Investigating the Roles of Homeobox Containing Transcription Factors Iroquois 3/5 in Mammalian Heart Development and Electrophysiology

Kim, Jieun

06 January 2011

Iroquois homeobox (Irx) family members, a group of highly conserved homeodomain containing transcription factors, are involved in the patterning and the proper functions of vertebrate organs. They can act as transcriptional activators or repressors in a context-dependent manner. Preliminary data indicated that Irx3 and Irx5 are functionally redundant during cardiac morphogenesis, and they physically interact with other cardiac transcription factors. At E14.5, outflow tract septation failure and ventricular septation failure were observed in Irx3/5DKO mouse hearts. Loss of Irx3/5 in neural crest and endothelial cell lineages led to outflow tract septation failure and ventricular septal defect. In adult mice, Irx3 is expressed in the atrioventricular conduction system, and loss of Irx3 leads to slower ventricular conduction velocity. qRT-PCR analysis and immunofluorescence staining revealed that the expression of gap junction proteins, Cx40 and Cx43, are affected by the loss of Irx3. Over-expression of Irx3 and a dominant repressor form of Irx3, Irx3-EnR, resulted in Cx40 upregulation, indicating that Irx3 acts as an indirect positive regulator of Cx40. Irx3-EnR over-expression in vivo resulted in postnatal onset of atrial enlargement, ventricular hypertrophy, and conduction failure. Taken together, this study demonstrates the significance of Irx3/5 in both cardiovascular development and cardiac electrophysiology.

Iroquois

homeobox

heart development

cardiac electrophysiology

cardiac transcription factor

0369

The Effects of Calcium Channel Blockade and Atrial Natriuretic Peptide Signalling on Proliferation and Differentiation of Cardiac Progenitor Cells

Hotchkiss, Adam, Gordon

01 August 2013

Cardiac progenitor cells (CPCs) are abundant in the embryonic heart and have hallmark features which include a rapid rate of cell division and the ability to differentiate into mature heart muscle cells (cardiomyocytes). Based on these features, CPCs are considered an attractive candidate cell type for transplantation therapies which aim to replenish the diseased heart muscle tissue (myocardium) with new muscle forming cells. A better understanding of how pharmacological drugs and endogenous hormones/signalling molecules modulate the balance between proliferation and differentiation of CPCs could be used to develop more effective cell based therapies for myocardial repair. Furthermore, this information could provide valuable new insight into molecular mechanisms regulating normal cardiogenesis during the embryonic period. The specific aims of the present study were to characterize the effects of the Ca2+ channel blocking drug nifedipine and the endogenous hormone/paracrine factor atrial natriuretic peptide (ANP) on CPC proliferation and differentiation. Results showed that primary cultured CPCs, isolated from the ventricles of embryonic day (E) 11.5 mouse embryos, underwent a reduction in cell cycle activity following exposure to nifedipine. Furthermore, systemic administration of nifedipine to adult mice receiving transplanted E11.5 ventricular cells (containing CPCs) was associated with smaller graft sizes compared to control animals that did not receive the drug. Results from the present study also demonstrated that ANP receptor mediated signalling systems are biologically active in E11.5 ventricular cells and have an antiproliferative effect on cultured E11.5 CPCs. Moreover, preliminary data provided evidence that genetic ablation of the ANP high affinity receptor (NPRA) may be associated with impaired development of the ventricular cardiac conduction system. Collectively, work from this thesis provides evidence that interactions between transplanted cells and pharmacological drugs could have a significant impact on the effectiveness of cell based therapies and that ANP signalling systems may play a critical role in cardiac ontogeny by regulating the balance between CPC proliferation and differentiation.

