Prevention of the development of heart failure with preserved ejection fraction by the phosphodiesterase-5A inhibitor vardenafil in rats with type 2 diabetes.

AIMS: Heart failure with preserved ejection fraction (HFpEF) has a great epidemiological burden. The pathophysiological role of cyclic guanosine monophosphate (cGMP) signalling has been intensively investigated in HFpEF. Elevated levels of cGMP have been shown to exert cardioprotective effects in various cardiovascular diseases, including diabetic cardiomyopathy. We investigated the effect of long-term preventive application of the phosphodiesterase-5A (PDE5A) inhibitor vardenafil in diabetic cardiomyopathy-associated HFpEF. METHODS AND
RESULTS: Zucker diabetic fatty (ZDF) rats were used as a model of HFpEF and ZDF lean rats served as controls. Animals received vehicle or 10 mg/kg body weight vardenafil per os from weeks 7 to 32 of age. Cardiac function, morphology was assessed by left ventricular (LV) pressure-volume analysis and echocardiography at week 32. Cardiomyocyte force measurements were performed. The key markers of cGMP signalling, nitro-oxidative stress, apoptosis, myocardial hypertrophy and fibrosis were examined. The ZDF animals showed diastolic dysfunction (increased LV/cardiomyocyte stiffness, prolonged LV relaxation time), preserved systolic performance, decreased myocardial cGMP level coupled with impaired protein kinase G (PKG) activity, increased nitro-oxidative stress, enhanced cardiomyocyte apoptosis, and hypertrophic and fibrotic remodelling of the myocardium. Vardenafil effectively prevented the development of HFpEF by maintaining diastolic function (decreased LV/cardiomyocyte stiffness and LV relaxation time), by restoring cGMP levels and PKG activation, by lowering apoptosis and by alleviating nitro-oxidative stress, myocardial hypertrophy and fibrotic remodelling.
CONCLUSIONS: We report that vardenafil successfully prevented the development of diabetes mellitus-associated HFpEF. Thus, PDE5A inhibition as a preventive approach might be a promising option in the management of HFpEF patients with diabetes mellitus.

Introduction

Heart failure (HF) is a complex clinical syndrome characterized by specific clinical signs and symptoms and it is one of the most common causes leading to hospitalization.1 Three main forms of HF are determined by the value of left ventricular (LV) ejection fraction (EF) including HF with preserved EF (HFpEF; LVEF ≥50%).1 In general, HFpEF is associated with diastolic dysfunction characterized by prolonged LV isovolumic relaxation, increased LV stiffness, increased LV end‐diastolic pressure and slow LV filling.2 To date, no pharmacological treatment has been shown to effectively reduce HFpEF‐associated morbidity and mortality.1

Many diseases lead to the development of HF, such as atherosclerosis, hypertension, cardiomyopathies, valvular diseases, arrhythmias, etc.1 Furthermore, different co‐morbidities such as diabetes mellitus (DM) and obesity are often observed in HFpEF patients and they play an important role in the progression and outcome of HF.1, 2 Therefore, the presence of these co‐morbidities must be taken into account in the prevention or treatment of HFpEF.

Diabetic cardiomyopathy is a distinct disease entity that develops in DM regardless of the presence of coronary artery disease and hypertension.3 Several key processes can be attributed to the development of diabetic cardiomyopathy including myocardial fibrosis, hypertrophy, cardiac (mainly diastolic) dysfunction, increased nitro‐oxidative stress, apoptosis, and inflammation.3

The nitric oxide (NO)–soluble guanylate cyclase (sGC)–cyclic guanosine monophosphate (cGMP)–protein kinase G (PKG) axis has been described as an important regulator of cardiac contractility.4 In brief, under physiological conditions NO is produced by the endothelial cells and activates sGC as a gaseous transmitter in its target cells such as cardiomyocytes and vascular smooth muscle cells. In response to this, sGC produces cGMP, the key regulator of the downstream effector PKG enzyme.4 Essential regulators of this system are the phosphodiesterases (PDEs) as they are able to degrade cGMP to 5′‐GMP.4 Phosphodiesterase‐5A (PDE5A) is specific for cGMP molecules4 and has been described to be upregulated in different types of HF and in diabetic cardiomyopathy in particular.5, 6 Theoretically, the above‐mentioned upregulation of PDEs coupled with the enhanced nitro‐oxidative stress3 could notably contribute to the impaired cGMP–PKG signalling in the myocardium of HFpEF patients.7, 8

