Abstract
Hyper-aldosteronism is associated with myocardial dysfunction including induction of cardiac fibrosis and maladaptive hypertrophy. Mechanisms of these cardiotoxicities are not fully understood. Here we show that mineralocorticoid receptor (MR) activation by aldosterone leads to pathological myocardial signalling mediated by mitochondrial G protein-coupled receptor kinase 2 (GRK2) pro-death activity and GRK5 pro-hypertrophic action. Moreover, these MR-dependent GRK2 and GRK5 non-canonical activities appear to involve cross-talk with the angiotensin II type-1 receptor (AT1R). Most importantly, we show that ventricular dysfunction caused by chronic hyper-aldosteronism in vivo is completely prevented in cardiac Grk2 knockout mice (KO) and to a lesser extent in Grk5 KO mice. However, aldosterone-induced cardiac hypertrophy is totally prevented in Grk5 KO mice. We also show human data consistent with MR activation status in heart failure influencing GRK2 levels. Therefore, our study uncovers GRKs as targets for ameliorating pathological cardiac effects associated with high-aldosterone levels.
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Introduction
The classic neurohormonal model of heart failure (HF) is rooted in the enhancement of molecules, such as sympathetic catecholamine neurotransmitters and over-activation of the renin–angiotensin–aldosterone system (RAAS). Aldosterone, a hormone secreted by the adrenal cortex, is directly involved in the regulation of blood pressure1. Aldosterone has also been implicated in the pathogenesis of HF as patients have markedly elevated plasma aldosterone concentrations2,3 and increased aldosterone after myocardial infarction (MI) has been implicated in HF progression4. Moreover, cardiac expression of aldosterone’s mineralocorticoid receptor (MR) has been shown to be elevated in HF patients5. In this regard, recent evidence indicates that chronic exposure to high-aldosterone levels and persistent activation of MRs can induce myocardial tissue damage via mechanisms that are independent of blood pressure elevation6. In fact, chronic infusion of aldosterone can lead to increased cardiac fibrosis7 and pathological hypertrophy5,7,8,9. Accordingly, MR antagonists such as spironolactone and eplerenone have emerged as key drugs in the armamentarium against HF to combat cardiac dysfunction associated with chronic hyper-aldosteronism10,11,12.
The underlying mechanisms of these deleterious effects are not completely understood and thus, there is an urgency to uncover molecular mechanisms involved in aldosterone-mediated cardiac dysfunction to identify new molecular targets and improve HF therapy. Recently, it has been shown that, through a ‘non-genomic’ mechanism, aldosterone can activate NADPH oxidases (NOX2 and 4), thus increasing reactive oxygen species (ROS) and eliciting an apoptotic and fibrotic response13,14. Intriguingly, some of the effects of aldosterone in the heart can be attributed to a linkage with G protein-coupled receptor (GPCR) signalling. In particular, it appears that aldosterone can activate cross-talk between the MR15,16,17,18 and the angiotensin II (AngII) type-1 receptor (AT1R), a GPCR critically involved in both hypertension and HF progression19.
Since the AT1R is implicated in aldosterone-mediated cardiac dysfunction, we posited that also GPCR kinases (GRKs), as regulator of this receptor, may be involved in this deleterious mechanism. In particular, we looked at GRK2 and GRK5, the major GRKs found in the heart, since both have been linked to HF development and progression20,21, and the levels of these kinases are elevated in human failing myocardium22,23,24. Of note, GRK2 but not GRK5, has been shown to desensitize AngII responses in the heart25,26,27; however, recent evidence show that these kinases can trigger pathological myocardial signalling independent of direct GPCR regulation27,28,29,30,31. These non-canonical GRK activities include the unique mitochondrial localization of GRK2 promoting cell death29,30, and the translocation of GRK5 within the nucleus of myocytes promoting pathological hypertrophic gene transcription27,31. The latter indeed occurs in the heart downstream of AT1R activation27.
In this study, we have found that these non-GPCR activities of GRK2 and GRK5 are directly involved in the pathological MR-AT1R signalling axis in the heart. By using in vitro systems and in vivo mouse models, we have uncovered a previously unknown dependence of GRK2 and GRK5 within cardiomyocytes in aldosterone-mediated cardiac dysfunction.
Results
Aldosterone activates myocyte AT1R signalling via c-Src/β-arrestin
Aldosterone treatment of cardiomyocytes is associated with a ‘rapid’ ERK 1/2 activation response that has been suggested to depend on the cross-talk between the MR and the AT1R18. Indeed, in ventricular myocytes isolated from neonatal rats (NRVMs), we found ERK activation by aldosterone peaking after 15 min (Fig. 1a). Importantly, pre-treatment of cells with spironolactone, a MR antagonist, or losartan, an AT1R antagonist, both could inhibit aldosterone-mediated ERK activation (Fig. 1a), indicating MR-AT1R cross-talk. ERK activation via GPCRs, and in particular the AT1R, can occur via both G protein-dependent and G protein-independent pathways32. The latter occurs via the combined action of, GRKs and β-ARRESTINs33. We therefore performed experiments to establish whether aldosterone causes AT1R-mediated β-arrestin recruitment and interestingly, found to be the case (Fig. 1b). Membrane β-ARRESTIN localization stimulated by aldosterone was attenuated with losartan pre-treatment, suggesting aldosterone-mediated activation of the AT1R endocytic machinery (Fig. 1b). Next, since C-SRC is involved in aldosterone-mediated ERK activation34 and is crucial for the β-ARRESTIN-mediated process of internalization and signalling transduction of the AT1R, even in the absence of agonist35, we assessed whether c-Src might play a role in this mechanism. To test this, we used the Src family kinase inhibitor, PP2 and we found that PP2-pre-treatment of cells could inhibit aldosterone-mediated ERK activation in myocytes (Fig. 1c). Further, using an adenovirus (Ad) carrying a HA-tagged AT1R (Ad-HA-AT1R) cDNA we performed a co-immunoprecipitation (Co-IP) assay to evaluate whether c-Src inhibition can affect the β-ARRESTIN recruitment to the AT1R. In line with previous results35, β-ARRESTIN recruitment was not affected in the presence of PP2 (Fig. 1d). Moreover, using an Ad-HA-AT1R and an Ad encoding for the MR to infect NRVMs, we found that aldosterone can induce the internalization of the AT1R similar to the receptor internalization induced by AngII (Fig. 1e). Interestingly, spironolactone, losartan as well as PP2 blocked aldosterone-mediated AT1R internalization (Fig. 1e). Thus, both AT1R internalization and ERK activation induced by aldosterone is C-SRC-dependent and appears to involve β-arrestins. To further support this mechanism, we used the βARKct, a peptide inhibitor of GRK2 activation via Gβγ sequestration36. βARKct expression reduced the activation of ERK by both MR and AT1R (Supplementary Fig. 1a).
