The role of bone morphogenic proteins in human aortic valvular endothelial cells

Ankeny, Randall Francis

01 April 2010

In the United States alone, there are nearly 49,000 aortic valvular repairs or replacements each year, and this number is expected to rise. Unlike atherosclerosis, the molecular mechanisms contributing to this side-dependent disease development are limited, which contributes to the lack of therapeutic treatments. Once clinically manifested, options for treatment are limited to valvular replacement or repair. Therefore understanding the mechanobiology and cellular responses in aortic valves may provide important information for disease development and possible biomarkers or therapeutic treatments. Aortic valve disease occurs on one side of the valvular leaflet. The fibrosa side, which faces the aorta, is prone to disease development, while the ventricularis remains relatively unaffected. The hemodynamics is hypothesized to play a role in side dependent disease formation. The fibrosa endothelium is exposed to oscillatory flow while the ventricularis endothelium is exposed to a pulsatile unidirectional flow. Previous work by our group has shown that bone morphogenic protein-4 is a mechanosensitve inflammatory cytokine in the vasculature. In the following study, we proposed that mechanosensitive bone morphogenic proteins play a role in side specific aortic valve disease. Recently, the bone morphogenic proteins (BMPs) have been found in calcified human aortic valves. Furthermore, BMP-4 in vascular endothelial cells is increased by oscillatory shear stress. However, the role of the BMPs in aortic valve endothelial cells and their contribution to aortic valve calcification remains unstudied. Therefore, the overall objective of this dissertation was to investigate how disease and hemodynamics affects the BMP pathway and inflammation in human aortic valvular endothelial cells. By understanding how the bone morphogenic proteins are regulated and what roles they play in aortic valve disease, we will have better insight into endothelial cell regulation and contribution in aortic valve pathology. The central hypothesis of this project was that oscillatory flow conditions on the fibrosa side of the aortic valve stimulate endothelial cells to produce BMP-4, which then activates an inflammatory response leading to accumulation of inflammatory cells, calcification, and ultimately valve impairment. This hypothesis was tested through three specific aims using calcified human aortic valves, non-calcified human aortic valves, and side-specific human aortic valve endothelial cells. We first worked to establish the importance of the BMPs in the aortic valvular endothelium by looking at two populations of aortic valves: 1) calcified human aortic valves were obtained from patients undergoing valve replacement, and 2) non-calcified valves were obtained from recipient hearts of patients undergoing heart transplantation. Using immunohistochemical techniques, we examined the BMPs, BMP antagonists, and SMADs. Surprisingly, we identified that the ventricularis endothelium had higher BMP expression in both calcified and non-calcified human aortic valves. Furthermore, no disease-dependent BMP expression was detected. Next, we examined the BMP antagonists and found that there was robust BMP antagonist expression in the ventricularis endothelium and very low expression in the fibrosa endothelium. Finally, to determine if the BMP pathway was activated, we stained for the canonical BMP signaling molecule phosphorylated-SMAD 1/5/8 and found increased staining in the endothelium of calcified human aortic valves. Furthermore, a significant increase in SMAD 1/5/8 phosphorylation was seen in the endothelium of calcified fibrosa when compared to the non-calcified fibrosa. Finally, inhibitory SMAD 6 was significantly increased in the ventricularis endothelium of non-calcified human aortic valves. These findings suggest that preferential activation of BMP pathways, controlled by the balance between the BMPs and their inhibitors, play an important role in side-dependent calcification of human AVs. We next wanted to examine the role of shear stress in BMP regulation, but before doing so, we needed to examine the endothelial response to fluid shear stress to validate the phenotype of our isolated human aortic valve endothelial cells. KLF2 and eNOS expression in vascular endothelial cells has been shown to be increased by laminar flow and to have anti-inflammatory effects by decreasing VCAM-1 levels. Conversely, oscillatory shear stress has been shown to increase NF-kappa B translocation and increase ICAM-1 and E-selectin. We found laminar shear stress causes human aortic valve endothelial cells align parallel to flow and have robust increases of KLF2 and eNOS and decreases in VCAM-1 levels; however, laminar shear-treated cells had similar levels of NF-kappa B activation as oscillatory treated cells while ICAM-1 and E-selectin was not affected by shear stress. In contrast, oscillatory shear had higher levels of monocytes bound which may be due to eNOS's protective effects under laminar shear and robust VCAM-1 expression in oscillatory shear. These studies suggest differential regulation of human aortic valvular endothelial cells than published reports on human aortic endothelial cells which adds to the growing evidence that valvular endothelial cells are phenotypically different than vascular endothelial cells. After verifying the shear response of our endothelial cells, we next determined the shear response of the BMPs and BMP antagonists and described BMPs' effect on inflammation. Previously, BMP-4 has been shown in vitro and in vivo to be increased in endothelial cells exposed to oscillatory flow, while the closely-related BMP-2 has not been shown to be shear sensitive. In this study we have found that BMPs -2 and -4 are shear sensitive while BMP-6 is not. Furthermore, we have found that follistatin is decreased by laminar flow only in the ventricularis, while MGP1 is decreased in the fibrosa valvular endothelial cells under both oscillatory and laminar flow. Finally, incubation with noggin did not affect monocyte adhesion after shear, suggesting differential regulation of inflammation in human aortic valvular endothelial cells. By addressing the specific aims of this project, we have investigate disease- and side-dependent valvular endothelial BMP expression in vivo, shear regulation of valvular endothelial inflammation in vitro, and shear regulation of valvular endothelial BMP expression in vitro. Our results suggest that the BMP pathway is playing a role in side specific aortic valve disease development; however, regulation of the BMPs does not appear to be shear regulated in vivo. Other factors that may be affecting BMP production include including pulsatile pressures, bending stresses, cyclic stretch, and humeral stimuli present in the blood of the patients. However, in vitro we have found BMPs -2 and -4 to be shear-regulated in human aortic valvular endothelial cells. Shear-induced inflammation in human aortic valve endothelial cells seems to be VCAM-1-dependent, and BMP-independent. Finally, by identifying factors that are modulated in calcific- and shear-dependent processes, new targets for the early detection of aortic valve disease can be determined and new therapeutics to slow or stop the progression of aortic valve disease may be discovered.