Many pharmacological interventions have been proposed to modulate NO signalling in the diabetic myocardium, including PDE inhibitors.6 Vardenafil, a highly selective PDE5A inhibitor is an on‐demand treatment for erectile dysfunction and it displays the highest potency compared with its comparators.9 Restoration of the impaired cGMP signalling by the PDE5A inhibitor vardenafil has been proven cardioprotective in different myocardial pathologies.10, 11, 12

Based upon this, we investigated, in the present study, whether long‐term application of the PDE5A inhibitor vardenafil, started in the prediabetic phase,13 could prevent the development of HFpEF in an animal model of type 2 DM (T2DM).

Methods

For details see the Supplementary material online, Methods S1.

Animals

The investigation conformed to the EU Directive 2010/63/EU and the Guide for the Care and Use of Laboratory Animals used by the US National Institutes of Health (NIH Publication No. 85–23, revised 1996). The experimental protocol was reviewed and approved by the institutional ethics committee (permission number: 22.1/1162/3/2010). The Zucker diabetic fatty (ZDF) rat was used as an animal model of HFpEF.14

Study protocol

Seven‐week‐old ZDF diabetic (fa/fa) and ZDF lean (+/?) rats (Charles River, Sulzfeld, Germany) were randomized into four groups: vehicle‐treated controls (ZDFLean; n = 8), vardenafil‐treated controls (ZDFLean + Vard; n = 7), vehicle‐treated diabetic (ZDF; n = 7), and vardenafil‐treated diabetic (ZDF + Vard; n = 8). Rats were fed Purina #5008 diet (Charles River) and water ad libitum. Everyday per os drug treatment [10 mg/kg body weight (BW) vardenafil dissolved in 0.01 mol/L citrate buffer] or vehicle (0.01 mol/L citrate buffer) administration via drinking water was initiated at the age of 7 week and continued until the end of the experimental period. Functional measurements were performed at the age of 32 weeks. The BW of the animals was measured every 2 days and the dose of vardenafil was adjusted accordingly.

Echocardiography

Echocardiography was performed as described previously.15 The LV anterior (AW) and posterior wall (PW) thicknesses and LV internal diameter (ID) in end‐diastole (d) and in end‐systole (s) were measured and relative wall thickness (RWT), LVmass, LVmass/tibia length (TL, cm), LVmass index (LVmass/BW) were calculated.

Invasive haemodynamics

Invasive haemodynamic investigation was performed as described earlier5 with a 2 F microtip pressure‐conductance microcatheter (SPR‐838; Millar Instruments, Houston, TX, USA) system under isoflurane anaesthesia (1–2%). Heart rate (HR), mean arterial blood pressure (MAP), EF, cardiac output (CO), stroke work (SW), maximal slope of systolic pressure increment (dP/dtmax) and diastolic pressure decrement (dP/dtmin), time constant of LV pressure decay (TauW) were calculated. The slope (Ees) of the LV end‐systolic pressure–volume relationships (ESPVR) and preload recruitable stroke work (PRSW) were used as load‐independent indices of contractility. The slope of the LV end‐diastolic pressure–volume relationship (EDPVR) was determined as an index of LV diastolic stiffness. TL and heart weight (HW, g) were measured.

Force measurement in permeabilized left ventricular cardiomyocytes

Permeabilized rat LV cardiomyocytes were mounted in a mechanical apparatus to measure isometric force and sarcomere length (SL). Maximal active force (Fmax) was determined in the presence of a saturating Ca2+ concentration [pCa 4.75; pCa = −lg(Ca2+)], and Ca2+‐independent passive force (Fpassive) was measured in relaxing solution (pCa 9.0) during release–restretch manoeuvres. Both Fmax and Fpassive were routinely recorded at a SL 2.3 µm, while Fpassive was also registered for a range of SLs (between 1.9 µm and 2.5 µm).

Biochemistry

Blood glucose (BG) level was determined by a digital blood glucose meter (Accu‐Chek® Sensor; Roche, Mannheim, Germany). Plasma cGMP was measured by using a cGMP enzyme immunoassay kit (Amersham cGMP EIA Biotrak System; GE Healthcare, Chalfont St Giles, UK). Plasma total nitrite/nitrate levels (NO bioavailability) were determined by Nitric Oxide Colorimetric Assay Kit (#K262–200; Biovision, Milpitas, CA, USA).