Critical role for GRK2 in MR-mediated myocardial pathology
Since the above data clearly show a myocyte MR-signalling dependence on AT1R and implicates GRK2 in this mechanism, we next examined whether this receptor cross-talk is involved in aldosterone-medtiated pathology in myocytes and its potential downstream signal transduction. We examined a NOX4-dependent ROS mechanism as a potential inducer of deleterious myocyte effects of aldosterone since that appears important in HF pathogenesis13,14,37,38. We found induction of NOX4 expression after aldosterone treatment of myocytes and this was blocked by both spironolactone and losartan (Fig. 2a). Aldosterone-mediated NOX4 upregulation was also blocked by βARKct expression (Supplementary Fig. 1b). Next, we assessed ROS formation in myocytes using MitoSOX Red as an indicator of NOX4 activity since it can detect superoxide production. As shown in Fig. 2b, aldosterone (30 min of exposure) increased mitochondrial ROS generation and this was blocked by antagonizing both the MR and AT1R as well as GRK2 via the βARKct. Further, we observed increased mitochondrial dysfunction, in response to 24 h of aldosterone using a MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay and, this was blocked by MR and AT1R antagonism and also by GRK2 inhibition (Fig. 2c). Importantly, treatment of myocytes with aldosterone (24 h) induced a significant apoptotic response that was MR, AT1R and GRK2 dependent (Fig. 2d), consistent with the above signalling mechanisms.
Since βARKct could block aldosterone-mediated NOX4 induction, ROS generation and myocyte apoptosis, we explored whether GRK2 played a direct role in this MR-dependent pathological signalling. Interestingly, we found that aldosterone treatment of myocytes for 12 h causes significant upregulation of GRK2 that was dependent on both MR and AT1R activation (Fig. 2e). To link GRK2 induction to aldosterone-mediated myocyte pathology, we overexpressed GRK2 in NRVMs and examined apoptosis, which we found to be significantly enhanced with GRK2 overexpression (Fig. 3a). Aldosterone can also induce hypertrophy of cardiomyocytes9 and thus, we also examined this pathological stress condition. Indeed, in control NRVMs treated with Ad encoding the green fluorescent protein (Ad-GFP), aldosterone induced increased cell size, as expected, however, unlike enhancement of apoptosis with Ad-GRK2 treatment, overexpression of GRK2 had no effect on cardiomyocyte hypertrophy in response to aldosterone (Fig. 3b).
The above data suggest that GRK2, downstream of MR activation, specifically regulates aldosterone-mediated ROS and cell death signalling. To better assess the absolute requirement of GRK2 in mitochondrial dysfunction and ROS generation, we treated cultured NRVMs with siRNA against GRK2 and as shown in Supplementary Fig. 2a,b, specific GRK2 silencing abolished the effects of aldosterone on ROS generation.
In this regard, our laboratory has shown that secondarily to ROS generation, GRK2 becomes phosphorylated by ERK at Ser670 (S670) and this causes mitochondrial localization that is dependent on the chaperone, heart shock 90 (Hsp90) protein, leading to an induction of myocyte apoptosis29. Accordingly, we investigated S670 phosphorylation (pS670) of GRK2 following aldosterone treatment and found that MR activation leads to GRK2 phosphorylation that is ERK dependent (Fig. 3c; Supplementary Fig. 2c). To assess whether the aldosterone-MR-ERK signalling axis could induce GRK2 translocation to mitochondria, we purified mitochondrial fractions from NRVMs treated with aldosterone and found significant mitochondrial GRK2 accumulation (Fig. 3d). Interestingly, blocking MR activation or AT1R activation inhibited mitochondrial translocation of GRK2 (Fig. 3d). To establish the role of GRK2 phosphorylation on ROS generation, we analysed the effects of elevated wild-type (WT) GRK2 in NRVMs versus a mutant GRK2 at Ser670 (GRK2-S670A) that cannot translocate to the mitochondria (Fig. 3e,f). As expected, following aldosterone treatment, WT GRK2 accumulated in mitochondria (Fig. 3e,f) and this was accompanied to an augmented ROS generation (Fig. 3g). Importantly, when GRK2 cannot be phosphorylated at S670, aldosterone did not lead to mitochondrial translocation of GRK2 and subsequent ROS generation was suppressed (Fig. 3g).
Previously, the ROS-, ERK- and Hsp90-dependent mitochondrial targeting of GRK2 was found to be inhibited by βARKct, since this peptide also contains S670 and ERK phosphorylation of βARKct, which competes with endogenous GRK2 for Hsp90 binding29. We found that aldosterone-mediated GRK2 mitochondrial translocation also appears consistent with this model as βARKct expression blocked aldosterone-mediated mitochondrial GRK2 accumulation (Supplementary Fig. 2d). As expected, βARKct expression did not inhibit mitochondrial translocation of Hsp90 downstream of aldosterone (Supplementary Fig. 2d). Further, we found that this intracellular targeting of GRK2 is dependent on the actions of AT1R transactivation-mediated β-arrestin function, since knockdown of β-arrestin 1/2 in NRVMs abolished GRK2 mitochondrial accumulation after aldosterone stimulation (Supplementary Fig. 2e).
Our data above suggest that aldosterone through a MR-AT1R-dependent pathway, induces a rapid response that increases ERK with a consequent increase in ROS generation. However, previous reports have shown that aldosterone can directly activate the oestrogen receptor (GPER) that is responsible for the rapid ERK activation observed following aldosterone stimulation39. To clarify whether aldosterone effects in myocytes are due to a GPER or MR-AT1R pathway, we used the GPER agonist E2 and the GPER antagonist G36. As expected, E2 stimulation resulted in a significant ERK activation that was efficiently blocked by G36 (Supplementary Fig. 3a). Notably, pre-treatment of cells with G36 resulted in a significant but incomplete inhibition of aldosterone-mediated ERK phosphorylation that was much less effective at blocking aldosterone signalling compared to spironolactone and losartan suggests that GPERs can be modestly involved in acute ERK activation mediated by aldosterone (Supplementary Fig. 3b). Since a recent report has shown that genetic silencing of GPER further increased aldosterone-induced ROS production with mechanisms that may suggest GPER-dependent inhibition of deleterious AT1R or MR signalling40, we explored the effects of GPER activation/inhibition on aldosterone-dependent GRK2 phosphorylation and ROS generation. Surprisingly, we found that E2 treatment of NRVMs resulted in a consistent reduction of basal phosphorylation of GRK2, at S670, that was restored by G36 (Supplementary Fig. 3c). Most importantly, we found that GPER inhibition did not affect aldosterone-dependent GRK2 phosphorylation (Supplementary Fig. 3d). In line with these results, we found that GPER activation was not able to increase ROS generation, and its inhibition with G36 also did not affect aldosterone-dependent ROS generation (Supplementary Fig. 3e). However, treatment of cells with both E2 and aldosterone resulted in an impaired cardiotoxicity compared to aldosterone alone-treated cells (Supplementary Fig. 3e). Taken together, these data suggest that GPER activation downstream of high aldosterone are not a major player in myocyte pathology as previously suggested39, and it appears to be due to MR-AT1R signalling.
