Comparação de modelos para estimativa da máxima variação do potencial elétrico transmembrana induzida por campos elétricos externos em cardiomiócitos isolados de ratos de diferentes idades / Comparison of models to estimate the maximal transmembrane electrical potential variation induced by electrical fields in isolated cardiomyocytes of rats of different ages

Milan, Hugo Fernando Maia, 1991-

26 August 2018

Orientadores: José Wilson Magalhães Bassani, Rosana Almada Bassani / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Elétrica e de Computação / Made available in DSpace on 2018-08-26T11:22:43Z (GMT). No. of bitstreams: 1 Milan_HugoFernandoMaia_M.pdf: 2735459 bytes, checksum: 650eb9ee4f85d8ff73ae612f72ae3534 (MD5) Previous issue date: 2015 / Resumo: Tendo em vista que a estimulação com campos elétricos externos (E) é utilizada na prática clínica para tratamento de arritmias cardíacas, é necessário um melhor entendimento do fenômeno de polarização da membrana plasmática de cardiomiócitos por E. O disparo de potencial de ação, e subsequente contração celular, induzido por E em cardiomiócitos depende da indução de variação do potencial elétrico transmembrana (?Vm) que leve este potencial ao valor limiar. Devido às limitações dos métodos atualmente disponíveis para medir ?Vm e seu valor máximo, ?Vmax, os modelos eletromagnéticos representam uma importante ferramenta para sua estimativa. Porém, os valores calculados dependem de como o fenômeno de polarização da membrana é modelado. Os modelos eletromagnéticos encontrados na literatura aproximam a forma irregular do cardiomiócito a formas geométricas regulares. Entretanto, até o momento, não se sabe qual destes modelos é o mais adequado para se estimar ?Vm. As células miocárdicas apresentam irregularidades em sua forma e, tanto a forma quanto as dimensões das células alteram-se com o desenvolvimento pós-natal. Neste trabalho, foi desenvolvido um modelo numérico tridimensional (MN3D) da forma irregular da célula, e comparou-se as estimativas de ?Vm induzida por E limiar (?VL) feitas com este modelo e com modelos simplificados, entre estes o modelo numérico bidimensional (MN2D) e os modelos analíticos para cilindro (MACil), esfera (MAEsf), esferóide prolato (MAEsPr) e elipsóide (MAElip). Para estimar ?VL, E limiar e as dimensões celulares foram medidos em células cardíacas isoladas de ratos neonatos (5-7 dias), infantes (28-32 dias) e adultos (4-6 meses), em 6 faixas de ângulos entre a direção de aplicação do campo e o eixo maior da célula. Os modelos foram calibrados do ponto de vista eletromagnético, o que mostrou que, MN2D e MACil são inadequados para estimar ?Vmax. Enquanto as estimativas de ?VL com MN3D e MAEsPr não variaram com o ângulo, mas sim com a idade, o oposto ocorreu com as estimativas feitas com o MAElip. Dentro de certas condições, as estimativas de ?VL feitas com MAEsPr foram as mais próximas daquelas feitas com MN3D. Conclui-se que o MAEsPr, menos complexo tecnicamente, pode fornecer estimativas confiáveis de ?VL, desde que o ângulo de aplicação de E seja pequeno (até 30º) / Abstract: Considering that stimulation with external electrical fields (E) is clinically used for arrhythmia treatment, it is important to understand the phenomenon of membrane polarization by E. Action potential and contraction triggering by E in cardiomyocytes depends on the induction of a transmembrane potential variation (?Vm) sufficient for the attainment of the excitation threshold. Due to the limitations of the methods currently available for measurement of ?Vm and its maximum value, ?Vmax, electromagnetic models represent an important tool for this purpose. However, the calculated values depend on how the membrane polarization phenomenon is modeled. The electromagnetic models available in the literature approximate the cardiomyocyte irregular shape to regular geometries. Nevertheless, it has not been ascertained yet which model is the most appropriated to estimate ?Vmax in these cells, of which both dimensions and shape vary markedly during postnatal development, and often present geometric irregularities. Thus, approximation of the cell shape to regular geometries may result in a considerable error in the ?Vm estimation. The aim of this study was to develop a three-dimensional numerical model (MN3D) based on the irregular cell shape and to compare the values of ?Vmax induced by the threshold E (?VL) estimated with this model with those calculated with simplified models, such as the twodimensional numerical model (MN2D) and the analytical models for cylinder (MACil), sphere (MAEsf), prolate spheroid (MAEsPr), and ellipsoid (MAElip). To estimate ?VL, the threshold E and cell dimensions were measured in cardiomyocytes isolated from neonatal (5-7 days), weaning (28-32 days) and adult (4-6 months) rats, for 6 ranges of the angle between the directions of E and the cell major axis. Electromagnetic calibration of the models showed that MN2D and MACil were not suitable for ?Vmax estimation in these cells. While ?VL estimated with MN3D and MAEsPr were angle-independent, but dependent on the animal's age, the opposite was observed regarding the estimates made with MAElip. Under certain conditions, ?VL values estimated with MAEsPr were the closest to those obtained with MN3D. It is concluded that MAEsPr, a less technically complex model, can provide reliable ?VL estimates provided that the angle between the directions of E and the cell major axis is small (up to 30º) / Mestrado / Engenharia Biomedica / Mestre em Engenharia Elétrica

Miócitos cardíacos

Método dos elementos finitos

Estimulação elétrica

Cardiac myocytes

Finite element method

Electrical stimulation

Localização e função de quinase de adesão focal e Calsarcina-1 em cardiomiócitos de ratos = emprego de sondas moleculares e lentivírus / Localization and function of focal adhesion kinase and Calsarcin-1 in rat cardiomyocytes : using of molecular probes and lentivirus