Calcification

Aortic valve

Bone morphogenic proteins

Endothelial cell

Aortic valve Surgery

Biomechanics

Hemodynamics

Vascular endothelium

Bone morphogenetic proteins

The mechanism of endothelial cell specific gene expression of Von Willebrand Factor in vivo

Nassiri, Marjan.

January 2010

Thesis (M.Sc.)--University of Alberta, 2009. / A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Master of Science in Experimental Medicine, Department of Medicine. Title from pdf file main screen (viewed on January 17, 2010). Includes bibliographical references.

Angiogenesis regulation and control at the ligand/receptor level and beyond /

Azzarello, Joseph Thaddeus.

January 2009

Thesis (Ph. D.)--University of Oklahoma. / Bibliography: leaves 147-164.

Role of shear stress in angiopoietin-2-dependent neovascularization: implications in occlusive vascular disease and atherosclerosis

Tressel, Sarah Lynne

06 March 2008

Neovascularization, or the formation of blood vessels, is important in both normal physiological processes as well as pathophysiological processes. The main players in neovascularization, endothelial cells (EC), are highly influenced by hemodynamic shear stress and this may play an important role in neovascularization. Two typical types of shear stress found in the vascular system are a unidirectional laminar shear stress (LS) found in straight regions and a disturbed, oscillatory shear stress (OS) found at branches or curves. At the cellular level, LS is thought to promote EC quiescence whereas OS is thought to promote EC dysfunction. Oscillatory sheared EC are pro-proliferative, pro-migratory, and secrete growth factors, all functions important in neovascularization. There are several diseases that involve both disturbed shear stress and neovascularization, such as atherosclerosis, aortic valve disease, and occlusive vascular disease. In these pathophysiological scenarios fluid shear stress may provide a driving force for neovascularization. Therefore, we hypothesized that oscillatory shear stress promotes greater neovascularization compared to unidirectional laminar shear stress through the secretion of angiogenic factors, which play a physiological role in neovascularization in vivo. To test this hypothesis, we first performed tubule formation and migration assays, two important functions in neovessel formation. We found that OS promotes greater tubule formation and migration of EC as compared to LS and this was mediated through secreted factors. Using gene and protein array analysis, we identified Angiopoietin-2 (Ang2) as being upregulated by OS compared to LS in EC. We found that inhibiting Ang2 blocked OS-mediated tubule formation and migration and that LS-inhibited tubule formation could be rescued by addition of Ang2. In addition, Ang2 was found to be upregulated at sites of disturbed flow in vivo, implicating a physiological role for Ang2. To further investigate the physiological role of Ang2 in neovascularization, we examined the effects of inhibiting Ang2 in a mouse model of hindlimb ischemia, which involves both disturbed flow and neovascularization. We found that Ang2 was upregulated in the ischemic adductor muscle suggesting that it plays a role in recovery during hindlimb ischemia. In addition, we found that inhibiting Ang2 decreased blood flow recovery. Ang2 