Parameter optimization in simplified models of cardiac myocytes

Mathavan, Neashan , Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW

January 2009

Atrial fibrillation (AF) is a complex, multifaceted arrhythmia. Pathogenesis of AF is associated with multiple aetiologies and the mechanisms by which it is sustained and perpetuated are similarly diverse. In particular, regional heterogeneity in the electrophysiological properties of normal and pathological tissue plays a critical role in the occurrence of AF. Understanding AF in the context of electrophysiological heterogeneity requires cell-specific ionic models of electrical activity which can then be incorporated into models on larger temporal and spatial scales. Biophysically-based models have typically dominated the study of cellular excitability providing detailed and precise descriptions in the form of complex mathematical formulations. However, such models have limited applicability in multidimensional simulations as the computational expense is too prohibitive. Simplified mathematical models of cardiac cell electrical activity are an alternative approach to these traditional biophysically-detailed models. Utilizing this approach enables the embodiment of cellular excitation characteristics at minimal computational cost such that simulations of arrhythmogensis in atrial tissue are conceivable. In this thesis, a simplified, generic mathematical model is proposed that characterizes and reproduces the action potential waveforms of individual cardiac myocytes. It incorporates three time-dependent ionic currents and an additional time-independent leakage current. The formulation of the three time-dependent ionic currents is based on 4-state Markov schemes with state transition rates expressed as nonlinear sigmoidal functions of the membrane potential. Parameters of the generic model were optimized to fit the action potential waveforms of the Beeler-Reuter model, and, experimental recordings from atrial and sinoatrial cells of rabbits. A nonlinear least-squares optimization routine was employed for the parameter fits. The model was successfully fitted to the Beeler-Reuter waveform (RMS error: 1.4999 mV) and action potentials recorded from atrial tissue (RMS error: 1.3398 mV) and cells of the peripheral (RMS error: 2.4821 mV) and central (RMS error: 2.3126 mV) sinoatrial node. Thus, the model presented here is a mathematical framework by which a wide variety of cell-specific AP morphologies can be reproduced. Such a model offers the potential for insights into possible mechanisms that contribute to heterogeneity and/or arrhythmia.

Parameter Optimization

Atrial Fibrillation

Cardiac Electrophysiology

Cardiac arrhythmia

Surgical treatment of atrial fibrillation : clinical, hormonal and electrophysiological aspects of the Maze operation /

Albåge, Anders,

January 2003

Diss. (sammanfattning) Stockholm : Karol. inst., 2003. / Härtill 5 uppsatser.

Cytoarcheology: understanding cellular turnover in the human brain and heart /

Bhardwaj, Ratan D.,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 3 uppsatser.

A clinical evaluation of non-invasive techniques for monitoring myocardial function and a model proposal for cardio-pulmonary evaluation a research report submitted in partial fulfillment ... /

Masud, Marie. Cramer, Sachiko.

January 1979

Thesis (M.S.)--University of Michigan, 1979.

A clinical evaluation of non-invasive techniques for monitoring myocardial function and a model proposal for cardio-pulmonary evaluation a research report submitted in partial fulfillment ... /

Masud, Marie. Cramer, Sachiko.

January 1979

Thesis (M.S.)--University of Michigan, 1979.

Arterial versus Venous Fluid Resuscitation; Restoring Cardiac Contractions in Cardiac Arrest Following Exsanguinations

Youssef, Asser M., Hamidian Jahromi, Alireza, Simpkins, Cuthbert O.

06 August 2016

Background: Arterial cannulation and intra-arterial (IA) fluid and blood resuscitation in the patients with severe shock is an easier approach compared with the intravenous (IV) access if concerns regarding the efficiency and safety of this approach are addressed. Objectives: We hypothesized that IA fluid resuscitation is more effective than IV resuscitation in restoring cardiac contractions (CC) of cardiac-arrested mice following severe hemorrhagic shock. Methods: Mice (N = 22) were anesthetized using ketamine/xylazine. Arterial and venous systems accessed through cannulation of the carotid artery and the Jugular vein, respectively. As much blood as possible was aspirated from the carotid artery access. Mice were observed until the complete cessation of chest wall motions. Following 30 seconds delay, IV (N = 5) and IA access (N = 6) were used for fluid resuscitation using Ringer Lactate (RL) in a similar volume to the aspirated blood. Mice were observed for restoration of chest wall motions. In phase-II of the study, after cessation of chest motions, mice (N = 11) underwent a thoracotomy and CCs were observed. In three mice, IV RL Infusion after cardiac arrest failed to restore CCs and was followed by IA RL infusion. In eight mice, following cardiac arrest intermittent IA RL infusion was performed. Results: While IV RL Infusion failed to restore chest motion in mice (N = 5), IA RL infusion restored chest motion in all mice examined (N = 6) (P = 0.0067). In three mice, IV RL infusion after cardiac arrest showed no effect on CC. After failure of venous infusion, IA RL infusion was performed which resulted in restoration of CC for 13.33 +/- 1.76 minutes. In eight mice, intermittent IA infusion of RL after cardiac arrest, sustained CC for 31.43 +/- 10.9 minutes (P = 0.017). Conclusions: IA fluid resuscitation is superior to IV resuscitation in hemorrhagic shock induced cardiac arrest.

