Nuclear localization of a novel calpain-2 mediated junctophilin-2 C-terminal cleavage peptide promotes cardiomyocyte remodeling.

Heart failure (HF) is a leading cause of morbidity and mortality worldwide. Patients with HF exhibit a loss of junctophilin-2 (JPH2), a structural protein critical in forming junctional membrane complexes in which excitation-contraction takes place. Several mechanisms have been proposed to mediate the loss of JPH2, one being cleavage by the calcium-dependent protease calpain. The downstream mechanisms underlying HF progression after JPH2 cleavage are presently poorly understood. In this study, we used Labcas to bioinformatically predict putative calpain cleavage sites on JPH2. We identified a cleavage site that produces a novel C-terminal JPH2 peptide (JPH2-CTP) using several domain-specific antibodies. Western blotting revealed elevated JPH2-CTP levels in hearts of patients and mice with HF, corresponding to increased levels of calpain-2. Moreover, immunocytochemistry demonstrated nuclear localization of JPH2-CTP within ventricular myocytes isolated from a murine model of pressure overload-induced HF as well as rat ventricular myocytes treated with isoproterenol. Nuclear localization of JPH2-CTP and cellular remodeling were abrogated by a genetic mutation of the nuclear localization sequence within JPH2-CTP. Taken together, our studies identified a novel C-terminal fragment of JPH2 (JPH2-CTP) generated by calpain-2 mediated cleavage which localizes within the cardiomyocyte nucleus during HF. Blocking nuclear localization of JPH2-CTP protects cardiomyocytes from isoproterenol-induced hypertrophy in vitro. Future in vivo studies of the nuclear role of JPH2-CTP may reveal a causal association with adverse remodeling during HF and establish CTP as a therapeutic target.

The MEF2 transcriptional target DMPK induces loss of sarcomere structure and cardiomyopathy.

Aims: The pathology of heart failure is characterized by poorly contracting and dilated ventricles. At the cellular level, this is associated with lengthening of individual cardiomyocytes and loss of sarcomeres. While it is known that the transcription factor myocyte enhancer factor-2 (MEF2) is involved in this cardiomyocyte remodelling, the underlying mechanism remains to be elucidated. Here, we aim to mechanistically link MEF2 target genes with loss of sarcomeres during cardiomyocyte remodelling. Methods and results: Neonatal rat cardiomyocytes overexpressing MEF2 elongated and lost their sarcomeric structure. We identified myotonic dystrophy protein kinase (DMPK) as direct MEF2 target gene involved in this process. Adenoviral overexpression of DMPK E, the isoform upregulated in heart failure, resulted in severe loss of sarcomeres in vitro, and transgenic mice overexpressing DMPK E displayed disruption of sarcomere structure and cardiomyopathy in vivo. Moreover, we found a decreased expression of sarcomeric genes following DMPK E gain-of-function. These genes are targets of the transcription factor serum response factor (SRF) and we found that DMPK E acts as inhibitor of SRF transcriptional activity. Conclusion: Our data indicate that MEF2-induced loss of sarcomeres is mediated by DMPK via a decrease in sarcomeric gene expression by interfering with SRF transcriptional activity. Together, these results demonstrate an unexpected role for DMPK as a direct mediator of adverse cardiomyocyte remodelling and heart failure.

Inhibition of MicroRNA-146a and Overexpression of Its Target Dihydrolipoyl Succinyltransferase Protect Against Pressure Overload-Induced Cardiac Hypertrophy and Dysfunction.

BACKGROUND: Cardiovascular diseases remain the predominant cause of death worldwide, with the prevalence of heart failure continuing to increase. Despite increased knowledge of the metabolic alterations that occur in heart failure, novel therapies to treat the observed metabolic disturbances are still lacking. METHODS: Mice were subjected to pressure overload by means of angiotensin-II infusion or transversal aortic constriction. MicroRNA-146a was either genetically or pharmacologically knocked out or genetically overexpressed in cardiomyocytes. Furthermore, overexpression of dihydrolipoyl succinyltransferase (DLST) in the murine heart was performed by means of an adeno-associated virus. RESULTS: MicroRNA-146a was upregulated in whole heart tissue in multiple murine pressure overload models. Also, microRNA-146a levels were moderately increased in left ventricular biopsies of patients with aortic stenosis. Overexpression of microRNA-146a in cardiomyocytes provoked cardiac hypertrophy and left ventricular dysfunction in vivo, whereas genetic knockdown or pharmacological blockade of microRNA-146a blunted the hypertrophic response and attenuated cardiac dysfunction in vivo. Mechanistically, microRNA-146a reduced its target DLST-the E2 subcomponent of the α-ketoglutarate dehydrogenase complex, a rate-controlling tricarboxylic acid cycle enzyme. DLST protein levels significantly decreased on pressure overload in wild-type mice, paralleling a decreased oxidative metabolism, whereas DLST protein levels and hence oxidative metabolism were partially maintained in microRNA-146a knockout mice. Moreover, overexpression of DLST in wild-type mice protected against cardiac hypertrophy and dysfunction in vivo. CONCLUSIONS: Altogether we show that the microRNA-146a and its target DLST are important metabolic players in left ventricular dysfunction.

