The expression, regulation and effects of inducible nitric oxide synthase in hibernating myocardium / Anke Sigrid Warner.

Warner, Anke Sigrid

January 2002

Amendments inserted at back. / "May 2002" / Includes bibliographical references (leaves 237-290) / xvii, 290 leaves : ill., plates (some col.) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Experiments described in this thesis address the potential role of inducible nitric oxide synthase (iNOS) in hibernating myocardium. Specifically it was sought to establish a cellular model of hibernating myocardium and investigate the expression, regulation and effects of iNOS in this model. Experiments were performed using primary cultures of neonatal rat ventricular myocytes. / Thesis (Ph.D.)--University of Adelaide, Dept. of Medicine, 2002

Heart Muscles Diseases

Heart Metabolism.

Coronary heart disease Molecular aspects

Nitric oxide Pathophysiology.

Coronary Vessels physiology

Mitochondrial Reactive Oxygen Species (ROS): Which ROS is Responsible for Cardioprotective Signaling?

Garlid, Anders Olav

31 March 2014

Mitochondria are the major effectors of cardioprotection by procedures that open the mitochondrial ATP-sensitive potassium channel (mitoKATP), including ischemic and pharmacological preconditioning. MitoKATP opening leads to increased reactive oxygen species (ROS), which then activate a mitoKATP-associated PKCε, which phosphorylates mitoKATP and leaves it in a persistent open state (Costa, ADT and Garlid, KD. Am J Physiol 295, H874-82, 2008). Superoxide (O2•-), hydrogen peroxide (H2O2), and hydroxyl radical (HO•) have each been proposed as the signaling ROS but the identity of the ROS responsible for this feedback effect is not known. Superoxide was excluded in earlier work on the basis that it does not activate PKCε and does not induce mitoKATP opening.To further examine the identity of the signaling ROS, respiring rat heart mitochondria were preincubated with ATP and diazoxide to induce the phosphorylation-dependent open state, together with agents that may interrupt feedback activation of mitoKATP by ROS scavenging or by blocking ROS transformations. Swelling assays of the preincubated mitochondria revealed that dimethylsulfoxide (DMSO), dimethylformamide (DMF), deferoxamine, trolox, and bromoenol lactone (BEL) each blocked the ROS-dependent open state but catalase did not interfere with this step. The lack of a catalase effect and the inhibitory effects of agents acting downstream of HO• excludes H2O2 as the endogenous signaling ROS and focuses attention on HO•. In support of the hypothesis that HO• is required, we also found that HO•-scavenging by DMF blocked cardioprotection by both ischemic preconditioning and diazoxide in the Langendorff perfused rat heart. HO• itself cannot act as a signaling molecule, because its lifetime is too short and it reacts immediately with nearest neighbor phospholipids and proteins. Therefore, these findings point to a product of phospholipid peroxidation, such as hydroperoxy-fatty acids. Indeed, this hypothesis was supported by the finding that hydroperoxylinoleic acid (LAOOH) opens the ATP-inhibited mitoKATP in isolated mitochondria. This effect was blocked by the specific PKCε inhibitor peptide εV1-2, showing that LAOOH activates the mitoKATP-associated PKCε. During ischemia, catabolism of mitochondrial phospholipids is accelerated, causing accumulation of plasmalogens and free fatty acids (FA) in the heart by the action of calcium independent phospholipases A2 (iPLA2). We first assessed the role of FAs and hydroxy FAs on mitoKATP opening and cardioprotection. Swelling assays of isolated rat heart mitochondria showed that naturally formed free FAs inhibit mitoKATP opening and that they are more potent inhibitors of the pharmacological open state of mitoKATP than the phosphorylation-dependent open state. That is, sustained mitoKATP opening induced by the phosphorylation-dependent feedback loop is more resistant to FA inhibition than direct mitoKATP opening by a potassium channel opener. Moreover, rat hearts perfused with micromolar concentrations of FA were resistant to cardioprotection by diazoxide or ischemic preconditioning. Racemic bromoenol lactone (BEL), a selective inhibitor of iPLA2, confers protection to otherwise untreated Langendorff perfused hearts by preventing ischemic FA release. To bring this story full circle, BEL blocks protection afforded by preconditioning and postconditioning by preventing the iPLA2-mediated release of FAOOH generated in the conditioned heart. HO• resulting from mitoKATP opening oxidizes polyunsaturated fatty acid components of the membrane phospholipids, resulting in a peroxidized side chain. FAOOH must be released in order to act on the mitochondrial PKCε, and this is achieved by the action of iPLA2. iPLA2 is essential for most modes of cardioprotection because it catalyzes the release of FAOOH. This fully supports the hypothesis that the second messenger of cardioprotective ROS-mediated signaling is hydroperoxy fatty acid (FAOOH), a downstream oxidation product of HO•.

Mitochondria -- Research

Potassium channels -- Research

Oxidation-reduction reaction -- Research

Heart -- Metabolism -- Research

Ischemia -- Research

Cell Biology

The hexosamine biosynthetic pathway induces gene promoter activity of the cardiac-enriched isoform of acetyl-CoA carboxylase

