Cardiovascular effects of Glucagon-like peptide 1 (GLP-1) receptor agonists

GLP-1R is a member of the class B1 family of G protein-coupled receptor for which there are only predicted structures [30]. GLP-1R has been detected by reverse transcriptase-polymerase chain reaction in cardiac and vascular tissues isolated from both human and animal models [11],[31], and their mRNA transcripts were demonstrated in the human heart [32].

GLP-1R protein has also been detected in human coronary artery endothelial cells (HCAEC) and human umbilical vein endothelial cells (HUVEC) [33],[34]. Ban et al. detected GLP-1R protein expression by immunohistochemistry in mouse coronary endothelial and smooth muscle cells [35].

Many reports using polyclonal antisera were unable to detect GLP-1R protein in ventricular cardiomyocytes leaded to the revaluation of those earlier reports. Because of lack of sensitivity and problems with non-specificity of commercially available GLP-1R antisera detected multiple nonspecific immunoreactive proteins even in tissue extracts from Glp1r^-/- mice. Although Glp1r mRNA transcripts are detected in whole heart extracts such methods do not distinguish between vascular smooth muscle cells or atrial cardiomyocytes, there were technical difficulties in isolating pure cardiomyocyte populations from the ventricle without contamination of atrial cardiomyocytes isolated from neonatal mouse [36].

There is considerable overlap between pathways induced by the GLP-1R activation. As shown in Figure 3, GLP-1R couples to adenylyl cyclase leading to the activation of cAMP. Using a GLP-1 conjugated to tetramethyl rhodamine to monitor the internalization of the receptor, Kuna et al. [37] observed that after internalization, GLP-1R/ligand complex could be co-localized with adenylate cyclase in the endosome. Indeed, cAMP levels can be elicited by GLP-1 treatment of mouse cardiomyocytes without increasing intracellular Ca²⁺ or inducing contractility [38].

The involvement of cAMP/PKA/CREB pathway on decrease myocyte apoptosis has been unveiled by experiments prepared in cultured mouse cardiomyocytes. This function is mediated via the activation of the cAMP/PKA/CREB (cAMP-responsive element binding protein) and the transactivation of the EGF-R (epidermal growth factor receptor) leading to the activation of phosphatidylinositol-3 kinase (PI3K), protein kinase Cζ(PKCζ), Akt-protein kinase B (AKT/PKB), extracellular regulated kinase (ERK1/2 or mitogen-activated protein kinase [MAPK]) signaling pathways and to the up-regulation of the expression of the cell cycle regulator cyclinD1 (Figure 3). The increase in Akt and ERK phosphorylations lead to cardiomyocyte growth and activation of glucose metabolism [24],[39]-[41].

The main mechanism of cardioprotective effects of GLP-1R agonists against oxidative stress-induced injury in H9c2 cells (cardiomyoblasts from Rattus norvegicus) and in cardiomyocytes is related to the scavenging of reactive oxygen species, by increasing the concentrations of endogenous antioxidant defenses and inhibiting cardiomyocyte apoptosis [42]. This cytoprotective effect is mediated by PI3K and partially dependent on ERK1/2 and seems to be glucose-independent. A protective role of retinoid X receptor is also related to hypoxia/reoxygenation injury in those cells [43]. Moreover, GLP-1 also inhibits palmitate- and ceramide-induced phosphatidylserine exposure and DNA fragmentation [44].

The observation that GLP-1 decreases contractility in primary culture of adult rat cardiomyocytes, despite increasing cAMP levels, [38] has also been reported in isolated rat hearts [45]. Studies in dogs demonstrated an increased myocardial glucose uptake during a hyperinsulinemic-euglycemic clamp [46].

Moreover, cardiometabolic effects of GLP-1 are attenuated in obesity and T2D, via mechanisms that may involve impaired p38-MAPK signaling. Using a swine experimental model, Moberly et al. confirmed and extended the observation, where GLP-1 significantly increased myocardial glucose uptake under basal conditions in lean humans, but this effect was impaired in T2D [47]. GLP-1 did not increase myocardial oxygen consumption or blood flow in humans or in swine, increasing p38-MAPK activity in lean, but not obese cardiac tissue [48].

Experimental studies in animals suggested that incretins may preserve cardiomyocyte viability, increase metabolic efficiency, inhibit the structural, and functional remodeling after MI [49]. Shannon’s group was the first to demonstrate that infusion of GLP-1(7-36) (1.5 pmol/kg/min) for 72 h in patients with left ventricular dysfunction (LVD) after MI improved global and regional left ventricular wall motion scores reducing hospital stay and in-hospital mortality [50],[51].

