Project description:Gestational hypoxia presents a significant stress to an unborn fetus that can lead to significant complications related to fetal growth restriction and resulting in diseases in the newborn as well as those manifesting later in life. Recent evidence indicates that inflammation and oxidative stress are contributing factors to hypoxia-related diseases. The Center for Perinatal Biology at Loma Linda University has studied gestational chronic hypoxia in a sheep model for over 20 years to study dysfunction of vascular and nonvascular tissues derived from mothers, fetuses and offspring. In this project we are attempting to use metabolomics to assess metabolic dysregulation in vascular tissues along with markers of oxidative stress and inflammation in the mother and offspring to determine the extent of dysregulation due to chronic hypoxia. Untargeted metabolomics analysis focused on sheep plasma and arteries from the lung, resistance arteries in the brain, uterine arteries, and cultured human myocytes will be used to explore markers of glucose and lipid metabolism disruption. Targeted analyses of oxylipins and endocannabinoids will be used on the same samples to explore markers of oxidative stress and inflammation, which should be increased during hypoxia. This study should delineate pathways and biomarkers that help explain how hypoxia leads to the development of neonatal as well as adult-onset diseases associated with chronic hypoxia that are inter-related with fetal growth restriction.

Project description:This project seeks to understand the metabolic consequences of gestational hypoxia on fetal, newborn, and adult plasma, arteries and other tissues using a sheep model of fetal growth restriction. Specifically we are interested testing the hypothesis that gestational hypoxia will result in discernable differences in glucose and lipid metabolism in tissues and plasma as well influence indicators of oxidative stress and inflammation. These studies aim to delineate pathways and biomarkers that help explain how hypoxia leads to the development of neonatal as well as adult-onset diseases associated with chronic hypoxia that are inter-related with fetal growth restriction. From a vascular perspective this includes cerebrovascular hemorrhage and pulmonary hypertension in the newborn, but more broadly it includes development of diseases later in life including diabetes, hypertension, and coronary artery disease.

Project description:IL-4-mediated pro-inflammatory vascular responses have been implicated in the pathogenesis of chronic cardiopulmonary diseases. Our results show that hypoxia-induced collagen synthesis and early recruitment of inflammatory cells are significantly less in the lungs of IL-4 knockout (KO) mice than in those of wild-type mice. In addition, we found that IL-4 significantly increased pro-inflammatory genes in primary pulmonary microvascular endothelial cells. This study was designed to identify the gene expression profile of IL-4-dependent pulmonary vascular inflammation induced by hypoxia.

Project description:IGF1R (Insulin-like Growth Factor 1 Receptor) is a ubiquitously expressed transmembrane tyrosine kinase receptor with multiple functions including inflammation. IGF activity maintains human lung homeostasis, being involved in relevant pulmonary diseases with an inflammatory component, such as lung cancer, COPD, asthma and pulmonary fibrosis. Here we examined the role of IGF1R in lung inflammation using mice with a postnatal deficiency of Igf1r and a model of bleomycin(BLM)-induced lung injury. Lung transcriptome analysis of Igf1r-deficient mice showed a general inhibition of transcription of genes related to epigenetics, inflammation/immune response and oxidative stress activity with potential pulmonary protective roles. Early upon intratracheal BLM treatment, mutant mice showed improved survival and milder pulmonary injury and inflammation. Their lungs presented down-regulation of macrophage (Marco/Adgre1), neutrophil-related (Cxcl1/Ly6g), pro-inflammatory (Tnf/Il1b/Il6), endothelial adhesion (Icam1/Pecam1) and alveolar damage (Aqp5/Sftpc) markers and up-regulation of resolution phase markers (Csf1/Il13/Cd209a). Changes in mRNA of IGF system genes were also found, in parallel to a hindered response to hypoxia (Hif1a) and increased expression of the anti-oxidative stress marker Gpx8. These findings identify Igf1r as an important player in oxidative stress and inflammation and suggest that targeting Igf1r may block the inflammatory response in lung diseases with this component.

Project description:sychological stress and affective disorders are clinically associated with hypertension and vascular disease, but the biological links between the conditions have not been fully explored. To examine this relationship, we used chronic social defeat (CSD) stress, which produces anxiety-like and depressive-like behavioral declines in susceptible mice. In such mice, CSD also produces cerebrovascular microbleeds in scattered locations. Here, we showed further evidence of vascular pathology and blood–brain barrier breakdown by visualizing plasma immunoglobulins and erythrocytes within the parenchyma and perivascular spaces of CSD brains. To further characterize the impact of stress on the cerebrovasculature, brain endothelial cells (bECs) were isolated, and global gene expression profiles were generated. Bioinformatic analysis of CSD-induced transcriptional changes in bECs showed enrichment in pathways that delineate the vascular response to injury. These pathways followed a temporal sequence of inflammation, oxidative stress, growth factor signaling, and wound healing (i.e., platelet aggregation, hemostasis, fibrinogen deposition, and angiogenesis). Immunohistochemical staining for markers of fibrinogen deposition and angiogenesis confirmed the existence of the markers at the sites of vascular disruptions. Recovery after CSD cessation was marked by recruitment of leukocytes perhaps participating in vascular repair. The data suggest that co-morbidity of affective disorders and vascular diseases may be attributed in part to a common link in altered endothelial cell function

Project description:Diabetes mellitus is one of the most chronic diseases, of which diabetic cardiomyopathy is the major cause of morbidity and involves in multiple processes such as inflammation, oxidative stress, fibrosis, extracellular collagen deposition, apoptosis, mitochondria dysfunction.

Project description:Angiogenesis and lymphangiogenesis have important roles in cancer progression and chronic inflammatory diseases, but efficient therapies against these diseases have been hampered by the lack of identified vascular lineage-specific markers and growth factors. Using transcriptional profiling of matched pairs of human dermal blood vascular and lymphatic endothelial cells, we first identified 236 lymphatic and 342 blood vascular signature genes. In silico analyses of the biologic pathways associated with these genes revealed lineage-specific functions for each cell type. Using a selection of 85 identified vascular lineage-specific genes, we developed a TaqMan RT-PCR-based, microfluidic card-formatted low-density microvascular differentiation array (LD-MDA) that was used to reliably identify and quantify the degree of lineage-specific differentiation in different types of endothelial cells, and to detect admixture of lymphatic endothelial cells in commercial preparations of microvascular endothelial cells. Application of Prediction Relevance Ranking and analysis of variance of LD-MDA expression profiles of 43 lesional skin samples obtained from patients with the chronic inflammatory disease psoriasis led to identification of cytokines which are significantly associated with angiogenesis or lymphangiogenesis in vivo. In particular, interleukin-7 and fibroblast growth factor-12 were identified as novel (lymph)angiogenic factors. This technology provides a novel tool to quantify lineage-specific vascular differentiation and to characterize (lymph)angiogenesis in clinical samples obtained from angiogenic diseases. This SuperSeries is composed of the following subset Series: GSE11306: Quantification of vascular lineage-specific differentiation (cell type comparison) GSE11307: Quantification of vascular lineage-specific differentiation, psoriasis (chronic inflammation) study Keywords: SuperSeries Refer to individual Series

Project description:Neutrophil oxidative stress mediates obesity-associated vascular inflammation and metastatic transmigration

Project description:Neutrophil oxidative stress mediates obesity-associated vascular inflammation and metastatic transmigration

Project description:Neutrophil oxidative stress mediates obesity-associated vascular inflammation and metastatic transmigration