Imbriolo, Jamie

03 1900

Thesis (PhD)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The cardiac isoform of acetyl-CoA carboxylase (ACCβ) produces malonyl-CoA, a potent inhibitor of mitochondrial fatty acid (FA) uptake; thus increased ACCβ activity decreases fatty acid utilization thereby potentially leading to intracellular myocardial lipid accumulation and insulin resistance (IR). Previous studies show that greater flux through the hexosamine biosynthetic pathway (HBP) contributes to the development of IR. In light of this, we hypothesize that increased HBP flux induces ACCβ gene expression thereby contributing to the onset of IR. Our initial work focused on ACCβ gene promoter regulation and suggest that the HBP modulates upstream stimulatory factor 2 (USF2) thereby inducing ACCβ gene expression. Here, we further investigated HBP-mediated regulation of ACCβ gene expression by transiently transfecting cardiac-derived H9c2 cells with an expression vector encoding the rate-limiting HBP enzyme (GFAT) ± the full length ACCβ and 4 truncated promoter-luciferase constructs, respectively. GFAT overexpression increased ACCβ gene promoter activity for the full length and 3 larger deletion constructs (p<0.001 vs. controls). However, GFAT-mediated and USF2-mediated ACCβ promoter induction was blunted when co-transfected with the -38/+65 deletion construct suggesting that USF2 binds to the proximal promoter region (near start codon). Further investigation proves that USF2 binds to ACCβ promoter and activates it, but that USF2 is not O-GlcNAc modified even though there is a strong correlation between increased O-GlcNac levels and USF2 activation of ACCβ. This would suggest that there is another O-GlcNac modified factor involved in this regulatory pathway. Our study demonstrates that increased HBP flux induces ACCβ gene promoter activity via HBP modulation of USF2. We propose that ACCβ induction reduces fatty acid oxidation, thereby leading to intracellular lipid accumulation (FA uptake>>FA oxidation) and the onset of cardiac IR. / AFRIKAANSE OPSOMMING: Die kardiale isoform van asetiel-CoA karboksilase (ACCβ) produseer maloniel-CoA, ‘n kragtige inhibeerder van mitochondriale vetsuur (VS) opname, en om hierdie rede sal verhoogde ACCβ aktiwiteit, vetsuur gebruik verlaag en potensieël aanleiding gee tot intrasellulêre miokardiale lipiedophoping en insulienweerstand (IW). Vorige studies toon dat groter fluks deur die heksosamienbiosintetiese weg (HBW) bydra tot die ontwikkeling van IW. In die lig hiervan hipotetiseer ons dat verhoogde HBW fluks, ACCβ geenuitdrukking induseer, en sodoende tot die onstaan van IW bydra. Ons aanvanglike werk het op ACCβ geenpromotorregulering gefokus, en voorgestel dat die HBW die opstroom stimuleringsfaktor 2 (USF2) moduleer en dus ACCβ geen uitdrukking induseer. Hier het ons verder die HBW-gemedieërde regulering van ACCβ-geenuitdrukking deur kortstondige tranfeksie van kardiaalverkrygde H9c2 selle met ‘n uitdrukkingsvektor wat kodeer vir die tempo-bepalende HBW ensiem (GFAT) ± die volle lengte ACCβ, en vier afgestompte promotor-lusiferase konstrukte onderskeidelik, te ondersoek. GFAT ooruidrukking het ACCβ geenpromotor aktiwiteit vir die volle lengte, en drie groter uitwissingskonstrukte verhoog (p<0.001 vs. kontrole). Hoewel GFAT- en USF2-gemedieërde ACCβ promotorinduksie tydens ko-transfeksie van die -38/+65 uitwissingskonstruk versag was, is dit voorgestel dat USF2 aan die proksimale promotor area (naby die beginkodon) bind. Verdere ondersoek bewys ook dat USF2 aan die ACCβ promotor bind en dit aktiveer, maar dat USF2 nie O-GlcNAc gemodifiseer word nie ten spyte van ‘n sterk korrelasie tussen verhoogde O-GlcNac vlakke en USF2 aktivering van ACCβ. Dit kan dus voogestel word dat daar ‘n alternatiewe O-GlcNac gemodifiseerde faktor betrokke is in hierdie reguleringsweg. Ons studie demonstreer dat verhoogde HBW fluks ACCβ geenpromotor aktiwiteit via HBW modulering van USF2 veroorsaak. Ons stel voor dat ACCβ induksie vetsuuroksidasie verlaag en so tot intrasellulêre lipiedophoping (VS opname >> VS oksidasie) en die onstaan van kardiale IW lei.

Insulin resistance

Hexosamine biosynthetic pathway

Fatty acids -- Metabolism

Heart -- Metabolism

Obesity

Theses -- Physiology (Human and animal)

Increased flux through the hexosamine biosynthetic pathway leads to the induction of acetol-CoA caboxylase gene expression in the heart

