An in vivo study on the distinctive role of inducible and endothelial nitric oxide synthase in carbon tetrachloride-induced liver injury

Leung, Tung-ming., 梁東明.

January 2006

published_or_final_version / abstract / Anatomy / Doctoral / Doctor of Philosophy

Nitric-oxide synthase.

Nitric oxide.

Liver - Wounds and injuries.

Biomimetic reactions of nitric oxide synthase: study of the reactions of n-substituted-N'-hydroxyguanidines with metalloporphyrin and non-heme complexes

Chu, Tsun-tung., 朱俊東.

January 2007

published_or_final_version / abstract / Chemistry / Doctoral / Doctor of Philosophy

Nitric-oxide synthase.

Chemical reactions.

Biomimetics.

Bioactive compounds.

Modulation of endothelium-dependent contractions by chronic inhibitionof nitric oxide synthase in the rat aorta

Qu, Chen, 屈晨

January 2008

published_or_final_version / Pharmacology / Master / Master of Philosophy

Nitric-oxide synthase.

Cyclooxygenases.

Vascular endothelium.

Arteries.

Blood-vessels - Contraction.

Sex, estrogen and the role of cardiac vasoactive gene systems in the modulation of cardiac hypertrophy in ANP gene-disrupted mice

Wong, Philip

28 August 2013

Sex dimorphism in the prevalence, onset, development and progression of cardiovascular disease (CVD) is well recognized. Sex-specific differences in adaptation to cardiac pathological progressions such as cardiac hypertrophy (CH), and the extent to which they are attributable to sex hormones requires further delineation. The objective of this dissertation was to determine which cardiac vasoactive systems are responsible for sex-specific differences in CH modulation using the atrial natriuretic peptide gene-disrupted (ANP-/-) mouse model. First, sex-specific differences in the expression of the cardiac natriuretic peptide (NP) and nitric oxide synthase (NOS) systems were evaluated. Next, the influence of 17β-Estradiol (E2) on the expression and signaling of the cardiac NP and NOS systems was determined in ovariectomized (OVX) female ANP+/+ and ANP-/- mice. Finally, sex-specific differences in cardiac adaptation to Angiotensin II (ANGII) pressure overload were elucidated in male and intact female ANP+/+ and ANP-/- mice. These studies revealed that males predominantly use the NP system and females predominantly use the NOS system. Sex-specific differences in the cardiac NOS system were further enhanced by E2 in OVX female ANP+/+ and ANP-/- mice. In the female ANP-/- mouse, E2 was found to signal through the NOS system to significantly increase plasma cGMP. Finally, male and female differences were demonstrated in the sex-specific patterns of cardiac vasoactive gene system expression and development of cardiac dysfunction in response to ANGII treatment. Sex dimorphism was observed in the expression of BNP and NPR-A in male and female ANP-/- mice treated with ANGII. Female ANP+/+ and ANP-/- ANGII-treated mice exhibited elevated E/E’ ratios that were not found to the same extent in genotype matched ANGII-treated male mice, demonstrating that female mice developed ANGII-mediated mild left ventricle diastolic dysfunction. Based on the results of this dissertation, we conclude that sex-specific differences do indeed exist in the cardiac adaptation to pathological stresses. These data support the understanding that a progression towards sex-specific CVD treatments is warranted, with a particular emphasis on the potential benefits of female-specific targeting of the cardiac NOS system. / Thesis (Ph.D, Anatomy & Cell Biology) -- Queen's University, 2013-08-23 14:21:45.324

Estrogen

Heart

Nitric Oxide Synthase

Mouse

Atrial Natriuretic Peptide

Insight into oxidative stress mediated by nitric oxide synthase (NOS) isoforms in atherosclerosis