inhibition resulted in decreased smooth muscle cell coverage of vessels as well as decreased macrophage infiltration. These findings suggest that Ang2 promotes blood flow recovery through the recruitment of smooth muscle cells and formation of collaterals, as well as the recruitment of macrophages that secrete important growth factors and help degrade the extracellular matrix in order for neovascularization to occur. In conclusion, this work illustrates the shear stress regulation of neovessel formation through the expression of Ang2, and the role of Ang2 in neovascularization in vivo. By understanding how angiogenic factors are regulated and what role they play in vivo, we can better understand human disease and develop important therapeutic targets.

Hindlimb ischemia

Endothelial cells

Arteriogenesis

Shear stress

Angiopoietin-2

Angiogenesis

Vascular endothelium

Blood-vessels Growth

Shear flow

Neovascularization

Papel dos receptores ativados por protease (PARs) na reatividade vascular de ratos espontaneamente hipertensos (SHR) / Role of protease activated receptors (PARs) in vascular reactivity of spontaneously hypertensive rats (SHR)

André Luiz Colaço

31 March 2010

Receptores ativados por protease (PARs) pertencem à família de GPCRs. Desses, PAR-1, PAR-3 e PAR-4 são ativados por trombina, e PAR-2 por tripsina. Como as proteases, peptídeos sintéticos (PARs-AP) também ativam esses receptores. Estudamos o papel dos PARs na reatividade vascular de Wistar e SHR. In vitro, PAR-1 AP, promoveu maior vasoconstrição em aorta com endotélio (E+) de SHR vs Wistar. PAR-2 AP promoveu vasodilatação similar em aorta E+ de SHR e Wistar, enquanto PAR-4 AP e peptídeos reversos não causaram efeito. In vivo/in situ PAR-1 e PAR-2 AP mostraram intensa vasomotilidade em arteríolas mesentéricas. A expressão gênica de PAR-1 está aumentada em aorta e arteríolas de SHR, mas a expressão protéica está aumentada apenas em arteríolas. Demonstramos ainda que a vasoconstrição induzida por PAR-1 AP, é dependente de Ca++ e da liberação de Ang II, ET-1 e O2- pelo endotélio. Assim, sugerimos que PAR-1 pode ser um alvo terapêutico para novos antihipertensivos com efeito antitrombótico, já que este receptor também tem sido envolvido em eventos romboembólicos. / Protease activated receptors are a new GPCRs family. The PAR-1, PAR-3 and PAR-4 are activated by thrombin and PAR-2 by tripsin. Like proteases, synthetic peptides (PARs-AP) can also activate those receptors. We studied the role of PARs in vascular reactivity of Wistar and SHR. In vitro, PAR-1 promoted higher vasoconstriction to PAR-1 AP in SHR aorta with endothelium (E+) than the Wistar ones. PAR-2 AP produced similar vasodilation in Wistar and SHR aorta E+, while neither PAR-4 nor reverse peptides presented any effect. In vivo/in situ PAR-1 and PAR-2 showed an intensive vasomotion in mesenteric vessels. PAR-1 gene expression was increased in SHR aorta and arterioles, while the protein expression was increased only in the arterioles. We have also shown that the vasoconstriction induced by PAR-1 AP, is Ca++-dependent and Ang II, ET-1 and O2- release from endothelium. Thus, we suggest that PAR-1 might represent a therapeutic target to new antihypertensive drugs with antithrombotic effect, since this receptor has been involved in thromboembolics events.

