Project description:Endothelial cell (EC) dysfunction precedes the development of cardiovascular disease in OSA; however, the mechanisms by which ECs respond to these hypoxic events is poorly understood. To better understand EC responses to hypoxia, we examined the effects of both sustained hypoxia (SH) and intermittent hypoxia (IH) on the activation of HIF-1α in Endothelial Cells (ECs). While SH stabilized HIF-1α and led to its nuclear localization, IH didn’t activate HIF-1α and its downsteram gene expression. Using RNA-sequencing, we evaluated transcriptional responses of ECs to hypoxia. SH induced expression of HIF-1α and hypoxia response genes, while IH affected cell-cycle regulation genes.

Project description:Obstructive sleep apnea (OSA) is an independent risk factor for cardiovascular disease. While intermittent hypoxia (IH) and catecholamine release play an important role in this increased risk, the mechanisms are incompletely understood. We have recently reported that IH causes endothelial cell (EC) activation, an early phenomenon in the development of cardiovascular disease, via IH-induced catecholamine release. Here, we investigated the effects of IH and epinephrine on gene expression in human aortic ECs using RNA-sequencing. We found a significant overlap between IH and epinephrine-induced differentially expressed genes (DEGs) including enrichment in leukocyte migration, cytokine-cytokine receptor interaction, cell adhesion and angiogenesis. Epinephrine caused higher number of DEGs compared to IH. Interestingly, IH when combined with epinephrine had an inhibitory effect on epinephrine-induced gene expression. Combination of IH and epinephrine induced MT1G (Metallothionein 1G), which has been shown to be highly expressed in ECs from parts of aorta (i.e., aortic arch) where atherosclerosis is more likely to occur. In conclusion, epinephrine has a greater effect than IH on EC gene expression in terms of number of genes and their expression level. IH inhibited the epinephrine-induced transcriptional response. Further investigation of the interaction between IH and epinephrine is needed to better understand how OSA causes cardiovascular disease.

Project description:we investigated the effects of IH and epinephrine on gene expression in human aortic ECs using RNA-sequencing. We found a significant overlap between IH and epinephrine-induced differentially expressed genes (DEGs).

Project description:Intermittent and sustained hypoxia exposures activate distinct transcriptional responses in human aortic endothelial cells

Project description:Time-course gene expression profiles were obtained from lung tissues of the rats treated with room air, intermittent- (IH) or sustained hypoxia (SH) for 1, 3, 7, 14 and 30 days using CodeLink microarrays. Using a systems biology approach, we observed that two different mechanisms are involved in the lung responses to IH and SH: IH leads to increased G-protein coupled signaling-, ion transport-, neuronal- and steroid hormone receptor activities; whereas SH causes increased blood vessel morphogenesis and immune responses. Our results provide insight into molecular mechanisms underlying IH and SH. Keywords: gene expression array-based, count rats were treated with intermittent- (IH) or sustained hypoxia (SH) for 1, 3, 7, 14 and 30 days; rats treated with room air were used as controls; gene expression profiles were obtained from these rats

Project description:Time-course gene expression profiles were obtained from lung tissues of the rats treated with room air, intermittent- (IH) or sustained hypoxia (SH) for 1, 3, 7, 14 and 30 days using CodeLink microarrays. Using a systems biology approach, we observed that two different mechanisms are involved in the lung responses to IH and SH: IH leads to increased G-protein coupled signaling-, ion transport-, neuronal- and steroid hormone receptor activities; whereas SH causes increased blood vessel morphogenesis and immune responses. Our results provide insight into molecular mechanisms underlying IH and SH. Keywords: gene expression array-based, count

Project description:Venous thromboembolism (VTE) is a common and deadly disease with unclear pathophysiological initiation. Hypoxia and inflammation are believed to contribute to promoting thrombosis, but how and if these potential triggers interact is unclear. We have stimulated primary endothelial cells with sustained and intermittent hypoxia, in the presence or absence of TNF. Effects to the cells were analyzed with RNA sequencing and flow cytometry after 24H and 48H stimulations. RNA sequencing confirmed strong pro-inflammatory effects of TNF, and indicated that hypoxia alone had modest effects, but when combined with TNF there were clear additive effects on the number of differentially expressed genes, as well as modest increases of pro-inflammatory GO terms assessed by GSEA. On protein level, flow cytometry confirmed additive effects of combingin hypoxia and TNF for several adhesion molecules including E-selectin and ICAM-1, as well as on associated molecules including tissue factor. Unsupervised clustering of the flow cytometric data also revealed the expansion of a subset of endothelial cells with strongly pro-thrombotic phenotype. Taken together, our data suggests that hypoxia combines with inflammatory cues in the in vivo situation to promote pro-thrombotic responses by endothelial cells in the venous valve pocket.