Consonni, Sílvio Roberto, 1986-

05 August 2015

Orientador: Kleber Gomes Franchini / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-27T14:15:11Z (GMT). No. of bitstreams: 1 Consonni_SilvioRoberto_D.pdf: 7954683 bytes, checksum: 766ce32e5bbb5a5c0b8cc78fd2735dc0 (MD5) Previous issue date: 2015 / Resumo: Há um crescente avanço no desenvolvimento das tecnologias que permitam a localização de proteínas em células por microscopias de luz e eletrônica combinadas, com o uso das sondas moleculares miniSOG e Apex2, por exemplo. Adicionalmente busca-se compreender como proteínas são responsáveis pelas funções celulares e teciduais. A Quinase de Adesão Focal (FAK), proteína da cascata de sinalização das integrinas é considerada uma mediadora em potencial do estresse mecânico nos cardiomiócitos. Sabe-se que em cardiomiócitos submetidos a estímulos hipertróficos, ocorre rápida ativação da FAK e sua redistribuição subcelular, contudo são pouco conhecidos os mecanismos envolvidos nesses processos. Outra proteína de grande importância no coração é a Calsarcina-1 (CS1), regulador negativo da via de Calcineurina, crucial no desenvolvimento da hipertrofia cardíaca. Entretanto os mecanismos envolvidos nessa regulação negativa, assim como a distribuição subcelular de CS1 são pouco conhecidos. Visando à interação entre essas áreas para estudo da distribuição espaço-temporal dos componentes celulares e de proteínas, bem como a importância da FAK e CS1 no sarcômero e seu papel na sinalização hipertrófica sob estímulo mecânico, o objetivo geral desse trabalho foi explorar a capacidade das proteínas FAK e CS1 para incorporar geneticamente sondas moleculares que permitissem monitorar por meio de imagens o comportamento dessas moléculas-chave na biologia do disco Z em MVRNs submetida ao estiramento mecânico. Para isso, foram realizados ensaios de localização subcelular com uso de sondas moleculares aplicadas à microscopia correlativa, bem como ensaios bioquímicos, moleculares e de atividade enzimática. Os dados confirmaram a FAK associada às fibras de actina e adesões focais em células H9c2 e foi demonstrado à microscopia de luz que FAK wild-type (wt) translocou-se parcialmente para o compartimento nuclear após estimulação do agonista fenilefrina, enquanto que FAK Y397F (forma mutante inativa) não apresentou mesmo fenótipo. Por outro lado, apesar da padronização e expressão das construções com FAK e miniSOG ou Apex2 em células HEK 293T e H9c2, não foi conclusiva a localização subcelular da FAK, por meio do uso de microscopia eletrônica em MVRN. Provavelmente devido à distribuição difusa da maior parte das moléculas de FAK, não foi identificada uma região elétron-densa conclusiva à microscopia eletrônica de transmissão. No tocante à importância da CS1, observou-se que o estiramento cíclico não induziu o aumento na expressão proteica ou gênica relativa de CS1 e CnA, assim como não houve alteração na atividade fosfatase de CnA. No entanto houve redução da interação de CS1 e CnA, bem como alteração na localização de CS1 em MVRN sob estímulo mecânico. Dados de superexpressão e silenciamento de CS1 corroboram a regulação negativa de CS1 à CnA em MVRN sob estímulo mecânico. Baseando-se em dados estruturais, especulou-se que como o sítio de ligação de NFAT e CS1 à CnA são muito próximos e ao mesmo tempo distante do sítio ativo da fosfatase, é possível que o papel de CS1 na regulação negativa de CnA ocorra por impedimento espacial ao fator de transcrição NFAT. Portanto, esses resultados podem contribuir para uma possível inferência farmacológica, visto que a via de Calcineurina-NFAT é uma das principais mediadoras de hipertrofia em cardiomiócitos, mediante estímulos patológicos / Abstract: There is an increasing move towards the development of technologies that allow the localization of proteins in cells by combined electron and light microscopy, with the use of molecular probes such as miniSOG and APEX2. Additionally we seek to understand how proteins are responsible for the cellular and tissue functions. The Focal Adhesion Kinase (FAK) is protein of integrin signaling cascade considered as a potential mediator of mechanical stress in cardiomyocytes. It is known that in cardiomyocytes subjected to hypertrophic stimuli by rapid activation of FAK and its subcellular redistribution, however the mechanisms involved in these processes are poorly understood. Another very important protein in the heart is Calsarcin-1 (CS1), a negative regulator of the Calcineurin pathway which is crucial in the development of cardiac hypertrophy. However the mechanisms involved in the negative regulation as well as the subcellular distribution CS1 are poorly understood. Aiming at the interaction between these areas to study the spatial-temporal distribution of cellular and protein components, and the importance of FAK and CS1 in the sarcomere and its role in hypertrophic signaling under mechanical stimulation, the aim of this study was to explore the ability of FAK and CS1 to incorporate genetically molecular probes that allow monitoring through images the behavior of these key molecules in the Z disc biology in MVRNs subjected to mechanical stretch. To this end, we performed subcellular localization assays using molecular probes applied to the correlative microscopy, biochemical and molecular assays and enzymatic activity. These data confirm the FAK associated with actin and focal adhesions fibers in H9c2 cells and has been shown by light microscopy that FAK wild-type (wt) is partially translocated to the nuclear compartment after stimulation of the agonist phenylephrine, while FAK Y397F (inactive mutant form) did not show the same phenotype. Moreover, despite standardization and expression of FAK and miniSOG or APEX2 in HEK 293T cells and H9c2, it was inconclusive subcellular localization of FAK, through the use of electron microscopy, in MVRN. Probably due to the diffuse distribution of most FAK molecules, it has no conclusive electron-dense region in transmission electron microscopy. Regarding the importance of CS1, it was observed that the cyclic stretch did not induce an increase in protein expression or gene relative CS1 and CnA, as there was no change in the phosphatase activity of CnA. However there was less interaction CS1 and CnA and change in CS1 location in MVRN under mechanical stimulation. CS1 overexpression and silencing corroborate the negative regulation of the CS1 over CnA in MVRN under mechanical stimulation. Based on structural data, it has been speculated that as the NFAT and CS1 binding sites are very close in CnA and at the same time distant from the active site of the phosphatase, it is possible that the role of CS1 in the negative regulation of CnA occur by steric hindrance to the NFAT transcription factor. Therefore, these results may contribute to a possible pharmacological inference, whereas Calcineurin-NFAT pathway is a major mediator of hypertrophy in cardiac myocytes by pathologic stimuli / Doutorado / Biologia Tecidual / Doutor em Biologia Celular e Estrutural

