Endothelial cell-ILC3 crosstalk via the ET-1/EDNRA axis promotes NKp46+ILC3 glycolysis to alleviate intestinal inflammation.

Multiple Pathogenic Roles of Microvasculature in Inflammatory Bowel Disease: A Jack of All Trades

IBD Genetics: Focus on (Dys) Regulation in Immune Cells and the Epithelium

Leukocyte-specific transcript 1 (LST1) encoded peptides are involved in immunomodulation and nanotube-mediated cell-cell communication. The aim of this study was to assess the expression of LST1 in colonic epithelium and endothelium during intestinal inflammation. LST1 expression was evaluated by RT-PCR, FACS, western blot analysis, and immunohistochemistry in intestinal epithelial Caco-2 cells, human intestinal microvascular endothelial cells and in human histological specimens from inflammatory bowel disease (IBD) patients and non-IBD colitis patients. LST1 expression was significantly increased upon proinflammatory stimulation in intestinal epithelial and endothelial cells. Furthermore, LST1 tissue expression was significantly enhanced in macroscopically inflamed colonic mucosal biopsies as compared to non-affected mucosal areas. This is the first report demonstrating regulated LST1 expression in human intestinal epithelial and microvascular endothelial cells and in inflamed colonic tissue from IBD patients. Proinflammatory expression of LST1 occurs in the setting of human IBD and is not restricted to immune cell populations. Future studies are needed to further elucidate the role of soluble and membrane-expressed LST1 in the regulation of mucosal intestinal immunity and inflammation as well as to reveal possible therapeutic implications.

The endothelins are synthesized in vascular endothelial and smooth muscle cells, as well as in neural, renal, pulmonal, and inflammatory cells. These peptides are converted by endothelin-converting enzymes (ECE-1 and -2) from 'big endothelins' originating from large preproendothelin peptides cleaved by endopeptidases. Endothelin (ET)-1 has major influence on the function and structure of the vasculature as it favors vasoconstriction and cell proliferation through activation of specific ET(A) and ET(B) receptors on vascular smooth muscle cells. In contrast, ET(B )receptors on endothelial cells cause vasodilation via release of nitric oxide (NO) and prostacyclin. Additionally, ET(B) receptors in the lung are a major pathway for the clearance of ET-1 from plasma. Indeed, ET-1 contributes to the pathogenesis of important disorders as arterial hypertension, atherosclerosis, and heart failure. In patients with atherosclerotic vascular disease (as well as in many other disease states), ET-1 levels are elevated and correlate with the number of involved sites. In patients with acute myocardial infarction, they correlate with 1-year prognosis. ET receptor antagonists have been widely studied in experimental models of cardiovascular disease. In arterial hypertension, they prevent vascular and myocardial hypertrophy. Experimentally, ET receptor blockade also prevents endothelial dysfunction and structural vascular changes in atherosclerosis due to hypercholesterolemia. In experimental myocardial ischemia, treatment with an ET receptor antagonist reduced infarct size and prevented left ventricular remodeling after myocardial infarction. Most impressively, treatment with the selective ET(A) receptor antagonist BQ123 significantly improved survival in an experimental model of heart failure. In many clinical conditions, such as congestive heart failure, both mixed ET(A/B )as well as selective ET(A) receptor antagonism ameliorates the clinical status of patients, i.e. symptoms and hemodynamics. A randomized clinical trial showed that a mixed ET(A/B) receptor antagonist effectively lowered arterial blood pressure in patients with arterial hypertension. In patients with primary pulmonary hypertension or pulmonary hypertension related to scleroderma, treatment with a mixed ET(A/B) receptor antagonist resulted in an improvement in exercise capacity. ET receptor blockers thus hold the potential to improve the outcome in patients with various cardiovascular disorders. Randomized clinical trials are under way to evaluate the effects of ET receptor antagonism on morbidity and mortality.

Endothelin (ET)-1 is a potent vasoconstrictor and mitogen, and because of these properties, it is thought to play a role in the development of hypertension.1,2 The vascular endothelium is a major source of ET-1 production, although a variety of other cell types also have been shown to synthesize and release ET-1. ET-1 is believed to act in a paracrine manner on ETA and ETB receptors on smooth muscle, which mediate contraction, cell proliferation, and hypertrophy. Activation of ETB receptors on endothelial cells stimulates the production of prostacyclin and nitric oxide to induce vasorelaxation and inhibition of sodium transport in renal tubules. Given these properties, considerable attention has been paid to the mechanisms of ET-1 action as it relates to the renal control of blood pressure and the pathogenesis of salt-dependent hypertension. Renal ET synthesis is increased in experimental animals maintained on a high-salt diet and ETA receptor antagonists lower arterial pressure primarily in salt-dependent models of hypertension.1,2 For the past 30 to 40 years, the actions of angiotensin (Ang) II has been arguably the most widely investigated factor in hypertension research. Although physiology textbooks agree on the major actions of Ang II, eg, vasoconstriction and release of aldosterone, recent attention has focused on its ability to stimulate the synthesis of ET-1,3–5 as well as reactive oxygen species.6 There are many reactive oxygen species such as superoxide, hydroxyl radical, and hydrogen peroxide that are produced by all cell types and can have profound effects on the vascular system to impact blood pressure regulation. Most recent attention has been paid to the role of superoxide. There are many enzymatic sources of superoxide including NADPH oxidase, xanthine oxidase, nitric oxide synthase, and cytochrome P450. The focus of the current review, however, is be on the …

