Ludovic Benard

Critical Role for Stromal Interaction Molecule 1 in Cardiac Hypertrophy

Background Cardiomyocytes (CM) utilize Ca2+ not only in excitation-contraction coupling (ECC), but also as a signaling molecule promoting for example cardiac hypertrophy. It is largely unclear how Ca2+ triggers signaling in CM in the presence of the rapid and large Ca2+ fluctuations that occur during ECC. A potential route is store-operated Ca2+ entry (SOCE), a drug-inducible mechanism for Ca2+ signaling that requires stromal interaction molecule 1 (STIM1). SOCE can also be induced in cardiomyocytes, which prompted us to study STIM1-dependent Ca2+-entry with respect to cardiac hypertrophy in vitro and in vivo.Background— Cardiomyocytes use Ca2+ not only in excitation-contraction coupling but also as a signaling molecule promoting, for example, cardiac hypertrophy. It is largely unclear how Ca2+ triggers signaling in cardiomyocytes in the presence of the rapid and large Ca2+ fluctuations that occur during excitation-contraction coupling. A potential route is store-operated Ca2+ entry, a drug-inducible mechanism for Ca2+ signaling that requires stromal interaction molecule 1 (STIM1). Store-operated Ca2+ entry can also be induced in cardiomyocytes, which prompted us to study STIM1-dependent Ca2+ entry with respect to cardiac hypertrophy in vitro and in vivo. Methods and Results— Consistent with earlier reports, we found drug-inducible store-operated Ca2+ entry in neonatal rat cardiomyocytes, which was dependent on STIM1. Although this STIM1-dependent, drug-inducible store-operated Ca2+ entry was only marginal in adult cardiomyocytes isolated from control hearts, it increased significantly in cardiomyocytes isolated from adult rats that had developed compensated cardiac hypertrophy after abdominal aortic banding. Moreover, we detected an inwardly rectifying current in hypertrophic cardiomyocytes that occurs under native conditions (ie, in the absence of drug-induced store depletion) and is dependent on STIM1. By manipulating its expression, we found STIM1 to be both sufficient and necessary for cardiomyocyte hypertrophy in vitro and in the adult heart in vivo. Stim1 silencing by adeno-associated viruses of serotype 9–mediated gene transfer protected rats from pressure overload–induced cardiac hypertrophy. Conclusion— By controlling a previously unrecognized sarcolemmal current, STIM1 promotes cardiac hypertrophy.

Abnormal muscle mechanosignaling triggers cardiomyopathy in mice with Marfan syndrome

Patients with Marfan syndrome (MFS), a multisystem disorder caused by mutations in the gene encoding the extracellular matrix (ECM) protein fibrillin 1, are unusually vulnerable to stress-induced cardiac dysfunction. The prevailing view is that MFS-associated cardiac dysfunction is the result of aortic and/or valvular disease. Here, we determined that dilated cardiomyopathy (DCM) in fibrillin 1-deficient mice is a primary manifestation resulting from ECM-induced abnormal mechanosignaling by cardiomyocytes. MFS mice displayed spontaneous emergence of an enlarged and dysfunctional heart, altered physical properties of myocardial tissue, and biochemical evidence of chronic mechanical stress, including increased angiotensin II type I receptor (AT1R) signaling and abated focal adhesion kinase (FAK) activity. Partial fibrillin 1 gene inactivation in cardiomyocytes was sufficient to precipitate DCM in otherwise phenotypically normal mice. Consistent with abnormal mechanosignaling, normal cardiac size and function were restored in MFS mice treated with an AT1R antagonist and in MFS mice lacking AT1R or β-arrestin 2, but not in MFS mice treated with an angiotensin-converting enzyme inhibitor or lacking angiotensinogen. Conversely, DCM associated with abnormal AT1R and FAK signaling was the sole abnormality in mice that were haploinsufficient for both fibrillin 1 and β1 integrin. Collectively, these findings implicate fibrillin 1 in the physiological adaptation of cardiac muscle to elevated workload.