Padmapriya, Ponnuswamy

January 2008

The principle product of each NOS is nitric oxide. However, under conditions of substrate and cofactor deficiency the enzymes directly catalyze superoxide formation. Considering this alternative chemistry of each NOS, the effects of each single enzyme on key events of atherosclerosis are difficult to predict. Here, we evaluate nitric oxide and superoxide production by all three NOS isoforms in atherosclerosis. ESR measurements of circulating and vascular wall nitric oxide production showed significantly reduced nitric oxide levels in apoE/eNOS double knockout (dko) and apoE/iNOS dko animals but not in apoE/nNOS dko animals suggesting that eNOS and iNOS majorly contribute to vascular nitric oxide production in atherosclerosis. Pharmacological inhibition and genetic deletion of eNOS and iNOS reduced vascular superoxide production suggesting that eNOS and iNOS are uncoupled in atherosclerotic vessels. Though genetic deletion of nNOS did not alter superoxide production, acute inhibition of nNOS showed that nNOS contributes significantly to superoxide production. In conclusion, uncoupling of eNOS occurs in apoE ko atherosclerosis but eNOS mediated superoxide production does not outweigh the protective effects of eNOS mediated nitric oxide production. We show that although nNOS is not a major contributor of the vascular nitric oxide formation, it prevents atherosclerosis development. Acute inhibition of nNOS showed a significant reduction of superoxide formation suggesting that nNOS is uncoupled. The exact mechanism of action of nNOS in atheroprotection is yet to be elucidated. Genetic deletion of iNOS reduced NADPH oxidase activity. Thus, iNOS has both direct and indirect proatherosclerotic effects, as it directly generates both nitric oxide and superoxide simultaneously resulting in peroxynitrite formation and indirectly modulates NADPH oxidase activity. We hypothesize that eNOS is coupled in the disease free regions of the vessel and contributes to nitric oxide generation whereas in the diseased region of the vessel it is uncoupled to produce superoxide (Figure 16). nNOS expressed in the smooth muscle cells of the plaque contributes to the local superoxide generation. iNOS expressed in smooth muscle cells and leukocytes of the plaque generates superoxide and nitric oxide simultaneously to produce the strong oxidant peroxynitrite. / Stickstoffmonoxid (NO) ist das prinzipielle Produkt aller Stickstoffmonoxid-Synthasen (NOS). Im Falle eines Mangels an Substrat (L-arginin) und Kofaktoren (Tetrahydrobiopterin, BH4) katalysieren die NOS-Enzyme direkt Superoxid (O2-). Diese Veränderung in der Radikalproduktion wird auch als Entkopplung der NOS bezeichnet. Die alternative Produktion von NO oder O2- durch die NOS bedingen, dass eine Voraussage über die Schlüsselfunktion der einzelnen Enzyme in der Entstehung der Atherosklerose schwierig ist. In unserer Studie evaluieren wir die Produktion von NO sowie O2- in atherosklerotischen Läsionen von apoE ko Mäusen und apoE/NOS doppel knockout (dko) Mäusen denen jeweils eine NOS-Isoform fehlt. Elektronen Spin Resonanz (ESR) Messungen konnten eine signifikante Reduktion sowohl des zirkulierenden, als auch der Gefäßwand eigenen Produktion von NO in apoE/eNOS dko und apoE/iNOS dko Mäusen zeigen, nicht jedoch in apoE/nNOS dko Mäusen. Dies lässt darauf schließen, dass eNOS und iNOS den hauptsächlichen Anteil der vaskulären NO-Produktion in atherosklerotischen Läsionen bewerkstelligen. Die pharmakologische Inhibierung wie auch die genetische Deletion von eNOS und iNOS führten ebenfalls zu einer reduzierten vaskulären O2- produktion, was die partielle Entkopplung beider Enzyme in atherosklerotisch veränderten Gefäßen nahe legt. Obwohl die chronische genetische Deletion von nNOS in apoE/nNOS dko die O2- Produktion nicht verändert, zeigte sich bei der akuten pharmakologischen Inhibierung von nNOS (durch L-NAANG) eine maßgebliche Beteiligung von nNOS an der O2- produktion in apoE ko Mäusen. Schlussfolgernd lässt sich sagen, dass in atherosklerotischen Gefäßen von apoE ko Tieren eine Entkopplung von eNOS statt findet, diese jedoch zu keinem Ausgleich der protektiven Effekte der eNOS vermittelten NO-Produktion führt. Unsere Ergebnisse in apoE/nNOS dko Mäusen zeigen eine atheroprotektive Rolle der nNOS, die sich nicht allein durch eine lokale, vaskuläre NO-Produktion durch das Enzym erklären lässt. Wir postulieren weitere systemisch atheroprotektive Eigenschaften der nNOS. Die signifikante Reduktion der Superoxidproduktion durch eine akute Inhibierung der nNOS weist auf eine Entkopplung der nNOS hin. Der exakte Wirkungsmechansimus von nNOS in der Atheroskleroseprävention ist weiterhin noch zu eruieren. Die genetische Deletion von iNOS führt zu einer reduzierten Aktivität der NADPH-Oxidase. Demnach sind für iNOS direkte sowie indirekte atherosklerosefördernde Effekte anzunehmen, da sie auf direktem Wege gleichzeitig NO und O2- produziert, was in einer Peroxynitritbildung resultiert. Wir stellen die Hypothese auf, dass eNOS in den läsionsfreien Gefäßregionen gekoppelt ist und dort seine atheroprotektiven Effekte durch die NO-Produktion vermittelt, während die eNOS in atherosklerotischen Läsionen entkoppelt vorliegt und hier O2- produziert (Fig. 16). iNOS, welches vor allem in den Plaques, in glatten Muskelzellen und Leukozyten zu finden ist, produziert gleichzeitig hohe Konzentrationen von O2- und NO, die als gemeinsames Endprodukt das stark oxidierende Peroxynitrit ergeben und die von uns dokumentierte proatherosklerotische Wirkung der iNOS vermittelt.

