Sildenafil stops progressive chamber, cellular, and molecular remodeling and improves calcium handling and function in hearts with pre-existing advanced hypertrophy caused by pressure overload

Objective: This study sought to test the efficacy of phosphodiesterase type 5A (PDE5A) inhibition for treating advanced hypertrophy/remodeling caused by pressure overload, and to elucidate cellular and molecular mechanisms for this response. Background: Sildenafil (SIL) inhibits cyclic guanosine monophosphate-specific PDE5A and can blunt the evolution of cardiac hypertrophy and dysfunction in mice subjected to pressure overload. Whether and how it ameliorates more established advanced disease and dysfunction is unknown. Methods: Mice were subjected to transverse aortic constriction (TAC) for 3 weeks to establish hypertrophy/dilation, and subsequently treated with SIL (100 mg/kg/day) or placebo for 6 weeks of additional TAC. Results: The SIL arrested further progressive chamber dilation, dysfunction, fibrosis, and molecular remodeling, increasing myocardial protein kinase G activity. Isolated myocytes from TAC-SIL hearts showed greater sarcomere shortening and relaxation, and enhanced Ca²⁺ transients and decay compared with nontreated TAC hearts. The SIL treatment restored gene and protein expression of sarcoplasmic reticulum Ca²⁺ uptake adenosine triphosphatase (SERCA2a), phospholamban (PLB), and increased PLB phosphorylation (S16), consistent with improved calcium handling. The phosphatase calcineurin (Cn) and/or protein kinase C-α (PKCα) can both lower phosphorylated phospholamban and depress myocyte calcium cycling. The Cn expression and PKCα activation (outer membrane translocation) were enhanced by chronic TAC and reduced by SIL treatment. Expression of PKCδ and PKCε also increased with TAC but were unaltered by SIL treatment. Conclusions: SIL treatment applied to well-established hypertrophic cardiac disease can prevent further cardiac and myocyte dysfunction and progressive remodeling. This is associated with improved calcium cycling, and reduction of Cn and PKCα activation may be important to this improvement.9 page(s

Pressure-overload magnitude-dependence of the anti-hypertrophic efficacy of PDE5A inhibition

Increased myocardial cGMP, achieved by enhancing cyclase activity or impeding cGMP hydrolysis by phosphodiesterase type-5 (PDE5A), suppresses cellular and whole organ hypertrophy. The efficacy of the latter also requires cyclase stimulation and may depend upon co-activation of maladaptive signaling suppressible by cGMP-stimulated kinase (cGK-1). Thus, PDE5A inhibitors could paradoxically be more effective against higher than lower magnitudes of pressure-overload stress. To test this, mice were subjected to severe or moderate trans-aortic constriction (sTAC, mTAC) for 6 wks ± co-treatment with oral sildenafil (SIL 200 mg/kg/d). LV mass (LVM) rose 130% after 3-wks sTAC and SIL blunted this by 50%. With mTAC, LVM rose 56% at 3 wks but was unaffected by SIL, whereas a 90% increase in LVM after 6 wks was suppressed by SIL. SIL minimally altered LV function and remodeling with mTAC until later stages that stimulated more hypertrophy and remodeling. SIL stimulated cGK-1 activity similarly at 3 and 6 wks of mTAC. However, pathologic stress signaling (e.g. calcineurin, ERK-MAPkinase) was little activated after 3-wk mTAC, unlike sTAC or later stage mTAC when activity increased and SIL suppressed it. With modest hypertrophy (3-wk mTAC), GSK3β and Akt phosphorylation were unaltered but SIL enhanced it. However, with more severe hypertrophy (6-wk mTAC and 3-wk sTAC), both kinases were highly phosphorylated and SIL treatment reduced it. Thus, PDE5A-inhibition counters cardiac pressure-overload stress remodeling more effectively at higher than lower magnitude stress, coupled to pathologic signaling activation targetable by cGK-1 stimulation. Such regulation could impact responses of varying disease models to PDE5A inhibitors.8 page(s

Regulator of G protein signaling 2 mediates cardiac compensation to pressure overload and antihypertrophic effects of PDE5 inhibition in mice

The heart initially compensates for hypertension-mediated pressure overload by enhancing its contractile force and developing hypertrophy without dilation. Gq protein-coupled receptor pathways become activated and can depress function, leading to cardiac failure. Initial adaptation mechanisms to reduce cardiac damage during such stimulation remain largely unknown. Here we have shown that this initial adaptation requires regulator of G protein signaling 2 (RGS2). Mice lacking RGS2 had a normal basal cardiac phenotype, yet responded rapidly to pressure overload, with increased myocardial Gq signaling, marked cardiac hypertrophy and failure, and early mortality. Swimming exercise, which is not accompanied by Gq activation, induced a normal cardiac response, while Rgs2 deletion in Gαq-overexpressing hearts exacerbated hypertrophy and dilation. In vascular smooth muscle, RGS2 is activated by cGMP-dependent protein kinase (PKG), suppressing Gq-stimulated vascular contraction. In normal mice, but not Rgs2-/- mice, PKG activation by the chronic inhibition of cGMP-selective phosphodiesterase 5 (PDE5) suppressed maladaptive cardiac hypertrophy, inhibiting Gq-coupled stimuli. Importantly, PKG was similarly activated by PDE5 inhibition in myocardium from both genotypes, but PKG plasma membrane translocation was more transient in Rgs2-/- myocytes than in controls and was unaffected by PDE5 inhibition. Thus, RGS2 is required for early myocardial compensation to pressure overload and mediates the initial antihypertrophic and cardioprotective effects of PDE5 inhibitors.13 page(s

Myocardial remodeling is controlled by myocyte-targeted gene regulation of phosphodiesterase type 5

Objectives: We tested the hypothesis that bi-directional, gene-targeted regulation of cardiomyocyte cyclic guanosine monophosphateselective phosphodiesterase type 5 (PDE5) influences maladaptive remodeling in hearts subjected to sustained pressure overload. Background: PDE5 expression is up-regulated in human hypertrophied and failing hearts, and its inhibition (e.g., by sildenafil) stimulates protein kinase G activity, suppressing and reversing maladaptive hypertrophy, fibrosis, and contractile dysfunction. Sildenafil is currently being clinically tested for the treatment of heart failure. However, researchers of new studies have questioned the role of myocyte PDE5 and protein kinase G (PKG) to this process, proposing alternative targets and mechanisms. Methods: Mice with doxycycline-controllable myocyte-specific PDE5 gene expression were generated (medium transgenic [TG] and high TG expression lines) and subjected to sustained pressure overload. Results: Rest myocyte and heart function, histology, and molecular profiling were normal in both TG lines versus controls at 2 months of age. However, upon exposure to pressure overload (aortic banding), TG hearts developed more eccentric remodeling, maladaptive molecular signaling, depressed function, and amplified fibrosis with up-regulation of tissue growth factor signaling pathways. PKG activation was inhibited in TG myocytes versus controls. After establishing a severe cardiomyopathic state, high-TG mice received doxycycline to suppress PDE5 expression/activity only in myocytes. This in turn enhanced PKG activity and reversed all previously amplified maladaptive responses, despite sustained pressure overload. Sildenafil was also effective in this regard. Conclusions: These data strongly support a primary role of myocyte PDE5 regulation to myocardial pathobiology and PDE5 targeting therapy in vivo and reveal a novel mechanism of myocyte-orchestrated extracellular matrix remodeling via PDE5/cyclic guanosine monophosphatePKG regulatory pathways.10 page(s