Quantitative real‐time polymerase chain reaction

LV mRNA samples were used for quantitative real‐time polymerase chain reaction (qRT‐PCR) experiments. Myocardial hypertrophy marker atrial natriuretic factor (ANF), fibrotic remodelling markers fibronectin‐1 (Fn1), collagen 1a1 (Col1a1) and 3a1 (Col3a1), markers related to oxidative stress,16 such as catalase and thioredoxin‐1 and sarcoplasmic reticulum calcium ATPase 2 (SERCA2a), phospholamban (PLB) and PLB/SERCA2a ratios were investigated (see the Supplementary material online, Table S1). Data were normalized to glyceraldehyde‐3‐phosphate dehydrogenase (GAPDH).

Western blot

Western blot experiments were performed from LV samples. We examined PDE5A, PKG, vasodilator‐stimulated phosphoprotein (VASP) and phospho‐VASP (p‐VASP) [p‐VASP/VASP ratio (marker of PKG activity)], cleaved caspase‐3, total/cleaved poly (ADP‐ribose) polymerase (PARP1), phospholamban (PLB), and phospho‐phospholamban (p‐PLB) (see the Supplementary material online, Table S2). After development, band densities were quantified and values were adjusted to α‐tubulin.

Histology and immunohistochemistry

Myocardial sections were deparaffinized and stained with haematoxylin and eosin (H&E), Masson's trichrome (MT) or PicroSirius. Cardiomyocyte diameter was measured as described previously.5 Fibrotic remodelling was evaluated on MT and PicroSirius stained sections. PicroSirius area was assessed on red, green and blue (RGB) stacked images by thresholding with Image J (NIH, Bethesda, MD, USA). Immunohistochemistry for 3‐nitrotyrosine (3‐NT) and cGMP were also performed (see the Supplementary material online, Table S2).

Terminal deoxynucleotidyl transferase dUTP nick‐end labelling assay

Terminal deoxynucleotidyl transferase dUTP nick‐end labelling (TUNEL) assay (DeadEnd™ Colorimetric TUNEL System; Promega, Mannheim, Germany) was performed to detect DNA fragmentation.

Statistics

Data are presented as mean ± SEM. Normal distribution was tested by the Shapiro–Wilks method. Two‐way analysis of variance (ANOVA) with the factors ‘T2DM’ and ‘Vardenafil’ was performed (see the Supplementary material online, Table S3). A Tukey honestly significant difference (HSD) post hoc test was used to examine intergroup differences. Pearson or Spearman test was used for correlation analysis appropriately depending on data distribution. A P‐value <0.05 was deemed significant.

Results

Basic characteristics

The BW of the animals did not differ statistically at the end of the study period (Table 1). Both ZDF and ZDF + Vard animals had significantly elevated BG levels throughout the study period (see the Supplementary material online, Figure S1).

Table 1

Basic characteristics and haemodynamic parameters in the study groups

Variable	ZDFLean	ZDFLean + Vard	ZDF	ZDF + Vard
Basic characteristics
BW (g)	421 ± 9	419 ± 12	395 ± 25	405 ± 28
HW (g)	1.46 ± 0.03	1.55 ± 0.02	1.55 ± 0.03	1.51 ± 0.04
HW/BW (g/kg)	3.46 ± 0.05	3.71 ± 0.13	3.98 ± 0.25	3.79 ± 0.24
HW/TL (g/cm)	0.346 ± 0.007	0.364 ± 0.005	0.389 ± 0.007*	0.377 ± 0.010
Echocardiography†
LVAWs (mm)	2.53 ± 0.04	2.58 ± 0.15	2.90 ± 0.08*	2.48 ± 0.05#
LVAWd (mm)	1.73 ± 0.03	1.76 ± 0.03	1.88 ± 0.01*	1.72 ± 0.03#
LVIDs (mm)	4.91 ± 0.21	4.84 ± 0.16	4.50 ± 0.14	5.04 ± 0.19
LVIDd (mm)	8.08 ± 0.20	7.83 ± 0.15	7.99 ± 0.32	8.08 ± 0.29
LVPWs (mm)	2.63 ± 0.07	2.69 ± 0.10	3.07 ± 0.10*	2.93 ± 0.11
LVPWd (mm)	1.72 ± 0.08	1.91 ± 0.07	2.12 ± 0.10*	2.02 ± 0.10
RWT	0.41 ± 0.02	0.47 ± 0.01	0.50 ± 0.03*	0.47 ± 0.02
LVmass (g)	0.98 ± 0.02	1.01 ± 0.05	1.15 ± 0.05	1.09 ± 0.07
LVmass/TL (g/cm)	0.232 ± 0.005	0.245 ± 0.118	0.299 ± 0.010*	0.271 ± 0.017
LVmass index (g/kg BW)	2.53 ± 0.09	2.66 ± 0.13	3.23 ± 0.23*	2.99 ± 0.23
Haemodynamic parameters
HR (b.p.m.)	326 ± 4	327 ± 8	310 ± 6	319 ± 8
MAP (mmHg)	96 ± 3	96 ± 3	99 ± 2	105 ± 2
EF (%)	65 ± 2	66 ± 2	61 ± 2	64 ± 4
CO (mL/min)	67 ± 5	70 ± 5	55 ± 5	58 ± 9
dP/dtmax (mmHg/s)	9426 ± 453	9061 ± 270	8478 ± 234	9994 ± 634
dP/dtmin (mmHg/s)	−9799 ± 549	−9706 ± 424	−9039 ± 639	−9463 ± 1084
SW (mmHg.µL)	19378 ± 1125	20567 ± 1231	17279 ± 1392	17848 ± 2576

