No abstract
Heart failure is a complex syndrome whose phenotypic presentation and disease progression depends on a complex network of adaptive and maladaptive responses. One of these responses is the endothelial release of NRG (neuregulin)-1-a paracrine growth factor activating ErbB2 (erythroblastic leukemia viral oncogene homolog B2), ErbB3, and ErbB4 receptor tyrosine kinases on various targets cells. NRG-1 features a multitasking profile tuning regenerative, inflammatory, fibrotic, and metabolic processes. Here, we review the activities of NRG-1 on different cell types and organs and their implication for heart failure progression and its comorbidities. Although, in general, effects of NRG-1 in heart failure are compensatory and beneficial, translation into therapies remains unaccomplished both because of the complexity of the underlying pathways and because of the challenges in the development of therapeutics (proteins, peptides, small molecules, and RNA-based therapies) for tyrosine kinase receptors. Here, we give an overview of the complexity to be faced and how it may be tackled.
Background: Peripartum cardiomyopathy (PPCM) is a life-threatening disease in women without previously known cardiovascular disease. It is characterized by a sudden onset of heart failure before or after delivery. Previous studies revealed that the generation of a 16-kDa PRL (prolactin) metabolite, the subsequent upregulation of miR-146a, and the downregulation of the target gene Erbb4 is a common driving factor of PPCM. Methods: miRNA profiling was performed in plasma of PPCM patients (n=33) and postpartum-matched healthy CTRLs (controls; n=36). Elevated miRNAs in PPCM plasma, potentially targeting ERBB4 (erythroblastic leukemia viral oncogene homolog 4), were overexpressed in cardiomyocytes using lentiviral vectors. Next, cardiac function, cardiac morphology, and PPCM phenotype were investigated after recurrent pregnancies of HZ (heterozygous) cardiomyocyte-specific Erbb4 mice ( Erbb4 F/+ αMHC-Cre + , n=9) with their age-matched nonpregnant CTRLs (n=9–10). Results: Here, we identify 9 additional highly conserved miRNAs (miR-199a-5p and miR-199a-3p, miR-145a-5p, miR-130a-3p, miR-135a-5p, miR-221-3p, miR-222-3p, miR-23a-3p, and miR19b-3p) that target tyrosine kinase receptor ERBB4 and are over 4-fold upregulated in plasma of PPCM patients at the time of diagnosis. We confirmed that miR-146a, miR-199a-5p, miR-221-3p, miR-222-3p, miR-23a-3p, miR-130a-5p, and miR-135-3p overexpression decreases ERBB4 expression in cardiomyocytes (−29% to −50%; P <0.05). In addition, we demonstrate that genetic cardiomyocyte-specific downregulation of Erbb4 during pregnancy suffices to induce a variant of PPCM in mice, characterized by left ventricular dilatation (postpartum second delivery: left ventricular internal diameter in diastole, +19±7% versus HZ-CTRL; P <0.05), increased atrial natriuretic peptide (ANP) levels (4-fold increase versus HZ-CTRL mice, P <0.001), decreased VEGF (vascular endothelial growth factor) and VE-cadherin levels (−33±17%, P =0.07; −27±20%, P <0.05 versus HZ-CTRL), and histologically enlarged cardiomyocytes (+20±21%, versus HZ-CTRL, P <0.05) but without signs of myocardial apoptosis and inflammation. Conclusions: ERBB4 is essential to protect the maternal heart from peripartum stress. Downregulation of ERBB4 in cardiomyocytes induced by multiple miRNAs in the peripartum period may be crucial in PPCM pathophysiology. Registration: URL: https://www.clinicaltrials.gov ; Unique identifier: NCT00998556.
Background: MiR-181c-5p is described to induce heart failure (HF), while its role in renal pathology is undetermined. Renal dysfunction is present in 40-60% of HF patients and associated with poor prognosis. This study is the first of its kind to investigate the role of miR-181c-5p in a mouse model of cardiorenal disease (CRD). Our hypothesis states a protective effect of miR-181c-5p inhibition on HF development. Methods: CRD was induced by feeding male C57BL/6J mice (n=20) a high-fat diet (HFD) and L-NAME in drinking water (5g/L) for 6 weeks, angiotensin-II was co-administered via osmotic minipumps (1000ng/kg/min) during the final 2 weeks. Healthy controls (n=16) underwent sham-surgery. Mice were randomly assigned to weekly injections (40mg/kg) with miR-181c-5p antagomiR (INH) or scrambled control for the duration of the study. We assessed cardiac function (echocardiography, hemodynamics), renal function (plasma creatinine), target expression (RT-qPCR), and histology. Results: CRD animals showed mild systolic and diastolic cardiac dysfunction compared to healthy controls, with cardiac fibrosis (2.5±0.3 vs 1.8±0.2% area; p=0.0004) and hypertrophy (0.11±0.03 vs 0.08±0.01g/cm; p=0.005). Renal dysfunction presents with kidney atrophy (0.07±0.006 vs 0.09±0.01g/cm; p=0.02), increased plasma creatinine (21±6 vs 10±5; p=0.01), renal fibrosis (0.26±0.22 vs 0.005±0.21 % area; p=0.036) and glomerular abnormalities (glomerulosclerosis, hypertrophy/atrophy, mesangial matrix expansion, reduced podocyte number). CRD+INH animals had comparable cardiac phenotype to CRD (p>0.05). Their renal phenotype was exacerbated with elevated glomerular damage (26±3 vs 18±9;p=0.04) and significantly increased mortality rate (50%) (Kaplan-Meier p=0.01) compared to healthy controls (0%) or CRD (20%), associated with increased occurrence of tubular atrophy, endothelial swelling and systemic thrombotic microangiopathy (TMA). qPCR analysis identified Vegf as potential target of miR-181c-5p. Conclusion: This study demonstrates a detrimental effect of miR-181c-5p inhibition on renal function in a CRD mouse model, driven by glomerular damage and TMA through Vegf signaling. Cardiac function was unaffected.
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