Pressure-overload Hypertrophy Research Articles

Bone marrow mesenchymal stem cell-derived exosomes attenuate cardiac hypertrophy and fibrosis in pressure overload induced remodeling.

The multiple therapeutic effects of bone marrow mesenchymal stem cells (BM-MSCs) have been verified in ischemic and reperfusion diseases. Exosomes are thought to play vital roles in MSCs-related cardioprotective effects. Recently, more and more evidences indicated that apoptosis and fibrosis were crucial pathological mechanisms in cardiac remodeling. Whether MSCs-derived exosomes could regulate cardiac hypertrophy and remodeling need to be explored. Murine BM-MSCs-derived exosomes were isolated by differential gradient centrifugation method. The transverse aortic constriction (TAC) mice model was established to promote cardiac remodeling. Cardiac function and remodeling were assessed via echocardiography and histology analysis. Myocytes apoptosis was determined by TUNEL fluorescence staining. Meanwhile, premature senescence was detected by β-galactosidase (SA-β-gal) staining. Related proteins and mRNA alternation were assessed via western blotting and quantitative reverse transcription polymerase chain reaction, respectively. MSCs-derived exosomes significantly protected myocardium against cardiac hypertrophy, attenuated myocardial apoptosis, and fibrosis and preserved heart function when pressure overload. In cultured myocytes, MSCs-derived exosomes also prevented cell hypertrophy stimulated with angiotensin II. One the other hand, exosomes promoted premature senescence of myofibroblasts vitro, indicating its anti-fibrosis effect in cardiac remodeling. Exosomes protected cardiomyocytes against pathological hypertrophy. It may provide a promising future treatment for heart failure.

Abstract 381: Mcur1 is a Potential Target to Modulate Cardiac Contractility and Alleviate Cardiac Function During Heart Failure

Cardiac contractility is regulated by the intracellular Ca 2+ concentration fluxes which are actively regulated by multiple channels and transporters. Ca 2+ uptake into the mitochondrial matrix is precisely controlled by the highly Ca 2+ selective channel, Mitochondrial Calcium Uniporter (MCU). Earlier studies on the cardiac-specific acute MCU knockout and a transgenic dominant-negative MCU mice have demonstrated that mitochondrial Ca 2+ ( m Ca 2+ ) signaling is necessary for cardiac ‘‘fight-or-flight’’ contractile response, however, the role of m Ca 2+ buffering to shape global cytosolic Ca 2+ levels and affect E-C coupling, particularly the Ca 2+ transient, on a beat-to-beat basis still remains to be solved. Our earlier studies have demonstrated that loss of MCU Regulator 1 (MCUR1) in cardiomyocytes results in the impaired m Ca 2+ uptake. We have now employed the cardiac-specific MCUR1 knockout mouse to dissect the precise role of MCU in regulating cytosolic Ca 2+ transients associated with excitation-contraction (E-C) coupling and cardiac function. Results from our studies including the in vivo analyses of cardiac physiology during normal and pressure-overloaded mouse models and in vitro experiments including single-cell cardiac contractility, calcium transients, and electrophysiology measurements demonstrate that MCUR1/MCU regulated m Ca 2+ buffering in cardiomyocytes, although insignificant under basal condition, becomes critical in stress induced conditions and actively participates in regulating the c Ca 2+ transients. Also, the ablation of MCUR1 in cardiomyocytes during stress conditions prevents m Ca 2+ overload and subsequent mROS overproduction. Our data indicate that MCUR1 ablation offers protection against pressure-overload cardiac hypertrophy. In summary, our results provide critical insights into the mechanisms by which the MCU channel contributes in regulating the contractile function of the cardiomyocytes and the role of m Ca 2+ in the development and progression of heart failure.