Dyscholesterolemia Protects Against Ischemia-Induced Ventricular Arrhythmias.

BACKGROUND: Hypercholesterolemia protects against ventricular fibrillation in patients with myocardial infarction. We hypothesize that hypercholesterolemia protects against ischemia-induced reentrant arrhythmias because of altered ion channel function. METHODS AND RESULTS: ECGs were measured in low-density lipoprotein receptor knockout (LDLr(-/-)), apolipoprotein A1 knockout (ApoA1(-/-)), and wild-type (WT) mice. Action potentials, calcium handling, and ion currents were recorded in ventricular myocytes. Gene expression was determined by quantitative polymerase chain reaction and Western blot. In isolated perfused hearts, regional ischemia was induced and arrhythmia inducibility was tested. Serum low-density lipoprotein (LDL) cholesterol was higher in LDLr(-/-) mice than in WT mice (2.6 versus 0.4 mmol/L), and high-density lipoprotein cholesterol was significantly lower in ApoA1(-/-) mice than in WT mice (0.3 versus 1.8 mmol/L). LDLr(-/-) and ApoA1(-/-) myocytes contained more cholesterol than WT (34.4±2.8 and 36.5±2.4 versus 25.5±0.4 µmol/g protein). The major potassium currents were not different in LDLr(-/-) and ApoA1(-/-) compared with WT mice. The L-type calcium current (I(Ca)), however, was larger in LDLr(-/-) and ApoA1(-/-) than in WT (12.1±0.7 and 12.8±0.8 versus 9.4±1.1 pA/pF). Calcium transient amplitude and fractional sarcoplasmic reticulum calcium release were larger and action potential and QTc duration longer in LDLr(-/-) and ApoA1(-/-) than in WT mice (action potential duration at 90% of repolarization: 102±4 and 106±3 versus 84±3.1 ms; QTc: 50.9±1.3 and 52.8±0.8 versus 43.5±1.2 ms). During ischemia, ventricular tachycardia/ventricular fibrillation inducibility was larger in WT than in LDLr(-/-) and ApoA1(-/-) hearts. Expression of sodium channel and Ca-handling genes were not significantly different between groups. CONCLUSIONS: Dyscholesterolemia is associated with action potential prolongation because of increased I(Ca) and reduces occurrence of reentrant arrhythmias during ischemia.

Quantitative co-expression of proteins at the single cell level--application to a multimeric FRET sensor.

BACKGROUND: Co-expression of proteins is generally achieved by introducing two (or more) independent plasmids into cells, each driving the expression of a different protein of interest. However, the relative expression levels may vary strongly between individual cells and cannot be controlled. Ideally, co-expression occurs at a defined ratio, which is constant among cells. This feature is of particular importance for quantitative single cell studies, especially those employing bimolecular Förster Resonance Energy Transfer (FRET) sensors. METHODOLOGY/PRINCIPAL FINDINGS: Four co-expression strategies based on co-transfection, a dual promotor plasmid, an internal ribosome entry site (IRES) and a viral 2A peptide were selected. Co-expression of two spectrally separable fluorescent proteins in single living cells was quantified. It is demonstrated that the 2A peptide strategy can be used for robust equimolar co-expression, while the IRES sequence allows expression of two proteins at a ratio of approximately 3:1. Combined 2A and IRES elements were used for the construction of a single plasmid that drives expression of three individual proteins, which generates a FRET sensor for measuring heterotrimeric G-protein activation. The plasmid drives co-expression of donor and acceptor tagged subunits, with reduced heterogeneity, and can be used to measure G-protein activation in single living cells. CONCLUSIONS/SIGNIFICANCE: Quantitative co-expression of two or more proteins can be achieved with little cell-to-cell variability. This finding enables reliable co-expression of donor and acceptor tagged proteins for FRET studies, which is of particular importance for the development of novel bimolecular sensors that can be expressed from single plasmid.