BW, body weight; HW, heart weight, TL, tibia length; LV, left ventricular; AW, anterior wall thickness; PW, posterior wall thickness; LVID, LV internal diameter; RWT, relative wall thickness; HR, heart rate; MAP, mean arterial pressure; EF, ejection fraction; CO, cardiac output; dP/dtmax and dP/dtmin, maximal and minimal slope of dP/dt; SW, stroke work.

P < 0.05 vs. ZDFLean; # P < 0.05 vs. ZDF.

The ‘s’ and ‘d’ after the acronyms indicate end‐systolic and end‐diastolic, respectively.

Vardenafil prevented type 2 diabetes mellitus‐associated left ventricular dysfunction in vivo

Neither HR nor MAP differed among the groups (Table 1). The slope of EDPVR (LV stiffness parameter) and TauW showed significant increase in ZDF (Figure 1 a,b). Vardenafil treatment markedly improved the slope of EDPVR, while TauW tended to decrease in ZDF rats (Figure 1 b). Factorial ANOVA revealed significant differences in EDPVR and TauW between T2DM and non‐diabetic animals (see the Supplementary material online, Table S3). Despite the marked diastolic dysfunction in T2DM, conventional systolic parameters, such as EF, CO, dP/dtmax, and SW did not differ among our study groups (Table 1). Moreover, reliable load‐independent systolic parameters Ees and PRSW remained unchanged (Figure 1 c).

Figure 1

The effect of vardenafil on the haemodynamic alterations and on myocardial hypertrophy in heart failure with preserved ejection fraction animals. (a) Representative left ventricular (LV) pressure–volume (P‐V) loops. The arrow indicates the increase of the slope of end‐diastolic pressure–volume relationship (EDPVR). (b) Graphs represent the value of the slope of (EDPVR) and TauW. (c) Graphs of the slope (Ees) of the LV end‐systolic P‐V relationship and the value of preload‐recruitable stroke work (PRSW). (d) Fpassive (cardiomyocyte stiffness marker) at different sarcomere lengths. (e) Fmax in the study groups. (f) Representative M‐mode echocardiography images at the mid‐papillary level on short axis view. (g) Relative gene expression of atrial natriuretic factor (ANF). (h) Representative haematoxylin‐eosin stained sections. Bar: 50 µm, Magnification: 200×. (i) Quantification of cardiomyocyte diameter/tibia length (TL). (j) Correlation analysis between cardiomyocyte diameter/tibia length (TL) and the slope of EDPVR. Study groups are defined in the text. *P < 0.05 vs. ZDFLean; # P < 0.05 vs. ZDF.

Vardenafil prevented type 2 diabetes mellitus‐associated stiffening of LV cardiomyocytes

The value of Fpassive (at different SLs; a marker of cardiomyocyte stiffness) increased significantly in ZDF rats (Figure 1 d). Vardenafil prevented the diabetes‐associated increase of Fpassive (Figure 1 d), however, it had no effect on Fmax (Figure 1 e).

