Changwon Kho

Inhibition of miR-25 improves cardiac contractility in the failing heart

Heart failure is characterized by a debilitating decline in cardiac function, and recent clinical trial results indicate that improving the contractility of heart muscle cells by boosting intracellular calcium handling might be an effective therapy. MicroRNAs (miRNAs) are dysregulated in heart failure but whether they control contractility or constitute therapeutic targets remains speculative. Using high-throughput functional screening of the human microRNAome, here we identify miRNAs that suppress intracellular calcium handling in heart muscle by interacting with messenger RNA encoding the sarcoplasmic reticulum calcium uptake pump SERCA2a (also known as ATP2A2). Of 875 miRNAs tested, miR-25 potently delayed calcium uptake kinetics in cardiomyocytes in vitro and was upregulated in heart failure, both in mice and humans. Whereas adeno-associated virus 9 (AAV9)-mediated overexpression of miR-25 in vivo resulted in a significant loss of contractile function, injection of an antisense oligonucleotide (antagomiR) against miR-25 markedly halted established heart failure in a mouse model, improving cardiac function and survival relative to a control antagomiR oligonucleotide. These data reveal that increased expression of endogenous miR-25 contributes to declining cardiac function during heart failure and suggest that it might be targeted therapeutically to restore function.

SUMO1-dependent modulation of SERCA2a in heart failure

The calcium-transporting ATPase ATP2A2, also known as SERCA2a, is a critical ATPase responsible for Ca2+ re-uptake during excitation–contraction coupling. Impaired Ca2+ uptake resulting from decreased expression and reduced activity of SERCA2a is a hallmark of heart failure. Accordingly, restoration of SERCA2a expression by gene transfer has proved to be effective in improving cardiac function in heart-failure patients, as well as in animal models. The small ubiquitin-related modifier (SUMO) can be conjugated to lysine residues of target proteins, and is involved in many cellular processes. Here we show that SERCA2a is SUMOylated at lysines 480 and 585 and that this SUMOylation is essential for preserving SERCA2a ATPase activity and stability in mouse and human cells. The levels of SUMO1 and the SUMOylation of SERCA2a itself were greatly reduced in failing hearts. SUMO1 restitution by adeno-associated-virus-mediated gene delivery maintained the protein abundance of SERCA2a and markedly improved cardiac function in mice with heart failure. This effect was comparable to SERCA2A gene delivery. Moreover, SUMO1 overexpression in isolated cardiomyocytes augmented contractility and accelerated Ca2+ decay. Transgene-mediated SUMO1 overexpression rescued cardiac dysfunction induced by pressure overload concomitantly with increased SERCA2a function. By contrast, downregulation of SUMO1 using small hairpin RNA (shRNA) accelerated pressure-overload-induced deterioration of cardiac function and was accompanied by decreased SERCA2a function. However, knockdown of SERCA2a resulted in severe contractile dysfunction both in vitro and in vivo, which was not rescued by overexpression of SUMO1. Taken together, our data show that SUMOylation is a critical post-translational modification that regulates SERCA2a function, and provide a platform for the design of novel therapeutic strategies for heart failure.

Altered sarcoplasmic reticulum calcium cycling—targets for heart failure therapy

Cardiac myocyte function is dependent on the synchronized movements of Ca2+ into and out of the cell, as well as between the cytosol and sarcoplasmic reticulum. These movements determine cardiac rhythm and regulate excitation–contraction coupling. Ca2+ cycling is mediated by a number of critical Ca2+-handling proteins and transporters, such as L-type Ca2+ channels (LTCCs) and sodium/calcium exchangers in the sarcolemma, and sarcoplasmic/endoplasmic reticulum calcium ATPase 2a (SERCA2a), ryanodine receptors, and cardiac phospholamban in the sarcoplasmic reticulum. The entry of Ca2+ into the cytosol through LTCCs activates the release of Ca2+ from the sarcoplasmic reticulum through ryanodine receptor channels and initiates myocyte contraction, whereas SERCA2a and cardiac phospholamban have a key role in sarcoplasmic reticulum Ca2+ sequesteration and myocyte relaxation. Excitation–contraction coupling is regulated by phosphorylation of Ca2+-handling proteins. Abnormalities in sarcoplasmic reticulum Ca2+ cycling are hallmarks of heart failure and contribute to the pathophysiology and progression of this disease. Correcting impaired intracellular Ca2+ cycling is a promising new approach for the treatment of heart failure. Novel therapeutic strategies that enhance myocyte Ca2+ homeostasis could prevent and reverse adverse cardiac remodeling and improve clinical outcomes in patients with heart failure.