GRK5 is a regulator of MR/AT1R-mediated cardiomyocyte hypertrophy
The above results show that, although GRK2’s non-canonical actions on mitochondrial-mediated cell death appear activated by MR-AT1R signalling, there was no effect on cardiac hypertrophy, prompted us to investigate another GRK involved in myocardial pathology, GRK5. The role of GRK5 in maladaptive hypertrophy has been shown to also entail non-canonical activity as a class II histone deacetylase (HDAC) kinase and nuclear factor of activated T-cells (NFAT) activator/co-factor where increased nuclear accumulation of GRK5 induces pathological gene transcription27,31,41. In fact, AngII, which is a potent inducer of myocardial hypertrophy, can induce GRK5 translocation to the nucleus and interestingly, the AT1R is not a target of GRK5-mediated desensitization27. Importantly, it has been previously shown that high-aldosterone levels can increase, in the heart, transcription of the myocyte enhancer factor-2 (MEF2) through the activation of Ca2+/calmodulin kinase II (CAMKII)13. Further, aldosterone can activate the calcineurin-NFAT pathway, in an AT1R-dependent manner42. Notably, these mechanisms are similar to the proposed model of pathological cardiac hypertrophy induced by the AT1R that is dependent on GRK5 (ref. 27). To test the hypothesis that aldosterone might induce this nuclear activity of GRK5, we first looked at NRVMs and found that aldosterone was indeed an inducer of GRK5’s nuclear accumulation similar to AngII (Fig. 4a). Moreover, in adult murine ventricular myocytes we found similar induction of nuclear translocation of GRK5 via immunofluorescence (Fig. 4b). GRK5’s nuclear localization after aldosterone was blocked by spironolactone treatment as well as losartan (Fig. 4c). Furthermore, we analysed the effects of GRK5 nuclear localization on MEF2 activation, and as shown in Fig. 4d, we found that in the presence of aldosterone MEF2 transcriptional activity was significantly increased compared to unstimulated cells. This increase was completely abolished by pre-treatment of cells with spironolactone and losartan (Fig. 4d). Moreover, through a GRK5 knockdown assay (Fig. 4e), we confirmed the absolute requirement of GRK5 in MEF2 activation (Fig. 4f) and in cardiac hypertrophy (Fig. 4g) downstream of aldosterone. Consistent with this, we found that overexpression of GRK5 enhanced NRVM cell size after 48 h of aldosterone treatment compared to the normal hypertrophy induced by aldosterone treatment without elevated GRK5 levels (GFP-control cells; Fig. 5a).
To better define the role of GRK5 and its nuclear activity being involved in aldosterone-mediated myocyte hypertrophy, we tested outcomes of elevated WT GRK5 versus overexpression of a mutant GRK5 lacking its nuclear localization signal (GRK5-ΔNLS). As expected, we observed that aldosterone treatment of myocytes induced consistent GRK5 nuclear localization with a robust increase in cell size growth (Fig. 5b–d). However, when GRK5-ΔNLS was overexpressed, there was no nuclear GRK5 localization and significantly diminished aldosterone-dependent cardiac hypertrophy (Fig. 5b–d).
To better evaluate the specific mechanism involved in MR-AT1R-dependent GRK5 nuclear translocation, we explored the ability of β-arrestin recruitment to influence the nuclear translocation of GRK5. Interstingly, we found that knockdown of β-arrestin 1/2 abolished GRK5 nuclear translocation downstream of aldosterone (Supplementary Fig. 4a). Finally, we explored the ability of aldosterone to induce the activation of Ca2+-calmodulin (CaM) that previously has been shown to be the nodal regulator of AngII-mediated GRK5-nuclear accumulation31. We pre-treated NRVMs with losartan, to inhibit the AT1R, and we stimulated the cells with aldosterone. Following this, we performed a Co-IP assay between GRK5 and CaM and importantly, we observed that while aldosterone induced a significant increase in CaM binding to GRK5, this was blocked by losartan (Supplementary Fig. 4b).
In vivo effects of aldosterone are mediated by GRK2 and GRK5
After MI in humans, plasma aldosterone concentrations are robustly increased43 and the augmented concentration of this hormone can negatively affect cardiac function and HF progression13. To determine if any of the above in vitro results translate in vivo, we administered aldosterone to mice for 4 weeks to create a state of hyper-aldosteronism. Following chronic administration of aldosterone (2 μg per day for 4 weeks) via mini-osmotic pumps implanted subcutaneously, serum aldosterone levels were similar to the endogenous upregulation of this hormone observed in the blood serum of post-MI mice at 4 weeks (Supplementary Fig. 5a), which is consistent with reports in the literature2,13,43,44 of a ∼2-fold increase after MI, including in humans.
We assessed the effects of 4 weeks of aldosterone treatment on murine cardiac function. As shown in Table 1, aldosterone induced significant pathology indicated by ventricular dysfunction and adverse remodelling, including cardiac hypertrophy. At the tissue level, we found increased cardiac apoptosis, as shown by terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL) staining (Fig. 6a), and increased myocardial fibrosis as assessed by Picro-Sirius red staining (Fig. 6b) in mice treated for 4 weeks with aldosterone. Consistent with the significant ventricular dysfunction observed in aldosterone-treated mice, GRK2 and GRK5 were upregulated in the heart (Fig. 6c,d). Interestingly, the in vivo increases in both GRKs, induced by aldosterone, resulted in the enhancement of their non-canonical pathological cellular locations as these hearts showed significantly more GRK2 localized to mitochondria (Fig. 6e) and significant GRK5 accumulation in nuclear fractions (Fig. 6f).
To determine the absolute requirement of GRK2 and GRK5 on the pathological myocardial effects of chronic hyper-aldosteronism, we used conditional Grk2 and Grk5 knockout (KO) mice where these kinases were deleted specifically in cardiomyocytes29,31,45. Control mice (floxed alleles alone), or cardiac Grk2 KO or Grk5 KO mice were treated as above for 4 weeks with aldosterone and we serially assessed their cardiac function with echocardiography. We also included αMHC-Cre alone mice as an additional control for Cre expression in the heart for these experiments. Impaired cardiac function (EF) and increased left ventricular diameter (LVIDd) were similarly altered in control mice (including αMHC-Cre alone mice; Supplementary Fig. 5b,c) consistent with the above results after 4 weeks of hyper-aldosteronism. However, these effects were completely prevented by the loss of GRK2 in myocytes and in part attenuated by the lack of GRK5 in cardiomyocytes (Fig. 7a,b). Of interest, posterior wall (PW) thickness, a marker of ventricular growth, was increased by aldosterone in both controls and Grk2 KO mice (Fig. 7c). However, consistent with the role of GRK5 (in the nucleus) in pathological cardiac hypertrophy, no PW increase was observed in Grk5 KO mice (Fig. 7c). To further examine mechanisms of aldosterone-mediated cardiac dysfunction, we analysed cardiac hypertrophy via heart weight and found that indeed after 4 weeks of aldosterone infusion there was significant cardiac hypertrophy as measured by heart weight to body weight (HW/BW) ratios with control mice have the largest hearts (Fig. 7d). Of note, both Grk2 KO and Grk5 KO had only slight increases in HW/BW ratios after 4 weeks of aldosterone compared to controls (Fig. 7d).
To explain the differences observed between PW thickness with loss of expression of GRK2 or GRK5 in myocytes, we evaluated the effects of aldosterone on cardiac apoptosis and fibrosis. Consistent with the above results, chronic hyper-aldosteronism caused significant cardiac apoptosis and fibrosis in control mice (Fig. 8a–d) and the loss of GRK2 or GRK5 significantly affected this; however, the loss of GRK2 was significantly more effective at attenuating myocyte death and replacement fibrosis compared to the loss of GRK5 (Fig. 8a–d). As a further proof of this GRK-selective mechanism, we analysed the expression of connective tissue growth factor (CTGF), a surrogate marker of pro-fibrosis shown to be modulated directly by MR46. Indeed, in the hearts of aldosterone-treated control mice there was robust upregulation of Ctgf mRNA (Fig. 8e). In cardiac Grk2 KO mice, there was no Ctgf induction while a significant but smaller reduction was observed when GRK5 was deleted in cardiomyocytes compared to control mice (Fig. 8e). These results are consistent with GRK2 being selectively involved in the fibrotic response induced by aldosterone via mitochondrial cell death, while GRK5 appears significantly involved in the hypertrophic mechanisms of pathology induced by this hormone, that is, translationally significant since both GRKs have been shown to be upregulated in human HF23,24,45,47.