atherosclerosis

oxidative stress

Nitric oxide synthase

ddc:570

Immunohistochemical studies on the autonomic innervation of the human pre-and postnatal male genitourinary organs. / CUHK electronic theses & dissertations collection

January 1996

Philip Y.P. Jen. / Thesis (Ph.D.)--Chinese University of Hong Kong, 1996. / Includes bibliographical references (p. 94-111). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web.

Urogenital System--innervation

Autonomic Nervous System

Nitric Oxide Synthase--immunology

Paradoxical Effects Of Nitric Oxide Synthase Isoforms In Brain Microvascular Endothelial Cells And Neurons

January 2018

archives@tulane.edu / Experimental stroke in endothelial nitric oxide synthase (eNOS) and neuronal nitric oxide synthase (nNOS) knockout mice showed diverse effects on brain injury. nNOS and eNOS have been shown to uncouple in pathological conditions to produce superoxide. Oxidative stress is believed to be the underlying cause of several cardiovascular diseases including ischemic stroke. However, the role of eNOS and nNOS uncoupling in ischemic stroke is not well studied. Our objective of the study was to determine the effect of eNOS and nNOS inhibition on reactive oxygen species (ROS), NO, viability and mitochondrial bioenergetics in rat brain microvascular endothelial cells (BMECs) and rat cortical neurons following oxygen-glucose deprivation-reoxygenation (OGD/R). We found that non-specific inhibition of NOS in endothelial cells reduced ROS levels in BMECs but increased ROS levels in neurons under normoxia. This suggests that a pool of uncoupled NOS exists in the BMECs whereas the dominant functional NOS in neurons produces NO. We observed increased levels of ROS following OGD/R that is sensitive to NOS inhibition in both BMECs and neurons indicating eNOS and nNOS uncoupling during OGD/R. Furthermore, NOS inhibition reduced mitochondrial respiration while it improved cell survival rate in both BMECs and neurons following OGD/R. Thus, it is possible that decreased mitochondrial respiration in the immediate aftermath (4 hours) of OGD/R could be protective against reoxygenation injury. Moreover, we identified the expression of nNOS in BMECs from rat, human, and mouse. We observed that the nNOS in the BMECs constitutively produces superoxide under physiological conditions instead of NO. In contrast, nNOS in the neurons produces NO and doesn’t contribute to ROS. We also confirmed the nNOS expression and its function in freshly isolated rat brain microvessels. In addition, we developed a novel method to measure mitochondrial respiration in freshly isolated mouse brain microvessels using Seahorse XFe24 Analyzer. We validated the method by demonstrating impaired mitochondrial respiration in cerebral microvessels isolated from old mice compared to young mice. In summary, the present doctoral research investigated the distinct role of NOS isoforms in BMECs and Neurons leading to the identification of novel functional variant of nNOS in BMECs and brain microvessels. / 1 / RAMARAO SVNL

(CCTTT)n repeat polymorphism in the NOS2 gene promoter is assosiated with atopy / NOS2遺伝子プロモーター領域のCCTTT繰り返し多型とアトピーとの関連

今野, 哲

25 March 2002

共著者あり。共著者名:Hizawa Nobuyuki, Yamaguchi Etsuro, Jinushi Eisei, Nishimura Masaharu. / Hokkaido University (北海道大学) / 博士 / 医学

Atopy

asthma

nitric oxide synthase 2 (NOS2)