Plasticity of Surface Structures and β2-Adrenergic Receptor Localization in Failing Ventricular Cardiomyocytes During Recovery from Heart Failure

Background— Cardiomyocyte surface morphology and T-tubular structure are significantly disrupted in chronic heart failure, with important functional sequelae, including redistribution of sarcolemmal &bgr;2-adrenergic receptors (&bgr;2AR) and localized secondary messenger signaling. Plasticity of these changes in the reverse remodeled failing ventricle is unknown. We used AAV9.SERCA2a gene therapy to rescue failing rat hearts and measured z-groove index, T-tubule density, and compartmentalized &bgr;2AR-mediated cAMP signals, using a combined nanoscale scanning ion conductance microscopy-Förster resonance energy transfer technique. Methods and Results— Cardiomyocyte surface morphology, quantified by z-groove index and T-tubule density, was normalized in reverse-remodeled hearts after SERCA2a gene therapy. Recovery of sarcolemmal microstructure correlated with functional &bgr;2AR redistribution back into the z-groove and T-tubular network, whereas minimal cAMP responses were initiated after local &bgr;2AR stimulation of crest membrane, as observed in failing cardiomyocytes. Improvement of &bgr;2AR localization was associated with recovery of &bgr;AR-stimulated contractile responses in rescued cardiomyocytes. Retubulation was associated with reduced spatial heterogeneity of electrically stimulated calcium transients and recovery of myocardial BIN-1 and TCAP protein expression but not junctophilin-2. Conclusions— In summary, abnormalities of sarcolemmal structure in heart failure show plasticity with reappearance of z-grooves and T-tubules in reverse-remodeled hearts. Recovery of surface topology is necessary for normalization of &bgr;2AR location and signaling responses.

Systems Pharmacology of Adverse Event Mitigation by Drug Combinations

Drug combinations that mitigate adverse events were identified using the FDA Adverse Event Reporting System, and one combination, exenatide and rosiglitazone, was tested in a rodent model. Two Drugs: Better Than One? Everyone has seen the commercial, where a drug is advertised as the much-awaited treatment for a disease. At the end of the commercial, there is a long list of adverse events (or side effects) that may affect anything from your heart to your eyesight. Surprisingly, the addition of a second drug can mitigate the side effects of the first drug, such that the combination is actually safer for the patient. To search for those mitigating combinations, Zhao and colleagues devised a computational method for scanning the Food and Drug Administration’s Adverse Event Reporting System (FAERS). This database is freely available and contains millions of records of drug-induced adverse events reported by patients, doctors, hospitals, lawyers, and drug companies. Thus, it represents a potentially useful source of beneficial drug combinations. The authors focused on rosiglitazone—a drug that effectively controls blood glucose levels in diabetic patients, but has been associated with myocardial infarction (MI). By searching through FAERS data, Zhao et al. found that when rosiglitazone was prescribed in combination with exenatide—another drug for treating type 2 diabetes—there were significantly fewer reports of MI as an adverse event. A cell biological interaction network was then developed to look for mechanisms by which rosiglitazone + exenatide affected the heart. The rosiglitazone target PPARγ was plugged into this network, and plasminogen activator inhibitor-1 (PAI-1) was obtained as a potential point of convergence between the two drugs. To test this hypothesis, the authors administered drugs to a mouse model of type 2 diabetes. Mice treated with rosiglitazone alone showed a marked increase in PAI-1 levels, whereas mice treated with the drug combination had significantly decreased levels of PAI-1, similar to those found in untreated mice. FAERS is self-reported and thus may contain some inaccurate data. Nevertheless, it could be a useful tool for generating meaningful hypotheses from human data and for then testing in vivo in clinically relevant disease models, as shown by Zhao et al. Animal models can provide information about drug mechanism of action, and prospective clinical trials will confirm that such combinations can indeed be translated to people to prevent adverse events. Drugs are designed for therapy, but medication-related adverse events are common, and risk/benefit analysis is critical for determining clinical use. Rosiglitazone, an efficacious antidiabetic drug, is associated with increased myocardial infarctions (MIs), thus limiting its usage. Because diabetic patients are often prescribed multiple drugs, we searched for usage of a second drug (“drug B”) in the Food and Drug Administration’s Adverse Event Reporting System (FAERS) that could mitigate the risk of rosiglitazone (“drug A”)–associated MI. In FAERS, rosiglitazone usage is associated with increased occurrence of MI, but its combination with exenatide significantly reduces rosiglitazone-associated MI. Clinical data from the Mount Sinai Data Warehouse support the observations from FAERS. Analysis for confounding factors using logistic regression showed that they were not responsible for the observed effect. Using cell biological networks, we predicted that the mitigating effect of exenatide on rosiglitazone-associated MI could occur through clotting regulation. Data we obtained from the db/db mouse model agreed with the network prediction. To determine whether polypharmacology could generally be a basis for adverse event mitigation, we analyzed the FAERS database for other drug combinations wherein drug B reduced serious adverse events reported with drug A usage such as anaphylactic shock and suicidality. This analysis revealed 19,133 combinations that could be further studied. We conclude that this type of crowdsourced approach of using databases like FAERS can help to identify drugs that could potentially be repurposed for mitigation of serious adverse events.