Protein arginine methyltransferase 6 mediates cardiac hypertrophy by differential regulation of histone H3 arginine methylation

Heart failure remains a major cause of hospitalization and death worldwide. Heart failure can be caused by abnormalities in the epigenome resulting from dysregulation of histone-modifying enzymes. While chromatin enzymes catalyzing lysine acetylation and methylation of histones have been the topic of many investigations, the role of arginine methyltransferases has been overlooked. In an effort to understand regulatory mechanisms implicated in cardiac hypertrophy and heart failure, we assessed the expression of protein arginine methyltransferases (PRMTs) in the left ventricle of failing human hearts and control hearts. Our results show a significant up-regulation of protein arginine methyltransferase 6 (PRMT6) in failing human hearts compared to control hearts, which also occurs in the early phase of cardiac hypertrophy in mouse hearts subjected to pressure overload hypertrophy induced by trans-aortic constriction (TAC), and in neonatal rat ventricular myocytes (NRVM) stimulated with the hypertrophic agonist phenylephrine (PE). These changes are associated with a significant increase in arginine 2 asymmetric methylation of histone H3 (H3R2Me2a) and reduced lysine 4 tri-methylation of H3 (H3K4Me3) observed both in NRVM and in vivo. Importantly, forced expression of PRMT6 in NRVM enhances the expression of the hypertrophic marker, atrial natriuretic peptide (ANP). Conversely, specific silencing of PRMT6 reduces ANP protein expression and cell size, indicating that PRMT6 is critical for the PE-mediated hypertrophic response. Silencing of PRMT6 reduces H3R2Me2a, a mark normally associated with transcriptional repression. Furthermore, evaluation of cardiac contractility and global ion channel activity in live NRVM shows a striking reduction of spontaneous beating rates and prolongation of extra-cellular field potentials in cells expressing low-level PRMT6. Altogether, our results indicate that PRMT6 is a critical regulator of cardiac hypertrophy, implicating H3R2Me2a as an important histone modification. This study identifies PRMT6 as a new epigenetic regulator and suggests a new point of control in chromatin to inhibit pathological cardiac remodeling.

Cardiac Overexpression of PDE4B Blunts β-Adrenergic Response and Maladaptive Remodeling in Heart Failure.

The cyclic AMP (adenosine monophosphate; cAMP)-hydrolyzing protein PDE4B (phosphodiesterase 4B) is a key negative regulator of cardiac β-adrenergic receptor stimulation. PDE4B deficiency leads to abnormal Ca2+ handling and PDE4B is decreased in pressure overload hypertrophy, suggesting that increasing PDE4B in the heart is beneficial in heart failure. We measured PDE4B expression in human cardiac tissues and developed 2 transgenic mouse lines with cardiomyocyte-specific overexpression of PDE4B and an adeno-associated virus serotype 9 encoding PDE4B. Myocardial structure and function were evaluated by echocardiography, ECG, and in Langendorff-perfused hearts. Also, cAMP and PKA (cAMP dependent protein kinase) activity were monitored by Förster resonance energy transfer, L-type Ca2+ current by whole-cell patch-clamp, and cardiomyocyte shortening and Ca2+ transients with an Ionoptix system. Heart failure was induced by 2 weeks infusion of isoproterenol or transverse aortic constriction. Cardiac remodeling was evaluated by serial echocardiography, morphometric analysis, and histology. PDE4B protein was decreased in human failing hearts. The first PDE4B-transgenic mouse line (TG15) had a ≈15-fold increase in cardiac cAMP-PDE activity and a ≈30% decrease in cAMP content and fractional shortening associated with a mild cardiac hypertrophy that resorbed with age. Basal ex vivo myocardial function was unchanged, but β-adrenergic receptor stimulation of cardiac inotropy, cAMP, PKA, L-type Ca2+ current, Ca2+ transients, and cell contraction were blunted. Endurance capacity and life expectancy were normal. Moreover, these mice were protected from systolic dysfunction, hypertrophy, lung congestion, and fibrosis induced by chronic isoproterenol treatment. In the second PDE4B-transgenic mouse line (TG50), markedly higher PDE4B overexpression, resulting in a ≈50-fold increase in cardiac cAMP-PDE activity caused a ≈50% decrease in fractional shortening, hypertrophy, dilatation, and premature death. In contrast, mice injected with adeno-associated virus serotype 9 encoding PDE4B (1012 viral particles/mouse) had a ≈50% increase in cardiac cAMP-PDE activity, which did not modify basal cardiac function but efficiently prevented systolic dysfunction, apoptosis, and fibrosis, while attenuating hypertrophy induced by chronic isoproterenol infusion. Similarly, adeno-associated virus serotype 9 encoding PDE4B slowed contractile deterioration, attenuated hypertrophy and lung congestion, and prevented apoptosis and fibrotic remodeling in transverse aortic constriction. Our results indicate that a moderate increase in PDE4B is cardioprotective and suggest that cardiac gene therapy with PDE4B might constitute a new promising approach to treat heart failure.