Arterial

Venous

Fluid Resuscitation

Cardiac Contractions

Cardiac Arrest

Exsanguinations

Overexpression of Myeloid Differentiation Protein 88 in Mice Induces Mild Cardiac Dysfunction, but No Deficit in Heart Morphology

Chen, W., Huang, Z., Jiang, X., Li, C., Gao, X.

01 January 2016

Cardiac remodeling involves changes in heart shape, size, structure, and function after injury to the myocardium. The proinflammatory adaptor protein myeloid differentiation protein 88 (MyD88) contributes to cardiac remodeling. To investigate whether excessive MyD88 levels initiate spontaneous cardiac remodeling at the whole-organism level, we generated a transgenic MyD88 mouse model with a cardiac-specific promoter. MyD88 mice (male, 20–30 g, n=~80) were born at the expected Mendelian ratio and demonstrated similar morphology of the heart and cardiomyocytes with that of wild-type controls. Although heart weight was unaffected, cardiac contractility of MyD88 hearts was mildly reduced, as shown by echocardiographic examination, compared with wild-type controls. Moreover, the cardiac dysfunction phenotype was associated with elevation of ANF and BNP expression. Collectively, our data provide novel evidence of the critical role of balanced MyD88 signaling in maintaining physiological function in the adult heart.

cardiac dysfunction

cardiac remodeling

myeloid differentiation protein 88

transgenic mice

Pellino1-Mediated TGF-β1 Synthesis Contributes to Mechanical Stress Induced Cardiac Fibroblast Activation

Song, Juan, Zhu, Yun, Li, Jiantao, Liu, Jiahao, Gao, Yun, Ha, Tuanzhu, Que, Linli, Liu, Li, Zhu, Guoqing, Chen, Qi, Xu, Yong, Li, Chuanfu, Li, Yuehua

01 February 2015

Activation of cardiac fibroblasts is a key event in the progression of cardiac fibrosis that leads to heart failure. However, the molecular mechanisms underlying mechanical stress-induced cardiac fibroblast activation are complex and poorly understood. This study demonstrates that Pellino1, an E3 ubiquitin ligase, was activated in vivo in pressure overloaded rat hearts and in cultured neonatal rat cardiac fibroblasts (NRCFs) exposed to mechanical stretch in vitro. Suppression of the expression and activity of Pellino1 by adenovirus-mediated delivery of shPellino1 (adv-shpeli1) attenuated pressure overload-induced cardiac dysfunction and cardiac hypertrophy and decreased cardiac fibrosis in rat hearts. Transfection of adv-shpeli1 also significantly attenuated mechanical stress-induced proliferation, differentiation and collagen synthesis in NRCFs. Pellino1 silencing also abrogated mechanical stretch-induced polyubiquitination of tumor necrosis factor-alpha receptor association factor-6 (TRAF6) and receptor-interacting protein 1 (RIP1) and consequently decreased the DNA binding activity of nuclear factor-kappa B (NF-κB) in NRCFs. In addition, Pellino1 silencing prevented stretch-induced activation of p38 and activator protein 1 (AP-1) binding activity in NRCFs. Chromatin Immunoprecipitation (ChIP) and luciferase reporter assays showed that Pellino1 silencing prevented the binding of NF-κB and AP-1 to the promoter region of transforming growth factor-β1 (TGF-β1) thus dampening TGF-β1 transactivation. Our data reveal a previously unrecognized role of Pellino1 in extracellular matrix deposition and cardiac fibroblast activation in response to mechanical stress and provides a novel target for treatment of cardiac fibrosis and heart failure.

cardiac fibroblasts

cardiac fibrosis

mechanical stretch

Pellino1

TGF-β1

Surgery