Effects of CXCR4 Gene Transfer on Cardiac Function After Ischemia-Reperfusion Injury

Acute coronary occlusion is the leading cause of death in the Western world. There is an unmet need for the development of treatments to limit the extent of myocardial infarction (MI) during the acute phase of occlusion. Recently, investigators have focused on the use of a chemokine, CXCL12, the only identified ligand for CXCR4, as a new therapeutic modality to recruit stem cells to individuals suffering from MI. Here, we examined the effects of overexpression of CXCR4 by gene transfer on MI. Adenoviruses carrying the CXCR4 gene were injected into the rat heart one week before ligation of the left anterior descending coronary artery followed by 24 hours reperfusion. Cardiac function was assessed by echocardiography couple with 2,3,5-Triphenyltetrazolium chloride staining to measure MI size. In comparison with control groups, rats receiving Ad-CXCR4 displayed an increase in infarct area (13.5% +/- 4.1%) and decreased fractional shortening (38% +/- 5%). Histological analysis revealed a significant increase in CXCL12 and tumor necrosis factor-alpha expression in ischemic area of CXCR4 overexpressed hearts. CXCR4 overexpression was associated with increased influx of inflammatory cells and enhanced cardiomyocyte apoptosis in the infarcted heart. These data suggest that in our model overexpressing CXCR4 appears to enhance ischemia/reperfusion injury possibly due to enhanced recruitment of inflammatory cells, increased tumor necrosis factor-alpha production, and activation of cell death/apoptotic pathways.

SUMO-1 Gene Transfer Improves Cardiac Function in a Large-Animal Model of Heart Failure

Cardiac gene delivery of small ubiquitin-related modifier 1 (SUMO-1) improved cardiac function and stabilized left ventricular volumes in a swine model of ischemic heart failure. Cardiac Gene Therapy to the Rescue Heart failure (HF) is one of the top reasons for hospitalization among the elderly and remains a leading cause of death in the Western world. Gene therapy has been proposed as a way to coerce the heart into being healthy by targeting cardiac-specific pathways. Replacing the gene sarcoplasmic reticulum Ca2+ adenosine triphosphatase (SERCA2a) in patients has made it to phase 2b/3 trials, with early signs pointing to an improvement in HF-related events. To boost the effects of SERCA2a, Tilemann et al. designed a large-animal study that also tests the delivery of small ubiquitin-related modifier 1 (SUMO-1)—an important regulator of SERCA2a. The authors compared the efficacy of SUMO-1 gene transfer to SERCA2a gene transfer alone and to the combined delivery of both genes in a pig model of HF. In addition to being safe, administering SUMO-1 directly to the heart of these animals showed improved cardiac contractility and prevented left ventricular dilatation (two major aspects of HF). According to the authors, the functional improvements in this model of heart failure are most likely the result of improved SR Ca2+ ATPase activity afforded by increased SUMO-1 protein levels. Delivery of both SUMO-1 and SERCA2a suggested additional beneficial effects, but more mechanistic studies will be needed to understand this potential synergy. With the precedent set by the SERCA2a clinical trials, moving SUMO-1 gene therapy from pigs to humans seems likely in the short-term. Recently, the impact of small ubiquitin-related modifier 1 (SUMO-1) on the regulation and preservation of sarcoplasmic reticulum calcium adenosine triphosphatase (SERCA2a) function was discovered. The amount of myocardial SUMO-1 is decreased in failing hearts, and its knockdown results in severe heart failure (HF) in mice. In a previous study, we showed that SUMO-1 gene transfer substantially improved cardiac function in a murine model of pressure overload–induced HF. Toward clinical translation, we evaluated in this study the effects of SUMO-1 gene transfer in a swine model of ischemic HF. One month after balloon occlusion of the proximal left anterior descending artery followed by reperfusion, the animals were randomized to receive either SUMO-1 at two doses, SERCA2a, or both by adeno-associated vector type 1 (AAV1) gene transfer via antegrade coronary infusion. Control animals received saline infusions. After gene delivery, there was a significant increase in the maximum rate of pressure rise [dP/dt(max)] that was most pronounced in the group that received both SUMO-1 and SERCA2a. The left ventricular ejection fraction (LVEF) improved after high-dose SUMO-1 with or without SERCA2a gene delivery, whereas there was a decline in LVEF in the animals receiving saline. Furthermore, the dilatation of LV volumes was prevented in the treatment groups. SUMO-1 gene transfer therefore improved cardiac function and stabilized LV volumes in a large-animal model of HF. These results support the critical role of SUMO-1 in SERCA2a function and underline the therapeutic potential of SUMO-1 for HF patients.