Therapeutic Efficacy of AAV1.SERCA2a in Monocrotaline-Induced Pulmonary Arterial Hypertension

Background— Pulmonary arterial hypertension (PAH) is characterized by dysregulated proliferation of pulmonary artery smooth muscle cells leading to (mal)adaptive vascular remodeling. In the systemic circulation, vascular injury is associated with downregulation of sarcoplasmic reticulum Ca2+-ATPase 2a (SERCA2a) and alterations in Ca2+ homeostasis in vascular smooth muscle cells that stimulate proliferation. We, therefore, hypothesized that downregulation of SERCA2a is permissive for pulmonary vascular remodeling and the development of PAH. Methods and Results— SERCA2a expression was decreased significantly in remodeled pulmonary arteries from patients with PAH and the rat monocrotaline model of PAH in comparison with controls. In human pulmonary artery smooth muscle cells in vitro, SERCA2a overexpression by gene transfer decreased proliferation and migration significantly by inhibiting NFAT/STAT3. Overexpresion of SERCA2a in human pulmonary artery endothelial cells in vitro increased endothelial nitric oxide synthase expression and activation. In monocrotaline rats with established PAH, gene transfer of SERCA2a via intratracheal delivery of aerosolized adeno-associated virus serotype 1 (AAV1) carrying the human SERCA2a gene (AAV1.SERCA2a) decreased pulmonary artery pressure, vascular remodeling, right ventricular hypertrophy, and fibrosis in comparison with monocrotaline-PAH rats treated with a control AAV1 carrying &bgr;-galactosidase or saline. In a prevention protocol, aerosolized AAV1.SERCA2a delivered at the time of monocrotaline administration limited adverse hemodynamic profiles and indices of pulmonary and cardiac remodeling in comparison with rats administered AAV1 carrying &bgr;-galactosidase or saline. Conclusions— Downregulation of SERCA2a plays a critical role in modulating the vascular and right ventricular pathophenotype associated with PAH. Selective pulmonary SERCA2a gene transfer may offer benefit as a therapeutic intervention in PAH.

Potential Role of BNIP3 in Cardiac Remodeling, Myocardial Stiffness and Endoplasmic Reticulum-Mitochondrial Calcium Homeostasis in Diastolic and Systolic Heart Failure

Background— We have shown that BNIP3 expression is significantly increased in heart failure (HF). In this study, we tested the effects of BNIP3 manipulation in HF. Methods and Results— In a rat model of pressure overload HF, BNIP3 knockdown significantly decreased left ventricular (LV) volumes with significant improvement in LV diastolic and systolic function. There were significant decreases in myocardial apoptosis and LV interstitial fibrosis. Ultrastructurally, BNIP3 knockdown attenuated mitochondrial fragmentation and restored mitochondrial morphology and integrity. On the molecular level, there were significant decreases in endoplasmic reticulum (ER) stress and mitochondrial apoptotic markers. One of the mechanisms by which BNIP3 mediates mitochondrial dysfunction is via the oligomerization of the voltage-dependent anion channels causing a shift of calcium from the ER to mitochondrial compartments, leading to the decrease in ER calcium content, mitochondrial damage, apoptosis, and LV interstitial fibrosis, and hence contributes to both systolic and diastolic myocardial dysfunction, respectively. In systolic HF, the downregulation of SERCA2a (sarcoplasmic-endoplasmic reticulum calcium ATPase), along with an increased BNIP3 expression, further worsen myocardial diastolic and systolic function and contribute to the major remodeling seen in systolic HF as compared with diastolic HF with normal SERCA2a expression. Conclusions— The increase in BNIP3 expression contributes mainly to myocardial diastolic dysfunction through mitochondrial apoptosis, LV interstitial fibrosis, and to some extent to myocardial systolic dysfunction attributable to the shift of calcium from the ER to the mitochondria and to the decrease in ER calcium content. However, SERCA2a downregulation remains a prerequisite for the major LV remodeling seen in systolic HF.Background—We have shown that BNIP3 expression is significantly increased in heart failure (HF). In this study, we tested the effects of BNIP3 manipulation in HF. Methods and Results—In a rat model of pressure overload HF, BNIP3 knockdown significantly decreased left ventricular (LV) volumes with significant improvement in LV diastolic and systolic function. There were significant decreases in myocardial apoptosis and LV interstitial fibrosis. Ultrastructurally, BNIP3 knockdown attenuated mitochondrial fragmentation and restored mitochondrial morphology and integrity. On the molecular level, there were significant decreases in endoplasmic reticulum (ER) stress and mitochondrial apoptotic markers. One of the mechanisms by which BNIP3 mediates mitochondrial dysfunction is via the oligomerization of the voltage-dependent anion channels causing a shift of calcium from the ER to mitochondrial compartments, leading to the decrease in ER calcium content, mitochondrial damage, apoptosis, and LV interstitial fibrosis, and hence contributes to both systolic and diastolic myocardial dysfunction, respectively. In systolic HF, the downregulation of SERCA2a (sarcoplasmic-endoplasmic reticulum calcium ATPase), along with an increased BNIP3 expression, further worsen myocardial diastolic and systolic function and contribute to the major remodeling seen in systolic HF as compared with diastolic HF with normal SERCA2a expression. Conclusions—The increase in BNIP3 expression contributes mainly to myocardial diastolic dysfunction through mitochondrial apoptosis, LV interstitial fibrosis, and to some extent to myocardial systolic dysfunction attributable to the shift of calcium from the ER to the mitochondria and to the decrease in ER calcium content. However, SERCA2a downregulation remains a prerequisite for the major LV remodeling seen in systolic HF.