Vardenafil decreased myocardial hypertrophy in Zucker Diabetic Fatty rats

Although HW and HW/BW ratios were not different, HW/TL ratio increased significantly in ZDF compared with ZDFLean rats (Table 1). The HW/TL ratio of ZDF + Vard rats tended to decrease compared with ZDF rats (Table 1). In addition, echocardiography revealed signs of myocardial hypertrophy in ZDF rats, indicated by the significantly elevated LVAW and LVPW in ‘s’ and ‘d’, increased RWT, LVmass/TL, and LVmass index (Table 1). All of these parameters tended to decline in ZDF + Vard rats, while LVAWs and LVAWd were reduced markedly in response to vardenafil treatment when compared with ZDF rats (Table 1). In addition to the robust hypertrophy observed on echocardiography (Figure 1 f), significant elevation of ANF (Figure 1 g), histological evaluation of H&E sections (Figure 1 h) along with the robust increase in cardiomyocyte diameter/TL (Figure 1 i) supported cardiac hypertrophy. Vardenafil significantly reduced the gene expression level of ANF (Figure 1 g) and decreased cardiomyocyte diameter/TL (Figure 1 i). The slope of EDPVR correlated robustly with the hypertrophy marker cardiomyocyte diameter/TL (Figure 1 j).

Vardenafil reduced alterations associated with myocardial nitro‐oxidative stress in type 2 diabetes mellitus

Type 2 DM was associated with markedly elevated 3‐NT content of the left ventricle (Figure 2 a,b), however, vardenafil prevention effectively reduced it (Figure 2 a,b). In accord with this, we observed significant upregulation of different antioxidant enzymes, including catalase and thiorexodin‐1 in the ZDF group (Figure 2 c). Nevertheless, as a result of chronic drug treatment catalase and thioredoxin‐1 levels declined significantly in ZDF rats (Figure 2 C). Moreover, SERCA2a was markedly downregulated in ZDF rats regardless of treatment (Figure 2 d). The PLB gene expression tended to decrease in the ZDF group (Fig.2D), although, in the ZDF + Vard group, it did not show any difference when compared with the ZDFLean group (Figure 2 d). Despite the unchanged PLB/SERCA2a ratio in T2DM (Figure 2 d), vardenafil treatment markedly increased the ratio of PLB/SERCA2a in ZDF animals (Figure 2 c).

Figure 2

Phosphodiesterase‐5A inhibition reduces the extent of cardiac nitro‐oxidative stress in heart failure with preserved ejection fraction. (a) Representative images of 3‐nitrotyrosine (3‐NT) stained sections. Arrows indicate the grey coloured 3‐NT positive area. Bar: 50 µm, Magnification: 200×. (b) Quantification of 3‐NT positive area in the experimental groups. (c) Relative gene expression levels of catalase and thioredoxin‐1. (d) Gene expression levels of sarcoplasmic reticulum calcium ATPase 2 (SERCA2a), phospholamban (PLB) and the ratio of PLB/SERCA2a are shown. A detailed description of the study groups is available in the text. *P < 0.05 vs. ZDFLean; # P < 0.05 vs. ZDF.

Vardenafil suppressed myocardial fibrotic remodelling in type 2 diabetes mellitus

Masson trichrome and PicroSirius staining revealed fibrotic remodelling of the myocardium in ZDF (Figure 3 a–d), the extent of which correlated robustly with the slope of EDPVR (Figure 3 e). Fibronectin‐1 was markedly overexpressed in T2DM (Figure 3 f). Both Col1a1 and Col3a1 mRNAs were also significantly downregulated in ZDF rats (Figure 3 g). Prevention by vardenafil effectively reduced the fibrotic remodelling of the myocardium (Figure 3 a‐d) and significantly reduced Fn1 gene expression (Figure 3 f) in T2DM. Interestingly, Col1a1 and Col3a1 gene expressions were unaltered by vardenafil in the ZDF + Vard group compared with the ZDF group (Figure 3 g).

