Project description:To investigate the role of a TIE1-function blocking antibody on gene expression of lung endothelial cells. Lung endothelial cells were FACS-isolated from primary tumor-bearing mice. Mice were treated either with IgG or TIE1-blocking antibody during primary tumor growth. Total RNA were used for microarray analysis using Clariom S mouse assays (Applied Biosystems).

Project description:Expression data from FACS-isolated liver endothelial cells

Project description:Bulk RNA-sequencing of FACS isolated human fetal lung, intestine, and kidney endothelial cells

Project description:Expression data from isolated mouse lung endothelial cells

Project description:Cellular sources of liver endothelial cells remain elusive. Here, we used irradiation-conditioned bone marrow chimeric mice to lineage trace the endothelial cells. Bone marrow-derived (YFP+) and resident (YFP-) liver endothelial cells were isolated and total RNA were used for microarray analysis using Clariom S mouse assays (Applied Biosystems).

Project description:Bulk RNA-sequencing of FACS isolated human fetal lung, intestine, and kidney endothelial cells

Project description:Adult endothelial cells (ECs) are known to possess organ-specific gene expression, morphology and function, but whether organ-specific EC gene expression is present during human development is not known. Here, we used bulk RNA-sequencing (RNA-seq) to interrogate the developing human intestine, lung, and kidney in order to identify organ-enriched EC-gene signatures. FACS was used to isolate EC (CD31+CD144+, n=13) and non-EC (CD31-CD144-, n=16) populations from these three organs, profiling at least 4 biological replicates for each organ system. The biological specimens profiled were between 11-20 gestational weeks. We also sequenced cultured human umbilical vein endothelial cells (HUVECs) via bulk RNAseq. Computational approaches were used to identify organ-specific EC-enriched gene signatures across human fetal lung, intestine, and kidney ECs.

Project description:Following the identification of a critical time window of Blood Brain Barrier formation in the mouse embryo, we aimed to identify genes important for barriergenesis. To this end, we isolated cortical and lung E13.5 endothelial cells and compared expression between the two populations. The working hypothesis was that endothelial cells which are actively building a barrier would have a uniqe pattern of gene expression that would be detectable in comparison to a non-barrier endothelial population that is also active in vasculogenesis. E13.5 Tie2-GFP embryos were micro-dissected for cortex and lungs. Cortex tissue was carefully cleared of the meninges and choroid plexus. FACS purification of GFP positive cells and GeneChip analysis was applied . All material from a single litter (10-13 embryos) was pooled and considered as a biological replicate. n=4 litters.

Project description:We isolated hematopoietic stem and progenitor cells from AML patients by FACS.

Project description:HUVEC-FUCCI cells were used to demonstrate that different endothelial cell cycle states provide distict windows of opportunity for gene expression in response to extrinsic signals. HUVEC-FUCCI were FACS-isolated into three different cell cycle states. Peptide digests from the resulting lysates showed differentially expressed proteins among the three cell cycles. These studies show that endothelial cell cycle state determines the propensity for arterial vs. venous fate specification.