To further explore the specific role of GRK2 and GRK5 in the aldosterone-dependent fibrotic response, we analysed the effects in vitro, in NRVMs, of the overexpression of GRK2 and GRK5 on Ctgf expression. Importantly, we found in control myocytes that aldosterone induced significant upregulation of CTGF (Supplementary Fig. 6a). Interestingly, GRK5 overexpression had no effect on aldosterone-mediated CTGF upregulation but GRK2 overexpression significantly enhanced this response (Supplementary Fig. 6a). Consistent with GRK2 being nodal in the fibrotic response of aldosterone in myocytes, we took conditional media from aldosterone-treated myocytes and found that the media from GRK2 overexpressing myocytes significantly enhanced the migration of cultured cardiac fibroblasts more than cultured media of control (Ad-GFP) and GRK5 overexpressing myocytes (Supplementary Fig. 6b).
These data strongly suggest that aldosterone-mediated activation of GRK2 increases the secretion of the stress-induced factor CTGF from cardiomyocytes that then acts as a paracrine factor that enhances the activation of cardiac fibroblasts contributing to fibrosis.
Finally, since we have observed that spironolactone treatment blocked the aldosterone-mediated upregulation of GRK2 in myocytes (Fig. 2e), we investigated whether MR-antagonist-treated human HF patients had altered GRK2 levels in peripheral lymphocytes. Importantly, lymphocyte GRK2 levels have been shown to mirror levels in failing human myocardium and negatively correlating with haemodynamic function23,24. Accordingly, we analysed, by immunoblot, lymphocyte GRK2 levels in human HF patients treated with spironolactone and compared these levels to a cohort of similarly diseased patients where the MR-antagonist was not used (Supplementary Table 1). Interestingly, patients treated with the MR-blocker had significantly lower GRK2 levels (Supplementary Fig. 7) consistent with this pathway having a pathophysiological influence on myocardial GRK2 levels and activity.
Discussion
It is well known that a primary pathogenic driver of cardiac dysfunction and HF is hyper-activation of neurohormonal signalling, which propagates and maintains a vicious cycle of injury. This involves chronic sympathetic nervous system activation through increased catecholamines and also enhanced RAAS activation2. The catecholamines, norepinephrine and epinephrine, chronically stimulate β-adrenergic receptors (βARs) on cardiomyocytes while the RAAS promotes chronic AT1R activation via AngII and enhanced hyper-aldosteronism that leads to chronic MR activation. Adding to the importance of these systems and their hyper-activation, agents that block the chronic stimulation of these receptors are part of the current standard of care of HF patients, including MR antagonists. However, not all patients benefit from these drugs and new and innovative strategies for treating HF are desperately needed. Accordingly, a deeper understanding of the molecular mechanisms contributing to HF development and progression represents the best case scenario for finding new therapeutics. In this study, we have uncovered that GRK2 and GRK5 are critical molecules downstream of aldosterone and MR activation. In fact, they appear to be nodally involved in MR-mediated cardiac pathology as loss of GRK2 and GRK5 in myocytes significantly alleviates cardiac dysfunction due to hyper-aldosteronism.
Our data clearly indicate that some of the pathological effects of the aldosterone are not mediated solely on MR activation, but are dependent on the transactivation of AT1R. We found that aldosterone treatment elicited a robust apoptotic, fibrotic and hypertrophic response in myocytes and these effects were completely abolished by selective MR- or AT1R-antagonism, in vitro (Figs 2). At the molecular level, we observed that following aldosterone-MR binding that specific GPCR-dependent endocytic machinery is recruited (Gβγ/β-arrestin/c-Src) at the plasma membrane leading to AT1R internalization and to the activation of ERK 1/2 and NOX4. This increase in ROS formation consequently can cause myocardial dysfunction via mitochondrial superoxide formation and a robust apoptotic response. Importantly, our data clearly show that GRK2 is vital to this response mainly through its non-canonical mitochondrial localization, which appears nodally involved in the ‘non-genomic’ actions of aldosterone (Fig. 9).
In addition to GRK2 being involved in aldosterone-dependent pathology, we found that MR-AT1R activation leads to the nuclear translocation of GRK5, thus explaining in part the mechanism of aldosterone-mediated hypertrophic response in cardiomyocytes where this non-canonical action of GRK5 contributes to the ‘genomic’ pathway of aldosterone-mediated pathology (Fig. 9).
Importantly, we also evaluated the role of the GPER that has been widely associated to the non-genomic role of aldosterone in non-myocytes and recently also in an in vitro model of cardiomyocytes (H9c2) (ref. 39). H9c2 cells are skeletal muscle myoblasts and although they are widely used as a surrogate of cardiomyocytes they have properties that complicate the state of MR signalling, including demonstration that H9c2 cells lose functional MRs and exhibit very low levels of aldosterone-specific MR-binding51. Interestingly, in H9c2 cells the GPER was found to play an important role in aldosterone-mediated deleterious signalling that could be crucial in human HF39.
Our data, in NRVMs show that high-aldosterone levels can activate GPER signalling but this receptor appears to have a minimal effect on myocardial pathology induced by aldosterone that instead is suggested to be fully mediated by AT1R-MR signalling.
Importantly, we uncovered in myocytes that aldosterone-dependent GPER activity does not explain induction of pathology, which is consistent with previous reports39,52, including in vascular smooth muscle cells where GPER stimulation can protect against hyper-activation of the MR52.
The most notable findings of our study were that the aldosterone-mediated negative effects on mitochondrial superoxide formation, myocyte cell death and hypertrophy were all attenuated by MR blockade with spironolactone or AT1R antagonism with losartan and limited aldosterone’s actions by reducing the non-canonical activities of GRK2 and GRK5. Similar effects were seen using the most selective MR-antagonist eplerenone and the AT1R antagonist irbesartan (Supplementary Fig. 8a–c). Our data appear to be relevant to human HF as we found patients, treated with a protocol that included spironolactone, had significantly lower GRK2 levels in white blood cells, which previously has been shown to mirror cardiac levels23,24. However, although these data need more investigation, they strongly suggest that GRK2 lowering in the myocardium and lymphocytes can be associated with improved cardiac function, as previously described24,48.
Of note, previous studies have already linked GRK2 and GRK5 to HF development20,21,27,31, but, our data demonstrate for the first time that GRK2 and GRK5, acting downstream of MR activation, can induce specific myocardial pathologies. We demonstrate in vivo that 4 weeks of aldosterone represent a trigger stimulus for GRK2 and GRK5 upregulation and the above-discussed, non-canonical activities. These activities of GRKs appear to be significantly relevant for aldosterone-mediated HF, since cardiac Grk2 and Grk5 KO mice have ameliorated myocardial dysfunction. The importance of GRK-mediated cardiac pathology following chronic hyper-aldosteronism is surprising since GRKs do not regulate MR signalling. However, with the finding that MR activation transactivates AT1Rs in myocytes there is still a potential GPCR dependence to these pathological actions of GRK2 and GRK5. These results also demonstrate that limiting MR activation can reduce these pathological actions.
