P5448Enzymatic regulation of the myocardial tissue renin-angiotensin-system of the failing heart

Abstract

Abstract Background In heart failure with reduced ejection fraction (HFrEF) the renin-angiotensin-system (RAS) is dysregulated and serves as therapeutic target. Research has been focusing on plasma RAS. Information on tissue RAS is scarce although assumedly more crucial for myocardial function. Among known angiotensins, only AngII and AngIII are detectable in the failing heart. Plasma samples in HFrEF show high AngI and AngII levels with clearly distinguishable AngI/AngII ratios for different RAS-inhibitors. AngII and AngIII levels in the myocardium were comparable for different RAS-inhibitors, i.e. no RAS-blocker, ACE-inhibitor, ARB or angiotensin-receptor neprilysin-inhibitor (ARNI). Here we aimed to elucidate the metabolic regulation of tissue RAS enzymes for these four different modalities of RAS-inhibition. Methods Enzyme regulation and metabolic activities were investigated in myocardial samples of end-stage HFrEF patients undergoing heart transplantation with a mass-spectrometry based method. Concentrations of respective angiotensin metabolites AngI, AngII, Ang1–7, AngIII, Ang1–5 and AngIV (RAS-fingerprints) were investigated after adding AngI or AngII and incubation to display metabolic patterns of the main plasma angiotensins. Metabolic activities of distinct enzymes have been assessed for the no therapy and ACE-I subgroups. Patients were stratified according to background therapy with RAS-inhibitors. Results A total of 30 patients were included (n=6 without RAS-blockade, n=16 with ACE-I, n=6 with ARB, n=2 with ARNI). Median age was 55 (IQR 45–63) years, 87%were male. Etiology of HF was ischemic in 40%, median NT-proBNP levels were 3498pg/ml (IQR 1761–8400). Patterns for tissue RAS metabolism of AngI and AngII was visually similar for all groups, indicating comparable regulation of tissue RAS enzymes independent from therapy (Figure 1). The formation of AngII from AngI was mainly chymase dependent with conversion rates of 99.4 (IQR 77.0–254.1) (pg/μg protein)/h for ACE-I and 141.8 (IQR 67.9–369.2) (pg/μg protein)/h for no RAS-blockade, whereas ACE-related generation of AngII was under the detection limit. The formation of Ang1–7 from AngI was mediated by NEP and PEP. The contribution of NEP was significantly higher [5022 (IQR 5002–5286) (pg/μg)/h vs 3555 (IQR 3351–3849) (pg/μg)/h, p=0.005 for the ACE-I group and 4729 (IQR 4438–6135) (pg/μg)/h vs 3601 (IQR 3052–4182) (pg/μg)/h, p=0.012 for no RAS-blockade]. No differences in tissue enzymatic activities between ACE-I and no therapy, as already indicated by the metabolization patterns occurred. Figure 1 Conclusions Enzymatic tissue RAS regulation in end-stage HF seems to be independent from the mode of established RAS-inhibitor therapy.In contrast to plasma, AngII formation of the tissue is mainly chymase dependent, whereas ACE seems to play an unsignificant role. NEP has a substantial role in generating beneficial Ang1–7 from AngI. The impact of NEP inhibition by ARNI on tissue RAS and mechanism of action have to be further investigated.