Endotílio vascular

Hipertensão

Peptídeos

Proteinases

Receptores celulares

Vasos sanguíneos

Blood vessels

Cellular receptors

Hypertension

Peptides

Proteinases

Vascular endothelium

Participação da via de sinalização da beta-arrestina na produção de óxido nítrico induzido pelo shear stress / Beta-arrestin-mediated signal transduction participates in laminar shear stress-induced production of nitric oxide in endothelial cells

Ana Paula Carneiro dos Santos

30 January 2015

As células endoteliais são capazes de converter o estímulo mecânico em sinais intracelulares e produzir fatores vasoativos como o óxido nítrico (oNO). Evidências recentes sugerem que as beta-arrestinas desempenham um papel importante não somente na dessensibilização e internalização de receptores acoplados à proteína G (GPCR) como também na mecanotransdução. Nós testamos a hipótese de que células endoteliais submetidas ao shear stress (SS) produzem oNO por meio da ativação da via de sinalização dependente de beta-arrestina. Para tal, células endoteliais de veia safena (hSVEC) foram transfectadas com siRNA contra as isoformas 1 e 2 da beta-arrestina e, posteriormente, submetidas ao SS (15 dinas/cm2) durante 10 min. Nós encontramos que as SVEC silenciadas para a beta-arrestina 1/2 (70%) exibiram uma menor produção de nitrito no meio de cultura em resposta ao SS (166±17 vs. 326±44% comparado com hSVEC transfectadas com siRNA controle). Além disso, o silenciamento da beta-arrestina 1 e 2 preveniu os níveis de fosforilação da Akt no resíduo de serina 473 e a fosforilação da eNOS no resíduo de serina 1177, enquanto que a fosforilação da ERK 1/2 manteve-se inalterada. Curiosamente, análises de imunoprecipitação mostraram que a beta-arrestina interage com caveolina-1, um mecanossensor do shear stress, mas não é influenciado pelo SS. Além disso, na situação estática, a beta-arrestina encontra-se em uma localização perinuclear e, após o SS, adquiriu um padrão mais difuso no citosol. Coletivamente, esses dados sugerem que a beta-arrestina e a sinalização downstream Akt/ eNOS são necessárias para a produção de oNO induzido por shear stress em células endoteliais vasculares humana / Endothelial cells are capable of converting mechanical stimuli into intracellular signals generating vasoactive factors such as nitric oxide (oNO). Recent evidence suggests that beta-arrestins play a role not only on G protein-coupled receptors (GPCR) desensibilization but also in mechanotransduction. We tested the hypothesis that beta-arrestin and its downstream signaling influence laminar shear stress (SS)-induced oNO production by endothelial cells. Towards this end, human saphenous vein endothelial cells (hSVEC) transfected with siRNA against beta-arrestins isoforms 1 and 2 were subjected to SS (15 dynes/cm2, 10 minutes). We found that the SS-induced production of nitrite in the cell culture medium from down-expressed beta-arrestin 1/ 2 (70%) SVEC decreased (166±17 vs. 326±44% compared to wild-type hSVEC; P < 0.001). The beta-arrestin 1 and 2 down-regulation in SVEC also inhibited the phosphorylation levels of Akt at the serine residue 473 and the phosphorylation levels of eNOS at the serine residue 1177, whereas ERK phosphorylation remained unchanged. Interestingly, immunoprecipitation analysis showed that beta-arrestin interacts with caveolin-1, a shear stress mechanosensor, which is not influenced by SS despite the fact that the static perinuclear localization of beta-arrestins changed to the cytosol upon SS. Collective these data suggest that beta-arrestin and Akt/eNOS downstream signaling are required for shear stress-induced nitric oxide production in human vascular endothelial cells

