Identification of inflammatory gene modules based on variations of human endothelial cell responses to oxidized lipids
Oxidized phospholipids are thought to promote atherogenesis by stimulating endothelial cells (ECs) to produce inflammatory cytokines, such as IL-8. In studies with mouse models, we previously demonstrated that genetic variation in inflammatory responses of endothelial cells to oxidized lipids contributes importantly to atherosclerosis susceptibility. We now show that similar variations occur in cultured aortic ECs derived from multiple heart transplant donors. These variations were stably maintained between passages and, thus, reflect either genetic or epigenetic regulatory differences. Expression array analysis of aortic EC cultures derived from 12 individuals revealed that >1,000 genes were regulated by oxidized phospholipids. We have used the observed variations in the sampled population to construct a gene coexpression network comprised of 15 modules of highly connected genes. We show that several identified modules are significantly enriched in genes for known pathways and confirm a module enriched for unfolded protein response (UPR) genes using siRNA and the UPR inducer tunicamycin. On the basis of the constructed network, we predicted that a gene of unknown function (MGC4504) present in the UPR module is a target for UPR transcriptional activator ATF4. Our data also indicate that IL-8 is present in the UPR module and is regulated, in part, by the UPR. We validate these by using siRNA. In conclusion, we show that interindividual variability can be used to group genes into pathways and predict gene-gene regulatory relationships, thus identifying targets potentially involved in susceptibility to common diseases such as atherosclerosis.genetic ͉ interleukin 8 ͉ atherosclerosis ͉ unfolded protein response ͉ network A therosclerosis, the major cause of heart disease, is characterized by the accumulation of cholesterol, inflammatory cells, smooth muscle cells, and fibrous elements beneath the endothelial cell (EC) monolayer that lines the artery wall (1). Although numerous risk factors for atherosclerosis, such as elevated blood pressure, hypercholesterolemia, and smoking, have been recognized, these factors do not alone account for the genetic contribution to risk (2). An important mechanism contributing to the recruitment of inflammatory cells in atherosclerosis is the induction of adhesion molecules, growth factors, and cytokines in vascular ECs by oxidized phospholipids, such as oxidized 1-palmitoyl-2-arachidonyl-sn-3-glycero-phosphorylcholine (oxPAPC) derived from lipoproteins trapped in the vessel wall (3).We have previously demonstrated that ECs from different strains of mice show differences in the induction of inflammatory genes when treated with oxidized lipoproteins, and that these differences segregate with susceptibility to atherosclerosis (4, 5). Studies in human populations show significant variability in the plasma levels of inflammatory mediators associated with atherosclerosis, including IL-8 and C-reactive protein (6-8). The plasma levels of cytokines are influenced by genetic and environmenta...
Objective-Oxidized 1-palmitoyl-2-arachidonyl-sn-3-glycero-phosphorylcholine (oxPAPC) accumulates in atherosclerotic lesions and in vitro studies suggest that it mediates chronic inflammatory response in endothelial cells (ECs). The goal of our studies was to identify pathways mediating the induction of inflammatory genes by oxPAPC. Methods and Results-Using expression arrays, quantitative polymerase chain reaction (PCR), and immunoblotting we demonstrate that oxPAPC leads to endoplasmic reticulum stress and activation of the unfolded protein response (UPR) in human aortic ECs. Immunohistochemistry analysis of human atherosclerotic lesions indicated that UPR is induced in areas containing oxidized phospholipids. Using the UPR inducing agent tunicamycin and selective siRNA targeting of the ATF4 and XBP1 branches of the UPR, we demonstrate that these transcription factors are essential mediators of IL8, IL6, and MCP1 expression in human aortic ECs required for maximal inflammatory gene expression in the basal state and after oxPAPC treatment. We also identify a novel oxPAPC-induced chemokine, the CXC motif ligand 3 (CXCL3), and show that its expression requires XBP1. Conclusions-These
Emerging literature suggests that metabolic pathways play an important role in the maintenance and progression of human cancers. In particular, recent studies have implicated lipid biosynthesis and desaturation as a requirement for tumor cell survival. In the studies reported here, we aimed to understand whether tumor cells require the activity of either human isoform of stearoyl-CoA-desaturase (SCD1 or SCD5) for survival. Inhibition of SCD1 by siRNA or a small molecule antagonist results in strong induction of apoptosis and growth inhibition, when tumor cells are cultured in reduced (2%) serum conditions, but has little impact on cells cultured in 10% serum. Depletion of SCD5 had minimal effects on cell growth or apoptosis. Consistent with the observed dependence on SCD1, but not SCD5, levels of SCD1 protein increased in response to decreasing serum levels. Both induction of SCD1 protein and sensitivity to growth inhibition by SCD1 inhibition could be reversed by supplementing growth media with unsaturated fatty acids, the product of the enzymatic reaction catalyzed by SCD1. Transcription profiling of cells treated with an SCD inhibitor revealed strong induction of markers of endoplasmic reticulum stress. Underscoring its importance in cancer, SCD1 protein was found to be highly expressed in a large percentage of human cancer specimens. SCD inhibition resulted in tumor growth delay in a human gastric cancer xenograft model. Altogether, these results suggest that desaturated fatty acids are required for tumor cell survival and that SCD may represent a viable target for the development of novel agents for cancer therapy. Mol Cancer Res; 9(11); 1551-61. Ó2011 AACR.