Figure 3

Protective effects of vardenafil on myocardial fibrosis in heart failure with preserved ejection fraction. (a) Representative images and (b) semiquantitative scoring of Masson's trichrome stained sections. Arrows indicate interstitial fibrosis of the myocardium. Bar: 50 µm, Magnification: 200×. (c) Representative images and (d) quantification of PicroSirius stained myocardium. Bar: 50 µm, Magnification: 200×. (e) Correlation analysis between PicroSirius positive area and the slope of end‐diastolic pressure–volume relationship (EDPVR). (f) Gene expression of fibronectin‐1 (Fn1), (g) collagen 1a1 and 3a1 (Col1a1; Col3a1). A detailed description of the study groups is available in the text. *P < 0.05 vs. ZDFLean; # P < 0.05 vs. ZDF

Phosphodiesterase‐5A inhibition prevented cardiomyocyte apoptosis in Zucker Diabetic Fatty rats

Evidence for increased cardiomyocyte apoptosis was shown by TUNEL assay (Figure 4 a,b), and demonstrated by markedly risen cleaved caspase‐3 and cleaved PARP1 band densities (Figure 4 c,d). However, vardenafil prevented the above alterations by significantly decreasing the number of TUNEL‐positive nuclei (Figure 4 b) and cleaved PARP1 band density (Figure 4 d). Cleaved caspase‐3 band density was not significantly different in ZDF + Vard group compared with the ZDFLean group (Figure 4 c).

Figure 4

The effects of vardenafil on myocardial DNA fragmentation and apoptosis. (a) Representative images of terminal deoxynucleotidyl transferase dUTP nick‐end labelling (TUNEL) assay. Bar: 50 µm, Magnification: 200×. (b) Quantification of TUNEL positive nuclei/field. (c) Graphs and representative western blot bands of cleaved caspase‐3 (17 kDa) and (d) cleaved poly (ADP‐ribose) polymerase (PARP1; 85 kDa) levels in the myocardium. A detailed description of the study groups is available in the text. *P < 0.05 vs. ZDFLean; # P < 0.05 vs. ZDF.

Vardenafil prevented the disturbances of myocardial cyclic guanosine monophosphate–protein kinase G signalling in Zucker Diabetic Fatty rats

The PDE5A–cGMP–PKG axis significantly deteriorated in T2DM, as demonstrated by the markedly lower cGMP staining intensity of the myocardium (Figure 5 a,b), by the increased protein levels of PDE5A and PKG (Figure 5 d) and by the lower p‐VASP/VASP ratio (as a marker of impaired PKG activity; Figure 5 d). Myocardial PDE5A levels in the ZDF + Vard group did not differ from the healthy controls (Figure 5 d). Vardenafil effectively increased the cGMP staining intensity of the ZDF group myocardium (Figure 5 a,b). Furthermore, vardenafil elevated the plasma cGMP content in ZDF rats (Figure 5 c) and restored the ratio of p‐VASP/VASP (Figure 5 d). Interestingly, the plasma cGMP level showed a strong tendency toward elevation in ZDFLean + Vard group (Figure 5 d). Plasma total nitrite/nitrate levels and p‐PLB/PLB ratios were not different among the groups (see the Supplementary material online, Figure S2).

Figure 5

Modulatory effects of vardenafil on the myocardial NO‐cGMP signalling in T2DM. (a) Representative images. Bar: 50 µm, Magnification: 200×. (b) Quantification of cGMP immunohistochemistry in the study groups. (c) Plasma cGMP levels in the experimental groups. (d) Graphs and representative western blot bands of phosphodiesterase‐5A (PDE5A, 130 kDa), protein kinase G (PKG, 75 kDa) and phospho‐vasodilator‐stimulated phosphoprotein (p‐VASP) and VASP (50 kDa) are shown. A detailed description of the study groups is available in the text. *P < 0.05 vs. ZDFLean; # P < 0.05 vs. ZDF.

Discussion

The main findings of the present study are that PDE5A inhibition with long‐term vardenafil application (i) effectively prevents the development of HFpEF (characterized by increased myocardial stiffness and worsened diastolic function), (ii) reduces the pathophysiological features of T2DM‐associated diabetic cardiomyopathy, and (iii) restores the activity of cGMP–PKG axis by increasing myocardial as well as plasma cGMP levels.

Heart failure with preserved EF is characterized by the clinical signs of HF, however, cardiac systolic function measured by EF is preserved (LVEF ≥50%) with a concomitant decrease in diastolic function (increased stiffness, decreased relaxation and slow LV filling).1, 2 The importance of co‐morbidities and the subsequent deterioration of the NO‐cGMP‐PKG signalling has been proposed in the development of HFpEF by Paulus and Tschope.8 The presence of co‐morbidities (especially obesity and T2DM) leads to an increased level of reactive oxygen species (ROS), decreased NO bioavailability, and lower cGMP levels, with subsequent deactivation of the main effector, PKG enzyme. In line with this finding, van Heerebeek et al. 7 found lower myocardial PKG activity in the myocardium of HFpEF patients.