Importantly, we observed that although GRK2 clearly is a nodal determinant of aldosterone-mediated myocyte death and ultimately fibrosis in vivo, this kinase did not influence aldosterone-mediated cardiac hypertrophy, which is also a pathological feature of hyper-aldosteronism8,9. This is an interesting finding and demonstrates that this MR-mediated hypertrophic signalling, which also may include AT1R transactivation, does not involve GRK2. This is in line with previous observation since GRK2 has not been previously shown to be important in cardiac hypertrophy49. However, GRK5 aldosterone-MR-AT1R signalling is a nodal regulator of pathological cardiac growth in hyper-aldosteronism due to nuclear accumulation where its recent transcriptional influence has been revealed27,41. This was clearly shown in cardiac GRK5 KO mice where ventricular wall thickness was prevented after hyper-aldosteronism.
Recently, He et al.13 showed that aldosterone can induce direct cardiotoxic effects through the activation of the NADPH oxidases and subsequent ROS generation via actions of CAMKII acting in the nucleus after it becomes oxidized. CAMKII could become oxidized by MR activation and AT1R activation separately, but the co-dependence of the two receptor systems was not directly studied as in our experiments herein where GRK2 and GRK5 appear to also be nodal regulators of the pathological effects of aldosterone. Importantly, the mechanism proposed for CAMKII appears to be only responsible for cardiac rupture and mortality after MI13, which was not directly, evaluated in our study. The authors in this study used aldosterone infusion after MI, which raises levels to supra-physiological concentrations13 and in our study, levels of aldosterone were equivalent to what is seen in control mice after MI. We importantly, did not see significant deaths via rupture with physiological levels of aldosterone, but significant ventricular dysfunction and remodelling that was beneficially altered with less GRK2 and GRK5. Interestingly, although a CamkII KO mouse was protected from rupture13, it was not protected from fibrosis, which we find in Grk2 KO mice, or by hypertrophy as seen in our Grk5 KO mice. Therefore, GRK pathways and an oxidated-CAMKII pathway appear parallel and distinct with GRK2 being a nodal regulator of aldosterone-mediated cell death and fibrosis, and GRK5 being involved in its hypertrophic response.
Over the past two decades, GRK2 inhibition has led to prevention or reversal of several animal models of HF20,21, including most recently with βARKct gene therapy in a pre-clinical large animal model of HF50. Thus, GRK2 inhibition appears to be a novel therapeutic strategy for alleviating cardiac dysfunction. New data are emerging, that part of the mechanism for the beneficial effects in the heart of limiting GRK2 activity includes non-canonical roles for GRK2, including its actions on insulin signalling28 and mitochondrial-dependent cell death29,30. Similarly, GRK5 is also becoming an emerging novel target for its non-canonical role in the pathological hypertrophic response. Importantly, our present study demonstrates that GRK2 and GRK5 are primary determinants of cardiac dysfunction downstream of hyper-aldosteronism via their non-GPCR activities. Further, at least for GRK2, clinical treatment in human HF with spironolactone can reduce this. Accordingly, both these kinases are potential targets for HF therapy not only because of pathologic activity downstream of elevated sympathetic tone but also hyper-active RAAS signalling.
Methods
Agonists and inhibitors
Aldosterone was purchased from Sigma-Aldrich (A9477, St. Louis, MO, USA); AngII was purchased from Sigma-Aldrich (A9525); losartan was purchased from Sigma-Aldrich (61188); spironolactone was purchased from Sigma-Aldrich (S3378); and PP2 was purchased from Santa Cruz Biotechnology (sc-202769, Dallas, TX, USA). U0126 was purchased from Sigma-Aldrich (U120); eplerenone was purchased from Sigma-Aldrich (107724-20-9); irbesartan was purchased from Sigma-Aldrich (I2286); and PD 98059 was purchased from Sigma-Aldrich (P215). β-Estradiol was purchased from Sigma-Aldrich (E8875) and G36 was purchased from AzanoBiotech (AZ00004-G36, AzanoScientific, Albuquerque, NM, USA).
Cell culture
Ventricular cardiomyocytes were isolated from 1- to 2-day-old neonatal rat hearts (NRVMs). Hearts were pre-washed in ADS buffer (NaCl 116 mmol l−1, HEPES 20 mmol l−1, Na2HPO4 0.8 mmol l−1, glucose 5.6 mmol l−1, KCl 7 mmol l−1 and MgSO4-7H2O 0.8 mmol l−1, pH 7.35) to remove blood and then divided and placed in dishes with 7 ml of ADS. They were minced with sterol razor blades in small pieces and then the whole solutions were transferred in flasks and incubated at 37 °C with 7 ml enzyme solution (ADS containing pancreatin 0.6 mg ml−1, collagenase II 8820 U l−1 and CaCl2 50 mmol l−1) for 10 min. The supernatant from this pre-digestion step was discarded and the pieces were incubated with 15 ml of digestion solution for 15-min intervals at 37 °C. After each interval, the supernatant was collected in 50 ml conical tubes containing 19 ml of F-10 media and 20% FBS pre-heated at 37 °C. The three to six collected fractions were spun down at 1,400g for 10 min, the supernatant was discarded and cells were washed with 5 ml of FBS for each tube. The cells were then centrifuged at 1,400g for 10 min and the supernatant was discarded. The resulting pellet containing the NRVMs was resuspendend in HAM's F10 complete media containing 10% horse serum (HS), 5% FBS and 1% penicilli-streptomycin (P/S), pH 7.4. The cell suspension was filtered through a 70 μm filter and pre-plated on a Nunc Nunclon 100 mm (Thermo Fisher Scientific, Waltham, MA, USA) cell culture dish for 2 h to separate the fibroblasts from the myocyte fraction. The supernatant containing mostly myocytes was collected and plated on culture dishes with Ham’s F-10 complete media. The fibroblast attached to the Nunclon dishes were cultured with DMEM 1 × plus 1% P/S. Next the cells were maintained in media without HS and supplemented only with 10% FBS and P/S. Stimulation of cells with each agonist or inhibitor was performed in serum-free media. Control unstimulated cells were maintained in serum-free media.