Project description:Acute ethanol intoxication is associated with Rapid Alterations in Neuroimmune Gene Expression (RANGE), including increased Interleukin (IL)-6 and Nuclear factor of kappa light polypeptide gene enhancer in B-cells inhibitor, alpha (IκBα), and suppressed IL-1β and Tumor necrosis factor (TNF) α, yet little is known about adaptations in cytokines across the first few ethanol exposures. Thus, the present studies examined central cytokines during intoxication (3h post-ethanol) following 2, 4 or 6 intragastric ethanol challenges (4g/kg) delivered either daily or every-other-day (EOD). Subsequent analyses of blood ethanol concentrations (BECs) and corticosterone were performed to determine whether the schedule of ethanol delivery would alter the pharmacokinetics of, or general sensitivity to, subacute ethanol exposure. As expected, ethanol led to robust increases in IL-6 and IκBα gene expression in hippocampus, amygdala and bed nucleus of the stria terminalis (BNST), whereas IL-1β and TNFα were suppressed, thereby replicating our prior work. Ethanol-dependent increases in IL-6 and IκBα remained significant in all structures - even after 6 days of ethanol. When these doses were administered EOD, modest IL-6 increases in BNST were observed, with TNFα and IL-1β suppressed exclusively in the hippocampus. Analysis of BECs revealed a small but significant reduction in ethanol after 4 EOD exposures - an effect which was not observed when ethanol was delivered after 6 daily intubations. These findings suggest that ethanol-induced RANGE effects are not simply a function of ethanol load per se, and underscore the critical role that ethanol dosing interval plays in determining the neuroimmune consequences of alcohol.

Project description:Although exposure to ambient hypoxia is known to cause proinflammatory vascular responses, the mechanisms initiating these responses are not understood. We tested the hypothesis that in systemic hypoxia, erythrocyte-derived H(2)O(2) induces proinflammatory gene transcription in vascular endothelium. We exposed mice or isolated, perfused murine lungs to 4 hours of hypoxia (8% O(2)). Leukocyte counts increased in the bronchoalveolar lavage. The expression of leukocyte adhesion receptors, reactive oxygen species, and protein tyrosine phosphorylation increased in freshly recovered lung endothelial cells (FLECs). These effects were inhibited by extracellular catalase and by the removal of erythrocytes, indicating that the responses were attributable to erythrocyte-derived H(2)O(2). Concomitant nuclear translocation of the p65 subunit of NF-?B and hypoxia-inducible factor-1? stabilization in FLECs occurred only in the presence of erythrocytes. Hemoglobin binding to the erythrocyte membrane protein, band 3, induced the release of H(2)O(2) from erythrocytes and the p65 translocation in FLECs. These data indicate for the first time, to our knowledge, that erythrocytes are responsible for endothelial transcriptional responses in hypoxia.

Project description:UnlabelledThe molecular networks underlying the lung response to hypoxia are not fully understood. We employed systems biology approaches to study temporal effects of intermittent or sustained hypoxia on gene expression in rat lungs. We obtained gene expression profiles from rats exposed to intermittent or sustained hypoxia lasting 0-30 days and identified differentially expressed genes, their patterns, biological processes, and regulatory networks critical for lung response to intermittent or sustained hypoxia. We validated selected genes with quantitative real-time PCR. Intermittent and sustained hypoxia induced two distinct sets of genes in rat lungs that displayed different temporal expression patterns. Intermittent hypoxia induced genes mostly involved in ion transport and homeostasis, neurological processes, and steroid hormone receptor activity, while sustained hypoxia induced genes principally participating in immune responses. The intermittent hypoxia-activated network suggested a role for cross talk between estrogen receptor 1 (ESR1) and other key proteins in hypoxic responses. The sustained hypoxia-activated network was indicative of vascular remodeling and pulmonary hypertension. We confirmed the temporal expression changes of 12 genes (including the Esr1 gene and 4 ESR1 target genes) in intermittent hypoxia and 8 genes in sustained hypoxia with quantitative real-time PCR.Conclusionsintermittent and sustained hypoxia induced distinct gene expression patterns in rat lungs. The functional characteristics of genes activated by these two distinct perturbations suggest their roles in the downstream physiological effects of intermittent and sustained hypoxia. Our results demonstrate the discovery potential of applying systems biology approaches to the understanding of mechanisms underlying hypoxic lung response.