The restoration of NO‐cGMP‐PKG axis has been proven to be cytoprotective in different cardiovascular diseases6, 17, 18 including diabetic cardiomyopathy.5, 6, 12 Phosphodiesterase‐5A inhibitors block one of the main regulator of cGMP degradation thereby preserving and/or increasing intracellular cGMP concentration.4 Theoretically, blocking the PDE5A in pathological LV remodelling could provide a useful tool in the management of HF patients. The above idea led to a clinical trial investigating the cardioprotective effects of sildenafil in HFpEF patients (RELAX study).19 Despite the promising preclinical data, sildenafil showed no improvements in exercise capacity or on the clinical outcomes in advanced HFpEF patients.19 However, cGMP plasma levels were not significantly different at the end of the study period between the study groups. In light of this, one can speculate that PDE5A inhibition might have been ineffective and it could have contributed to the negative results.19 The above data suggest that improving cGMP signalling is a promising avenue of research; however, the result of the RELAX trial raises important questions about the appropriate pharmacological approach. In line with this, Franssen and Gonzalez Miqueo20 reported that the initial phase of HFpEF is presumably predominated by the dysfunction of cardiomyocytes, thus it could be useful to improve cGMP signalling to reduce cardiomyocyte stiffness. In contrast, sildenafil has been shown to exert anti‐remodelling effect in T2DM diabetic cardiomyopathy in humans.21 Moreover, Koka et al. 22 showed beneficial effects of tadalafil on systolic performance and mitochondrial function in db/db mice. Nevertheless, they did not report how PDE5A inhibitors affect diastolic dysfunction in T2DM.

Accordingly, we believe that instead of treating the already developed HFpEF, effective pharmacological prevention by PDE5A inhibitors might be more appropriate in the management of HFpEF patients with co‐morbidities such as obesity and DM. Thus, in the present study, we investigated the effects of PDE5A inhibition in a preventive manner (from the pre‐diabetic state) on the development of HFpEF (mainly on diastolic function) in the ZDF rat.

Several studies have focused on the investigation of cardiac function in HFpEF. Previous data showed that diastolic dysfunction can be determined in the HFpEF animal model ZDF rat.23, 24 In accord with the literature we observed a significant increase in LV stiffness and prolonged relaxation time by pressure–volume analysis in our model. In addition, cardiomyocyte stiffness (as shown by increased Fpassive) was also evident in T2DM. However, in vivo and in vitro systolic performance was preserved, fulfilling the criteria for HFpEF in ZDF rats. Interestingly, we did not observe any difference in HR and MAP. Vardenafil effectively prevented diastolic dysfunction both in vivo (decreased LV stiffness, improved relaxation time) and at the sarcomeric level (decreased cardiomyocyte Fpassive) in ZDF rats. Hypophosphorylation of the PEVK‐domain of titin might play a role in the observed phenomena.25

We found lower myocardial cGMP level coupled with increased protein expression of PDE5A (a possible contributor to the low myocardial cGMP content) and PKG enzymes in the heart of HFpEF animals. Although PKG protein levels were increased, PKG activity (as reflected by the p‐VASP/VASP ratio) showed significant impairment in the diabetic myocardium. Interestingly, plasma cGMP levels remained unchanged in ZDF. One can speculate that this might be a consequence of the observed compensatory upregulation of ANF and subsequent activation of particulate GC in other organs. Thus preserved plasma cGMP is seen as a sign of overspill of cGMP from different tissues.5 Vardenafil effectively restored the activity of the cGMP–PKG axis, as shown by increased plasma/cardiac cGMP concentrations and p‐VASP/VASP ratio.