Miócitos cardíacos

Cardiomiopatia hipertrófica

Sinalização celular

Sondas moleculares

Myocytes, Cardiac

Cardiomyopathy, hypertrophic

Focal adhesion protein-tyrosine kinases

Cell signaling

Molecular probes

Influência da lesão mitocondrial na atividade e expressão de NAD(P)H oxidase da membrana celular em células musculares lisas vasculares / Influence of mitochondrial DNA damage on NAD(P)H oxidase activity and expression in vascular smooth muscle cells

João Wosniak Junior

17 April 2008

Lesão do DNA mitocondrial (mtDNA) promove disfunção desta organela, contribuindo para a gênese do envelhecimento e fisiopatologia de doenças como aterosclerose e diabetes. A mitocôndria é a principal fonte quantitativa de espécies reativas de oxigênio (ROS) em células, e o complexo NAD(P)H oxidase a principal fonte de ROS envolvidas na sinalização celular. A possível inter-relação entre estas duas importantes vias produtoras de ROS não está definida. O objetivo deste estudo foi investigar o perfil de alterações na expressão e atividade da NAD(P)H oxidase de células musculares lisas vasculares (VSMC) em resposta a perturbações mínimas da função mitocondrial análogas às esperadas em doenças crônico-degenerativas vasculares. Inicialmente, validamos modelo in vitro de disfunção mitocondrial induzida por incubação de VSMC com brometo de etídio (24 - 72 h). Lesões mínimas do mtDNA foram documentadas por alterações nos produtos de amplificação (PCR) da região repetitiva da D-loop e redução da taxa de consumo de oxigênio total em ~15% vs. basal (p<0,05). Este grau de lesão não foi suficiente para induzir alterações morfológicas evidentes ou apoptose, e foi associado ao retardo de 25 - 30% no aumento de população celular induzido por soro fetal bovino. Nestas condições, não se detectou aumento da produção basal de superóxido ou mudanças nos níveis de glutationa, óxidos de nitrogênio, ou da atividade superóxido dismutase. A produção basal de peróxido de hidrogênio aumentou ~15%. Após disfunção mitocondrial, houve significativo aumento (30 - 45%) na atividade basal do complexo NAD(P)H oxidase em fração de membrana de VSMC. Entretanto, a ativação da oxidase pela AII, conhecido agonista da oxidase vascular, foi essencialmente abolida, indicando dependência funcional da ativação da oxidase com a integridade da mitocôndria. Em sintonia com esses dados, na condição basal, ocorreu aumento de expressão da isoforma Nox4 da oxidase, enquanto o aumento do mRNA da Nox1 normalmente visto após AII foi minimizado. Por outro lado, o aumento da atividade da NADPH oxidase causado pelo estressor do RE tunicamicina (indutor de Nox4) foi também abolido pela disfunção mitocondrial, entretanto, ocorreu aumento do mRNA da Nox4, indicando que as alterações funcionais da oxidase nesta situação não decorrem apenas de mudanças da expressão. Dissociação semelhante entre expressão e atividade ocorreu após exposição de 72 horas ao EtBr (i.e., durante adaptação). Nesta, ocorreu maior expressão do mRNA de Nox1 e Nox4 com AII, sem aumento da atividade da oxidase em membranas. Incubação do EtBr por 24 horas não induziu per se aumento consistente nos índices de estresse do RE e induziu inversão do padrão do tráfego subcelular da dissulfeto isomerase protéica (PDI), uma chaperona redox descrita recentemente como reguladora da NADPH oxidase. Após 72 horas de incubação com EtBr, a expressão de chaperonas marcadoras de estresse do RE foi bastante diminuída e o tráfego da PDI teve o padrão restaurado. Demonstramos por microscopia confocal evidências preliminares de possível co-localização entre Nox1 e mitocôndria. Estes dados sugerem uma relevante inter-relação funcional entre mitocôndria e complexo NAD(P)H oxidase, associada pelo menos a alterações de expressão e/ou tráfego subcelular de subunidades catalíticas e reguladoras desse complexo. / Mitochondrial DNA (mtDNA) damage induces dysfunction of this organelle, contributing to the genesis of aging and to the pathophysiology of diseases such as atherosclerosis and diabetes. Mitochondria are the main quantitative source of reactive oxygen species (ROS) in cells, while NAD(P)H oxidase complex is a major source of cell signaling-associated ROS. The possible crosstalk between these two relevant sources of ROS is unclear. The aim of this study was to investigate changes in activity and/or expression of vascular smooth muscle cell (VSMC) NAD(P)H oxidase in response to minor perturbations of mitochondrial function similar to those expected to occur in chronic degenerative vascular diseases. Initially, we validated an in vitro model of mitochondrial dysfunction in VSMC, through incubation with ethidium bromide (24 - 72 h). Minimal mtDNA damage after EtBr was shown by distinct amplification patterns (at PCR) of D-loop repetitive region and by ~ 15% oxygen consumption decrease vs. basal (p<0.05). Such mtDNA damage was not sufficient to induce morphologic changes or apoptosis, whereas serum-stimulated increase in cell number was prevented by 25-30%. Under those conditions, baseline superoxide production, as well as levels of glutathione or nitrogen oxides or superoxide dismutase activity were unchanged. Baseline hydrogen peroxide production increased ~15%. VSMC membrane fraction NADPH oxidase activity was increased by 30-45% after mitochondrial dysfunction. However, oxidase activation due to AII (100 nM, 4h) was markedly abrogated, indicating that A-II-driven oxidase activation requires integrity of mitochondrial function. Accordingly, there were increases in baseline mRNA expression of Nox4 oxidase isoform, while the expected increase in Nox1 by AII was minimized. On the other hand, the NADPH oxidase activity induced by the endoplasmic reticulum stressor tunicamycin (Nox4 inducer) after mitochondrial dysfunction was abrogated, however simultaneously with increased Nox4 mRNA, thus indicating that the observed functional alterations in the oxidase complex in these conditions cannot be associated only to mRNA expression changes. After VSMC EtBr incubation for 72 h, similar dissociation between expression and activity was observed, with increase in Nox 1 and Nox4 mRNA by AII, without parallel increase in membrane fraction oxidase activity. Although there was little change in ER stress markers after 24h EtBr, protein disulfide isomerase (PDI), a redox chaperone recently described by us as a novel NAD(P)H oxidase regulator, exhibited a reversal of its subcellular traffic pattern. After 72 h EtBr, the expression of ER markers was strongly decreased and normal PDI traffic was restored. Confocal microscopy suggested possible co-localization between Nox1 and mitochondria. These results suggest a functionally relevant crosstalk between mitochondria and NADPH oxidase complex associated at least to changes in expression and/or subcellular traffic of catalytic or regulatory subunits of this complex.