Imbriolo, Jamie

03 1900

Thesis (MSc)--Stellenbosch University, 2008. / ENGLISH ABSTRACT: Gene expression of the cardiac isoform of acetyl-CoA carboxylase (ACCb) is induced in a glucose-dependent manner. ACCb produces malonyl-CoA, a potent inhibitor of mitochondrial fatty acid uptake. Previous studies show that increased flux through the hexosamine biosynthetic pathway (HBP) under hyperglycaemic conditions may contribute to the development of insulin resistance. In light of this, we hypothesised that increased HBP flux induces cardiac ACCb gene expression thereby contributing to the onset of insulin resistance. We tested our hypothesis by transiently transfecting cardiac-derived rat H9c2 myoblasts with a 1,317 bp human ACCb promoter-luciferase construct (pPIIb-1317) and an expression construct encoding the rate-limiting step of the HBP i.e. glutamine: fructose 6-phosphate amidotransferase (GFAT). Overexpression of GFAT increased ACCb gene promoter activity by 75 ± 23% versus controls (n=6, p<0.001). When cotransfection experiments were repeated in the presence of varying concentrations of L-glutamine (0 mM, 4 mM, 8 mM), a substrate for the HBP, ACCb promoter activity was dose-dependently increased. To further corroborate these findings, we employed two inhibitors of GFAT, i.e. 40 μM azaserine and 40 μM 6-diazo-5-oxo-Lnorleucine were administered to transfected cells for a period of 24 hours. Here both azaserine and 6-diazo-5-oxonorleucine attenuated ACCb gene promoter activity. In agreement, co-transfections with two dominant negative GFAT constructs also diminished ACCb gene promoter activity. We next inhibited two enzymes of the HBP acting downstream of GFAT, i.e. O-GlcNAc transferase and O-GlcNAcase using alloxan (0.1 mM, 1 mM and 2 mM) and streptozotocin (5 mM and 10 mM), respectively, for a period of 24 hours. Addition of alloxan attenuated ACCb gene promoter activity by 35.6 ± 1.9% (n=16, p<0.001) and streptozotocin increased activity by 32 ± 12% (n=12, p<0.001). We also investigated USF1 and USF2 as transcriptional regulatory candidates for HBP-induced ACCβ promoter regulation. Our data implicates USF2 as an important transcriptional regulator of HBP-induced ACCβ promoter regulation. In summary, this study demonstrates that increased flux through the hexosamine biosynthetic pathway induces ACCb gene promoter activity. We further propose that such an induction would reduce cardiac fatty acid oxidation, thereby leading to intracellular lipid accumulation due to a mismatch between sarcolemmal FA uptake and mitochondrial FA oxidation in the insulin resistant setting (i.e. hyperlipidaemia). / AFRIKAANSE OPSOMMING: Geen uitdrukking van die kardiale isoform asetiel-KoA karboksilase (ACCb) word in ‘n glukose afhanklike wyse geïnduseer. ACCb produseer maloniel-KoA, ‘n kragtige inhibeerder van mitochondriale vetsuuropname. Vorige studies toon aan dat verhoogde fluks deur die heksosamien biosintestiese weg (HBW) onder hiperglukemiese toestande bydra tot die ontwikkeling van insulienweerstand. In die lig hiervan, word daar gehipotetiseer dat verhoogde HBP fluks kardiale ACCb geenuitdrukking induseer en so bydra tot die ontstaan van insulienweerstand. Ons hipotese is getoets deur die kardiale afkomstige rot H9c2 mioblaste met ‘n 1.317 bp mens ACCb-lusiferase promotor konstruk (pPII-1317) te transfekteer en ‘n uitdrukking te konstrueer wat die tempo bepalende stap van HBP i.e. glutamien: fruktose-6-fosfaat amidotransferase (GFAT) kodeer. Ooruitdrukking van GFAT verhoog ACCb geenpromotor aktiviteit deur 75 ± 23% teenoor kontrole (n=6, p<0.001). Die herhaling van ko-transfeksie eksperimente is herhaal in die teenwoordigheid van variëerbare L-glutamienkonsentrasies (0 mM, 4 mM, 8 mM), ’n substraat vir die HBP, ACCb promotor aktiwiteit is dosisafhanglik verhoog. Om die bevindinge verder te staaf, is twee inhibeerders van GFAT, i.e. 40 μM azaserien en 40 μM 6-diazo-5-oxo-L-norleusien aan transfeksie selle toegedien vir ’n tydperk van 24 uur. Beide azaserien en 6-diazo-5-oxo-L-norleusien verlaag ACCb geenpromotor aktiwiteit. In ooreenstemming met die bogenoemde het ko-transfeksies met twee dominante negatiewe GFAT konstrukte ook ACCb geenpromoter aktiwiteit verminder. Die volgende stap is om twee ensieme van die HBP wat stroomaf van GFAT aktief is, vir ‘n periode van 24 uur te inhibeer i.e. O-GlcNAc transferase en O-GlcNAcase deur alloxan (0.1 mM, 1 mM en 2 mM) and streptozotosien (5 mM en 10 mM) onderskeidelik vir ‘n 24 uur periode te gebruik. Toevoeging van alloxan het die ACCb geenpromotor aktiwiteit by 35.6 ± 1.9% (n=16, p<0.001) verlaag en streptozotosien aktiwiteit verhoog by 32 ± 12% (n=12, p<0.001). Ons het ook die USF1 en USF2 as transkripsie regulerings kandidate vir HBP-geïnduseerde ACCβ promotor regulering ondersoek. Ons data impliseer dat USF2 as ‘n belangrike transkripsie reguleerder van HBP-geïndiseerde ACCβ promotor regulering is. Samevattend het hierdie studie demonstreer dat verhoogde fluks deur die hexosamien biosintetiese weg ACCb geenpromotor aktiwiteit induseer. Ons stel verder voor dat hierdie induksie die kardiale vetsuuroksidasie verlaag wat daartoe lei dat intrasellulêre lipied akkumulasie as gevolg van onparing tussen sarkolemma vetsuuropname en mitochondriale vetsuuroksidasie in ’n insulien weerstandige situasie (i.e. hiperlipidaemia).

Heart -- Metabolism

Insulin resistance

Hyperlipidemia

Fatty acids -- Metabolism

Glucose -- Metabolism

Hexosamine biosynthetic pathway

Theses -- Physiology (Human and animal)

The effect of creatine supplementation on myocardial metabolism and function in sedentary and exercised rats

