induces p53 loss and tdTomato labelling in GFAP+ astrocytes. Astrocytes were treated with 4OHT in media supplemented with EGF and FGF to induce recombination and astrocyte dedifferentiation in vitro.

Project description:Primary cultures of astrocytes from rat optic nerve heads were treated with EGFR ligand, EGF. Two cell lines from two different rat donors were used. The sister cell cultures were set as control and EGF treated groups. Experiment Overall Design: experiment #1: compared control astrocyte cultures to sister cultures treated with EGF for 4 hours. Experiment Overall Design: experiment #2: compared control astrocyte cultures to sister cultures treated with EGF for 12 hours

Project description:Uncontrolled accumulation of pulmonary artery smooth muscle cells (PASMC) to the distal pulmonary arterioles (PAs) is one of the major characteristics of pulmonary hypertension (PH). Cellular senescence contributes to aging and lung diseases associated with PH and links to PH progression. However, the mechanism by which cellular senescence controls vascular remodeling in PH is not fully understood. The levels of senescence marker, p16INK4A and senescence-associated β-galactosidase (SA-β-gal) activity are higher in PA endothelial cells (ECs) isolated from idiopathic pulmonary arterial hypertension (IPAH) patients compared to those from healthy individuals. Hypoxia-induced accumulation of α-smooth muscle actin (αSMA)-positive cells to the PAs is attenuated in p16fl/fl-Cdh5(PAC)-CreERT2 (p16iΔEC) mice after tamoxifen induction. We have reported that endothelial TWIST1 mediates hypoxia-induced vascular remodeling by increasing platelet-derived growth factor (PDGFB) expression. Transcriptomic analyses of IPAH patient or hypoxia-induced mouse lung ECs reveal the alteration of senescence-related gene expression and their interaction with TWIST1. Knockdown of p16INK4A attenuates the expression of PDGFB and TWIST1 in IPAH patient PAECs or hypoxia-treated mouse lungs and suppresses accumulation of αSMA–positive cells to the supplemented ECs in the gel implanted on the mouse lungs. Hypoxia-treated mouse lung EC-derived exosomes stimulate DNA synthesis and migration of PASMCs in vitro and in the gel implanted on the mouse lungs, while p16iΔEC mouse lung EC-derived exosomes inhibit the effects. These results suggest that endothelial senescence controls αSMA–positive cell proliferation and migration in PH through TWIST1-PDGFB signaling.