Small-molecule activation of SERCA2a SUMOylation for the treatment of heart failure

Decreased activity and expression of the cardiac sarcoplasmic reticulum calcium ATPase (SERCA2a), a critical pump regulating calcium cycling in cardiomyocyte, are hallmarks of heart failure. We have previously described a role for the small ubiquitin-like modifier type 1 (SUMO-1) as a regulator of SERCA2a and have shown that gene transfer of SUMO-1 in rodents and large animal models of heart failure restores cardiac function. Here, we identify and characterize a small molecule, N106, which increases SUMOylation of SERCA2a. This compound directly activates the SUMO-activating enzyme, E1 ligase, and triggers intrinsic SUMOylation of SERCA2a. We identify a pocket on SUMO E1 likely to be responsible for N106s effect. N106 treatment increases contractile properties of cultured rat cardiomyocytes and significantly improves ventricular function in mice with heart failure. This first-in-class small-molecule activator targeting SERCA2a SUMOylation may serve as a potential therapeutic strategy for treatment of heart failure.

Mechanoelectrical remodeling and arrhythmias during progression of hypertrophy

Despite a clear association between left ventricular (LV) mechanical dysfunction in end‐stage heart failure and the incidence of arrhythmias, the majority of sudden cardiac deaths occur at earlier stages of disease development. The mechanisms by which structural, mechanical, and molecular alterations predispose to arrhythmias at the tissue level before the onset of LV dysfunction remain unclear. In a rat model of pressure overload hypertrophy (PoH) produced by ascending aortic banding, we correlated mechanical and structural changes measured in vivo with key electrophysiological changes measured ex vivo in the same animals. We found that action potential prolongation, a hallmark of electrical remodeling at the tissue level, is highly correlated with changes in LV wall thickness but not mechanical function. In contrast, conduction delays are not predicted by either mechanical or structural changes during disease development. Moreover, disrupted Cx43 phosphorylation at intermediate (increased) and late (decreased) stages of PoH are associated with moderate and severe conduction delays, respectively. Interest‐ingly, the level of interaction between Cx43 and the cytoskeletal protein ZO‐1 is exclusively decreased at the late stage of PoH. Closely coupled action potentials consistent with afterdepolarization‐mediated triggered beats were readily observed in 6 of 15 PoH hearts but never in controls. Similarly, PoH (8/15) but not control hearts exhibited sustained episodes of ventricular tachycardia after rapid stimulation. The initiation and early maintenance of arrhythmias in PoH were formed by rapid and highly uniform activation wavefronts emanating from sites distal to the former site of stimulation. In conclusion, repolarization but not conduction delays are predicted by structural remodeling in PoH. Cx43 phosphorylation is disrupted at intermediate (increased) and late (decreased) stages, which are associated with conduction delays. Dephosphorylation of Cx43 is associated with loss of interaction with ZO‐1 and severe conduction delays. Remodeling at all stages of PoH predisposes to triggers and focal arrhythmias.—Jin, H., Chemaly, E. R., Lee, A., Kho, C., Hadri, L., Hajjar, R. J., Akar, F. G. Mechanoelectrical remodeling and arrhythmias during progression of hypertrophy. FASEBJ. 24, 451–463 (2010). www.fasebj.org

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.