Adult ventricular cardiac myocytes (AVMs) were isolated from LV-free wall and septum of C57/Bl6 mice. Mice were kept under anaesthesia with isoflurane and to facilitate the perfusion they were injected with heparin 100 USP into the renal artery. After removal from thoracic cavity, hearts were washed in cold perfusion buffer (NaCl 120.4 mmol l−1, KCl 14.7 mmol l−1, KH2PO4 0.6 mmol l−1, Na2HPO4 0.6 mmol l−1, MgSO4-7H2O 1.2 mmol l−1, Na-HEPES 10 mmol l−1, NaHCO3 4.6 mmol l−1, taurine 30 mmol l−1, butanedione monoxime (BDM) 10 mmol l−1 and glucose 5.5 mmol l−1, pH 7.0). Followed cannulation on a Langendorff system, they were perfused with perfusion buffer at 37 °C for 2–3 min and then digested with digestion solution (50 ml perfusion solution with collagenase 364 U ml−1, 5 mg BD Difco-trypsin 250 and 20 μmol l−1 CaCl2) for 6–7 min. The atrias were removed and the ventricles were gently minced with plastic pipettes in a 100 mm dish containing 2.5 ml of digestion solution. Once the ventricles are almost completely dissolved, the digestion is stopped adding 7 ml of stopping buffer. The resulting post-digestion solutions were filtered through a 100 μm filter. The cardiomyocytes were separated from fibroblasts and smaller cells by 5-min gravity sedimentation and followed by centrifuging at 100g for 30 s. The supernatant was discarded and the pellet containing adult myocytes was resuspended in a stopping solution (perfusion buffer contains 250 mg BSA and 125 μmol l−1 CaCl2) and allowed to rest for 10 min. Cells were spun down with the same conditions described above and then underwent three steps to increase gradient (100 μmol l−1 calcium solution: 10 ml stopping buffer plus 10 μl of 100 mmol l−1 CaCl2; 400 μmol l−1 calcium solution: 10 ml stopping buffer plus 40 μl of 100 mmol l−1 CaCl2; and 900 μmol l−1 calcium solution: 10 ml stopping buffer plus 90 μl of 100 mmol l−1 CaCl2) to reach a final calcium concentration of 1.025 mmol l−1.
All cells were used within 2−8 h of isolation. Myocytes were plated on laminin-coated coverslips and were bathed in HEPES-buffered (20 mM, pH 7.4) medium 199 containing 1.8 mM extracellular Ca2+.
Adenoviral constructs
To generate the adenoviral vector (Ad) encoding for the human MR, cDNA was first amplified from the Addgene Plasmid #23059 (ref. 53). Next, the MR PCR product was inserted into pIRES2-EGFP (Clontech, Mountain View, CA). This allows for co-expression of the GFP with the MR gene. The MRiGFP was then cloned into pAd/CMV/V5-DEST (Thermo Fisher Scientific). To generate the Ad-AT1R, the cDNA encoding for the rat AT1R with a N-terminal HA tag was subcloned into pIRESdsRed (Clontech). The AT1RiRED was then cloned into pAd/CMV/V5-DEST (Thermo Fisher Scientific). The Ad-vector encoding for the bovine WT Grk2 gene (Ad-GRK2), for the WT Grk5 gene (Ad-GRK5) and one encoding for the C-terminal region containing the last 194 amino acids of GRK2 denominated βARKct (Ad-βARKct) were previously obtained54,55. The Ad-vector encoding for the mutated form of GRK5 lacking the nuclear localization signal (GRK5-ΔNLS) was obtained previously55. The Ad-vector encoding the mutated form of GRK2 at Ser670 (GRK2-S670A) was previously obtained29. Ad-GFP was used as a control.
Adenoviral infection
At 24 h post-isolation, NRVMs were infected with recombinant, replication-deficient adenoviruses expressing the following genes with their respective multiplicity of infection (MOI): GRK2 (50 MOI), GRK2-S670A (50 MOI), GRK5-ΔNLS (50 MOI), GRK5 (50 MOI), βARKct (50 MOI), GFP (50 MOI) HA-tagged AT1R (50 MOI) and MR (50 MOI). Equal particles of Ad-GFP were used to control for nonspecific adenoviral effects. Cells were cultured for 24 h before experimentation.
GRK2, GRK5 and β-arrestin 1/2 knockdown assay
NRVMs were transfected with specific siRNAs targeting: Grk2 (Ambion, Thermo Fisher Scientific); Grk5 (Invitrogen-Stealth siRNA; GRK5 RSS329343, Thermo Fisher Scientific); and β-arrestin 1/2 (Arrb1–197273; Arrb2–197276; Thermo Fisher Scientific). Scrambled siRNAs were used as negative control (Thermo Fisher Scientific). The transfection was performed using 5 nmol of siRNAs together with HiPerfect Transfection Reagent (Qiagen, Germantown, Maryland, USA) according to the manufacturer’s protocols.
Western blot analysis
Cells (NRVMs and human lymphocytes) and LV samples (0.1 mg) were lysed in a RIPA buffer with protease (cOmplete-Roche, Indianapolis, IN, USA) and phosphatase inhibitors (PhosSTOP-Roche, Indianapolis, IN, USA) cocktail. Protein content was quantified with the Bio-Rad BCA protein assay (Bio-Rad Laboratories, Richmond, California, USA). Protein samples were separated by 4–20% SDS–polyacrylamide gel electrophoresis (Thermo Fisher Scientific), and proteins were transferred to nitrocellulose membrane (Bio-Rad Laboratories). After blocking, with a specific blocking buffer (Odyssey, LI-COR, Lincoln, Nebraska, USA), the membranes were incubated and probed with the first antibody at 4 °C overnight according to manufacturer’s instructions. Then, the proteins were stained with a corresponding Alexa Fluor 680- (1:5,000; Thermo Fisher Scientific) or IRDye 800CW-coupled (1:5,000; Rockland Inc. Limerick, PA, USA) secondary antibody, followed by visualization of the proteins with a LI-COR infrared imager (Odyssey), and quantitative densitometric analysis was performed applying Odyssey version 1.2 infrared imaging software.
Protein levels of: GRK2 (sc-562, C-15; Santa Cruz Biotechnology, 1:1,000; 05-465; EMD Millipore, Billerica, MA, USA, 1:1,000), GRK5 (05-466; EMD Millipore, 1:2,000), GAPDH (sc-32233, 6C5; Santa Cruz Biotechnology, 1:2,000), phospho ERK 1/2 (#9106; Cell Signaling, Danvers, MA, USA, 1:1,000), total ERK 1/2 (#9102; Cell Signaling, 1:1,000), HA (sc-7392, F-7; Santa Cruz Biotechnology, 1:1,000), β-ACTIN (A5316; Sigma-Aldrich, 1:2,000), β-ARRESTIN 1/2 (#4674; Cell Signaling, 1:1,000), NOX4 (ab109225; Abcam, Cambridge, MA, USA, 1:1,000), phospho-GRK2 (pS670 44–202; Thermo Fisher Scientific, 1:1,000), voltage-dependent anion channel (VDAC) (ab14734; Abcam, 1:5,000), HSP90 (sc-13119, F-8; Santa Cruz Biotechnology, 1:1,000), LAMIN A/C (#2032; Cell Signaling, 1:1,000), FIBRILLARIN (sc-25397; Santa Cruz Biotechnology, 1:1,000) and CALMODULIN (CaM, sc-137079; Santa Cruz Biotechnology, 1:1,000) were assessed. Full scans of western blots are shown in Supplementary Fig. 9.
Cell fractionation
Membrane proteins were isolated from LV samples (0.1 mg) and NRVMs (30 mm dish containing ∼2 × 106 cells) using a homogenization buffer (0.25 M sucrose, 10 mM Tris-HCl (pH 7.4), 1 mM EDTA and protease inhibitors; cOmplete-Roche). The tissues were lysed by homogenization while the cells by scraping and pipetting. Next, both the lysates were sonicated and centrifuged for 15 min at 4 °C at 2,000 r.p.m. The supernatant was then centrifuged at 54,000 r.p.m. for 30 min at 4 °C. The pellet was washed twice using the homogenization buffer and then centrifuged again at the same speed. The washed pellet was then resuspended in PBS with 0.5% TritonX-100. The final lysate was used for western blot analysis or stored at −80 °C.