Endothelin (ET), a vasoconstrictive peptide, is known to have a variety of biological actions. Although ET is released by vascular endothelial cells, other cell populations also have been reported to synthesize and release ET. In this study, we examined whether ET is synthesized by intestinal epithelial cells and whether it affects induction of epithelial cell proliferation by interleukin-2 (IL-2). Subconfluent monolayers of intestinal epithelial cells (IEC-6 and IEC-18) were maintained in serum-free medium before addition of rat IL-2. Both IEC-6 and IEC-18 cells released ET-1 into the medium under unstimulated conditions, as determined by a sandwich ELISA. IL-2 significantly enhanced ET-1 release in a time-dependent manner. ET-3 was not detectable in the culture media of either cell line. Expression of ET-1 and ET-3 mRNA in epithelial cells was assessed by competitive PCR. Both cell lines were shown to express ET-1 mRNA, but no ET-3 mRNA was detected. IL-2 treatment enhanced ET-1 mRNA expression by both IEC-6 and IEC-18 cells. Both cell lines also expressed mRNA for ETA and ETB receptor subtypes. When cell proliferation was assessed, exogenous ET-1 induced a slight proliferative response in both types of cells that was consistent and significant at low ET-1 concentrations; cell growth was inhibited at a higher concentration (10(-7) M). IL-2 produced a significant proliferative response in both cell lines. However, the addition of ET-1 (10(-7) M) to culture media attenuated the IL-2-induced increase in cell proliferation. ETA-receptor antagonists significantly enhanced cellular proliferation, suggesting involvement of the ETA receptor in modulation of IL-2-induced intestinal epithelial cell growth.

See related article, pages 1439–1445 Traditionally, the role of the endothelium was thought to be primarily that of a selective barrier to the diffusion of macromolecules from the vessel lumen to the interstitial space. During the past 20 years, numerous additional roles for the endothelium have been defined such as regulation of vascular tone, modulation of inflammation, promotion as well as inhibition of vascular growth, and modulation of platelet aggregation and coagulation. Endothelial dysfunction is a characteristic feature of patients with cardiovascular risk factors such as hypercholesterolemia, hypertension, diabetes mellitus, and chronic smoking. More recent studies indicate that it may predict long-term atherosclerotic disease progression as well as cardiovascular event rate.1 There is a growing body of evidence that decreased endothelial bioavailability of nitric oxide (NO·) in particular attributable to increased production of reactive oxygen species, such as superoxide (O2·−), leads to an activation of the renin–angiotensin system,2,3 increased formation of cyclooxygenase (COX)-dependent vasoconstrictors,4 but also to increased expression of the most potent endogenous vasoconstrictor endothelin-1 (ET-1).5–9 Of the 4 active endothelins (ET-1 to ET-4) ET-1 is the predominant isoform in the cardiovascular system. ET-1 exerts its major cardiovascular effects through activation of 2 distinct G protein–coupled receptors, the ETA and ETB receptors. ETA receptors are found exclusively in smooth muscle cells. Endothelin-1 promotes vasoconstriction, mitogenesis, and thrombosis predominantly via binding to the ETA receptor. ETB receptors are localized to some extent in smooth muscle cells, but also in endothelial cells. Activation of ETB receptors has been demonstrated to cause the release of NO· and prostacyclin (PGI2).10,11 In normal states with p reserved vascular (endothelial) NO …

Hypertension Editors' Picks: Novel Drugs.

T84-Intestinal Epithelial Exosomes Bear MHC Class II/Peptide Complexes Potentiating Antigen Presentation by Dendritic Cells

Covering the Cover

The discovery of endothelin two decades ago has now evolved into an intricate vascular endothelin (ET) system. Several ET isoforms, receptors, signaling pathways, agonists, antagonists, and clinical applications have been identified and documented in first-rate patents. The role of ET as one of the most potent endothelium-derived vasoconstricting factors is now complemented by a newly discovered role in vascular relaxation. ET synthesis is initiated by the transcription of ET genes in endothelial cells and the generation of the gene products preproET and big ET, which are further cleaved by specific ET converting enzymes into ET-1, -2, -3 and -4 isoforms. ET isoforms bind with different affinities to ET(A) and ET(B2) receptors in vascular smooth muscle, and stimulate [Ca(2+)](i), protein kinase C, mitogen-activated protein kinase and other signaling mechanisms of smooth muscle contraction, growth and proliferation. ET also binds to endothelial ET(B1) receptors, which mediate the release of vasodilator substances such as nitric oxide, prostacyclin and endothelium-derived hyperpolarizing factor. Endothelial ET(B1) receptors may also function in ET re-uptake and clearance. Although the effects of ET on vascular function and growth are well-recognized, the role of ET and its receptors in the regulation of blood pressure and in the pathogenesis of hypertension is not clearly established. Salt-dependent hypertension in experimental animals and some forms of moderate to severe hypertension in human may show elevated levels of plasma or vascular ET; however, other forms of hypertension show normal ET levels. The currently available ET receptor antagonists reduce blood pressure in some forms of experimental hypertension. Careful examination of recent patents may identify more effective and specific modulators of the vascular ET system for clinical use in human hypertension.