Arrestina

Células endoteliais

Endotélio vascular

Estresse mecânico

Mecanotransdução

Óxido nítrico

Arrestin

Endothelial cells

Mechanical stress

mechanotransduction

Nitric oxide

Vascular endothelium

Antígenos variantes de superfície de hemácias infectadas por Plasmodium falciparum na Amazônia brasileira: aderência a receptores do endotélio vascular (CD36 e ICAM-1) e reconhecimento por anticorpos. / Variant surface antigens from Plasmodium falciparum-infected erythrocytes in Brazilian Amazon: adherence to endothelium receptors (CD36 and ICAM-1) and antibodies recognition.

Bianca Cechetto Carlos

16 December 2013

A relativa raridade de casos graves de malária no Brasil sugere que os isolados locais de Plasmodium falciparum tenham menor virulência que os parasitas africanos e asiáticos. Este trabalho investigou os padrões de aderência de sete isolados de P. falciparum, provenientes de uma área da Amazônia brasileira em que a malária grave é rara, a dois receptores do endotélio vascular, CD36 e ICAM-1. Também analisamos a resposta de anticorpos de indivíduos locais contra oitos antígenos de superfície, incluindo isolados de campo e a cepa 3D7. Mostramos que: (a) de modo geral, os isolados locais de P. falciparum expressam VSAs capazes de aderir tanto a ICAM-1 quanto a CD36; (b) detectamos anticorpos contra antígenos apresentados por isolados de campo e pela cepa 3D7 entre moradores de uma área endêmica próxima à origem dos isolados; (c) vimos que alguns dos soros testados foram capazes de bloquear a adesão de hemácias parasitadas a ICAM-1 e CD36, in vitro; (d) detectamos uma baixa prevalência do alelo S (hemoglobina S) na população de estudo. / The relative rarity of severe malaria in Brazil suggests that the local Plasmodium falciparum isolates are less virulent than African and Asian parasites. This work investigated adherence patterns to CD36 and ICAM-1, two receptors of the vascular endothelium, in P. falciparum isolates from an area of the Brazilian Amazonia, where severe malaria is rare. We also analyzed, in the same area, the antibody responses of people against eight VSAs. We found that: (a) local P. falciparum isolates express VSAs capable to adhere to both receptors, CD36 and ICAM-1; (b) we detected antibodies against VSAs in a human population exposed to malaria, expressed from local parasites and the 3D7 control; (c) we found in vitro that some sera contained naturally acquired antibodies which blocked the adherence of the parasitized RBCs to ICAM-1 and CD36; (d) we detected a low frequency of the S allele (hemoglobin S) in the study population.

Plasmodium

Aderência celular

Amazônia brasileira

Anticorpos

Endotélio vascular

Receptores celulares

Plasmodium

Antibodies

Brazilian Amazon

Cell adhesion

Cell receptors

Vascular endothelium

Combinatorial Activation of STAT3 by EGF and Thrombin in Endothelial Cells

Waitkus, Matthew S.

10 March 2014

No description available.

Molecular Biology

Cellular Biology

Biochemistry

STAT3

EGFR

GSK-3

signal integration

vascular endothelium

signal transduction

phosphorylation

EGR1

Mcl1

mass spectrometry

Modulação promovida pelo peptídeo natriurético tipo C sobre a resposta contrátil induzida pela fenilefrina em aorta torácica e artéria mesentérica de resistência isoladas de ratos submetidos ao choque séptico / C-type natriuretic peptide-induced modulation over the phenylephrine-induced contraction on thoracic aorta and resistance mesenteric arteries isolated from septic shock rats