DNA mitocondrial

Envelhecimento celular

Espécies de oxigênio reativas

Etídio

Miócitos de músculo liso

NADPH oxidase

Aging cell

DNA mitochondrial

Ethidium

Myocytes smooth muscle

NADPH oxidase

Reactive oxygen species

The impact of the β-subunit DPP10 on cardiac action potential and native voltage-gated K+ and Na+ currents

Metzner, Katharina

16 March 2020

Cardiac accessory β-subunits are part of macromolecular ion channel complexes. They can modulate electrophysiological properties of resulting ion currents and action potentials and are supposed to contribute to cardiac disease e.g. arrhythmias or Brugada syndrome. In my thesis, we characterized the functions of dipeptidyl peptidase-like protein 10 (DPP10), a transmembrane β-subunit of cardiac Na+ and K+ channels. Previous studies revealed that DPP10 is expressed in human heart and acts as regulator of Kv channel kinetics. In electrophysiological experiments, we found that DPP10 modulates Ito through Kv4.3 channel complexes by accelerating current densities and the time course of activation, inactivation and recovery from inactivation. Interestingly, co-expression of DPP10 with Kv4.3 and KChIP2 in CHO cells induced a slowly inactivating fraction of Ito, providing evidence for a contribution of Ito on the sustained outward K+ current in cardiomyoctes. Until then, the sustained fraction of K+ currents was thought to be due to IKur. We further studied the contribution of Kv4-mediated Ito to total K+ currents in human atrial myocytes using 4-Aminopyridine to block IKur in combination with Heteropoda toxin 2 to block Kv4 channels. Using this approach, it was possible to separate an Ito fraction of about 19% contributing to the late current component. These data suggest that the generation of a sustained current component of Ito induced by DPP10 may affect the late repolarization phase of an atrial action potential. To further explore the functions of DPP10, we investigated a potential interaction with Nav channels in cardiomyocytes. It was possible to detect DPP10 in human ventricles, with higher expression levels in patients with heart failure. We demonstrated that DPP10 affects cellular action potentials in isolated rat cardiomyocytes after adenoviral gene transfer indicating a reduction in Na+ current density. Voltage-dependent Na+ channel activation and inactivation curve was shifted to more positive potentials with overexpression of DPP10, resulting in enhanced availability of Na+ channels for activation, along with increasing window Na+ current. Thus, we assumed a role of DPP10 on promotion of arrhythmias via interaction with Nav1.5. The results of this study can help to understand the complex interaction pattern between Nav and Kv channels and the role of their β-subunits, especially DPP10. In conclusion, DPP10 was identified as a new modulator of Kv and Nav currents in the human heart, suggesting that this β-subunit may contributes to cardiac arrhythmias and might be a new therapeutic target.:1 Introduction 1.1 The cardiac action potential 1.2 Cardiac potassium channels 1.2.1 The Kv4.3 channel complex 1.2.2 Accessory β subunits of K+ channel 1.2.3 The Kv1.5 channel 1.2.4 Separation of Ito and IKur in native cardiomyocytes 1.3 Cardiac sodium channels 1.3.1 Molecular construction of Nav1.5 channel 1.3.2 Accessory β subunits of Na+ channel 1.3.3 The role of Nav1.5 in cardiac electrical disorders 1.4 Aim of the thesis and systematic approach 2 The research articles 3 Summary 4 Zusammenfassung 6 References 7 Appendices 7.1 Abbreviations

info:eu-repo/classification/ddc/610

ddc:610

cAMP BIOSENSORS AND SPATIOTEMPORAL cAMP SIGNALING IN ADULT CARDIAC MYOCYTES

Warrier, Sunita

06 April 2007

No description available.

cyclic AMP

cAMP

cardiac myocytes

biosensors

signaling

G-protein Coupled receptors

PGE1: beta-adrenergic receptor

muscarinic receptor

acetylcholine

prostaglandin

FRET

CFP

YFP

Alpha1-Adrenergic Receptor Activation Mimics Ischemic Postconditioning in Cardiac Myocytes

Janota, Danielle Marie

04 August 2014

No description available.