Cardiac Stim1 Silencing Impairs Adaptive Hypertrophy and Promotes Heart Failure Through Inactivation of mTORC2/Akt Signaling

Background— Stromal interaction molecule 1 (STIM1) is a dynamic calcium signal transducer implicated in hypertrophic growth of cardiomyocytes. STIM1 is thought to act as an initiator of cardiac hypertrophic response at the level of the sarcolemma, but the pathways underpinning this effect have not been examined. Methods and Results— To determine the mechanistic role of STIM1 in cardiac hypertrophy and during the transition to heart failure, we manipulated STIM1 expression in mice cardiomyocytes by using in vivo gene delivery of specific short hairpin RNAs. In 3 different models, we found that Stim1 silencing prevents the development of pressure overload–induced hypertrophy but also reverses preestablished cardiac hypertrophy. Reduction in STIM1 expression promoted a rapid transition to heart failure. We further showed that Stim1 silencing resulted in enhanced activity of the antihypertrophic and proapoptotic GSK-3&bgr; molecule. Pharmacological inhibition of glycogen synthase kinase-3 was sufficient to reverse the cardiac phenotype observed after Stim1 silencing. At the level of ventricular myocytes, Stim1 silencing or inhibition abrogated the capacity for phosphorylation of AktS473, a hydrophobic motif of Akt that is directly phosphorylated by mTOR complex 2. We found that Stim1 silencing directly impaired mTOR complex 2 kinase activity, which was supported by a direct interaction between STIM1 and Rictor, a specific component of mTOR complex 2. Conclusions— These data support a model whereby STIM1 is critical to deactivate a key negative regulator of cardiac hypertrophy. In cardiomyocytes, STIM1 acts by tuning Akt kinase activity through activation of mTOR complex 2, which further results in repression of GSK-3&bgr; activity.

Potential Role of BNIP3 in Cardiac Remodeling, Myocardial Stiffness, and Endoplasmic ReticulumClinical Perspective