Webster, Ingrid

12 1900

Thesis (PhD (Biomedical Sciences. Medical Physiology))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: Background: There has been a dramatic increase in the use of dietary creatine supplementation among sports men and women, and by clinicians as a therapeutic agent in muscular and neurological diseases. The effects of creatine have been studied extensively in skeletal muscle, but knowledge of its myocardial effects is limited. Objectives: To investigate the effects of dietary creatine supplementation with and without exercise on 1) basal cardiac function, 2) susceptibility to ischaemia/reperfusion injury and 3) myocardial protein expression and phosphorylation and 4) mitochondrial oxidative function. Methods: Male Wistar rats were randomly divided into control or creatine supplemented groups. Half of each group was exercise trained by swimming for a period of 8 weeks, 5 days per week. At the end of the 8 weeks the open field test was performed and blood corticosterone levels were measured by RIA to determine whether the swim training protocol had any effects on stress levels of the rats. Afterwards hearts were excised and either freeze-clamped for biochemical and molecular analysis or perfused on the isolated heart perfusion system to assess function and tolerance to ischaemia and reperfusion. Five series of experiments were performed: (i) Mechanical function was documented before and after 20 minutes global ischaemia using the work heart model, (ii) A H2O filled balloon connected to a pressure transducer was inserted into the left ventricle to measure LVDP and ischaemic contracture in the Langendorff model, (iii) The left coronary artery was ligated for 35 minutes and infarct size determined after 30 minutes of reperfusion by conventional TTC staining methods. (iv) Mitochondrial oxidative capacity was quantified. (v) High pressure liquid chromatography (HPLC) and Western Blot analysis were performed on blood and heart tissue for determination of high energy phosphates and protein expression and phosphorylation. Results: Neither the behavioural studies nor the corticosterone levels showed any evidence of stress in the groups investigated. Hearts from creatine supplemented sedentary (33.5 ± 4.5%), creatine supplemented exercised rats (18.22 ± 6.2%) as well as control exercised rats (26.1 ± 5.9%) had poorer aortic output recoveries than the sedentary control group (55.9 ± 4.35% p < 0.01) and there was also greater ischaemic contracture in the creatine supplemented exercised group compared to the sedentary control group (10.4 ± 4.23 mmHg vs 31.63 ± 4.74 mmHg). There were no differences in either infarct size or in mitochondrial oxygen consumption between the groups. HPLC analysis revealed elevated phosphocreatine content (44.51 ±14.65 vs 8.19 ±4.93 nmol/gram wet weight, p < 0.05) as well as elevated ATP levels (781.1 ±58.82 vs 482.1 ±75.86 nmol/gram wet weight, p<0.05) in blood from creatine supplemented vs control sedentary rats. These high energy phosphate elevations were not evident in heart tissue and creatine tranporter expression was not altered by creatine supplementation. GLUT4 and phosphorylated AMPK and PKB/Akt were all significantly higher in the creatine supplemented exercised hearts compared to the control sedentary hearts. Conclusion: This study suggests that creatine supplementation has no effects on basal cardiac function but reduces myocardial tolerance to ischaemia in hearts from exercise trained animals by increasing the ischaemic contracture and decreasing reperfusion aortic output. Exercise training alone also significantly decreased aortic output recovery. However, the exact mechanisms for these adverse myocardial effects are unknown and need further investigation. / AFRIKAANSE OPSOMMING: Agtergrond: Die gebruik van kreatien as dieetaanvulling het in die afgelope aantal jaar dramaties toegeneem onder sportlui, sowel as mediese praktisyns wat dit as ‘n terapeutiese middel vir die behandeling van spier- en neurologiese siektes aanwend. Die effekte van kreatien op skeletspier is reeds deeglik ondersoek, maar inligting aangaande die miokardiale effekte van die preperaat is beperk. Doelwitte: Om die effekte van kreatien dieetaanvulling met of sonder oefening ten opsigte van die volgende aspekte te ondersoek: 1) basislyn miokardiale funksie, 2) vatbaarheid vir iskemie/herperfusie besering, 3) proteïenuitdrukking en -fosforilering in die miokardium en 4) mitochondriale oksidatiewe funksie. Metodes: Manlike Wistar rotte is ewekansig in kontrole of kreatien aanvullings groepe verdeel. Helfte van elke groep is aan oefening in die vorm van swemsessies, vir ‘n periode van 8 weke, 5 dae per week blootgestel. Gedrags- en biochemiese toetse is aangewend om die moontlike effek van die swemprotokol op die rotte se stres vlakke te bepaal. In hierdie verband is die oop area toets gebruik, asook bloed kortikosteroon vlakke gemeet deur radioaktiewe immuunessais. Harte is daarna uit die rotte gedissekteer en gevriesklamp vir biochemiese en molekulêre analise, of geperfuseer op die geïsoleerde werkhart perfusiesisteem om sodoende funksie en weerstand teen iskemie en herperfusie beskadeging te bepaal. Vyf eksperimentele reekse is uitgevoer: (i) Meganiese funksie is noteer voor en na 20 minute globale isgemie in die werkhart model; (ii) ‘n Water gevulde plastiek ballon, gekoppel aan ‘n druk omsetter, is in die linker ventrikel geplaas om sodoende linker ventrikulêre ontwikkelde druk (LVDP), asook iskemiese kontraktuur te meet; (iii) Linker koronêre arterie afbinding is vir ‘n periode van 35 minute toegepas en die infarktgrootte bepaal na 30 minute herperfusie deur gebruik te maak van standaard kleuringsmetodes; (iv) Mitochondriale oksidatiewe kapasiteit is gemeet; (v) Hoë druk vloeistof chromatografie (HPLC) en Western Blot analises is uitgevoer op bloed en hartweefsel vir die bepaling van hoë energie fosfate (HEFe), sowel as proteïenuitdrukking en -fosforilering. Resultate: Beide gedragsstudies en kortikosteroonvlakke het geen teken van stres in die betrokke groepe getoon nie. Die groep blootgestel aan kreatienaanvulling en oefening se harte het na iskemie funksioneel swakker herstel as harte van die onaktiewe kontrole groep (18.22±6.2% vs 55.9±4.35%; p<0.01), asook ‘n groter ikgemiese kontraktuur in vergelyking met die onaktiewe kontrole groep ontwikkel (31.63±4.74 mmHg vs 10.4±4.23 mmHg). Daar was geen verskille in infarktgrootte of mitochondriale suurstofverbruik tussen die verskillende groepe waargeneem nie. HPLC analise het verhoogde fosfokreatien (44.51±14.65 vs 8.19±4.93 nmol/gram nat gewig, p<0.05) en adenosientrifosfaat (ATP) bloedvlakke (781.1±58.82 vs 482.1±75.86 nmol/gram nat gewig, p<0.05) in kreatien aanvullings vergelyk met die kontrole groepe getoon. Daar was egter geen meetbare veranderings in HEF vlakke in hartweefsel nie. Gepaardgaande hiermee het kreatienaanvulling geen effek gehad op die uitdrukking va die kreatien transporter nie. In vergelyking met onaktiewe kontrole harte was GLUT4, en fosforileerde AMPK en PKB/ Akt beduidend hoër in harte van geoefende rotte met kreatienaangevulling. Gevolgtrekking: Hierdie data dui daarop dat kreatienaanvulling geen effek op basislyn miokardiale funksie het nie. Kreatienaanvulling het egter die miokardium se weerstand teen iskemiese skade verlaag in harte van rotte blootgestel aan oefening: iskemiese kontraktuur is verhoog en aorta-uitset tydens herperfusie is verlaag. Die presiese meganismes hierby betrokke is egter onbekend en vereis dus verdere studie. / Division of Medical Physiology (University of Stellenbosch), The National Research Foundation and the Harry Crossley Fund for financial support.