Biomedical Research

Biology

alpha1-adrenergic receptors

cardiac, heart

myocardial infarction

ischemia

reperfusion

postconditioning

autophagy

apoptosis

cell death

myocytes

cardiomyocytes

HL-1

Studies on Cell Injury Induced by Hypoxia-Reoxygenation and Oxidized Low Density Lipoprotein : With Special Reference to the Protectiove Effect of Mixed Tocopherols, Omega-3 Fatty Acids and Transforming Growth Factor-beta1

Chen, Hongjiang

January 2003

<p>Hypoxia-reoxygenation (H-R) injury is an important clinical phenomenon in patients with coronary artery disease (CAD). Endothelial injury is a critical step in the initiation and progression of atherosclerosis. Therefore, endothelial and cardiomyocyte protection has been considered an effective step in prevention and treatment of CAD.</p><p>To investigate the cardioprotective effect of tocopherols, omega-3 fatty acid [eicosapentaenoic acid (EPA)] and transforming growth factor-β₁ (TGF-β₁) during H-R, calcium tolerant myocytes isolated from adult rats were cultured and subjected to hypoxia for 24 hrs followed by reoxygenation of 3 hrs. All strategies, including tocopherol preparations, EPA and TGF-β₁, showed attenuation of H-R-induced myocyte injury indicated by reduction of lactate dehydrogenase (LDH) release. Both a-tocopherol and a mixed- tocopherols (α-, γ-, and δ-) decreased the effects of H-R on iNOS expression and SOD activity in cultured myocytes. The mixed-tocopherols was more potent than a-tocopherol alone. EPA inhibited H-R-induced lipid peroxidation, MMP-1 expression and p38MAPK phosphorylation. TGF-β₁ blocked the increase in iNOS and PKB phosphorylation as well as the decrease in eNOS expression in cultured myocytes exposed to H-R.</p><p> To further investigate the protective effect of omega-3 fatty acids [docosahexaenoic acid (DHA) and EPA] and TGF-β₁, the cultured endothelial cells were exposed to oxidant injury mediated by oxidized low-density lipoprotein (ox-LDL). Ox-LDL markedly reduced TGF-β₁ release, increased the expression of TGF-β₁ receptors, upregulated the expression of adhesion molecules, P-selectin and ICAM-1, enhanced the adhesion of monocytes to endothelial cells, and decreased protein kinase B (PKB) activation. Both DHA and EPA blocked these effects of ox-LDL on endothelial cells. Exogenous recombinant TGF-β₁ also ameliorated ox-LDL-induced expression of adhesion molecules and monocytes adhesion, which were blocked by antibodies to the TGF-β₁ type 2, but not to the type 3 receptor.</p><p>These observations provide mechanistic insights into H-R and oxidant injury and tissue protection by three different strategies.</p>

Medicine

Tocopherols

fish oil

TGF-β1

NOS

adhesion molecules

MMPs

PKB

MAPK

H-R

Ox-LDL

Myocytes

HCAECs

Medicin

Studies on Cell Injury Induced by Hypoxia-Reoxygenation and Oxidized Low Density Lipoprotein : With Special Reference to the Protectiove Effect of Mixed Tocopherols, Omega-3 Fatty Acids and Transforming Growth Factor-beta1

Chen, Hongjiang

January 2003

Hypoxia-reoxygenation (H-R) injury is an important clinical phenomenon in patients with coronary artery disease (CAD). Endothelial injury is a critical step in the initiation and progression of atherosclerosis. Therefore, endothelial and cardiomyocyte protection has been considered an effective step in prevention and treatment of CAD. To investigate the cardioprotective effect of tocopherols, omega-3 fatty acid [eicosapentaenoic acid (EPA)] and transforming growth factor-β1 (TGF-β1) during H-R, calcium tolerant myocytes isolated from adult rats were cultured and subjected to hypoxia for 24 hrs followed by reoxygenation of 3 hrs. All strategies, including tocopherol preparations, EPA and TGF-β1, showed attenuation of H-R-induced myocyte injury indicated by reduction of lactate dehydrogenase (LDH) release. Both a-tocopherol and a mixed- tocopherols (α-, γ-, and δ-) decreased the effects of H-R on iNOS expression and SOD activity in cultured myocytes. The mixed-tocopherols was more potent than a-tocopherol alone. EPA inhibited H-R-induced lipid peroxidation, MMP-1 expression and p38MAPK phosphorylation. TGF-β1 blocked the increase in iNOS and PKB phosphorylation as well as the decrease in eNOS expression in cultured myocytes exposed to H-R. To further investigate the protective effect of omega-3 fatty acids [docosahexaenoic acid (DHA) and EPA] and TGF-β1, the cultured endothelial cells were exposed to oxidant injury mediated by oxidized low-density lipoprotein (ox-LDL). Ox-LDL markedly reduced TGF-β1 release, increased the expression of TGF-β1 receptors, upregulated the expression of adhesion molecules, P-selectin and ICAM-1, enhanced the adhesion of monocytes to endothelial cells, and decreased protein kinase B (PKB) activation. Both DHA and EPA blocked these effects of ox-LDL on endothelial cells. Exogenous recombinant TGF-β1 also ameliorated ox-LDL-induced expression of adhesion molecules and monocytes adhesion, which were blocked by antibodies to the TGF-β1 type 2, but not to the type 3 receptor. These observations provide mechanistic insights into H-R and oxidant injury and tissue protection by three different strategies.