Pernomian, Laena

14 August 2015

O choque séptico é uma síndrome inflamatória sistêmica secundária a um processo infeccioso, no qual as disfunções das células endoteliais e do músculo liso vascular contribuem para suprimento sanguíneo insuficiente a órgãos vitais, com consequente hipotensão sistêmica, insuficiência múltipla de órgãos e morte. Em geral, nos pacientes com choque séptico, existe um desequilíbrio dos fatores hemodinâmicos, levando ao baixo débito cardíaco e vasodilatação, além da redução da resposta contrátil aos diferentes agonistas, nos quais a participação do óxido nítrico (NO), de NO-sintases (NOS) e do estresse oxidativo são evidentes. A contribuição do sistema de peptídeos natriuréticos é evidenciada nos pacientes e em animais submetidos à sepse severa ou ao choque séptico. O peptídeo natriurético tipo C (CNP) é um agente vasodilatador que leva ao relaxamento vascular pela produção de GMPc intracelular, NO, hiperpolarização de membrana das células do músculo liso vascular e redução da concentração citosólica de cálcio. O tratamento com antagonista de receptores NPR-A/B tornou os animais menos susceptíveis à sepse, com menor resposta hipotensora, melhora da contração a agonistas e redução do processo inflamatório e NO plasmático. Portanto, a hipótese do presente trabalho é que no modelo de choque séptico induzido por ligação e perfuração cecal (CLP) em ratos, ocorreria menor resposta vasoconstritora ao agonista seletivo 1-adrenérgico Fenilefrina (PE) e este efeito seria atenuado pela inibição da sinalização desencadeada pelo CNP e modulado pelo estresse oxidativo. A sobrevivência dos ratos CLP foi menor do que a observada em ratos controle-operados (Sham). Os parâmetros cardiovasculares foram mais prejudicados nos ratos CLP do que em ratos Sham. A PE apresentou efeito pressórico menor em ratos CLP comparados aos ratos Sham. O CNP induziu efeito hipotensor em ambos os grupos, porém com maior aumento de frequência cardíaca nos ratos CLP. A contração induzida pela PE foi menor em aorta e artéria mesentérica de resistência, isoladas de ratos CLP, cujo efeito foi modulado pelo endotélio vascular. A vasodilatação induzida pelo CNP foi menor em aorta de ratos CLP. Além disso, o CNP apresentou efeito modulador negativo sobre a contração da PE em aortas com ou sem endotélio, mas não em artérias mesentéricas de resistência isoladas de ratos Sham e CLP. A menor resposta contrátil induzida pela PE em aortas de ratos CLP foi aumentada pelo antagonista de receptor NPR-B, pela inibição das enzimas NOS, xantina oxidase e metaloproteinases da matriz extracelular (MMPs) em aortas com endotélio. O efeito modulador negativo do CNP sobre a contração da PE foi revertido pelo antagonista de receptor NPR-B, inibição de NOS, redução da disponibilidade de O2- e pela degradação de H2O2, em ambos os grupos. Além disso, o estresse oxidativo e a concentração citosólica de H2O2 foram maiores no músculo liso vascular de ratos CLP. A expressão protéica de CNP endógeno foi menor no endotélio e maior no músculo liso da aorta de ratos CLP do que de Sham. Porém, a expressão protéica dos receptores 1-adrenérgicos e NPR-B não foram diferentes entre os grupos, mas a expressão protéica do receptor NPR-C foi menor na aorta de ratos CLP. A mobilização de cálcio intracelular foi menor no músculo liso da aorta de ratos CLP e a alta concentração de potássio extracelular não foi suficiente para despolarizar a membrana das células musculares da aorta de ratos CLP. A expressão protéica dos receptores NPR-B e NPR-C não foram diferentes no coração de ratos CLP. Entretanto, o potencial de membrana do ventrículo esquerdo (VE) dos ratos CLP foi menor que aquele de ratos Sham. Além disso, a concentração citosólica de cálcio no VE de ratos CLP foi menor que em ratos Sham, mas a redução de cálcio citoplasmático induzida pelo CNP foi maior no VE de ratos CLP comparada aquela em ratos Sham. Ocorreu disfunção cardíaca nos ratos CLP. No