Creatine

Ischaemia

Theses -- Medical physiology

Dissertations -- Medical physiology

Dissertations -- Medicine

Rats -- Effect of dietary supplements on

Theses -- Medicine

Creatine

Heart -- Effect of exercise on

Medical Physiology

Obesity alters global response to ischemia and GLP-1 agonism

Sassoon, Daniel Jay

13 May 2016

Indiana University-Purdue University Indianapolis (IUPUI) / Glucagon-like peptide 1 (GLP-1) receptor agonists are a class of incretin based therapeutics which aid in blood glucose management in Type II diabetes mellitus (T2DM). Recent studies have demonstrated direct cardiovascular benefits conferred by these agents including protection in ischemia and heart failure. Despite these observations, human clinical trials fail to support improvements in cardiovascular outcomes independent of glucose lowering effects in the T2DM populations. Prior data from our lab demonstrate that obesity impairs GLP-1 associated increases in myocardial glucose uptake. However, the reasons for this impairment/resistance to cardiac effects of GLP-1 in the setting of obesity remain ill defined. This investigation tested the hypothesis that underlying differences in the cardiac proteome and microRNA (miR) transcriptome could contribute to distinct cardiac responses to ischemia and activation of GLP-1 signaling in the setting of obesity. To identify whether obesity modulated cardiac functional responses to GLP 1 related drugs, we first examined the effects of obesity on cardiac function, miR transcriptome, and proteome in response to short duration ischemia-reperfusion (I/R). We observed divergent physiologic responses (e.g. increased diastolic volume and systolic pressure in lean, decreased diastolic volumes in obese) to regional I/R in obese vs lean hearts that were associated with significant molecular changes as detected by protein mass spectrometry and miR microarray. Molecular changes were related to myocardial calcium handling (SERCA2a, histidine-rich Ca2+ binding protein), myocardial structure and function (titin), and miRs relating to cardiac metabolism, hypertrophy, and cell death, including miR-15, miR-30, miR-199a, miR-214. Importantly, these effects were modified differently by GLP-1 agonism in lean vs obese swine. Additional studies investigated the functional effects of 30 days of treatment with the GLP-1 analogue liraglutide on a model of slowly-developing, unrelieved coronary ischemia. Liraglutide failed to reduce infarct size or collagen deposition. However, analysis of left ventricular pressure-volume relationships support that liraglutide improved diastolic relaxation/filling, load-dependent indices of cardiac function, and cardiac efficiency in response to sympathetic stimulation in obese swine. Taken together, these findings support that miR and proteomic differences underlie distinct changes in functional cardiac responses to I/R and pharmacologic activation of GLP-1 signaling in the setting of obesity.

microRNA

Cardiac

Incretin

Infarction

Obesity

Proteome

Glucagon-like peptide 1

Gastrointestinal hormones

Peptide hormones

Blood sugar monitoring

Non-insulin-dependent diabetes

Obesity

Heart -- Metabolism

Adaptations métaboliques cardiaques chez le fœtus de rat dans un modèle de restriction de croissance intra-utérine

Maréchal, Loïze

12 1900

La restriction de croissance intra-utérine (RCIU) est une conséquence immédiate d’un environnement utérin défavorable qui prédispose les individus atteints à de plus grands risques de développer des maladies cardiométaboliques une fois adulte. L’environnement fœtal s’ajoute ainsi à l’hérédité, au sexe et au mode de vie comme facteur déterminant de la santé cardiométabolique. Afin de mieux comprendre les différents aspects de cette prédisposition, notre laboratoire a développé un modèle animal de RCIU asymétrique recréant une diminution de la perfusion placentaire. La caractérisation des animaux a mis en évidence des différences dans la physiologie cardiovasculaire des individus adultes avec des dissemblances selon le sexe, ainsi qu’une différence dans l’expression de plusieurs gènes impliqués dans le métabolisme lipidique chez le fœtus. A partir de ces données, nous émettons l’hypothèse que le cœur fœtal RCIU subit une reprogrammation métabolique, conséquence du stress causé par l’environnement fœtal défavorable. Nous nous attendons aussi à une régulation différente du métabolisme entre les mâles et les femelles. Pour répondre à cette hypothèse, nous avons tout d’abord déterminé la contribution du métabolisme lipidique dans les cœurs fœtaux RCIU ainsi que sa régulation. Ensuite, nous avons approfondi les conséquences d’un métabolisme lipidique élevé dans les cœurs fœtaux RCIU. Le sexe des animaux a été pris en compte dans nos travaux. L’ensemble de ces travaux démontrent une plus grande utilisation du métabolisme lipidique chez les fœtus RCIU, impliquant une activation du récepteur nucléaire PPARα et du coactivateur PGC1a par une abondance d’acides gras (AG) à longue chaîne dans les cœurs fœtaux RCIU. L’activation de PPARα entraine une augmentation de l’expression de nombreux gènes impliqués dans l’oxydation des AG et de la biogenèse mitochondriale. Les mitochondries des cœurs fœtaux RCIU femelles montrent de plus grandes capacités de production d’ATP, comparées aux femelles témoins, mais aucune différence n’a été montrée chez les mâles. Un tel dysmorphisme a également été observé dans l’augmentation des capacités d’oxydation des AG à très longues chaînes chez les femelles RCIU, mais pas chez les mâles. L’augmentation de l’expression de Pdk4 dans les cœurs fœtaux RCIU confirme le fort métabolisme lipidique et suggère une abondance d’acétyl-CoA, molécule intermédiaire à plusieurs voies métaboliques, dont la production de corps cétoniques. Nous avons montré une synthèse intracardiaque de corps cétoniques chez les fœtus RCIU, sans élévation de la cétolyse, causant une accumulation d’acétoacétate et de β-hydroxybutyrate (bHB). Enfin, l’exploration des rôles signalétiques du bHB nous a permis d’observer une régulation positive de ce corps cétonique sur le métabolisme lipidique, par une activation de PPARα. En conclusion, ce projet de thèse a contribué à mieux comprendre les mécanismes d’adaptation métabolique des cœurs fœtaux à une RCIU causée par une diminution de la perfusion placentaire en fonction du sexe. Notre travail ouvre également la voie à de nouvelles avenues de recherche sur le rôle signalétique des corps cétoniques et des AG à longue chaîne dans la programmation des maladies cardiométaboliques. / An unfavorable womb environment often leads to intrauterine growth restriction (IUGR), which is known to increase the likelihood of developing cardiometabolic diseases later in life. The fetal environment is thus added to other factors such as heredity, sex and lifestyle that have an impact on cardiometabolic health. To investigate IUGR predisposed condition, our laboratory has developed an animal model of asymmetric IUGR by decreasing placental perfusion. Our findings using this animal model have highlighted sex-dependent differences in the cardiovascular physiology of IUGR adults, and specific changes in the expression of key genes involved in lipid metabolism in IUGR fetuses. Therefore, we hypothesize that the IUGR fetal heart undergoes a metabolic remodeling in response to the stress caused by the unfavorable uterine environment. We also expect selective metabolic changes in males and females. To verify this hypothesis, we addressed the contribution and regulation of lipid metabolism in IUGR fetal hearts. We also thoroughly investigated the consequences of a high lipid metabolism in IUGR fetal hearts. Changes between males and females were also considered. This study shows an increased use of lipid metabolism in IUGR fetuses, which involves the transcriptional activation of the nuclear receptor PPARα and the coactivator PGC1 in response to accumulated levels of specific long-chain fatty acids (FA) in IUGR fetal hearts. Activation of PPARα lead to an increase in the expression of critical genes involved in the oxidation of FAs and mitochondrial biogenesis. Mitochondrial respiration analysis demonstrated a greater ATP production capability in female IUGR fetal hearts compared to control females, a finding not observed in males. The increased expression of Pdk4 in IUGR fetal hearts attests such a strong lipid metabolism and suggests an abundance of acetyl-CoA, an intermediate molecule to several metabolic pathways, including the production of ketone bodies. Indeed, our results indicate an increased intracardiac synthesis of ketone bodies in IUGR fetuses without inducing ketolytic genes, resulting in significant accumulation of acetoacetate and β-hydroxybutyrate (bHB). Moreover, we provide evidence of a signaling role of bHB with a positive regulation of lipid metabolism through the transcriptional activation of PPARα. In conclusion, this thesis contributes to a better understanding of the mechanisms involved in the metabolic adaptation of fetal hearts to IUGR and highlights selective changes according to sex. Our study also paves the way for new research avenues on the signaling role of ketone bodies and long-chain FAs on the programming of cardiometabolic diseases.