SUMMARY Insulin Resistance (IR) is a complex trait with multiple genetic and environmental components. Confounded by large differences between the sexes, environment and disease pathology, the genetic basis of IR has been difficult to dissect. Here we examine IR and related traits in a diverse population of more than 100 unique male and female inbred mouse strains after feeding a diet rich in fat and refined carbohydrates. Our results show dramatic variation in IR among strains of mice and widespread differences between sexes that is dependent on genotype. We uncover more than 15 genome-wide significant loci and validate a gene, Agpat5, associated with IR. We also integrate plasma metabolite levels and global gene expression from liver and adipose tissue to identify metabolite Quantitative Trait Loci (mQTL) and expression QTL (eQTL), respectively. Our results provide a resource for analysis of interactions between diet, sex and genetic background in IR.
Tyrosine 1101 of Tie2 Is the Major Site of Association of p85 and Is Required for Activation of Phosphatidylinositol 3-Kinase and Akt
Tie2 is an endothelium-specific receptor tyrosine kinase that is required for both normal embryonic vascular development and tumor angiogenesis and is thought to play a role in vascular maintenance. However, the signaling pathways responsible for the function of Tie2 remain unknown. In this report, we demonstrate that the p85 subunit of phosphatidylinositol 3-kinase (PI3-kinase) associates with Tie2 and that this association confers functional lipid kinase activity. Mutation of tyrosine 1101 of Tie2 abrogated p85 association both in vitro and in vivo in yeast. Tie2 was found to activate PI3-kinase in vivo as demonstrated by direct measurement of increases in cellular phosphatidylinositol 3-phosphate and phosphatidylinositol 3,4-bisphosphate, by plasma membrane translocation of a green fluorescent protein-Akt pleckstrin homology domain fusion protein, and by downstream activation of the Akt kinase. Activation of PI3-kinase was abrogated in these assays by mutation of Y1101 to phenylalanine, consistent with a requirement for this residue for p85 association with Tie2. These results suggest that activation of PI3-kinase and Akt may in part account for Tie2's role in both embryonic vascular development and pathologic angiogenesis, and they are consistent with a role for Tie2 in endothelial cell survival.Tie2 (also called Tek) is a member of a novel family of receptor tyrosine kinases (RTKs) (16,17,37,42,72) that are expressed predominantly on endothelial cells or their embryonic precursors (14,16,17,37,42) and that are required for normal vascular development (15,52,55). Functional disruption of Tie2 in transgenic mice results in embryonic lethality by day E9.5 to 10.5 with effects on the microvasculature resulting in reduced numbers of endothelial cells and abnormalities of vascular morphogenesis (15,55). Knockout of the activating Tie2 ligand, angiopoietin-1 (Ang1), or overexpression of a related, inhibitory ligand, angiopoietin-2 (Ang2), resulted in phenotypes similar to the Tie2 knockout (43, 64). Taken together, these findings suggest a role for Tie2 in endothelial cell maintenance, survival, and/or vascular morphogenesis (24).In addition to a role in embryonic vascular development, data from our laboratory suggest that Tie2 plays an important role in the adult vasculature. For example, Tie2 expression is increased in the vasculature of malignant breast tumors (49), and a soluble extracellular domain of Tie2 inhibits tumor angiogenesis and growth (39). Tie2 is also broadly expressed and tyrosine phosphorylated in a variety of adult tissues in which the endothelium is normally quiescent (69). These findings are consistent with a dual role for Tie2 in both the growth and the maintenance of the adult vasculature.To better understand the role of Tie2 in vascular growth and maintenance, it will be important to identify the signal transduction pathways responsible for these functions. Currently, little is known about the specific signaling proteins and pathways utilized by Tie2. We demonstrated previously that Tie2 a...