modelo de choque séptico induzido por cirurgia CLP em ratos, a participação do sistema de peptídeos natriuréticos, sobretudo do CNP, contribui para a menor resposta contrátil à fenilefrina e representa potencial via de intervenção na sepse severa e no choque séptico. / Septic shock is a systemic inflammatory syndrome secondary to an infection which the vascular dysfunction leads to an insufficient blood flow to vital organs with systemic hypotension, multiple organ injury and death. Usually, in septic shock patients there is an imbalance on hemodynamic factors, leading to low cardiac output and vasodilation, with decrease on contractile responses to several agonists, which the contribution of nitric oxide (NO), NO-synthases (NOS) and oxidative stress are evident. The contribution of natriuretic peptide system is observed on patients and animals submitted to severe sepsis or septic shock. C-type natriuretic peptide (CNP) is a vasodilator that leads to vascular relaxation through cGMP, NO, vascular smooth muscle hyperpolarization and reduction in cytosolic calcium. Treatment of animals with NPR-A/B antagonist, as well as knockout mice to NPR-A receptor are less susceptible to sepsis, with less hypotension, enhanced contraction to different agonists and reduction in inflammation and plasma NO. Therefore, the hypothesis of the present work is in septic shock induced by cecal ligation and puncture (CLP) model in rats there is low vasoconstriction to the selective 1- adrenoceptor agonist Phenylephrine (PE) and this effect could be attenuated by the inhibition of CNP signaling, strongly modulated by the oxidative stress. CLP survival was lower than the control rats (Sham) and cardiovascular parameters were impaired in CLP compared to the Sham rats. PE had positive pressure effect lower in CLP than in Sham rats. CNP induced hypotension in both groups with greater increases of cardiac rate in CLP. PE-induced contraction was decreased in aorta and resistance mesenteric artery isolated from CLP rats and this effect was modulated by the vascular endothelium. CNP-induced vasodilation was lower in rat aorta of CLP. Moreover, CNP had a negative modulator effect over the PE contraction on aortas with or without endothelium, but not on resistance mesenteric artery isolated from Sham and CLP rats. The low contractile response induced by PE on CLP aortas was enhanced by NPR-B antagonist, and by NOS, xanthine oxidase or extracellular matrix metalloproteinases (MMPs) inhibition on aortas with endothelium. The negative modulation induced by CNP over the PE contraction was reversed by the presence of NPR-B antagonist, NOS inhibition, and by the decrease on O2- availability and H2O2 degradation in both groups. Furthermore, oxidative stress and H2O2 intracellular content were greater on vascular smooth muscle of CLP rats. Protein expression of endogenous CNP was lower on endothelium and greater on smooth muscle of aortas isolated from CLP compared to Sham rats. However, the protein expression of 1-adrenoceptor and NPR-B were not different between the groups, but the protein expression of NPR-C was lower on smooth muscle of CLP aortas. Intracellular calcium mobilization was decreased on vascular smooth muscle of CLP aortas and extracellular high potassium solution was not able to depolarize smooth muscle layer of CLP aortas. Protein expression of NPR-B and NPR-C were not different on CLP hearts. However, membrane potential of left ventricle (LV) of CLP was lower than in Sham rats. Besides, intracellular calcium content of LV of CLP was lower than Sham rats but the decrease on cytosolic calcium induced by CNP was greater on LV of CLP compared to the Sham rats. There was cardiac dysfunction on CLP rats. In rat CLP septic shock model, the role of natriuretic peptide, mainly CNP, is of great importance in the decreased 1-adrenoceptor contraction, representing a potential via of intervention on severe sepsis and septic shock.