Background— We have shown that BNIP3 expression is significantly increased in heart failure (HF). In this study, we tested the effects of BNIP3 manipulation in HF. Methods and Results— In a rat model of pressure overload HF, BNIP3 knockdown significantly decreased left ventricular (LV) volumes with significant improvement in LV diastolic and systolic function. There were significant decreases in myocardial apoptosis and LV interstitial fibrosis. Ultrastructurally, BNIP3 knockdown attenuated mitochondrial fragmentation and restored mitochondrial morphology and integrity. On the molecular level, there were significant decreases in endoplasmic reticulum (ER) stress and mitochondrial apoptotic markers. One of the mechanisms by which BNIP3 mediates mitochondrial dysfunction is via the oligomerization of the voltage-dependent anion channels causing a shift of calcium from the ER to mitochondrial compartments, leading to the decrease in ER calcium content, mitochondrial damage, apoptosis, and LV interstitial fibrosis, and hence contributes to both systolic and diastolic myocardial dysfunction, respectively. In systolic HF, the downregulation of SERCA2a (sarcoplasmic-endoplasmic reticulum calcium ATPase), along with an increased BNIP3 expression, further worsen myocardial diastolic and systolic function and contribute to the major remodeling seen in systolic HF as compared with diastolic HF with normal SERCA2a expression. Conclusions— The increase in BNIP3 expression contributes mainly to myocardial diastolic dysfunction through mitochondrial apoptosis, LV interstitial fibrosis, and to some extent to myocardial systolic dysfunction attributable to the shift of calcium from the ER to the mitochondria and to the decrease in ER calcium content. However, SERCA2a downregulation remains a prerequisite for the major LV remodeling seen in systolic HF.Background—We have shown that BNIP3 expression is significantly increased in heart failure (HF). In this study, we tested the effects of BNIP3 manipulation in HF. Methods and Results—In a rat model of pressure overload HF, BNIP3 knockdown significantly decreased left ventricular (LV) volumes with significant improvement in LV diastolic and systolic function. There were significant decreases in myocardial apoptosis and LV interstitial fibrosis. Ultrastructurally, BNIP3 knockdown attenuated mitochondrial fragmentation and restored mitochondrial morphology and integrity. On the molecular level, there were significant decreases in endoplasmic reticulum (ER) stress and mitochondrial apoptotic markers. One of the mechanisms by which BNIP3 mediates mitochondrial dysfunction is via the oligomerization of the voltage-dependent anion channels causing a shift of calcium from the ER to mitochondrial compartments, leading to the decrease in ER calcium content, mitochondrial damage, apoptosis, and LV interstitial fibrosis, and hence contributes to both systolic and diastolic myocardial dysfunction, respectively. In systolic HF, the downregulation of SERCA2a (sarcoplasmic-endoplasmic reticulum calcium ATPase), along with an increased BNIP3 expression, further worsen myocardial diastolic and systolic function and contribute to the major remodeling seen in systolic HF as compared with diastolic HF with normal SERCA2a expression. Conclusions—The increase in BNIP3 expression contributes mainly to myocardial diastolic dysfunction through mitochondrial apoptosis, LV interstitial fibrosis, and to some extent to myocardial systolic dysfunction attributable to the shift of calcium from the ER to the mitochondria and to the decrease in ER calcium content. However, SERCA2a downregulation remains a prerequisite for the major LV remodeling seen in systolic HF.

Differential patterns of replacement and reactive fibrosis in pressure and volume overload are related to the propensity for ischaemia and involve resistin

•  Pressure overload hypertrophy is profibrotic while volume overload hypertrophy is not profibrotic. •  Fibrosis occurs in the form of replacement or reactive fibrosis. •  Replacement fibrosis in pressure overload is considered ischaemic in origin. •  There is less propensity for ischaemia in volume overload, explaining the relative lack of fibrosis. •  Reactive fibrosis pathways are more active in pressure than in volume overload. •  Local resistin expression reflects replacement fibrosis in chronic ischaemia.

High-dose chloroquine is metabolically cardiotoxic by inducing lysosomes and mitochondria dysfunction in a rat model of pressure overload hypertrophy

Autophagy, macroautophagy and chaperone‐mediated autophagy (CMA), are upregulated in pressure overload (PO) hypertrophy. In this study, we targeted this process at its induction using 3 methyladenine and at the lysosomal level using chloroquine and evaluated the effects of these modulations on cardiac function and myocyte ultrastructure. Sprague–Dawley rats weighing 200 g were subjected to ascending aortic banding. After 1 week of PO, animals were randomized to receive 3 methyladenine versus chloroquine, intraperitoneally, for 2 weeks at a dose of 40 and 50 mg/kg/day, respectively. Saline injection was used as control. Chloroquine treatment, in PO, resulted in regression in cardiac hypertrophy but with significant impairments in cardiac relaxation and contractility. Ultrastructurally, chloroquine accentuated mitochondrial fragmentation and cristae destruction with a plethora of autophagosomes containing collapsed mitochondria and lysosomal lamellar bodies. In contrast, 3 methyladenine improved cardiac function and attenuated mitochondrial fragmentation and autophagososme formation. Markers of macroautophagy and CMA were significantly decreased in the chloroquine group; whereas 3 methyladenine treatment significantly attenuated macroautophagy with a compensatory increase in CMA. Furthermore, chloroquine accentuated PO induced oxidative stress through the further decrease in the expression of manganese superoxide dismutase; whereas, 3 MA had a completely opposite effect. Taken together, these data suggest that high‐dose chloroquine, in addition to its effect on the autophagy‐lysosome pathway, significantly impairs mitochondrial antioxidant buffering capacity and accentuates oxidative stress and mitochondrial dysfunction in PO hypertrophy; highlighting, the cautious administration of this drug in high oxidative stress conditions, such as pathological hypertrophy or heart failure.