The urotensin II receptor antagonist DS37001789 ameliorates mortality in pressure-overload mice with heart failure

This study was designed to evaluate the effects of DS37001789, a novel and highly potent urotensin II (U-II) receptor (GPR14) antagonist, against mortality, hypertrophy, and cardiac dysfunction in pressure-overload hypertrophy by transverse aortic constriction (TAC) in mice. In addition, we analyzed the phenotype of GPR14 knockout (KO) mice after TAC induction to confirm the contribution of the U-II/GPR14 system. The oral administration of 0.2% DS37001789 to TAC mice for 12 weeks significantly ameliorated the mortality rate and 0.2% DS37001789 for 4 weeks significantly improved cardiac function by pressure-volume analysis. GPR14 expression was significantly upregulated in the left ventricle in the TAC mice treated with 0.2% DS37001789. Moreover, we confirmed that the significant amelioration of mortality was accomplished by the inhibition of cardiac enlargement and the improvement of cardiac function in GPR14 KO mice after TAC surgery. These results suggest that the U-II/GPR14 system contributes to the progression of heart failure and its blockade ameliorates the mortality via improved cardiac function. The U-II/GPR14 system may thus be an attractive target for treating heart failure with pathological cardiac hypertrophy and DS37001789 may be a novel therapeutic agent for heart failure in patients with pressure-overload conditions such as hypertension and aortic valve stenosis.

RETRACTED: Cardiac Expression of Factor X Mediates Cardiac Hypertrophy and Fibrosis in Pressure Overload

Activated factor X is a key component of the coagulation cascade, but whether it directly regulates pathological cardiac remodeling is unclear. In mice subjected to pressure overload stress, cardiac factor X mRNA expression and activity increased concurrently with cardiac hypertrophy, fibrosis, inflammation and diastolic dysfunction, and responses blocked with a low coagulation-independent dose of rivaroxaban. In vitro, neurohormone stressors increased activated factor X expression in both cardiac myocytes and fibroblasts, resulting in activated factor X-mediated activation of protease-activated receptors and pro-hypertrophic and -fibrotic responses, respectively. Thus, inhibition of cardiac-expressed activated factor X could provide an effective therapy for the prevention of adverse cardiac remodeling in hypertensive patients.

Heart failure as interstitial cancer: emergence of a malignant fibroblast phenotype.

A prolonged state of left ventricular pressure overload, commonly caused by hypertension and aortic valve disease, promotes remodelling of the myocardium that can progress to heart failure with preserved ejection fraction (HFpEF). In animal models, a major factor driving progression from pressure-overload hypertrophy (POH) to HFpEF is the activation and proliferation of an abnormal fibroblast phenotype that is resistant to apoptosis, degrades normal stromal matrix and is replaced with a fibrotic matrix structure. A similar fibroblast phenotype has been identified in the stroma of solid cancers. This cancer-associated fibroblast drives tumour growth and invasion. The proliferation and expansion of these abnormal fibroblast populations in both HFpEF and cancer contribute to progression of disease. In early-phase clinical trials, chemotherapeutic agents targeting cancer-associated fibroblasts had antitumour properties. In this Perspectives article, we postulate that, because the abnormal fibroblast populations in POH and cancer have identical characteristics, chemotherapeutic agents targeting the POH-related fibroblast might attenuate the development of myocardial fibrosis, a pathophysiological hallmark of HFpEF. These agents must be designed to target the abnormal fibroblasts with high specificity because many classes of chemotherapeutic drugs can themselves cause myocardial dysfunction and heart failure.

Differential effects of various genetic mouse models of the mechanistic target of rapamycin complex I inhibition on heart failure.