To isolate mitochondria, NRVMs (30 mm dish containing ∼2 × 106 cells) and LV specimens (0.1 mg) were lysed in an ice cold mitochondrial isolation buffer (MIB) containing: 200 mmol l−1 mannitol, 70 mmol l−1 sucrose, 5 mmol l−1 HEPES and 1 mmol l−1 EGTA, pH 7.5. The MIB was supplemented with protease inhibitors (cOmplete-Roche). Cardiac specimens were first homogenized using a tissue homogenizer (PT-1200E POLYTRON), and then the lysate was subsequently homogenized on ice by passage in a 1 cc syringe with a 27 1/2 G needle (BD, Franklin lakes, NJ, USA) twenty times. NRVMs were only homogenized by passage in the syringe. Lysate was then centrifuged at 600g for 10 min at 4 °C. The supernatant was transferred to a new 1.5 ml tube and centrifuged again at 14,000g for 15 min at 4 °C. The supernatant was collected in a new tube (cytosolic fraction). While, pellet containing the mitochondria fraction was resuspended in fresh MIB buffer and centrifuged again at 14,000g for 15 min at 4 °C. The washed mitochondrial pellet was resuspended in MIB and directly used for protein quantification and immunoblotting. When mitochondria were taken from NRVMs, cells were washed once with ice cold Dulbecco’s PBS, scraped into MIB buffer and processed as described above. Nuclear fractions were obtained from NRVMs (30 mm dish containing ∼2 × 106 cells) and from LV specimens (0.1 mg). After stimulation, the cells were washed with ice cold PBS and processed using a nuclear/cytosol fractionation kit (BioVision Inc., Milpitas, CA) according to manufacturer’s instructions.
Confocal microscopy
NRVMs or AVMs washed three times in ice cold PBS and fixed in 3% paraformaldehyde (PFA) for 10 min. Then the cells were permeabilized with 0.2% Triton X-100 for 2 min. After three washes in PBS, the cells were incubated with 1% BSA for 30 min and then incubated with an anti-HA (Santa Cruz Biotechnology, 1:200) and anti-GRK5 (Santa Cruz Biotechnology, 1:200), respectively, diluted in 1% BSA. Next, the cells were incubated with the respective secondary antibodies: a mouse monoclonal to reveal the HA-tag (Alexa Fluor 647; Thermo Fisher Scientific, 1:200) and a rabbit polyclonal to reveal GRK5 (Alexa Fluor 546; Thermo Fisher Scientific 1:200). The fluorescent data sets were visualized with a Zeiss 510 confocal laser scanning microscope and analysed by LSM 510 software.
MTT assay
MTT assay, to assess the mitochondrial function56, was performed in NRVMs as previously described57. Briefly, the cells (∼3 × 105 cells) were plated in 12-well multi-well plate and were subjected to treatments (aldosterone 12 h). Following stimulation, aseptically MTT solution (5 mg ml−1 MTT in PBS; Sigma-Aldrich) was added in an amount equal to culture volume and the cells were incubated for 1 h. Next, MTT solvent (dimethylsulphoxide) was added to the cells in an amount equal to the original culture volume. Further, cell plates were subjected to gyratory shaker that enhanced dissolution of the MTT formazan crystals, and then the reaction was read at absorbance of 590 nm with a reference filter of 620 nm.
MitoSOX Red staining
MitoSOX Red staining (Life Sciences, Thermo Fisher Scientific) was performed in NRVMs as previously described58. Briefly, after isolation ∼3 × 105 cells were plated in a 30 mm dish and stimulated as described in figure legends. Then, cells were incubated for 10 min with 3 μM MitoSOX working solution. After incubation, cells were washed with warm Hank’s balanced salt solution with calcium and magnesium (HBSS/Ca/Mg) and counterstained with DAPI Fluoromount-G (Southern Biotech, Birmingham, AL). Finally, cells were examined with a microscope (Nikon Eclipse Ti) and images were acquired with a digital camera (Nikon).
For each of the samples, five to six fields (NRVMs: ∼30–60 cells for field) were acquired.
TUNEL staining
TUNEL was performed on fixed paraffin-embedded LV sections (4 μm) or on NRVMs using a commercial kit (Roche) and the assay was performed according to manufacturer’s instructions. NRVMs (∼3 × 105 cells) were plated in a six-well multi-well dish and stimulated as described in figure legends. TUNEL staining was visualized by specific red (Texas Red) or green fluorescence (fluorescein) and nuclei by 40,6-diamidino-2-phenylindole (DAPI; nuclear counterstain). All sections and cells were examined with a microscope (Nikon Eclipse Ni) and images were acquired with a digital camera (Nikon). For each of the samples, five to six fields (NRVMs: ∼100–300 cells for field; cardiac section: ∼600–1,000 cells for field) were acquired.
Cell hypertrophy
After isolation, NRVMs (∼3 × 105 cells) were plated in a six-well multi-well dish and stimulated as described in figure legends. NRVMs were then fixed in 3% PFA for 10 min and then washed three times in ice cold PBS and permeabilized with 0.2% Triton X-100. Then the cells were incubated with 1% BSA for 30 min and then incubated overnight at 4 °C with an anti-α-sarcomeric actinin (α-SMA, A7811, Sigma-Aldrich; 1:200) dissolved in 1% BSA. Next, cells were incubated with the respective secondary antibody (Texas Red conjugated; Sigma-Aldrich; 1:200). Cells were examined with a microscope (Nikon Eclipse Ni) and images were acquired with a digital camera (Nikon). For each of the samples, five to six fields (NRVMs: ∼50 cells for field) were acquired.
MEF2 luciferase assay
Luciferase activity was measured using a luciferase assay system kit (Promega, Madison, WI, USA) according to manufacturer’s protocol. NRVMs (24-well multi-well dish containing ∼2 × 105 cells) were co-infected with the Ad-MEF2-Luc. After stimulation, cells were washed three times with ice cold PBS and collected in passive lysis buffer (Promega). Then, luciferase activity was measured using a plate reader (Infinite M1000 PRO-TECAN).
Cell migration
Cell migration was assessed by wound-healing scratch assay as previously described59. After isolation, cardiac fibroblasts (∼3 × 105) were plated in 12-well tissue culture plates. Twenty-four hours after plating, scratches were made using 100 μl pipette tips and the wells were washed twice with PBS. Then the cells were stimulated with conditioned media from NRVMs stimulated with aldosterone (1 μM) for 24 h. Following 3 and 12 h of stimulation, the cells were fixed in 3.7% paraformaldehyde and stained with 0.1% crystal violet staining solution. Photographs were taken on Nikon TE inverted microscope connected to a Nikon camera. Quantification of cell migration was performed by measuring the distance between 10 random points within the wound edge. Gap distance of the wound was measured using ImageJ software, and the data were normalized to the average of the wound of control cells fixed at the time of scratches.
