A microporous metal–organic framework with rare lvt topology for highly selective C2H2/C2H4separation at room temperature

Dilated cardiomyopathies (DCM) show remarkable variability in their age of onset, phenotypic presentation, and clinical course. Hence, disease mechanisms must exist that modify the occurrence and progression of DCM, either by genetic or epigenetic factors that may interact with environmental stimuli. In the present study, we examined genome-wide cardiac DNA methylation in patients with idiopathic DCM and controls. We detected methylation differences in pathways related to heart disease, but also in genes with yet unknown function in DCM or heart failure, namely Lymphocyte antigen 75 (LY75), Tyrosine kinase-type cell surface receptor HER3 (ERBB3), Homeobox B13 (HOXB13) and Adenosine receptor A2A (ADORA2A). Mass-spectrometric analysis and bisulphite-sequencing enabled confirmation of the observed DNA methylation changes in independent cohorts. Aberrant DNA methylation in DCM patients was associated with significant changes in LY75 and ADORA2A mRNA expression, but not in ERBB3 and HOXB13. In vivo studies of orthologous ly75 and adora2a in zebrafish demonstrate a functional role of these genes in adaptive or maladaptive pathways in heart failure.

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PINCH Proteins Regulate Cardiac Contractility by Modulating Integrin-Linked Kinase-Protein Kinase B Signaling

Meder

Huttner

Sedaghat‐Hamedani

et al. 2011

Molecular and Cellular Biology

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Integrin-linked kinase (ILK) is an essential component of the cardiac mechanical stretch sensor and is bound in a protein complex with parvin and PINCH proteins, the so-called ILK-PINCH-parvin (IPP) complex. We have recently shown that inactivation of ILK or ␤-parvin activity leads to heart failure in zebrafish via reduced protein kinase B (PKB/Akt) activation. Here, we show that PINCH proteins localize at sarcomeric Z disks and costameres in the zebrafish heart and skeletal muscle. To investigate the in vivo role of PINCH proteins for IPP complex stability and PKB signaling within the vertebrate heart, we inactivated PINCH1 and PINCH2 in zebrafish. Inactivation of either PINCH isoform independently leads to instability of ILK, loss of stretch-responsive anf and vegf expression, and progressive heart failure. The predominant cause of heart failure in PINCH morphants seems to be loss of PKB activity, since PKB phosphorylation at serine 473 is significantly reduced in PINCH-deficient hearts and overexpression of constitutively active PKB reconstitutes cardiac function in PINCH morphants. These findings highlight the essential function of PINCH proteins in controlling cardiac contractility by granting IPP/PKB-mediated signaling.Integrin-linked kinase (ILK) is an essential component of the cardiac mechanical stretch sensor, modulating expression of stretch-responsive genes such as anf and vegf and thereby enabling the heart to adapt its force of contraction to changing hemodynamic needs. Many of the currently known ILK-mediated functions require additional cofactors and interacting proteins. Increasing focus has therefore been put on the roles of the ternary complex comprising the proteins ILK, ␣-, ␤-, or ␥-parvin, and PINCH, PINCH1 or PINCH2 (5,26,30,34).The ILK-parvin-PINCH (IPP) complex provides physical linkage between integrin transmembrane receptors and the actin cytoskeleton and serves as a signaling mediator that transduces mechanical signals to downstream effectors (32). PINCH and parvins do not have catalytic activity but rather function as adapters for other signaling molecules such as Nck-2 and Ras suppressor 1 (RSU-1), through which PINCH can regulate c-Jun N-terminal kinase (JNK) (7,25).In cardiomyocyte cell cultures, the IPP complex is known to regulate integrin-mediated signaling pathways involved in hypertrophic and apoptotic responses (5). In vivo, a role of the IPP complex and specifically of PINCH proteins in the control of cardiac contractility was demonstrated in a recent study using PINCH-deficient mice. Cardiac muscle-specific double knockout of pinch1 and pinch2, but not single deletion of either gene, resulted in heart failure and early postnatal lethality; however, the underlying molecular pathway was ultimately not elucidated (16).We recently found that zebrafish ILK regulates the cardiac stretch response and contractility via protein kinase B (PKB)-VEGF signaling (2). To investigate if PINCH affects IPP-PKB signaling, we analyzed PINCH1 and PINCH2 function in the zebrafish heart. We show...

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Right Ventricular Failure and Pathobiology in Patients with Congenital Heart Disease – Implications for Long-Term Follow-Up

et al. 2013

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Right ventricular dysfunction represents a common problem in patients with congenital heart defects, such as Tetralogy of Fallot or pulmonary arterial hypertension. Patients with congenital heart defects may present with a pressure or volume overloaded right ventricle (RV) in a bi-ventricular heart or in a single ventricular circulation in which the RV serves as systemic ventricle. Both subsets of patients are at risk of developing right ventricular failure. Obtaining functional and morphological imaging data of the right heart is technically more difficult than imaging of the left ventricle. In contrast to findings on mechanisms of left ventricular dysfunction, very little is known about the pathophysiologic alterations of the right heart. The two main causes of right ventricular dysfunction are pressure and/or volume overload of the RV. Until now, there are no appropriate models available analyzing the effects of pressure and/or volume overload on the RV. This review intends to summarize clinical aspects mainly focusing on the current research in this field. In future, there will be increasing attention to individual care of patients with right heart diseases. Hence, further investigations are essential for understanding the right ventricular pathobiology.

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RNA splicing regulated by RBFOX1 is essential for cardiac function in zebrafish

Frese

Meder

Keller

et al. 2015

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Alternative splicing is one of the major mechanisms through which the proteomic and functional diversity of eukaryotes is achieved. However, the complex nature of the splicing machinery, its associated splicing regulators and the functional implications of alternatively spliced transcripts are only poorly understood. Here, we investigated the functional role of the splicing regulator rbfox1 in vivo using the zebrafish as a model system. We found that loss of rbfox1 led to progressive cardiac contractile dysfunction and heart failure. By using deep-transcriptome sequencing and quantitative real-time PCR, we show that depletion of rbfox1 in zebrafish results in an altered isoform expression of several crucial target genes, such as actn3a and hug. This study underlines that tightly regulated splicing is necessary for unconstrained cardiac function and renders the splicing regulator rbfox1 an interesting target for investigation in human heart failure and cardiomyopathy.

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Doreen Köhler

Atlas of the clinical genetics of human dilated cardiomyopathy

Alterations in cardiac DNA methylation in human dilated cardiomyopathy

PINCH Proteins Regulate Cardiac Contractility by Modulating Integrin-Linked Kinase-Protein Kinase B Signaling

Right Ventricular Failure and Pathobiology in Patients with Congenital Heart Disease – Implications for Long-Term Follow-Up

RNA splicing regulated by RBFOX1 is essential for cardiac function in zebrafish

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