Pathological remodelling of the myocardium in diabetic cardiomyopathy is a well‐known phenomenon and is characterized by fibrosis, hypertrophy, increased nitro‐oxidative stress, and cardiomyocyte apoptosis.3 Hyperglycaemia can directly lead to the accumulation of ROS and to the development of severe nitro‐oxidative stress in DM.3 Several mechanisms have been described to play a decisive role in DM‐associated nitro‐oxidative stress such as the upregulation of NADPH‐oxidases and NO synthases.3 Moreover, in nitro‐oxidative stress peroxynitrite is generated when ROS directly reacts with NO thus it contributes to the decreased NO bioavailability.26 Peroxynitrite is a highly reactive molecule that directly deteriorates different cellular elements, enzymes, myofibrillar proteins, and DNA.26 In agreement with this, we observed hyperglycaemia at an early age which increased gradually during the study. We also found increased nitro‐oxidative stress as well as an upregulation of the different antioxidant enzymes in the LV myocardium of ZDF animals. However, plasma nitrite/nitrate levels (reflecting NO bioavailability) were not diminished. In addition, SERCA2a gene expression was significantly lower, which might reflect the disturbance of intracellular Ca2+ homeostasis and could contribute to the prolonged relaxation time in T2DM.27 Vardenafil, however, significantly affected the DM‐associated nitro‐oxidative stress as it prevented an increase of 3‐NT staining and the elevation of catalase and thioredoxin‐1 in the ZDF group myocardium. The protective feature of PDE5A inhibition is probably attributed to its antioxidative effects28 and to the enhancement of cGMP signalling.12 Moreover, vardenafil significantly increased the ratio of PLB/SERCA2a gene expression which might have contributed to the observed improved diastolic function in the ZDF + Vard group.

Not only peroxynitrite but ROS also directly propagates DNA fragmentation and apoptosis in DM leading to the loss of cardiomyocytes.5, 26 In addition to the increased rate of apoptosis, several pathological processes play role in the development of myocardium hypertrophy and fibrosis (both interstitial and replacement types), including the dysregulation of the transforming growth factor β (TGF‐β) signalling,3, 5 fibroblast proliferation,3 and disturbance of the matrix metalloproteinases (MMPs).29 Corresponding to this, our DM model developed HFpEF characterized by increased apoptosis. Moreover, our experiments revealed massive cardiac hypertrophy not only by echocardiography but also by the post‐mortem analysis of the myocardium (increased HW/TL, cardiomyocyte diameter/TL, and ANF gene expression). In addition to the development of concentric hypertrophy, fibrotic remodelling was present in the left ventricle of our ZDF animals (higher MT score, PicroSirius area and Fn1 gene expression). Interestingly, Col1a1 and Col3a1 mRNA levels were significantly reduced in T2DM; however, in agreement with data in the literature,5, 29 this might be the consequence of a negative feedback mechanism. Through the improved cGMP signalling, vardenafil effectively reduced myocardial apoptosis (via the inhibition of PARP cleavage), cardiomyocyte hypertrophy, and fibrotic remodelling of the myocardium. Our results are in line with the data of previous studies that reported antihypertrophic effects of the enhancement of cGMP signalling.5, 30 In the background of improved fibrosis a regulatory cross‐talk between the enhanced PKG signalling and the key members of cardiac remodelling such as TGF‐β signalling,5, 12 microvascular inflammation, endothelin‐1, angiotensin II, and aldosterone8 can be assumed. It is notable that diastolic dysfunction (slope of EDPVR) correlated with both cardiac hypertrophy and fibrosis. Although many contributing factors have been identified in the progression of HFpEF, we still lack a treatment for proper patient management. A significant point of intervention might be to improve the myocardial NO‐cGMP‐PKG signalling. However, from previous clinical trials it seems rather that a pharmacological prevention could contribute significantly to the improvement of HFpEF. To our knowledge, this is the first study reporting the preventive cardioprotective effects of vardenafil on diastolic function in an animal model of HFpEF. The presence of co‐morbidities in HFpEF patients has to be taken into account when planning the pharmacological management of patients. In agreement with this, early initiated pharmacological prevention with the PDE5A inhibitor vardenafil might be a therapeutic alternative for patients with DM and HFpEF.

Study limitations

Our study is limited to young, male rats. Although the p‐VASP/VASP ratio was considered as a marker to estimate PKG activity, direct measurement of PKG activity is the gold standard method as VASP phosphorylation could also be influenced by other PKs. Involvement of cGMP–cAMP crosstalk and PKA activation as a subsidiary mechanism in the observed effects of vardenafil cannot be ruled out. Our present work focused on the effects of preventive therapy by vardenafil in T2DM. However, the determination of the optimal time‐point of the pharmaceutical intervention might be an important aspect of future investigations.

Figure S1. Blood glucose values in the study groups.

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Figure S2. Plasma total nitrate/nitrite level and phospholamban assay.

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Method S1. Expanded methods.

Table S1. TaqMan gene expression assays used.

Table S2. Antibodies used in the study.

Table S3. Results of two‐way analysis of variance.

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