Animal models
All animal procedures were performed in accordance with the guidelines of the Institutional Animal Care and Use Committee of Temple University School of Medicine. For in vivo experiments, we used WT C57BL/6 mice and conditional mice bearing floxed Grk2 (Grk2 -fl/fl), which have previously been described29,60. In addition αMHC-Cre mice15 were bred on to the Grk2-fl/fl background to generate cardiac Grk2 KO mice or to Grk5-fl/fl background to generate cardiac Grk5 KO mice31, initiated by the activation of the αMHC-promoter and were included in the study61. All animals (female and males, 9–10 weeks) were bred and maintained on a C57Bl/6 background.
Aldosterone infusion in mice
As previously described44, aldosterone (2 μg per mouse per day) dissolved in PBS and 5% ethanol was continuously infused subcutaneously into mice via an osmotic minipump (ALZET, DURECT Co., Cupertino, USA) for 4 weeks. A control group was infused only with PBS and 5% ethanol (vehicle). Mice were anesthetized with isoflurane (2.5% (vol/vol)) and pumps were implanted subcutaneously through a sub-scapular incision, which was then closed using 4.0 silk suture (Ethicon). After 4 weeks of infusion, transthoracic echocardiographic studies were performed, and then blood samples were collected by puncturing the heart, and heart samples were excised for pathological examination and immunohistochemistry.
Echocardiography
Four weeks after aldosterone treatment, transthoracic echocardiography was used to assess cardiac structure and function and performed using a VisualSonics VeVo 2100 system (VisualSonics, Toronto, Ontario, Canada). Mice were anesthetized in a specific isoflurane sedation box (induction 3.0% and maintenance 1–3%). Mice were next shaved to remove hair from the ventral thorax (from the neckline to mid-chest level). Then, mice were placed in a supine position on a heated table with embedded ECG leads. During echocardiography anaesthesia was maintained throughout the procedure with 1–3% isoflurane. LV diameters and subsequently fractional shortening were evaluated with a 18–38 MHz probe. We first performed two-dimensional imaging to obtain a view along the parasternal short axis at the level of the greatest LV dimension, that include the left ventricle and a slight portion of the right ventricle. Next, we will use M-mode echocardiography, which provides a one-dimensional view, to obtain fine measurements of cardiac dimensions (LV end-diastolic and end-systolic diameter and LV anterior and PW thickness) and contractility (ejection fraction and fractional shortening). End diastole was determined at the maximal LV diastolic dimension and end systole was taken at the peak of PW motion.
Histology
Cardiac specimens were fixed in 4% formaldehyde embedded in paraffin. After de-paraffinization and re-hydration, 5-μm-thick sections were prepared, mounted on glass slides and stained with 1% Sirius red in picric acid (Sigma-Aldrich) to detect interstitial fibrosis. The percentage of fibrosis was quantified using a software (ImageJ). All sections were examined with a microscope (Nikon Eclipse Ni) and images were acquired with a digital camera (Nikon).
Real-time PCR
Total RNA was isolated from NRVMs and from LV specimens with TRIzol (Thermo Fisher Scientific) according to the company’s instructions. After RNA isolation, cDNA was synthesized by reverse transcription of the RNA (iScript cDNA synthesis kit, Bio-Rad Laboratories). Real-time PCR was performed in duplicate on a CFX96 real-time PCR detection system (Bio-Rad Laboratories) using the SYBR Green mix (Bio-Rad Laboratories) and specific primers for mouse Ctgf as follows: forward 5′-GGAAGACACATTTGGCCCAG-3′; reverse 5′-TAGGTGTCCGGATGCACTTT-3′.
The expression levels of CTGF were normalized to the rRNA 18S. Specificity of PCR products was confirmed by melting curve and gel electrophoresis.
Enzyme-linked immunosorbent assay
Aldosterone serum levels were measured in mice using a commercial kit (KA1883; Abnova, Walnut, CA, USA) and the assay was performed according to manufacturer’s instructions. The assay was performed on blood serum isolated from aldosterone-treated (4 weeks) mice. Blood (300 μl) was collected by puncturing the heart. Then, blood samples were centrifuged at 1,500 r.p.m. for 15 min at room temperature and the serum was transferred to a 1.5 ml tube. Blood serum isolated from vehicle-treated mice was used as control.
Lymphocytes GRK2 protein levels in human HF patients
We studied 127 patients with an established diagnosis of HF enroled at Federico II University (Naples, Italy) and Salvatore Maugeri Foundation, Scientific Institute of Telese Terme (Telese Terme, BN, Italy). All patients signed consent form. The patients’ inclusion criteria were as follows: diagnosis of HF due to ischaemic or non-ischaemic aetiology, LV ejection fraction (LVEF) ≤45%, stable clinical conditions for at least 1 month before inclusion and guideline-based optimal pharmacotherapy. All subjects underwent a complete clinical examination (including New York Heart Association (NYHA) functional class assessment and echocardiography) and blood draw (3 ml) for lymphocyte isolation. The blood, collected in a tube containing EDTA (Vacutainer-BD, Franklin Lakes, NJ, USA), was diluted with an equal volume of PBS. The diluted blood was layered over 3 ml of Lympholyte-H Cell Separation Media (Cedarlane, Burlington, NC, USA) and centrifuged for 20 min at 800g. The lymphocyte layer was transferred to a new tube using a Pasteur pipette. The transferred cells were diluted with PBS and centrifuged at 800g for 10 min to pellet the lymphocytes. After three washes with PBS, the cells were centrifuged as above and the supernatant was removed. The resulting lymphocyte pellet was stored at −80 °C and lysed, and was analysed by immunoblot for GRK2 levels, as described above. Demographic data including age, sex, HF medications and cardiovascular risk factors and presence of comorbidities were also collected.
Statistics
Data are expressed as mean±s.e. Statistical significance was determined by a Student’s t-test or Mann-Whitney exact test (when sample size was <10). For multiple comparisons, one-way analysis of variance (ANOVA) followed by Bonferroni post hoc correction was performed. Categorical variables were expressed as proportion and compared by use of χ2 test. All data were analysed using GraphPad Prism software version 6. Statistical significance was accepted at P<0.05.
Additional information
How to cite this article: Cannavo, A. et al. Myocardial pathology induced by aldosterone is dependent on non-canonical activities of G protein-coupled receptor kinases. Nat. Commun. 7:10877 doi: 10.1038/ncomms10877 (2016).
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Acknowledgements
This work was supported by NIH grants R37 HL061690, RO1 HL088503, P01 HL08806, P01 HL075443 and P01 HK091799 (all to W.J.K.), and by NIH grant HL128324 (to S.E.).
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A.C. designed and performed experiments, analysed data and wrote the manuscript; D.Li. performed experiments and assisted with animal and human studies; A.E. assisted with immunoblotting; K.J.E. assisted in developing adenoviral constructs; C.J.T. assisted with animal studies; J.I. performed the isolation of cardiomyocytes; S.E. assisted in developing adenoviral constructs and edited the manuscript; D.Le. and N.F. assisted with human studies and edited the manuscript. G.R. assisted with animal and human studies and edited the manuscript; W.J.K. designed experiments, analysed data, co-wrote the manuscript and supervised the project.
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Cannavo, A., Liccardo, D., Eguchi, A. et al. Myocardial pathology induced by aldosterone is dependent on non-canonical activities of G protein-coupled receptor kinases. Nat Commun 7, 10877 (2016). https://doi.org/10.1038/ncomms10877
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DOI: https://doi.org/10.1038/ncomms10877
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