Medicine

Tocopherols

fish oil

TGF-β1

NOS

adhesion molecules

MMPs

PKB

MAPK

H-R

Ox-LDL

Myocytes

HCAECs

Medicin

Characterization of the Hypersensitive Response of Glycogen Phosphorylase to Catecholamine Stimulation in Primary Culture Diabetic Cardiomyocytes: A Thesis

Buczek-Thomas, Jo Ann

01 August 1992

The primary goal of my thesis research was to characterize the basis for the hypersensitive response of glycogen phosphorylase to catecholamine stimulation in primary culture diabetic cardiomyocytes. Toward this goal, I have investigated several key regulatory sites in this signaling pathway which could promote the hypersensitive activation of phosphorylase. Specifically, I investigated (1) which adrenergic receptors are involved in mediating the hypersensitive response of glycogen phosphorylase to epinephrine stimulation; (2) whether the presence of fatty acid metabolites affects phosphorylase activation; (3) whether the hypersensitive response of phosphorylase results from altered signal transduction through the β-adrenergic receptor system or from a post-receptor defect; and (4) the potential role for phosphorylase kinase in mediating the hypersensitive response of phosphorylase to catecholamine stimulation. The basis for adrenergic receptor mediation of the catecholamine-induced activation of glycogen phosphorylase was investigated in adult rat cardiomyocytes isolated from normal and alloxan-diabetic animals. Cells derived from diabetic animals exhibited a hypersensitive response to epinephrine stimulation which was apparent 3 hours after cell isolation and was further enhanced upon maintenance of the myocytes in culture for 24 hours. Normal cells initially lacked the hypersensitive response to epinephrine stimulation although upon maintenance of these cells in culture for 24 hours, the hypersensitive response was acquired in vitro. To assess alpha- and beta- adrenergic mediation of the response, normal and diabetic cardiomyocytes were incubated with propranolol, a β-receptor antagonist, prior to direct α1receptor stimulation with phenylephrine. Both normal and diabetic myocytes failed to undergo activation of phosphorylase in 3 or 24 hour cell cultures. In addition, the effects of epinephrine on phosphorylase activation were completely inhibited by propranolol whereas prazosin, an α-receptor antagonist, was unsuccessful. This data suggests that the hypersensitive response of glycogen phosphorylase in normal and diabetic cardiomyocytes is solely mediated through β-adrenergic receptor activation. Since the accumulation of various fatty acid metabolites can affect certain enzymes and signal transduction pathways within the cell, the potential effect of various fatty acid metabolites on phosphorylase activation was investigated. To determine the potential effects of fatty acid metabolites on phosphorylase activation in cultured cardiomyocytes, normal and alloxan-diabetic cells were incubated with either carnitine or palmitoylcarnitine prior to stimulation with epinephrine. Pretreatment of cardiomyocytes with or without carnitine or palmitoylcarnitine for 3 or 24 hours before epinephrine stimulation failed to alter phosphorylase activation. The addition of exogenous carnitine in the absence and presence of insulin was also unsuccessful in attenuating the hypersensitive phosphorylase activation response in 3 and 24 hour, normal and alloxan-diabetic derived cardiomyocytes. To determine if carnitine palmitoyltransferase 1 (CPT-1) activity was responsible for the hypersensitive response of phosphorylase in the diabetic myocytes, both normal and diabetic myocytes were maintained for 3 and 24 hours in the absence and presence of etomoxir, a CPT-1 inhibitor. Subsequent activation of phosphorylase by epinephrine in normal and diabetic myocytes was unaltered in the presence of etomoxir. Collectively, these data fail to support a critical role for fatty acid metabolite involvement in the hypersensitive activation of glycogen phosphorylase in acute, alloxan-diabetic cardiomyocytes. To assess potential G-protein involvement in the response, normal and diabetic-derived myocytes were incubated with either cholera or pertussis toxin prior to hormonal stimulation. Pretreatment of cardiomyocytes with cholera toxin resulted in a potentiated response to epinephrine stimulation whereas pertussis toxin did not affect the activation of this signaling pathway. To determine if the enhanced response of phosphorylase activation resulted from an alteration in adenylyl cyclase activation, the cells were challenged with forskolin. After 3 hours in primary culture, diabetic cardiomyocytes exhibited a hypersensitive response to forskolin stimulation relative to normal cells. However, after 24 hours in culture, both normal and diabetic myocytes responded identically to forskolin challenge. The present data suggest that a cholera toxin sensitive G-protein mediates the hypersensitive response of glycogen phosphorylase to catecholamine stimulation in diabetic cardiomyocytes. This response, which is present in alloxan-diabetic cells, and is induced in vitroin normal cardiomyocytes, is primarily due to a defect at a post-receptor site. To assess the role of phosphorylase kinase in the hypersensitive activation of glycogen phosphorylase in the diabetic heart, phosphorylase kinase activity was measured initially in perfused hearts (to optimize the assay parameters) and subsequently in primary culture cardiomyocytes. Results from these experiments demonstrate that the present method for measuring phosphorylase kinase activity is a reliable indicator of the enzyme's activity in the heart, although the assay conditions must be further optimized before this system can be applied to the measurement of phosphorylase kinase activity in primary cultured cardiomyocytes.

