Signalling regulation of cardiac hypertrophy by the mitogen activated protein kinase (MAPK) pathways

Jin, Jiawei

January 2012

Heart failure induced by cardiac hypertrophy is a cause of high mortality in the world and has been the fastest growing cardiovascular disease over the past decade. Cardiac hypertrophy is characterised as a reactive increase in cardiac mass growth with a complex of ventricular remodelling. It occurs initially as a compensatory response to an increased workload but eventually leads to cardiac dysfunction. An in-depth understanding of cardiac hypertrophy and the capacity to regulate it has profound clinical implications. The MAPK pathways provide an important connection between external stimuli and intracellular signals for cardiac hypertrophic response. At least four MAPK subfamilies have been identified: extracellular-regulated protein kinases 1 and 2 (ERK1/2), ERK5, c-Jun NH2-terminal protein kinases (JNKs) and p38 MAPKs. Mitogen-activated protein kinase kinase 4 (MKK4), a vital activator of JNK and p38 is implicated as an important mediator of hypertrophy. ERK5, an atypical MAPK, is also involved in both hypertrophic growth and cardiomyocyte survival. However, conflicting data have been yielded from previously-published studies, since the results are based entirely on experiments conducted in cultured cardiomyocytes or transgenic and conventional knockout mouse models. To elucidate their biological roles and underlying signalling mechanisms in hypertrophy, mice with a cardiomyocyte-specific deletion of MKK4 or ERK5 (MKK4cko and ERK5cko mice) were generated in the present study. In response to pathological hypertrophic stresses including pressure overload or isoprenaline stimulation, MKK4cko mice developed exacerbated pathological hypertrophy with increased cardiomyocyte apoptosis, impaired cardiac function and remarkably upregulated NFAT (nuclear factor of T-cell) transcriptional activity. However, MKK4cko mice exhibited a similar extent of swimming exercise-induced physiological hypertrophy compared with the controls. In response to pathological hypertrophic stimuli, ERK5cko mice were resistant to hypertrophic growth, foetal gene induction and ventricular fibrosis, which is associated with repressed activation of MEF2 (myocyte enhancer factor 2). ERK5 deficiency also caused a profound increase in cardiomyocyte apoptosis which accounted for the impaired cardiac function. In conclusion, the present study provides biological evidence that clarifies in vivo functions of MKK4 and ERK5 in hypertrophy. MKK4 acts a protective role against pathological hypertrophy through inhibiting NFAT signalling, but it is not necessary for the regulation of physiological hypertrophy. ERK5 is essential for pathological hypertrophic remodelling and cardiomyocyte survival and its function in hypertrophic remodelling is mediated through regulation of MEF2 activity. Taken together, these data presented in my thesis advances knowledge about biological functions of MAPK pathways in the heart.

Modelling of calcium handling in genetically modified mice

Li, Liren

January 2011

This thesis develops biophysically-based data-driven mathematical models of intracellular calciumdynamics in ventricularmyocytes for both normal and genetically modified mouse hearts, based on species- and temperature-consistent experimental data. The models were subsequently applied to quantitatively examine the changes in calcium dynamics in mice with cardiomyocyte-specific knockout (KO) of the cardiac sarco/endoplasmic reticulum ATPase (SERCA2) gene, to determine the contributing mechanisms which underlie the ultimate development of heart failure in these animals. In Chapter 1, with emphasis on calcium dynamics and calcium regulation in heart failure, an overview of cardiac electrophysiology, excitation-contraction coupling and mathematical models of cardiac electrophysiology is provided. In Chapter 2, models of calcium dynamics in the ventricular myocytes from the C57BL/6 mouse heart at a physiological temperature is developed and validated based on species- and temperature-consistent measurements. In Chapter 3, the C57BL/6 model framework is re-parameterised to experimental data from the control and SERCA2 KO mice at 4 weeks after gene deletion. The models are then used to quantitatively characterise changes in calcium dynamics in the KO animals and the role of the compensatory mechanisms. In Chapter 4, the model framework is extended to include differential distributions of ion channels in the sarcolemma and the calcium dynamics in the sub-sarcolemmal space, with parameters in these sub-components fitted to experimentally measured calcium dynamics from the control and KO cardiomyocytes at 7-week after gene deletion. Finally in Chapter 5, conclusions are drawn, the limitations of this study are discussed, and the future extensions to this study are described.