The clinical features of long QT syndrome result from episodic life-threatening cardiac arrhythmias, specifically the polymorphic ventricular tachycardia torsades de pointes. KVLQT1 has been established as the human chromosome 11-linked gene responsible for more than 50% of inherited long QT syndrome. Here we describe the cloning of a full-length KVLQT1 cDNA and its functional expression. KVLQT1 encodes a 676-amino acid polypeptide with structural characteristics similar to voltage-gated potassium channels. Expression of KvLQT1 in Xenopus oocytes and in human embryonic kidney cells elicits a rapidly activating, K ؉ -selective outward current. The I Kr -specific blockers, E-4031 and dofetilide, do not inhibit KvLQT1, whereas clofilium, a class III antiarrhythmic agent with the propensity to induce torsades de pointes, substantially inhibits the current. Elevation of cAMP levels in oocytes nearly doubles the amplitude of KvLQT1 currents. Coexpression of minK with KvLQT1 results in a conductance with pharmacological and biophysical properties more similar to I Ks than other known delayed rectifier K ؉ currents in the heart.
The inherent heterogeneity of bone cells complicates the interpretation of microarray studies designed to identify genes highly associated with osteoblast differentiation. To overcome this problem, we have utilized Col1a1 promoter-green fluorescent protein transgenic mouse lines to isolate bone cells at distinct stages of osteoprogenitor maturation. Comparison of gene expression patterns from unsorted or isolated sorted bone cell populations at days 7 and 17 of calvarial cultures revealed an increased specificity regarding which genes are selectively expressed in a subset of bone cell types during differentiation. Furthermore, distinctly different patterns of gene expression associated with major signaling pathways (Igf1, Bmp, and Wnt) were observed at different levels of maturation. Some of our data differ from current models of osteoprogenitor cell differentiation and emphasize components of the pathways that were not revealed in studies based on a total cell population. Thus, applying methods to generate more homogeneous populations of cells at a defined level of cellular differentiation from a primary osteogenic culture is feasible and leads to a novel interpretation of the gene expression associated with increasing levels of osteoprogenitor maturation.
Benign familial neonatal convulsions (BFNC), a class of idiopathic generalized epilepsy, is an autosomal dominantly inherited disorder of newborns. BFNC has been linked to mutations in two putative K ؉ channel genes, KCNQ2 and KCNQ3. Amino acid sequence comparison reveals that both genes share strong homology to Kv-LQT1, the potassium channel encoded by KCNQ1, which is responsible for over 50% of inherited long QT syndrome. Here we describe the cloning, functional expression, and characterization of K ؉ channels encoded by KCNQ2 and KCNQ3 cDNAs. Individually, expression of KCNQ2 or KCNQ3 in Xenopus oocytes elicits voltagegated, rapidly activating K ؉ -selective currents similar to KCNQ1. However, unlike KCNQ1, KCNQ2 and KCNQ3 currents are not augmented by coexpression with the KCNQ1  subunit, KCNE1 (minK, IsK). Northern blot analyses reveal that KCNQ2 and KCNQ3 exhibit similar expression patterns in different regions within the brain. Interestingly, coexpression of KCNQ2 and KCNQ3 results in a substantial synergistic increase in current amplitude. Coexpression of KCNE1 with the two channels strongly suppressed current amplitude and slowed kinetics of activation. The pharmacological and biophysical properties of the K ؉ currents observed in the coinjected oocytes differ somewhat from those observed after injecting either KCNQ2 or KCNQ3 by itself. The functional interaction between KCNQ2 and KCNQ3 provides a framework for understanding how mutations in either channel can cause a form of idiopathic generalized epilepsy.Potassium channels are the largest and most diverse group of ion channels. They are primary regulators of resting membrane potential and action potential configuration and, therefore, modulate excitability of neurons, cardiac myocytes, and other electrically active cells. Recent identification of KCNQ1 (KvLQT1), the gene responsible for more than 50% of inherited cardiac long QT syndrome (LQTS), 1 established a new family of six-transmembrane domain K ϩ channels (1). KCNQ1, in combination with the KCNE1 subunit, encodes the slow component of the cardiac delayed rectifier K ϩ current (2-4), and mutations in KCNQ1, which occur in LQTS patients, partially or completely inhibit the channel in a dominant-negative fashion (5, 6). In an attempt to identify additional members of the KCNQ1 K ϩ channel gene family, the KCNQ1 sequence was used to search DNA and protein sequence data banks. Two additional KCNQ1-related genes, KCNQ2 and KCNQ3, were identified.Recent publications indicate that mutations in KCNQ2 or KCNQ3 are associated with BFNC, an autosomal dominantly inherited epilepsy in newborns (7-9). Preliminary functional characterization of KCNQ2 confirmed that this gene encodes a voltage-activated K ϩ channel (9). Here we describe the cloning, tissue distribution, and functional expression of both KCNQ2 and KCNQ3. More importantly, we demonstrate that these two channels interact functionally with each other and with KCNE1. EXPERIMENTAL PROCEDURES Molecular Cloning and Expression of KCNQ2 and KCNQ3-5ЈRap...
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