Inhibition of mammalian target of rapamycin complex I (mTORC1) by rapamycin improves cardiac function in both aging and heart failure. While the protective mechanisms are not fully understood in mammals, they are presumably mediated through metabolic regulation and suppression of protein translation by reduced phosphorylation of 4EBP1, a target of mTORC1. Using transverse aortic constriction (TAC) and Gαq overexpression-induced heart failure models, we examined the effect of cardiac-specific heterozygous deletion (het) of Raptor, a component of mTORC1, and cardiac-specific transgenic overexpression of wild type or phosphorylation site mutant 4EBP1. In wild-type mice with TAC-induced heart failure, quantitative shotgun proteomics revealed decreased abundance of proteins of mitochondrial metabolism and increased abundance of proteins in oxidative stress response, ubiquitin, and other pathways. The Raptor het ameliorated both TAC- and Gαq overexpression-induced heart failure and the associated proteomic remodeling, especially those pathways involved in mitochondrial function, citric acid cycle, and ubiquitination. In contrast, transgenic overexpression of either wild type or mutant 4EBP1 aggravated TAC and Gαq, consistent with reduced adaptive hypertrophy by suppression of protein translation, in parallel with adverse remodeling of left ventricular proteomes. Partial mTORC1 inhibition by Raptor heterozygous deletion ameliorates heart failure and is associated with better preservation of the mitochondrial proteome; however, this effect does not appear to be mediated through suppression of protein translation by increased 4EBP1. Increased activity of 4EBP1 reduced adaptive hypertrophy and aggravated heart failure, suggesting that protein translation is essential for adaptive hypertrophy in pressure overload.

Abstract 371: Chromatin Remodeling Mechanisms by Bromodomain PHD Finger Transcription Factor in Cardiac Hypertrophy and Heart Failure

Alteration of chromatin conformation has a profound effect on gene expression, and can lead to heart failure, which remains a major cause of death worldwide. ATP-dependent chromatin remodelers utilize the energy of ATP to remodel chromatin in specific regions of the genome. However, the mechanisms of ATP-dependent chromatin remodeling and how they connect to the genome remain poorly understood. We have discovered that the nucleosome remodeler Bromodomain PHD-finger Transcription Factor (BPTF), the largest subunit of the Nucleosome Remodeling Factor (NURF), plays an important role in cardiac hypertrophy. Our preliminary data show that BPTF is enriched in failing human hearts, a phenomenon similarly observed in mouse hearts subjected to pressure overload hypertrophy (TAC). BPTF is up-regulated in primary neonatal rat ventricular myocytes (NRVM) and human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) stimulated with the hypertrophic agonist phenylephrine (PE). Strikingly, specific silencing of BPTF in NRVM and hiPSC-CMs, inhibits the expression of the atrial natriuretic peptide (ANP), a marker of cardiac hypertrophy. Chromatin immunoprecipitation performed in NRVM show that BPTF binds to the ANP promoter, but not to GAPDH. Proteomics experiments performed in failing human hearts revealed a multi-protein complex formed between BPTF and novel chromatin regulators. At the level of the nucleosome, BPTF in combination with one of its partners, remodels chromatin by facilitating nucleosomes “sliding” along the DNA. This mechanism is mediated by the binding of BPTF to histone H3 trimethylated at Lysine-4 (H3K4me3), an “active” mark of transcription also up-regulated in the early phase of cardiac hypertrophy in NRVM and in mouse TAC hearts. Our study suggests a novel chromatin signature controlled by BPTF, that dictates specific gene patterns implicated in pathological cardiac hypertrophy. Our study uncovers a new epigenetic mechanism controlling pathological cardiac remodeling and heart failure.

Abstract 655: Protein Arginine Methyltransferase 6 Controls Cardiac Hypertrophy by Differential Arginine and Lysine Methylation of Histone H3