GLP-1-mediated control of heart rate (HR) and blood pressure (BP) is complex and species specific. Synthetic human GLP-1 administered into the jugular vein of male rats acutely increased systolic and diastolic BP, as well as HR, which returned to basal levels 25 min after GLP-1 administration. The pre-treatment with propranolol or phentolamine did not prevent the increase in BP and HR. In rodents, these increases involve a dual pathways originating from both central nervous system and periphery with intact neural vagus transmission [52].

Intravenous infusion of GLP-1 for 48 h in healthy human subjects increased muscle sympathetic nerve activity but had no effect on BP, norepinephrine plasma concentration, or the sympathetic/parasympathetic balance as estimated by the HR variability, suggesting that the increase in sympathetic drive is at least partially compensated by an increase in the parasympathetic activity [53]. On the other hand, acute subcutaneous (SC) injection of GLP-1 increases HR and BP transiently in healthy human subjects, returning to normal ranges 50-60 min after injection [54]. A mean increase in HR of 1.86 beats/min was reported in a meta-analysis including available data from randomized controlled trials testing GLP-1 agonists against placebo in patients with T2D [53].

In the cardiovascular system, incretins have been recently associated to the increase of endogenous antioxidant defenses, inhibition of cardiomyocyte apoptosis, attenuation of endothelial inflammation and dysfunction [55].

GLP-1 has pleiotropic effects on the cardiovascular system. A GLP-1R agonist (liraglutide) increased endothelial nitric oxide synthase phosphorylation and nitric oxide (NO) production by the 5-AMP-activated protein kinase (AMPK)-dependent pathway and subsequent NO production in cultured HCAEC [56],[57]. GLP-1 protects the cardiac microvessels against oxidative stress, apoptosis, and the resultant microvascular barrier dysfunction in diabetes, contributing to improvement of cardiac function and cardiac glucose metabolism. The protective effects of GLP-1 are dependent on downstream inhibition of Rho through a cAMP/PKA-mediated pathway [58].

As shown by Batchuluun at al., metformin and liraglutide improve high glucose-induced oxidative stress via inhibition of PKC-NADPH oxidase pathway in human aortic endothelial cells. All these effects were even more pronounced when both drugs were used together, suggesting a potential clinical benefit of this drug combination in decreasing the endothelial damage induced by hyperglycemia [59].

In humans, Kelly et al. showed that exenatide therapy for that 3-mo in patients with obesity and pre-diabetes had similar effects on microvascular endothelial function, markers of inflammation, oxidative stress, and vascular activation, as metformin. They assumed that improvements in endothelial function with GLP-1R agonists might be limited to the postprandial setting, particularly following the consumption of a high-fat meal [60].

GLP-1 enhanced acetylcholine-induced forearm blood flow but had no effect on blood flow induced by sodium nitro-prusside in healthy human subjects [61]. Patients with T2D with stable CAD presented an improvement in endothelial function expressed by an increase in flow-mediated vasodilation of the brachial artery, independent of changes in systolic and diastolic blood pressure during a hyperinsulinemic clamp in response to GLP-1 [35]. However, GLP- 1-mediated improvements in blood flow were considerably attenuated after a 2-month period of better glycemic control [62].

In obese patients, GLP-1 infusion significantly increased excretion of sodium (by 60%), calcium (by 60%) and chloride (by 44%) and significantly decreased excretion of H⁺ (by 75%). Besides these renoprotective qualities, these changes suggest that GLP-1 may have renoprotective qualities [63]. Moreover, Kim et al. demonstrated that cardiac GLP-1R expression is localized in cardiac atria and that GLP-1R activation promotes secretion of atrial natriuretic peptide (ANP) and increases BP [64].

In animal and cell models, GLP-1 has been shown to impact the development and/or progression of atherosclerotic plaques. Since GLP-1R has been localized by immunocytochemistry in mouse aortic smooth muscle cells, endothelial cells, monocytes, and macrophages, both direct and indirect actions of GLP-1 may contribute to the potential reduction of atherogenesis. Continuous infusion of exendin-4 in nondiabetic C57BL/6 and ApoE^-/- mice reduced monocyte adhesion to aortic endothelial cells and atherosclerotic lesion size after 40 days of treatment. The inflammatory markers monocyte chemoattractant protein-1 (MCP-1) and tumor necrosis factor α(TNF- α), were reduced by treatment with exendin-4 in response to lipopolysaccharide in cultured peritoneal macrophages harvested from mice [65]. However, circulating GLP-1 was found to be positively associated with total coronary load in humans in a fully adjusted model [OR: 2.53 (95% CI: 1.12-6.08; p = 0.03)], [66] but further studies are required to confirm these observations.