Restriction de Croissance Intra-Utérine

RCIU

Métabolisme cardiaque

Lipides

Corps Cétoniques

PPAR

Intrauterine Growth Restriction

IUGR

Heart Metabolism

Lipids

Ketone Bodies

The effect of CPT-1 inhibition on myocardial function and resistance to ischemia/reperfusion injury in a rodent model of the metabolic syndrome

Maarman, Gerald Jerome

12 1900

Thesis (MScMedSc (Dept. of Biomedical Sciences. Medical Physiology))University of Stellenbosch, 2010. / ENGLISH ABSTRACT: Background: Obesity is associated with dyslipidemia, insulin resistance and glucose intolerance and together these components characterise the metabolic syndrome (Dandona et al. 2005). In the state of obesity, there are high levels of circulating free fatty acids and increased rates of fatty oxidation which inhibit glucose oxidation. This: (i) reduce the heart‘s contractile ability, (ii) exacerbates ischemic/reperfusion injury and (iii) decreases cardiac mechanical function during reperfusion (Kantor et al. 2000; Liu et al. 2002; Taegtmeyer, 2000). Aim: The aim of our study was to investigate the effect of inhibiting fatty acid oxidation, with oxfenicine (4-Hydroxy-L-phenylglycine), on (i) cardiac mechanical function, (ii) mitochondrial respiration, (iii) myocardial tolerance to ischemia/reperfusion injury, (iv) CPT-I expression, MCAD expression, IRS-1 activation, total GLUT- 4 expression and (v) the RISK pathway (ERK42/44 and PKB/Akt). Methods: Male Wistar rats were fed a control rat chow diet or a high calorie diet (HCD) for 16 weeks. The HCD caused diet induced obesity (DIO). The animals were randomly divided into 4 groups [Control, DIO, Control + oxfen and DIO + oxfen]. The drug was administered for the last 8 weeks of feeding (200mg/kg/day). Animals were sacrificed and the hearts were perfused on the Langendorff perfusion system. After being subjected to regional ischemia and two hours of reperfusion, infarct size was determined. A separate series of animals were fed and/or treated and hearts were collected after 25 minutes global ischemia followed by 30 min reperfusion for determination of GLUT- 4, CPT-1, IRS -1, MCAD, ERK (42/44) and PKB/Akt expression/phosphorylation using Western blot analysis. A third series of hearts were excised and used for the isolation of mitochondria. Results: In the DIO rats, chronic oxfenicine treatment improved cardiac mechanical function by improving mitochondrial respiration. Oxfenicine inhibited CPT-1 expression but had no effect on MCAD or GLUT- 4 expression. Oxfenicine decreased IRS-1 iv expression, but not IRS-1 activation. Oxfenicine also improved myocardial tolerance to ischemia/reperfusion without activation of the RISK pathway (ERK & PKB). In the control rats, chronic oxfenicine treatment worsened cardiac mechanical function by adversely affecting mitochondrial respiration. Oxfenicine also worsened myocardial tolerance to ischemia/reperfusion in the control rats without changes in the RISK pathway (ERK & PKB). Oxfenicine had no effect on CPT-1, MCAD or GLUT- 4 expression. Oxfenicine increased IRS-1 expression, but not IRS-1 activity. Conclusion: Chronic oxfenicine treatment improved cardiac mechanical function and myocardial resistance to ischemia/reperfusion injury in obese animals, but worsened it in control animals. The improved cardiac mechanical function and tolerance to ischemia/reperfusion injury may be due to improvement in mitochondrial respiration. / AFRIKAANSE OPSOMMING: Agtergrond: Vetsug word geassosieer met dislipidemie, insulien weerstandigheid en glukose intoleransie, wat saam die metaboliese sindroom karakteriseer (Dandona et al. 2005). Met vetsug is daar ‗n hoë sirkulasie van vetsure, sowel as verhoogde vertsuur oksidasie wat gevolglik glukose oksidasie onderdruk. Dit: (i) verlaag die hart se vermoë om saam te trek, (ii) vererger isgemiese/herperfusie skade en (iv) verlaag kardiale effektiwiteit gedurende herperfusie (Kantor et al. 2000; Liu et al. 2002; Taegtmeyer, 2000). Doel: Die doel van die studie was om die effekte van vetsuur onderdrukking m.b.v. oksfenisien (4-Hidroksie-L-fenielglisien) op (i) meganiese hart funksie, (ii) mitokondriale respirasie, (iii) miokardiale toleransie teen isgemiese/herperfusie skade, (iv) CPT-I uitdrukking, MCAD uitdrukking, IRS-1 aktiwiteit, totale GLUT-4 uitdrukking en (v) die RISK pad (ERK42/44 en PKB/Akt) te ondersoek. Metodes: Manlike Wistar rotte was gevoer met ‗n kontrole rot dieet of ‗n hoë kalorie dieet (HKD) vir 16 weke. Die HKD lei tot dieet-geïnduseerde vetsug (DGV). Die diere was lukraak verdeel in 4 groepe [kontrole, DGV, kontrole + oksfen en DGV + oksfen]. Die behandeling met die middel was toegedien vir die laaste 8 weke van die voeding protokol (200mg/kg/dag). Die diere was geslag en die harte was geperfuseer op die Langendorff perfusie sisteem. Na blootstelling aan streeks- of globale isgemie en 2 ure herperfusie was infark groottes bepaal. ‗n Aparte reeks diere was gevoer en/of behandel en die harte was versamel na 25 minute globale isgemie gevolg deur 30 minute herperfusie vir die bepaling van GLUT-4, CPT 1, IRS -1, MCAD, ERK (42/44) en PKB/Akt uitdrukking/aktivering d.m.v. Western blot analise. ‗n Derde reeks diere was gebruik vir die isolasie van mitokondria. Resultate: In die DGV diere, het kroniese oksfenisien behandeling meganiese hart funksie verbeter d.m.v. die verbetering van mitokondriale respirasie. Oksfenisien het CPT-1 uitdrukking verlaag terwyl GLUT- 4 en MCAD uitdrukking nie geaffekteer was vi nie. Oksfenisien het IRS-1 uitdrukking verlaag, maar nie IRS-1 aktiwiteit nie. Oksfenisien het ook miokardiale weerstand teen isgemiese/herperfusie verbeter met sonder aktivering van die RISK pad (ERK & PKB). In die kontrole diere, het kroniese oksfenisien behandeling die meganiese hart funksie versleg d.m.v. negatiewe effekte op mitokondriale respirasie. Oksfenisien het die miokardiale weerstand teen isgemiese/herperfusie van die kontrole rotte versleg sonder veranderinge in die RISK pad (ERK & PKB). Oksfenisien het geen effek gehad op CPT-1, MCAD en GLUT-4 uitdrukking nie. Oksfenisien het IRS-1 uitdrukking verhoog, maar nie IRS-1 aktiwiteit nie. Samevatting: Kroniese oksfenisien behandeling het die meganiese hart funksie en miokardiale weerstand teen isgemiese/herperfusie skade in die vet diere verbeter, maar versleg in die kontrole diere. Hierdie verbetering van meganiese hart funksie en weerstand teen isgemiese/herperfusie skade kon dalk wees a.g.v. ‗n verbetering in mitokondriale respirasie.