Heart failure remains a common cause of hospitalization and death worldwide. Heart failure can be caused by dysregulation of gene expression following abnormal expression of histone modifying enzymes. While lysine acetylation and methylation of histones have been the topic of many investigations, the role of arginine methylation in H3 has been overlooked. In an effort to understand regulatory mechanisms implicated in cardiac hypertrophy and heart failure, we assessed protein arginine methyl transferase (PRMT) members in the left ventricle of failing human hearts and control hearts. Our results show a specific up-regulation of PRMT6 mRNA in failing human hearts (5.95±2.16 fold in failing versus control, p=0.003) which also occurs in the compensatory phase of cardiac hypertrophy in mouse hearts subjected to pressure overload hypertrophy, and in neonatal rat ventricular myocytes (NRVM) stimulated with the hypertrophic agonist phenylephrine (PE). These changes are associated with a significant increase in arginine 2 asymmetric methylation of H3 (H3R2me2a) and reduced lysine 3 tri-methylation of H3 (H3K4me3) both in NRVM and in vivo . Importantly, forced expression of PRMT6 in NRVM stimulated with PE, enhances the expression of atrial natriuretic peptide (ANP). Conversely, silencing of PRMT6 reduces ANP protein expression and cell size, indicating that PRMT6 is critical for PE-mediated cardiac hypertrophy of NRVM. Also, silencing of PRMT6 reduces H3R2me2a, a mark associated with transcriptional repression. To evaluate the role of PRMT6 on cardiac contractility and global ion channel activity, we assessed contractility and global field potentials in live NRVM expressing normal and low level PRMT6 using the RTCA CardioECR system (ACEA Bioscience Inc.). Strikingly, reduced expression of PRMT6 drastically inhibits the contraction rate of NRVM, which is paralleled by a slight increase in the QT interval. All together, our results indicate that PRMT6 is a critical regulator of cardiac hypertrophy, implicating H3R2me2a as an important histone modification. Future studies investigating the specific gene programs regulated by PRMT6 are on their way. This study may help identify novel points of control to design new drugs for the treatment of heart failure.

O-GlcNAc Transferase Promotes Compensated Cardiac Function and Protein Kinase A O-GlcNAcylation During Early and Established Pathological Hypertrophy From Pressure Overload.

BackgroundProtein posttranslational modifications by O‐linked β‐N‐acetylglucosamine (O‐GlcNAc) increase with cardiac hypertrophy, yet the functional effects of these changes are incompletely understood. In other organs, O‐GlcNAc promotes adaptation to acute physiological stressors; however, prolonged O‐GlcNAc elevations are believed to be detrimental. We hypothesize that early O‐GlcNAcylation improves cardiac function during initial response to pressure overload hypertrophy, but that sustained elevations during established pathological hypertrophy negatively impact cardiac function by adversely affecting calcium handling proteins.Methods and ResultsTransverse aortic constriction or sham surgeries were performed on littermate controls or cardiac‐specific, inducible O‐GlcNAc transferase knockout (OGTKO) mice to reduce O‐GlcNAc levels. O‐GlcNAc transferase deficiency was induced at different times. To evaluate the initial response to pressure overload, OGTKO was completed preoperatively and mice were followed for 2 weeks post‐surgery. To assess prolonged O‐GlcNAcylation during established hypertrophy, OGTKO was performed starting 18 days after surgery and mice were followed until 6 weeks post‐surgery. In both groups, OGTKO with transverse aortic constriction caused significant left ventricular dysfunction. OGTKO did not affect levels of the calcium handling protein SERCA2a. OGTKO reduced phosphorylation of phospholamban and cardiac troponin I, which would negatively impact cardiac function. O‐GlcNAcylation of protein kinase A catalytic subunit, a kinase for phospholamban, decreased with OGTKO.ConclusionsO‐GlcNAcylation promotes compensated cardiac function in both early and established pathological hypertrophy. We identified a novel O‐GlcNAcylation of protein kinase A catalytic subunit, which may regulate calcium handling and cardiac function.

Increased ketone body oxidation provides additional energy for the failing heart without improving cardiac efficiency.

The failing heart is energy-starved and inefficient due to perturbations in energy metabolism. Although ketone oxidation has been shown recently to increase in the failing heart, it remains unknown whether this improves cardiac energy production or efficiency. We therefore assessed cardiac metabolism in failing hearts and determined whether increasing ketone oxidation improves cardiac energy production and efficiency. C57BL/6J mice underwent sham or transverse aortic constriction (TAC) surgery to induce pressure overload hypertrophy over 4-weeks. Isolated working hearts from these mice were perfused with radiolabelled β-hydroxybutyrate (βOHB), glucose, or palmitate to assess cardiac metabolism. Ejection fraction decreased by 45% in TAC mice. Failing hearts had decreased glucose oxidation while palmitate oxidation remained unchanged, resulting in a 35% decrease in energy production. Increasing βOHB levels from 0.2 to 0.6 mM increased ketone oxidation rates from 251 ± 24 to 834 ± 116 nmol·g dry wt-1 · min-1 in TAC hearts, rates which were significantly increased compared to sham hearts and occurred without decreasing glycolysis, glucose, or palmitate oxidation rates. Therefore, the contribution of ketones to energy production in TAC hearts increased to 18% and total energy production increased by 23%. Interestingly, glucose oxidation, in parallel with total ATP production, was also significantly upregulated in hearts upon increasing βOHB levels. However, while overall energy production increased, cardiac efficiency was not improved. Increasing ketone oxidation rates in failing hearts increases overall energy production without compromising glucose or fatty acid metabolism, albeit without increasing cardiac efficiency.