572.516

An integrative framework for computational modelling of cardiac electromechanics in the mouse

Land, Sander

January 2013

This thesis describes the development of a framework for computational modelling of electromechanics in the mouse, with the purpose of being able to integrate cellular and tissue scale observations in the mouse and investigate physiological hypotheses. Specifically, the framework is applied to interpret electromechanical coupling mechanisms and the progression of heart failure in genetically modified mice. Chapter 1 introduces the field of computational biology and provides context for the topics to be investigated. Chapter 2 reviews the biological background and mathematical bases for electromechanical models, as well as their limitations. In Chapter 3, a set of efficient computational methods for coupled cardiac electromechanics was developed. Among these are a modified Newton method combined with a solution predictor which achieves a 98% reduction in computational time for mechanics problems. In Chapter 4, this computational framework is extended to a multiscale electromechanical model of the mouse. This electromechanical model includes our novel cardiac cellular contraction model for mice, which is able to reproduce murine contraction dynamics at body temperature and high pacing frequencies, and provides a novel explanation for the biphasic force-calcium relation seen in cardiac myocytes. Furthermore, our electromechanical model of the left ventricle of the mouse makes novel predictions on the importance of strong velocity-dependent coupling mechanisms in generating a plateau phase of ventricular pressure transients during ejection. In Chapter 5, the framework was applied to investigate the progression of heart failure in genetically modified 'Serca2 knockout' mice, which have a major disruption in mechanisms governing calcium regulation in cardiac myocytes. Our modelling framework was instrumental in showing for the first time the incompatibility between previously measured cellular calcium transients and ventricular ejection. We were then able to integrate new experimental data collected in response to these observations to show the importance of beta-adrenergic stimulation in the progression of heart failure in these knockout mice. Chapter 6 presents the conclusions and discusses possibilities for future work.

616.129

Lymphocyte Contributions to Local and Systemic Cardiovascular Regulation in Mouse Pregnancy

Burke, Suzanne Diana

02 September 2010

Healthy term pregnancy requires precisely timed coordination of multiple systems, including reproductive, neuroendocrine, immune and cardiovascular. Dynamic maternal alterations occur systemically as well as locally within the reproductive tract. Systemic cardiovascular changes during gestation are relatively conserved in mammals, permitting comparison. These physiological changes are relatively acute and reversible, in contrast to the pathological changes seen during cardiovascular disease development. Gestational hypertensive disorders, such as preeclampsia, are the leading causes of maternal and fetal morbidity and mortality. The pathogenesis of preeclampsia is not fully elucidated, but perturbation of the immune system is a fundamental component. The angiogenic and vascular properties of uterine NK lymphocytes have been well studied in mice and women, but their relationships to gestational blood pressure regulation and cardiovascular adaptations have not been addressed. In non-pregnant women and mice, T cells, but not B cells, have been found to alter cardiovascular functioning. NK cells in humans also possess these capabilities, but no functional studies have been completed. The aim of this thesis was to define the role of NK and T lymphocytes in cardiovascular adaptations during mouse gestation. Using chronic radiotelemetry, histology, post-mortem and other techniques, female inbred mice of differing genotypes that lack specific lymphocyte subsets were compared before and across gestation. In normal, immune competent mice, a five-phase gestational blood pressure profile was found. This dynamic profile corresponded to stages of placental development. In mice with a compound deficit in arterial modification and lymphocytes, no gestational hypertension was observed. To elevate the maternal challenge of pregnancy, studies of pregnant, autoimmune Type 1 Diabetic mice were conducted. Impaired spiral artery remodeling, dysfunctional lymphocytes and growth-restricted fetuses were identified. From mid-gestation, diabetic pregnant mice were hypotensive and bradycardic and showed signs of pre-renal failure (proteinuria and electrolyte imbalances). In pregnant mice lacking T cells, tachycardia was observed despite otherwise normal gestational outcomes. In pregnant mice lacking T cells with impaired NK cells, blood pressure was blunted and tachycardia was observed. These findings support the conclusion that impaired spiral artery remodeling is insufficient to cause gestational hypertension in mice. The data further identify a role for T and NK cells in cardiac function during gestation. / Thesis (Ph.D, Anatomy & Cell Biology) -- Queen's University, 2010-09-01 20:56:15.648

Immunology

Lymphocytes

Radiotelemetry

Blood Pressure

Type 1 Diabetes

Genetically modified mice

Pregnancy

Uterine natural killer cells

Vascular remodeling