Oxfenicine

Cardiac protection

Fatty acid Oxidation inhibition

Cardio metabolism

Theses -- Medical physiology

Dissertations -- Medical physiology

Theses -- Medicine

Dissertations -- Medicine

Heart -- Metabolism

Obesity -- Prevention

Insulin resistance

Glucose intolerance

Biomedical Sciences

Investigation of the N-terminal interactions of cardiac myosin-binding protein C (cMyBPC) under defined phosphorylation states

Ramburan, A.

12 1900

PhD / The overall objective of this thesis is to provide additional data to assist clinicians and experimental neurologists alike in the quest for better understanding, more accurately diagnosing and more successfully treating patients suffering from Parkinson’s disease (PD). The general theme of the thesis is the interaction between certain environmental stimuli, including the exposure to adverse events during early central nervous system (CNS) development and the manifestation of elements of neurodegeneration, whether by means of neurochemical changes or expressed as a dysfunctional voluntary motor system. The first chapter provides a general introduction to the research theme of the thesis. This includes, in particular, a discussion on current understanding concerning the etiology and clinical profile of PD, the relative contribution made by genetic factors compared to environmental ones, and current treatment strategies for treating the disease. Mention is also made of the failure of these therapeutic applications for reversing or protecting against the disease, due to the side-effects associated with them. The material covered in chapter 1 provides the basis for the more complete discussion concerning these various aspects, contained in the chapters to follow. The overall aim was also to characterise the effects of commonly used toxin-induced animal models of PD, and the extent of vulnerability that the CNS displays towards them. The destruction of dopaminergic neurons following the administration of 6-OHDA at targeted points along the nigrostriatal tract is used extensively to model PD pathology in rats and is an established animal model of the disease. However, mature or even aged animals are mainly used in these studies, while the effects that the toxin might have on the developing CNS remain unclear. The study reported in chapter 4 aimed to elucidate some of 6-OHDA’s actions on the young adolescent (35 days-old) CNS by comparing the motor and biochemical effects of a unilateral infusion of the toxin into two anatomically distinct basal ganglia loci: The medial forebrain bundle (MFB) and the striatum. Animals were randomly assigned to receive either a direct delivery of 6-OHDA (12μg/4μl) into the MFB or an indirect injection, into the striatum. Although both lesion types were used, the MFB model is considered a more accurate portrayal of end-stage PD, while the striatum-model better reflects the long-term progressive pathology of the disease. The different lesions’ effects on motor function were determined by observing animal’s asymmetrical forelimb use to correct for weigh shifting during the vertical exploration of a cylindrical enclosure. Following the final behavioral assessment, the concentration of dopamine (DA) and DA metabolites remaining in the post-mortem brains were determined using 4 HPLC electrochemistry (HPLC-EC) and the levels compared between the two groups. The HPLC-EC results revealed a compensatory effect for DA production and DA turnover on the lesioned hemisphere side of the toxin-infused animal group. Thus, following 6-OHDA treatment, there appears to be extensive adaptive mechanisms in place within the remaining dopaminergic terminals that may be sufficient for maintaining relatively high extracellular and synaptic concentrations of DA. However, since substantial changes in motor-function were observed, it is suggested that the capacity of the remaining dopaminergic neurons to respond to increased functional demands may be limited. In addition, the behavioral results indicate that the distinct indices relating to different functional deficits depend on the lesioning of anatomically distinct structures along the nigrostrial tract. It has long been known that far fewer women are diagnosed with PD than men are. This seeming protection offered to females against degenerative disease of the CNS may relate to estrogen, although the hormone’s mechanism of action on the dopaminergic system is poorly defined. With an estimated 10-15 million women using oral contraceptives (OCs) in the United States alone, the aim of chapter 2 was to examine the evidence for a possible relationship between PD and the female reproductive hormone estrogen. A review of the current literature available on the topic was performed by consulting Medline, and by performing a search of the case-reports contained within the World Health Organization’s (WHO) International Drug Monitoring database, for possible PD-related symptoms that may arise from estrogen replacement therapy (ERT). The results, whilst conflicting, seem to suggest that estrogen protects women from obtaining the disease, or at least some features of it. Intensive research efforts are called for, with sufficient power to establish the relationship between ERT and the onset and development of parkinsonism. Chapter 3 reports on the results obtained from an experiment that subjected young Sprague-Dawley rats, 35 days of age, to a lower and a higher dose of 6-OHDA delivered to the MFB. Control rats received equivalent saline infusions. At 14 days post-surgery, the rats were evaluated for forelimb akinesia. For the higher dose of 6- OHDA the female rats were less impaired than males in making adjustment steps in response to a weight shift and in the vibrissae-evoked forelimb placing test. In addition, Tyrosine hydroxylase (TH) immunoreactivity was significantly higher for the female rats. Early gender differences in cell survival factors and/or other promoters of neuroplasticity may have contributed to the beneficial outcome seen in the females. For example, nerve growth factor (NGF) was found to be higher in the female rats following