Abstract 366: The Role of Mitochondrial Calcium Uniporter Complex in Cardiac Contractility and Function

Cardiac contractility is regulated by the intracellular Ca 2+ concentration fluxes which are maintained by multiple channels and transporters. Mitochondrial Calcium Uniporter (MCU) is the highly selective Ca 2+ ion channel responsible for the electrophoretic Ca 2+ uptake into the mitochondrial matrix. Earlier studies on the cardiac-specific acute MCU knockout and transgenic dominant-negative MCU mice have demonstrated that mitochondrial Ca 2+ ( m Ca 2+ ) signaling is necessary for cardiac ‘‘fight-or-flight’’ contractile response, however, the role of m Ca 2+ in the beat-to-beat regulation of cardiac contractility is highly debated. The MCU channel function is regulated by varied molecular regulatory components as well as ROS mediated modification at the Cys-96 residue of the core MCU protein. Our earlier studies have demonstrated that loss of MCU Regulator 1 (MCUR1) in cardiomyocytes results in the impaired m Ca 2+ uptake. To dissect the precise role of MCU in regulating cytosolic Ca 2+ transients associated with excitation-contraction (E-C) coupling and cardiac functions, we have employed the loss-of-function, cardiac-specific MCUR1 knockout mouse and a gain-of-function MCU C96A knockin mouse generated by CRISPR/Cas9 approach. Using these novel mouse models, both by in vivo analyses of cardiac physiology and in vitro experiments including single-cell cardiac contractility, calcium transients, and electrophysiology measurements, our study demonstrates that m Ca 2+ buffering actively participates in E-C coupling. MCUR1/MCU regulated m Ca 2+ buffering in cardiomyocytes, although insignificant under basal condition, becomes critical in stress-induced conditions and actively participates in regulating the c Ca 2+ transients during adrenergic stimulation. Our data indicate that MCUR1 ablation offers protection against pressure-overload cardiac hypertrophy and MCU C96A KI mice exhibit significantly decreased LV ejection fraction at baseline. In summary, our results provide critical insights into the mechanisms by which the MCU channel contributes in regulating the contractile function of the cardiomyocytes and the role of m Ca 2+ in the development and progression of heart failure.

Deficiency of GATA3-Positive Macrophages Improves Cardiac Function Following Myocardial Infarction or Pressure Overload Hypertrophy

BackgroundMacrophages are highly plastic cells that play an important role in the pathogenesis of cardiovascular disease. ObjectivesThis study investigated the role of GATA3-positive macrophages in modulating cardiac function after myocardial infarction (MI) or in response to pressure overload hypertrophy. MethodsMyeloid-specific GATA3-deficient (mGATA3KO) mice were generated, MI or pressure overload was induced, and cardiac function was determined by echocardiography. GATA3-sufficient Cre mice were used as a control. Immunohistochemical staining, flow cytometry, MILLIPLEX Mouse Cytokine/Chemokine Assay, cultured macrophages, quantitative real-time polymerase chain reaction, and western blot were used to determine the role of GATA3 in macrophages. ResultsGATA3-positive macrophages rapidly accumulated in the infarcted region of the myocardium after acute MI. Deficiency of GATA3-positive macrophages led to a significant improvement of cardiac function in response to acute MI or pressure overload hypertrophy compared with the control mice. This improvement was associated with the presence of a large number of proinflammatory Ly6Chi monocytes/macrophages and fewer reparative Ly6Clo macrophages in the myocardium of mGATA3KO mice compared with control mice. Analysis of serum proteins from the 2 mouse genotypes revealed no major changes in the profile of serum growth factors and cytokines between the 2 mice genotypes before and after MI. GATA3 was found to be specifically and transiently induced by interleukin 4 in cultured macrophages through activity of the proximal promoter, whereas the distal promoter remained silent. In addition, the absence of GATA3 in macrophages markedly attenuated arginase-1 expression in cultured macrophages. ConclusionsWe demonstrated that the presence of GATA3-positive macrophages adversely affects remodeling of the myocardium in response to ischemia or pressure overload, whereas the absence of these macrophages led to a significant improvement in cardiac function. Targeting of signaling pathways that lead to the expression of GATA3 in macrophages may have favorable cardiac outcomes.