PICOT increases cardiac contractility by inhibiting PKCζ activity

Protein kinase C (PKC)-interacting cousin of thioredoxin (PICOT) has distinct anti-hypertrophic and inotropic functions. We have previously shown that PICOT exerts its anti-hypertrophic effect by inhibiting calcineurin-NFAT signaling through its C-terminal glutaredoxin domain. However, the mechanism underlying the inotropic effect of PICOT is unknown. The results of protein pull-down experiments showed that PICOT directly binds to the catalytic domain of PKCζ through its N-terminal thioredoxin-like domain. Purified PICOT protein inhibited the kinase activity of PKCζ in vitro, which indicated that PICOT is an endogenous inhibitor of PKCζ. The inhibition of PKCζ activity with a PKCζ-specific pseudosubstrate peptide inhibitor was sufficient to increase the cardiac contractility in vitro and ex vivo. Overexpression of PICOT or inhibition of PKCζ activity down-regulated PKCα activity, which led to the elevation of sarcoplasmic reticulum Ca(2+)-ATPase (SERCA) 2a activity, concomitant with the increased phosphorylation of phospholamban (PLB). Overexpression of PICOT or inhibition of PKCζ activity also down-regulated protein phosphatase (PP) 2A activity, which subsequently resulted in the increased phosphorylation of troponin (Tn) I and T, key myofilament proteins associated with the regulation of contractility. PICOT appeared to inhibit PP2A activity through the disruption of the functional PKCζ/PP2A complex. In contrast to the overexpression of PICOT or inhibition of PKCζ, reduced PICOT expression resulted in up-regulation of PKCα and PP2A activities, followed by decreased phosphorylation of PLB, and TnI and T, respectively, supporting the physiological relevance of these events. Transgene- or adeno-associated virus (AAV)-mediated overexpression of PICOT restored the impaired contractility and prevented further morphological and functional deterioration of the failing hearts. Taken together, the results of the present study suggest that PICOT exerts its inotropic effect by negatively regulating PKCα and PP2A activities through the inhibition of PKCζ activity. This finding provides a novel insight into the regulation of cardiac contractility.

Stem Cell Factor Gene Transfer Improves Cardiac Function After Myocardial Infarction in Swine

Background—Stem cell factor (SCF), a ligand of the c-kit receptor, is a critical cytokine, which contributes to cell migration, proliferation, and survival. It has been shown that SCF expression increases after myocardial infarction (MI) and may be involved in cardiac repair. The aim of this study was to determine whether gene transfer of membrane-bound human SCF improves cardiac function in a large animal model of MI. Methods and Results—A transmural MI was created by implanting an embolic coil in the left anterior descending artery in Yorkshire pigs. One week after the MI, the pigs received direct intramyocardial injections of either a recombinant adenovirus encoding for SCF (Ad.SCF, n=9) or &bgr;-gal (Ad.&bgr;-gal, n=6) into the infarct border area. At 3 months post-MI, ejection fraction increased by 12% relative to baseline after Ad.SCF therapy, whereas it decreased by 4.2% (P=0.004) in pigs treated with Ad.&bgr;-gal. Preload-recruitable stroke work was significantly higher in pigs after SCF treatment (Ad.SCF, 55.5±11.6 mm Hg versus Ad.&bgr;-gal, 31.6±12.6 mm Hg, P=0.005), indicating enhanced cardiac function. Histological analyses confirmed the recruitment of c-kit+ cells as well as a reduced degree of apoptosis 1 week after Ad.SCF injection. In addition, increased capillary density compared with pigs treated with Ad.&bgr;-gal was found at 3 months and suggests an angiogenic role of SCF. Conclusions—Local overexpression of SCF post-MI induces the recruitment of c-kit+ cells at the infarct border area acutely. In the chronic stages, SCF gene transfer was associated with improved cardiac function in a preclinical model of ischemic cardiomyopathy.