Glycogen Phosphorylase

Receptors

Catecholamine

Diabetes Mellitus

Experimental

Enzyme Activation

Heart

Myocytes

Cardiac

Epinephrine

Rats

Sprague-Dawley

Animal Experimentation and Research

Carbohydrates

Cardiovascular System

Cells

Endocrine System Diseases

Macromolecular Substances

Nutritional and Metabolic Diseases

Organic Chemicals

Tissues

Spiral-Wave Dynamics in Ionically Realistic Mathematical Models for Human Ventricular Tissue

Nayak, Alok Ranjan

January 2013

There is a growing consensus that life-threatening cardiac arrhythmias like ven- tricular tachycardia (VT) or ventricular fibrillation (VF) arise because of the formation of spiral waves of electrical activation in cardiac tissue; unbroken spiral waves are associated with VT and broken ones with VF. Several experimental studies have shown that in homogeneities in cardiac tissue can have dramatic effects on such spiral waves. In this thesis we focus on spiral-wave dynamics in mathematical models of human ventricular tissue which contain (a) conduction in homogeneities, (b) ionic in- homogeneities, (c) fibroblasts, (d) Purkinje fibers. We also study the effect of a periodic deformation of the simulation domain on spiral wave-dynamics. Chapter 2 contains our study of “Spiral-Wave Dynamics and Its Control in the Presence of In homogeneities in Two Mathematical Models for Human Cardiac Tissue”; this chapter follows closely parts of a paper we have published [1]. Chapter 3 contains our study of “Spiral-wave dynamics in a Mathematical Model of Human Ventricular Tissue with Myocytes and Fibroblasts”; this chapter follows closely a paper that we have submitted for publication. Chapter 4 contains our study of “Spiral-wave Dynamics in Ionically Realistic Mathematical Models for Human Ventricular Tis- sue: The Effects of Periodic Deformation”; this chapter follows closely a paper that we have submitted for publication. Chapter 5 contains our study of “Spiral-wave dynamics in a Mathematical Model of Human Ventricular Tissue with Myocytes and Purkinje fibers”; this chapter follows closely a paper that we will submit for publication soon. In chapter 2, we study systematically the AP morphology in a state-of-the-art mathematical model of human ventricular tissue due to ten-Tusscher, Noble, Noble, and Panfilov (the TNNP04 model); we also look at the contribution of individual ionic currents to the AP by partially or completely blocking ion channels associated with the ionic currents. We then carry out systematic studies of plane- wave and circular-wave dynamics in the TNNP04 model for cardiac tissue model. We present a detailed and systematic study of spiral-wave turbulence and spa- tiotemporal chaos in two mathematical models for human cardiac tissue due to (a) ten-Tusscher and Panfilov (the TP06 model) and (b) ten-Tusscher, Noble, Noble, and Panfilov (the TNNP04 model). In particular, we use extensive numerical simulations to elucidate the interaction of spiral waves in these models with conduction and ionic in homogeneities. Our central qualitative result is that, in all these models, the dynamics of such spiral waves depends very sensitively on such in homogeneities. A major goal here is to develop low amplitude defibrillation schemes for the elimination of VT and VF, especially in the presence of in homogeneities that occur commonly in cardiac tissue. Therefore, we study a control scheme that has been suggested for the control of spiral turbulence, via low-amplitude current pulses, in such mathematical models for cardiac tissue; our investigations here are designed to examine the efficacy of such control scheme in the presence of in homogeneities in biophysical realistic models. We find that a scheme that uses control pulses on a spatially extended mesh is more successful in the elimination of spiral turbulence than other control schemes. We discuss the theoretical and experimental implications of our study that have a direct bearing on defibrillation, the control of life-threatening cardiac arrhythmias such as ventricular fibrillation. In chapter 3, we study the role of cardiac fibroblasts in ventricular tissue; we use the TNNP04 model for the myocyte cell, and the fibroblasts are modelled as passive cells. Cardiac fibroblasts, when coupled functionally with myocytes, can modulate their electrophysiological properties at both cellular and tissue levels. Therefore, it is important to study the effects of such fibroblasts when they are coupled with myocytes. Chapter 3 contains our detailed and systematic study of spiral-wave dynamics in the presence of fibroblasts in both homogeneous and inhomogeneous domains of the TNNP04 model for cardiac tissue. We carry out extensive numerical studies of such modulation of electrophysiological properties in mathematical models for (a) single myocyte fibroblast (MF) units and (b) two-dimensional (2D) arrays of such units; our models build on earlier ones and allow for no, one-way, or two-way MF couplings. Our studies of MF units elucidate the dependence of the action-potential (AP) morphology on parameters such as Ef , the fibroblast resting membrane potential, the fibroblast conductance Gf , and the MF gap-junctional coupling Ggap. Furthermore, we find that our MF composite can show autorhythmic and oscillatory behaviors in addition to an excitable response. Our 2D studies use (a) both homogeneous and inhomogeneous distributions of fibroblasts, (b) various ranges for parameters such as Ggap, Gf , and Ef , and (c) intercellular couplings that can be no, one-way, and two-way connections of fibroblasts with myocytes. We show, in particular, that the plane-wave conduction velocity CV decreases as a function of Ggap, for no and one-way couplings; however, for two-sided coupling, CV decreases initially and then increases as a function of Ggap, and, eventually, we observe that conduction failure occurs for low values of Ggap. In our homogeneous studies, we find that the rotation speed and stability of a spiral wave can be controlled either by controlling Ggap or Ef . Our studies with fibroblast inhomogeneities show that a spiral wave can get anchored to a local fibroblast inhomogeneity. We also study the efficacy of a low-amplitude control scheme, which has been suggested for the control of spiral-wave turbulence in mathematical models for cardiac tissue, in our MF model both with and without heterogeneities. In chapter 4, we carry out a detailed, systematic study