Cx43 Channel Gating and Permeation: Multiple Phosphorylation-Dependent Roles of the Carboxyl Terminus.

Connexin 43 (Cx43), a gap junction protein seemingly fit to support cardiac impulse propagation and synchronic contraction, is phosphorylated in normoxia by casein kinase 1 (CK1). However, during cardiac ischemia or pressure overload hypertrophy, this phosphorylation fades, Cx43 abundance decreases at intercalated disks and increases at myocytes’ lateral borders, and the risk of arrhythmia rises. Studies in wild-type and transgenic mice indicate that enhanced CK1-phosphorylation of Cx43 protects from arrhythmia, while dephosphorylation precedes arrhythmia vulnerability. The mechanistic bases of these Cx43 (de)phosphoform-linked cardiac phenotypes are unknown. We used patch-clamp and dye injection techniques to study the channel function (gating, permeability) of Cx43 mutants wherein CK1-targeted serines were replaced by aspartate (Cx43-CK1-D) or alanine (Cx43-CK1-A) to emulate phosphorylation and dephosphorylation, respectively. Cx43-CK1-D, but not Cx43-CK1-A, displayed high Voltage-sensitivity and variable permselectivity. Both mutants showed multiple channel open states with overall increased conductivity, resistance to acidification-induced junctional uncoupling, and hemichannel openings in normal external calcium. Modest differences in the mutant channels’ function and regulation imply the involvement of dissimilar structural conformations of the interacting domains of Cx43 in electrical and chemical gating that may contribute to the divergent phenotypes of CK1-(de)phospho-mimicking Cx43 transgenic mice and that may bear significance in arrhythmogenesis.

Distinct roles of resident and nonresident macrophages in nonischemic cardiomyopathy

Nonischemic cardiomyopathy (NICM) resulting from long-standing hypertension, valvular disease, and genetic mutations is a major cause of heart failure worldwide. Recent observations suggest that myeloid cells can impact cardiac function, but the role of tissue-intrinsic vs. tissue-extrinsic myeloid cells in NICM remains poorly understood. Here, we show that cardiac resident macrophage proliferation occurs within the first week following pressure overload hypertrophy (POH; a model of heart failure) and is requisite for the heart's adaptive response. Mechanistically, we identify Kruppel-like factor 4 (KLF4) as a key transcription factor that regulates cardiac resident macrophage proliferation and angiogenic activities. Finally, we show that blood-borne macrophages recruited in late-phase POH are detrimental, and that blockade of their infiltration improves myocardial angiogenesis and preserves cardiac function. These observations demonstrate previously unappreciated temporal and spatial roles for resident and nonresident macrophages in the development of heart failure.

CARDIOMYOCYTE-SPECIFIC OVEREXPRESSION OF THE β3-ADRENERGIC RECEPTOR PREVENTS HEART FAILURE IN A MODEL OF PRESSURE OVERLOAD

β3-adrenergic receptor (β3AR) expression in the heart is relatively low, nevertheless β3AR agonists have a protective effect in pressure overload hypertrophy. Moreover, overexpression of this receptor has been shown to improve remodeling in neurohormonal hypertrophic remodeling. The aim of his

Experimental modelling of cardiac pressure overload hypertrophy: Modified technique for precise, reproducible, safe and easy aortic arch banding-debanding in mice

Pressure overload left ventricular hypertrophy is a known precursor of heart failure with ominous prognosis. The development of experimental models that reproduce this phenomenon is instrumental for the advancement in our understanding of its pathophysiology. The gold standard of these models is the controlled constriction of the mid aortic arch in mice according to Rockman’s technique (RT). We developed a modified technique that allows individualized and fully controlled constriction of the aorta, improves efficiency and generates a reproducible stenosis that is technically easy to perform and release. An algorithm calculates, based on the echocardiographic arch diameter, the intended perimeter at the constriction, and a suture is prepared with two knots separated accordingly. The aorta is encircled twice with the suture and the loop is closed with a microclip under both knots. We performed controlled aortic constriction with Rockman’s and the double loop-clip (DLC) techniques in mice. DLC proved superiority in efficiency (mortality and invalid experiments) and more homogeneity of the results (transcoarctational gradients, LV mass, cardiomyocyte hypertrophy, gene expression) than RT. DLC technique optimizes animal use and generates a consistent and customized aortic constriction with homogeneous LV pressure overload morphofunctional, structural, and molecular features.