C-type natriuretic peptide

cardiac dysfunction

choque séptico

disfunção cardíaca

endotélio vascular

estresse oxidativo

fenilefrina

oxidative stress

Peptídeo natriurético tipo C

phenylephrine

septic shock

vascular endothelium

Studies on ion channels of coronary endothelium with clinical implications. / 冠狀動脈內皮離子通道的研究及其臨床意義 / CUHK electronic theses & dissertations collection / Guan zhuang dong mai nei pi li zi tong dao de yan jiu ji qi lin chuang yi yi

January 2011

Ca2+-activated potassium channels (KCa) and canonical transient receptor potential (TRPC) channels are essential to endothelial function. In ischemic heart disease, or in cardiac surgery, coronary endothelium is subjected to ischemia-reperfusion (I-R) / hypoxia-reoxygenation (H-R) injury. Hyperkalemic cardioplegic or organ preservation solutions used in cardiac surgery including heart transplantation also impair endothelial function. The present study was designed to mainly investigate whether endothelial dysfunction occurring in H-R or in hyperkalemic exposure is attributable to alterations of intermediate- and small-conductance KCa (IKCa and SKCa) channels, or TRPC channels, in particular, the TRPC3 channel. / Exposure to 60-min hypoxia followed by reoxygenation inhibited the vasorelaxant response of coronary arteries to IKCa / SKCa activator 1-EBIO. H-R reduced endothelial IKCa and SKCa currents and downregulated IKCa expression in PCECs. 1-EBIO enhanced endothelial K+ current that was blunted by H-R. / Exposure to hyperkalemic solutions decreased Ca2+ influx via TRPC3 in PCECs. The reduced Ca2+ influx in PCECs and the attenuated EDHF-mediated vasorelaxation in porcine coronary arteries, which were caused by hyperkalemic or cardioplegic / organ preservation solutions, were restored by OAG. / In PCECs, hypoxia for 60-min with reoxygenation reduced TRPC3 current and Ca2+ influx via TRPC3, which was accompanied by decreased NO release and endothelium-dependent vasorelaxation of porcine coronary arteries. The compromised endothelial function was restored by OAG. The translocation of TRPC3 to endothelial membrane was inhibited by H-R. / In TRPC3-overexpressing HEK293 cells, followed by reoxygenation, short-time hypoxia (10-min) enhanced, whereas prolonged hypoxia (60-min) reduced the current induced by TRPC3/6/7 activator OAG. / Our results indicate that: (1) Endothelial IKCa, SKCa and TRPC3 play an important role in regulating vascular tone; TRPC3 contributes to NO release from endothelial cells and is also involved in the function of EDHF. (2) H-R (60-30 min) reduces endothelial IKCa and SKCa currents with downregulation ofthe protein expression of IKCa. (3) H-R has dual effect on TRPC3 with short-time hypoxia (lO-min) enhancing whereas prolonged hypoxia (60-min) decreasing the electrophysiological activity of this channel. H-R (60-30 min) inhibits the translocation of TRPC3 to endothelial membrane. Furthermore, H-R inhibits Ca2+ influx via TRPC3 and such inhibition is associated with a decrease of NO production. (4) The activator of IKCa / SKCa or TRPC protects coronary endothelium against H-R injury. In coronary endothelium exposed to hyperkalemic or cardioplegic / organ preservation solutions, TRPC activator also exhibits protective effect. / The above findings are likely to have significant implications in ischemic heart disease and in modem cardiopulmonary surgery. / Whole-cell membrane currents of IKCa, SKCa, or TRPC3 were recorded by patch-clamp in primary cultured porcine coronary endothelial cells (PCECs). TRPC3 current was also studied in human embryonic kidney cells (HEK293 cells) transiently overexpressed with TRPC3 gene. Protein or mRNA expression of these channels was detected by Western blot or RT-PCR. Intracellular Ca2+ concentration was measured by Ca2+ imaging technique. Isometric force study was performed in a wire myograph and endothelial nitric oxide (NO) release was measured electrochemically by using a NO-specific microsensor in porcine coronary small arteries. / Huang, Junhao. / "December 2010." / Adviser: Qin Yang. / Source: Dissertation Abstracts International, Volume: 73-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2011. / Includes bibliographical references (leaves 138-165). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Coronary arteries

Coronary heart disease

Potassium channels

TRP channels

Vascular endothelium

Coronary Vessels

Endothelium, Vascular

Myocardial Ischemia

Potassium Channels, Calcium-Activated

Transient Receptor Potential Channels