of spiral-wave dynamics in the presence of periodic deformation (PD) in two state-of-the-art mathematical models of human ventricular tissue, namely, the TNNP04 model and the TP06 model. To the best of our knowledge, our work is the first, systematic study of the dynamics of spiral waves of electrical activation and their transitions, in the presence of PD, in such biophysically realistic mathematical models of cardiac tissue. In our studies, we use three types of initial conditions whose time evolutions lead to the following states in the absence of PD: (a) a single rotating spiral (RS), (b) a spiral-turbulence (ST) state, with a single meandering spiral, and (c) an ST state with multiple broken spirals for both these models. We then show that the imposition of PD in these three cases leads to a rich variety of spatiotemporal pat- terns in the transmembrane potential including states with (a) an RS state with n-cycle temporal evolution (here n is a positive integer), (b) rotating-spiral states with quasiperiodic (QP) temporal evolution, (c) a state with a single meandering spiral MS, which displays spatiotemporal chaos, (d) an ST state, with multiple bro- ken spirals, and (e) a quiescent state in which all spirals are absorbed (SA). For all three initial conditions, precisely which one of the states is obtained depends on the amplitudes and the frequencies of the PD in the x and y directions. We also suggest specific experiments that can test the results of our simulations. We also study, in the presence of PD, the efficacy of a low-amplitude control scheme that has been suggested, hitherto only without PD, for the control of spiral-wave turbulence, via low-amplitude current pulses applied on a square mesh, in mathematical models for cardiac tissue. We also develop line-mesh and rectangular-mesh variants of this control scheme. We find that square- and line-mesh-based, low-amplitude control schemes suppress spiral-wave turbulence in both the TP06 and TNNP04 models in the absence of PD; however, we show that the line-based scheme works with PD only if the PD is applied along one spatial direction. We then demonstrate that a minor modification of our line-based control scheme can suppress spiral-wave turbulence: in particular, we introduce a rectangular-mesh-based control scheme, in which we add a few control lines perpendicular to the parallel lines of the line- based control scheme; this rectangular-mesh scheme is a significant improvement over the square-mesh scheme because it uses fewer control lines than the one based on a square mesh. In chapter 5, we have carried out detailed numerical studies of (a) a single unit of an endocardial cell and Purkinje cell (EP) composite and (b) a two-dimensional bilayer, which contains such EP composites at each site. We have considered bio- physically realistic ionic models for human endocardial cells (Ecells) and Purkinje cells (Pcells) to model EP composites. Our study has been designed to elucidate the sensitive dependence, on parameters and initial conditions, of (a) the dynamics of EP composites and (b) the spatiotemporal evolution of spiral waves of electrical activation in EP-bilayer domains. We examine this dependence on myocyte parameters by using the three different parameter sets P1, P2, and P3; to elucidate the initial-condition dependence we vary the time at which we apply the S2 pulse in our S1-S2 protocol; we also investigate the dependence of the spatiotemporal dynamics of our system on the EP coupling Dgap, and on the number of Purkinje- ventricular junctions (PVJs), which are measured here by the ratio R, the ratio of the total number of sites to the number of PVJs in our simulation domain. Our studies on EP composites show that the frequency of autorhythmic activity of a P cell depends on the diffusive gap-junctional conductance Dgap. We perform a set of simulations to understand the source-sink relation between the E and P cells in an EP composite; such a source-sink relation is an important determinant of wave dynamics at the tissue level. Furthermore, we have studied the restitution properties of an isolated E cell and a composite EP unit to uncover this effect on wave dynamics in 2D, bilayers of EP composites. Autorhythmicity is an important property of Purkinje cell; it helps to carry electrical signals rapidly from bundle of His to the endocardium. Our investigation of an EP composite shows that the cycle length (CL) of autorhythmic activity decreases, compared to that of an uncoupled Purkinje cell. Furthermore, we find that the APD increases for an EP composite, compared to that of an uncoupled P cell. In our second set of simulations for an EP-composite unit, we have obtained the AP behaviors and the amount of flux that flows from the E to the P cell during the course of the AP. The direction of flow of this flux is an important quantity that identifies which one of these cells act as a source or a sink in this EP composite. We have found that the P cell in an EP composite acts as a stimulation-current source for the E cell in the depolarization phase of the AP, when the stimulus is applied to both cells or to the P cell only. However, the P cell behaves both as a source and a sink when the stimulus is applied to the E cell only. In our third set of simulations for an EP composite unit, we have calculated the restitution of the APD; this plays an important role in deciding the stability of spiral waves in mathematical models for cardiac tissue. Our simulation shows that, for the EP composite with high coupling (Dgap = Dmm~10), the APDR slope decreases, relative to its value for an isolated E cell, for parameter sets P1 and P2, and first increases (for 50 ≤ DI ≤ 100 ms) and then decreases for the parameter set P3 ; however, for low coupling (Dgap = Dmm~100), the variation of the AP D as function of DI, for an EP composite, shows biphasic behavior for all these three parameter sets. We found that the above dynamics in EP cable type domains, with EP composites, depends sensitively on R. We hope our in silico studies of spiral-wave dynamics in a variety of state-of-the- art ionic models for ventricular tissue will stimulate more experimental studies that examine such dynamics.

Cardiomyocytes - Ionic Models

Ventricular Fibrillation

Cardiac Fibroblasts

Purkinje Fibers

Ventricular Tissue - Ionic Models

Cardiac Myocytes

Cardiac Tissue - Spiral-Wave Turbulence

Human Ventricular Tissue

Biophysics