Activation of Serine One-Carbon Metabolism by Calcineurin Aβ1 Reduces Myocardial Hypertrophy and Improves Ventricular Function

BackgroundIn response to pressure overload, the heart develops ventricular hypertrophy that progressively decompensates and leads to heart failure. This pathological hypertrophy is mediated, among others, by the phosphatase calcineurin and is characterized by metabolic changes that impair energy production by mitochondria. ObjectivesThe authors aimed to determine the role of the calcineurin splicing variant CnAβ1 in the context of cardiac hypertrophy and its mechanism of action. MethodsTransgenic mice overexpressing CnAβ1 specifically in cardiomyocytes and mice lacking the unique C-terminal domain in CnAβ1 (CnAβ1Δi12 mice) were used. Pressure overload hypertrophy was induced by transaortic constriction. Cardiac function was measured by echocardiography. Mice were characterized using various molecular analyses. ResultsIn contrast to other calcineurin isoforms, the authors show here that cardiac-specific overexpression of CnAβ1 in transgenic mice reduces cardiac hypertrophy and improves cardiac function. This effect is mediated by activation of serine and one-carbon metabolism, and the production of antioxidant mediators that prevent mitochondrial protein oxidation and preserve ATP production. The induction of enzymes involved in this metabolic pathway by CnAβ1 is dependent on mTOR activity. Inhibition of serine and one-carbon metabolism blocks the beneficial effects of CnAβ1. CnAβ1Δi12 mice show increased cardiac hypertrophy and declined contractility. ConclusionsThe metabolic reprogramming induced by CnAβ1 redefines the role of calcineurin in the heart and shows for the first time that activation of the serine and one-carbon pathway has beneficial effects on cardiac hypertrophy and function, paving the way for new therapeutic approaches.

The contribution of fatty acid and ketone body oxidation to energy production increases in the failing heart and is associated with a decrease in cardiac efficiency

Background: The failing heart is energy-starved and inefficient due to perturbations in energy metabolism. Since recent evidence suggests that ketone body oxidation increases in the failing heart as an adaptive mechanism to counteract reductions in fatty acid oxidation, our aim was to assess overall cardiac metabolism in heart failure, to establish what metabolic alterations contribute to reduced cardiac efficiency. Methods: C57BL/6J male mice (12 wk old) underwent either sham surgery, or transverse aortic constriction (TAC) surgery to induce pressure overload hypertrophy over a 4 wk period. Isolated working hearts from these mice were then perfused with appropriately 3H or 14C labelled glucose (5 mM), palmitate (0.8 mM), and ß-hydroxybutyrate (0.6 mM) to assess oxidative metabolism and glycolysis. Results: A 45% reduction in %EF was seen in intact TAC mice and a 54% decrease in cardiac work was seen in isolated working hearts from TAC mice. However, normal cardiac Krebs Cycle acetyl CoA production was seen compared to sham mice, reflecting a reduction in cardiac efficiency. Correspondingly, absolute glucose oxidation rates decreased in TAC compared to sham hearts, whereas absolute rates of fatty acid and ketone body oxidation were similar. However, normalization to cardiac work revealed that glucose oxidation was not depressed in failing hearts, although glycolysis was increased. Conversely, both fatty acid and ketone body oxidation increased in TAC hearts when normalized to cardiac work. This increased reliance on fatty acid oxidation challenges the current dogma suggesting that fatty acid oxidation is depressed in the failing heart. Conclusion: In the failing heart, a decreased cardiac efficiency is associated with increases in the contributions of ketone body and fatty acid oxidation to energy production. The latter observation suggests that normalizing excessive fatty acid oxidation in the failing heart may be a novel approach to improve cardiac efficiency.