IL-6 loss causes ventricular dysfunction, fibrosis, reduced capillary density, and dramatically alters the cell populations of the developing and adult heart

Banerjee, Indroneal; Fuseler, John W.; Intwala, Arti; Baudino, Troy A.

doi:10.1152/ajpheart.00908.2008

Cited by 106 publications

(89 citation statements)

References 47 publications

(114 reference statements)

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“…Of particular interest, the ERBB2-dependent E2F-1 targets include several proteins involved in cardiac muscle contractility, conduction, maintenance of heart rate, cardiac homeostasis, adaptive stress response, hypertrophy, ventricle morphology, and vascular integrity that have previously been shown to play important roles in cardiac development and/or adult heart function. Cardiac tissue-specific ablation of a number of these pathways, such as ILK and AHR signaling, results in heart dysfunction and sudden death in animals, reinforcing the importance of the cardiac ERBB2/E2F-1 transcriptional program identified in our study (26)(27)(28)(29)(30)(31)(32). Of interest, thrombopoietin and ILK signaling, which have both been shown to protect against in vitro and in vivo anthracycline-induced cardiotoxicity (33,34), were modulated in the ERBB2-deficient hearts.…”

Section: Discussionsupporting

confidence: 75%

ERBB2 Deficiency Alters an E2F-1-Dependent Adaptive Stress Response and Leads to Cardiac Dysfunction

Perry

Dufour

Eichner

et al. 2014

Molecular and Cellular Biology

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The tyrosine kinase receptor ERBB2 is required for normal development of the heart and is a potent oncogene in breast epithelium. Trastuzumab, a monoclonal antibody targeting ERBB2, improves the survival of breast cancer patients, but cardiac dysfunction is a major side effect of the drug. The molecular mechanisms underlying how ERBB2 regulates cardiac function and why trastuzumab is cardiotoxic remain poorly understood. We show here that ERBB2 hypomorphic mice develop cardiac dysfunction that mimics the side effects observed in patients treated with trastuzumab. We demonstrate that this phenotype is related to the critical role played by ERBB2 in cardiac homeostasis and physiological hypertrophy. Importantly, genetic and therapeutic reduction of ERBB2 activity in mice, as well as ablation of ERBB2 signaling by trastuzumab or siRNAs in human cardiomyocytes, led to the identification of an impaired E2F-1-dependent genetic program critical for the cardiac adaptive stress response. These findings demonstrate the existence of a previously unknown mechanistic link between ERBB2 and E2F-1 transcriptional activity in heart physiology and trastuzumab-induced cardiac dysfunction.

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Section: Discussionsupporting

confidence: 75%

ERBB2 Deficiency Alters an E2F-1-Dependent Adaptive Stress Response and Leads to Cardiac Dysfunction

Perry

Dufour

Eichner

et al. 2014

Molecular and Cellular Biology

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“…This cytokine is secreted by cardiofibroblasts and functions in heart remodeling (Porter & Turner 2009). Cardiac cells that lack Il6 activity attenuated the activation of Stat3 and Vegfa production, leading to interstitial collagen accumulation, which promotes cardiac dilatation and ventricular dysfunction (Porter & Turner 2009;Banerjee et al 2009). In both the CP and CM networks, Cxcr4, Cxcl12 and Cxcl13 interacted directly with S1P (Fig.…”

Section: Inflammatory and Apoptotic Molecules Associated With Bioactimentioning

confidence: 99%

Systems Chemo‐Biology and Transcriptomic Meta‐Analysis Reveal the Molecular Roles of Bioactive Lipids in Cardiomyocyte Differentiation

Poloni

Bonatto

2015

J of Cellular Biochemistry

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Lipids, which are essential constituents of biological membranes, play structural and functional roles in the cell. In recent years, certain lipids have been identified as regulatory signaling molecules and have been termed "bioactive lipids". Subsequently, the importance of bioactive lipids in stem cell differentiation and cardiogenesis has gained increasing recognition. Therefore, the aim of this study was to identify the biological processes underlying murine cardiac differentiation and the mechanisms by which bioactive lipids affect these processes. For this purpose, a transcriptomic meta-analysis of microarray and RNA-seq data from murine stem cells undergoing cardiogenic differentiation was performed. The differentially expressed genes identified via this meta-analysis, as well as bioactive lipids, were evaluated using systems chemo-biology tools. These data indicated that bioactive lipids are associated with the regulation of cell motility, cell adhesion, cytoskeletal rearrangement, and gene expression. Moreover, bioactive lipids integrate the signaling pathways involved in cell migration, the secretion and remodeling of extracellular matrix components, and the establishment of the cardiac phenotype. In conclusion, this study provides new insights into the contribution of bioactive lipids to the induction of cellular responses to various stimuli, which may originate from the extracellular environment and morphogens, and the manner in which this contribution directly affects murine heart morphogenesis.

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“…Members of the IL-6 family are also mainly secreted from cardiac fibroblasts and have been demonstrated to play an important role during cardiac development and postnatally for cardiomyocyte growth [Banerjee et al, 2009]. The biological activity of IL-6 is regulated by the transmembrane receptor subunit gp130, and continuous stimulation with IL-6 or other members of the IL-6 family, including leukemia inhibitor factor (LIF) and cardiotrophin (CT-1), leads to cardiac hypertrophy [Hirota et al, 1995].…”

Section: Paracrine Communication Between Fibroblasts and Cardiomyocytesmentioning

confidence: 99%

The Cardiogenic Niche as a Fundamental Building Block of Engineered Myocardium

Christalla¹,

Hudson²,

Zimmermann³

2011

Cells Tissues Organs

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Cardiac muscle engineering is evolving rapidly, aiming at the provision of innovative models for drug development and therapeutic myocardium. The progress in this field will depend crucially on the proper exploitation of stem cell technologies. Understanding the processes governing stem cell differentiation towards a desired phenotype and subsequent maturation in an organotypic manner will be key to ultimately providing realistic tissue models or therapeutics. Cardiogenesis is controlled by milieu factors that collectively constitute a so-called cardiogenic niche. The components of the cardiogenic niche are not yet fully defined but include paracrine factors and instructive extracellular matrix. Both are provided by supportive stromal cells under strict spatial and temporal control. Detailed knowledge on the exact composition and functionality of the dynamic cardiogenic niche during development will likely be instrumental to further advance cardiac muscle engineering. This review will discuss the concept of myocardial tissue engineering from the stem cell/developmental biology perspective and put forward the hypothesis of the cardiogenic niche as a fundamental building block of tissue-engineered myocardium.

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IL-6 loss causes ventricular dysfunction, fibrosis, reduced capillary density, and dramatically alters the cell populations of the developing and adult heart

Cited by 106 publications

References 47 publications

ERBB2 Deficiency Alters an E2F-1-Dependent Adaptive Stress Response and Leads to Cardiac Dysfunction

ERBB2 Deficiency Alters an E2F-1-Dependent Adaptive Stress Response and Leads to Cardiac Dysfunction

Systems Chemo‐Biology and Transcriptomic Meta‐Analysis Reveal the Molecular Roles of Bioactive Lipids in Cardiomyocyte Differentiation

The Cardiogenic Niche as a Fundamental Building Block of Engineered Myocardium

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