Interaction between resident luminal bacteria and the host: can a healthy relationship turn sour?

Members of the interleukin (IL)-12 family constitute subunits of IL-12, -23, and -27. These ILs represent pivotal mediators in the regulation of cell-mediated immune responses and in animal models of human inflammatory bowel disease. Recent work has suggested that intestinal endothelial cells might serve as a second line of defense in bacterial sensing of invading pathogens. The purpose of this study was to examine the production of IL-12 family members in intestinal endothelial cells (HIMEC). HIMEC were stimulated with proinflammatory agents (TNF-alpha, IFN-gamma, IL-1beta) and microbial antigens [LPS, lipoteichoic acid, peptidoglycan, CpG-DNA, flagellin, poly(I:C)]. Expression of IL-12 family members and of Toll-like receptor (TLR)3 in HIMEC was assessed by real-time RT-PCR, immunostaining, flow cytometry, and immunoblot analysis. HIMEC display an induction of Epstein-Barr virus-induced gene 3 (EBI3), IL-12p35, and IL-23p19, whereas no expression of IL-12p40 and IL-27p28 was detectable. The strongest induction was induced by proinflammatory factors known to utilize the NF-kappaB pathway, and expression of EBI3 and IL-23p19 was diminished by an NF-kappaB inhibitor. HIMEC display regulated expression of TLR3. Adhesion and transmigration assays showed proinflammatory responses after HIMEC stimulation. HIMEC are capable of producing IL-12 family members as a response to microbial stimuli. The TLR3 agonist, poly(I:C), was shown to enhance leukocyte adhesion in vitro in HIMEC. Our data suggest that the intestinal microvasculature is responsive to ligands of TLR3 expressed on intestinal endothelial cells, thereby adding to the regulation of adaptive immunity and leukocyte recruitment.

Endothelins (ETs) are a family of peptides with 21-amino-acid residues. ET-1 was identified as a potent vasoconstrictor produced by vascular endothelial cells. Three distinct isoforms of ET, i.e. ET-1, ET-2 and ET-3, have been found to exist in a variety of tissues. ET was later found to cause contraction as well as relaxation of smooth muscle in many physiologic systems. In the gastrointestinal tract, ET causes contraction and/or relaxation of the esophagus, stomach, ileum and colon. In the hepatobiliary system, ET causes contraction of the portal vein, hepatic stellate cells, gallbladder and common bile duct. In mammalian species, two classes of ET receptors, ET(A) and ET(B), have been cloned. ET(A) receptors have higher affinities for ET-1 and ET-2 than ET-3, while ET(B) receptors have the same affinities for ET-1, ET-2 and ET-3. In the gastrointestinal system, ET causes smooth muscle contraction through interaction with ET(A) receptors, ET(B) receptors or both ET(A) and ET(B) receptors, depending on the tissues and species. In addition to contraction, ET causes smooth muscle relaxation through interaction with ET(A) receptors or ET(B) receptors. At the present time, there are no studies showing that ET causes smooth muscle relaxation through interaction with both ET(A) and ET(B) subtypes. ET induces contraction in most of the non-sphincter muscle except the fundus of the stomach. On the other hand, ET causes relaxation and contraction in the lower esophageal and internal anal sphincters. ET may play an important role in the control of human gastrointestinal motility and portal vein pressure.

Endothelin (ET) is one of the most investigated molecules in vascular biology. Since its discovery two decades ago, several ET isoforms, receptors, signaling pathways, agonists and antagonists have been identified. ET functions as a potent endothelium-derived vasoconstrictor, but could also play a role in vascular relaxation. In endothelial cells, preproET and big ET are cleaved by ET converting enzymes into ET-1, -2, -3 and -4. These ET isoforms bind with different affinities to ET(A) and ET(B) receptors in vascular smooth muscle (VSM), and in turn increase [Ca(2+)](i), protein kinase C and mitogen-activated protein kinase and other signaling pathways of VSM contraction and cell proliferation. ET also binds to endothelial ET(B) receptors and stimulates the release of nitric oxide, prostacyclin and endothelium-derived hyperpolarizing factor. ET, via endothelial ET(B) receptor, could also promote ET re-uptake and clearance. While the effects of ET on vascular reactivity and growth have been thoroughly examined, its role in the regulation of blood pressure and the pathogenesis of hypertension is not clearly established. Elevated plasma and vascular tissue levels of ET have been identified in salt-sensitive hypertension and in moderate to severe hypertension, and ET receptor antagonists have been shown to reduce blood pressure to variable extents in these forms of hypertension. The development of new pharmacological and genetic tools could lead to more effective and specific modulators of the vascular ET system for treatment of hypertension and related cardiovascular disease.