490

NMR Study of Calmodulin’s Interaction with Inducible Nitric Oxide Synthase

Duangkham, Yay

January 2010

The increase of calcium in the cell can induce cellular functions such as fertilization, cell division and cell communication. Calcium (Ca2+) carries out these processes through proteins called calcium sensors. An important calcium modulator is calmodulin. Calmodulin has four possible Ca2+ binding sites that have the characteristic helix-loop-helix (EF hand) motif. When the EF hands bind to Ca2+, methionine rich hydrophobic patches are exposed allowing for CaM to interact with target proteins. However, there are proteins that can interact with CaM at low levels of Ca2+ or in the absence of Ca2+. An enzyme that is activated by CaM is nitric oxide synthase (NOS), which converts L-arginine to L-citrulline and nitric oxide (•NO), where •NO is used to carry out important cellular functions. There are three isoforms of the enzyme; endothelial, neuronal and inducible NOS. The first two isoforms are activated by Ca2+-bound CaM when there is an influx of Ca2+ and are therefore Ca2+-dependent whereas inducible NOS (iNOS) is activated and binds tightly to CaM regardless of the Ca2+ concentration and is therefore Ca2+-independent. Of particular interest is the iNOS enzyme, since no three-dimensional structures of the reductase domain or the CaM-binding region have been solved. All three isoforms of NOS exist as homodimers, where each monomer consisting of a reductase domain and an oxygenase domain separated by a CaM-binding region. The reductase domain contains binding sites for NADPH and the flavins, FAD and FMN, which facilitate electron transfer from the NADPH to the catalytic heme in the oxygenase domain of the opposite monomer. The transfer of electrons from the FAD to the heme is carried out by the FMN domain which is proposed to swing between the two docking points since the distance between the two points is too large for electron transfer. This electron transfer point is under the control of CaM, which is essential for NOS activation. This dynamic process and the direct role of CaM have yet to be observed structurally. A method to monitor dynamics structurally is through the use of nuclear magnetic resonance (NMR) spectroscopy. Therefore as the first step to determine the NMR structure of the FMN domain with the CaM-binding region, the structure of the iNOS CaM-binding region bound to CaM will be determined. The structure will allow for further characterization and identification of important interactions between the iNOS CaM-binding region and CaM which contribute to the unique properties of iNOS.

Calmodulin

Nitric oxide synthase

Nuclear magnetic resonance spectroscopy

Chemistry

NMR Study of Calmodulin’s Interaction with Inducible Nitric Oxide Synthase

Duangkham, Yay

January 2010

The increase of calcium in the cell can induce cellular functions such as fertilization, cell division and cell communication. Calcium (Ca2+) carries out these processes through proteins called calcium sensors. An important calcium modulator is calmodulin. Calmodulin has four possible Ca2+ binding sites that have the characteristic helix-loop-helix (EF hand) motif. When the EF hands bind to Ca2+, methionine rich hydrophobic patches are exposed allowing for CaM to interact with target proteins. However, there are proteins that can interact with CaM at low levels of Ca2+ or in the absence of Ca2+. An enzyme that is activated by CaM is nitric oxide synthase (NOS), which converts L-arginine to L-citrulline and nitric oxide (•NO), where •NO is used to carry out important cellular functions. There are three isoforms of the enzyme; endothelial, neuronal and inducible NOS. The first two isoforms are activated by Ca2+-bound CaM when there is an influx of Ca2+ and are therefore Ca2+-dependent whereas inducible NOS (iNOS) is activated and binds tightly to CaM regardless of the Ca2+ concentration and is therefore Ca2+-independent. Of particular interest is the iNOS enzyme, since no three-dimensional structures of the reductase domain or the CaM-binding region have been solved. All three isoforms of NOS exist as homodimers, where each monomer consisting of a reductase domain and an oxygenase domain separated by a CaM-binding region. The reductase domain contains binding sites for NADPH and the flavins, FAD and FMN, which facilitate electron transfer from the NADPH to the catalytic heme in the oxygenase domain of the opposite monomer. The transfer of electrons from the FAD to the heme is carried out by the FMN domain which is proposed to swing between the two docking points since the distance between the two points is too large for electron transfer. This electron transfer point is under the control of CaM, which is essential for NOS activation. This dynamic process and the direct role of CaM have yet to be observed structurally. A method to monitor dynamics structurally is through the use of nuclear magnetic resonance (NMR) spectroscopy. Therefore as the first step to determine the NMR structure of the FMN domain with the CaM-binding region, the structure of the iNOS CaM-binding region bound to CaM will be determined. The structure will allow for further characterization and identification of important interactions between the iNOS CaM-binding region and CaM which contribute to the unique properties of iNOS.

Calmodulin

Nitric oxide synthase

Nuclear magnetic resonance spectroscopy

Chemistry