administration of the DA neurotoxin. It is unclear whether gonadal steroids are involved, and, if so, whether female hormones are protective or whether male hormones are prodegenerative. Determining the mechanisms for the improved outcome seen in the young female rats may lead to potential treatment strategies against PD. 5 Many studies have shown that early life stress may lead to impaired brain development, and may be a risk factor for developing psychiatric diseases, including clinical depression. However, few studies have investigated the impact that early stress may have on the onset and development of neurodegenerative disorders such as PD. The study reported on in chapter 5 conjointly subjected rat pups to a maternal separation (MS) paradigm that is a well characterised model of adverse early life events, and a unilateral, intrastriatal injection of 6- OHDA. The combined effects of these models on motor deficits and brain protein levels were investigated. Specifically, the animals were assessed for behavioral changes at 28 days postlesion with a battery of tests that are sensitive to the degree of DA loss sustained. The results show that animals that had been subjected to MS display poorer performance in the vibrissae and single-limb akinesia test compared to non-MS control animals (that had also been subjected to the toxin exposure). In addition, there was a significant increase in the loss of TH staining in MS rats compared to non-MS ones. The results from this study therefore suggest that exposure to adverse experiences during the early stages of life may contribute towards making dopaminergic neurons more susceptible to subsequent insults to the CNS occurring during mature stages of life. Therefore, taken together, early exposure to stress may predispose an individual towards the onset and development of neurodegenerative disease, which especially becomes a threat during the later stages of adult life. Moreover, within the framework of these characteristics, the capacity of a widely-used pharmacological agent (statins) was tested for possible future therapeutic application in PD (chapter 7). Although the precise cause of sporadic PD remains an enigma, evidence suggests that it may associate with defective activity of complex I of the mitochondrial electron transport chain. Mitochondrial DNA transmit and express this defect in host cells, resulting in increased oxygen free radical production, depressed antioxidant enzyme activities, and greater susceptibility to apoptotic cell death. Simvastatin is a member of the 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors (statins) group of drugs that are widely used for lowering cholesterol levels in patients who display elevated concentrations of low-density lipoprotein cholesterol. The study aimed to investigate the effects that statin-treatment have on motor-function and at the mitochondrial-protein level, using rotenone, a mitochondrial complex I inhibitor, as a rat-model of PD. Adult male Sprague-Dawley rats were treated either with simvastatin (6mg/day for 14 days) or with a placebo. Two different tests to assess motor function were used: The apomorphine-rotation test, and the vibrissae-elicited forelimb placement test. Following the drug administration protocol, the nigrostriatal tract was unilaterally lesioned with either rotenone (3 μg/4 μl) or, for the controls, were sham-operated by infusing the vehicle (DMSO:PEG) only. Five days later the rats were killed and a highly purified concentration of isolated mitochondria was prepared from the substantia nigra (SN) sections. 2- 6 Dimensional electrophoresis (2-DE) with subsequent identification of the spots using electronspray ionization quadruple time-of-flight mass spectrometrical (ESI-Q-TOF MS) was performed and the results BLAST-searched using bio-informatics tools for naming the identified peptides. The motor test results indicate that while unilateral rotenone causes behavioral asymmetries, treatment with simvastatin improved motor function relative to the rotenoneinduced ones. Mass Spectroscopy identified 23 mitochondrial proteins that differ significantly in protein expression (p < 0.05) following simvastatin treatment. The altered proteins were broadly classified according to their cellular function into 6 categories, with the majority involved in energy metabolism. This study effectively illustrated how neuroproteomics, with its sophisticated techniques and non-biased ability to quantify proteins, provides a methodology with which to study the changes in neurons associated with neurodegeneration. As an emerging tool for establishing disease-associated protein profiles, it also generates a greater understanding as to how these proteins interact and undergo post-translational modifications. Furthermore, due to the advances made in bioInformatics, insight is created concerning their functional characteristics. Chapter 4 summarises the most prominent proteomics techniques and discuss major advances made in the fast-growing field of neuroproteomics in PD. Ultimately, it is hoped that the application of this technology will lead towards a presymptomatic diagnosis of PD, and the identification of risk factors and new therapeutic targets at which pharmacological intervention can be aimed. The final chapter (chapter 8) provides a retrospective look at the academic work that had been performed for the purpose of this thesis, recaps on the main findings, and also highlights certain aspects of the project and provides relevant suggestions for future research. Lastly, the appendix provides a detailed overview of the methods followed for the experiments described in this thesis. It provides not only a comprehensive description of the techniques that had been followed, but provides information concerning the care taken with the animals (i.e. post-surgery) in order to control for the potential influence of experimental variables on the results.

Protein-protein interactions

Y2H

Co-localisation

BRET assays

Cardiac dysfunction

Myosin binding protein

Medicine

Heart function tests

Muscle proteins

Heart -- Metabolism