Continuous infusion of exendin-4 for 4 wk. in C57BL/6 mice reduced neointimal formation after endothelial denudation of the femoral artery [67]. Nagashima et al. [68] reported that continuous GLP-1 infusion reduced foam cell formation and the development of atherosclerotic lesions in ApoE^-/- mice. Recently, the same group demonstrated similar effects after infusion of liraglutide in apoE^-/- mice [69]. In addition to these findings on atherosclerotic plaque formation, GLP-1R agonists prevented the increase in plasminogen activator inhibitor type-1 (PAI-1) and vascular cell adhesion molecule-1 (VCAM-1) gene expression in response to TNF- α or hyperglycemia in HUVEC through PKA pathway [24],[70].

The first pieces of evidence of the potential clinical benefit of GLP-1 agonists have emerged recently, pointing to a decrease of major adverse cardiovascular and cerebrovascular events (MACCE) including stroke, MI, cardiac mortality, acute coronary syndrome, and revascularization procedures. A retrospective medical database analysis of T2D patients (n = 39,275) treated with exenatide or other glucose-lowering therapies (n = 381,218) indicated that the GLP-1 agonist might reduce in 19% the incidence of MACCE and in 12% cardiovascular hospitalizations [71]. Despite the absence of adverse cardiovascular effects has been confirmed, this benefit was not verified in an integrated analysis of 12 controlled, randomized, short-term clinical trials (12-52 weeks) comparing exenatide with placebo or insulin [72].

In both diabetic and non-diabetic patients presenting class II/IV heart failure, GLP-1 infusion led to an improvement of left ventricular (LV) ejection fraction, myocardial ventilation oxygen consumption, 6-min walk distance, and quality of life [50]. A study with infusion of exenatide in T2D patients with chronic heart failure reduced the pulmonary capillary wedge pressure and increased both inotropism and chronotropism [73]. These favorable results require further clinical trials in order to elucidate whether these effects will result or not in reduced mortality. In a study involving patients with CAD and preserved LV function, who were scheduled to undergo coronary artery bypass grafting (CABG), were randomized to receive standard therapy or treatment with GLP-1 (1.5 pmol/kg/min) as a continuous infusion beginning 12 h before CABG and continuing for 48 h after the procedure. The control group required greater use of inotropic and vasoactive infusions during the 48 h period after CABG to achieve the same hemodynamic results observed in the group receiving GLP-1. There were also more frequent arrhythmias requiring anti-arrhythmic agents in the control group [50].

In a non-randomized pilot study, Nikolaidis et al. investigated the safety and efficacy of a 72-h infusion of native GLP-1 combined to background therapy in 10 patients with acute MI and LV ejection fraction <40% (mean 29  ± 2%) after successful primary angioplasty, compared to 11 control patients. GLP-1 treatment was safe and elicited a significant improvement in LV ejection fraction (to a mean of 39  ± 2%) [74].

In a study involving 14 patients with normal ejection fraction and CAD awaiting revascularization, normal saline and native GLP-1 were infused on two different occasions from 30 min before until 30 min after a dobutamine stress echocardiography for evaluation of the global LV function; native GLP-1 significantly improved LV function at peak stress and at 30 min into recovery, predominantly in ischemic segments [75].

Fifty-eight patients with ST-segment-elevation MI and thrombolysis were randomized to receive either saline (n = 40) or exenatide (n = 18, 10 μg SC and 10 μg as an IV bolus 5 min before the onset of reperfusion plus 10 μg SC twice daily on the following 2 days) to evaluate whether this GLP-1R agonist could reduce the area of necrosis; exenatide administration significantly decreased release of CK-MB and troponin and reduced infarct size as evaluated by cardiac magnetic resonance after 1 month [14].

GLP-1R agonists already in the market and others in development present the same mode of action and, having the same pleiotropic effects of native GLP-1, the differences in clinical profiles between them are related to differences in pharmacokinetics, structure and size of each formulation. The most remarkable clinically Important pharmacokinetic characteristic is the difference between the short-acting and continuous-acting compounds (Table 1) [13]. Indeed, continuous exenatide exposure once weekly elicited a greater response than did short-acting exenatide, improving glycemic and lipids controls and lipoprotein metabolism, and decreasing systemic inflammation. Indeed, as shown by Hermansen et al. liraglutide treatment in patients with T2D significantly reduced postprandial excursions of triglyceride and apo B48 after a fat-rich meal, independently of gastric emptying. Results indicate that liraglutide’s potential to reduce CVD risk via improvement of postprandial lipemia.

Meloni et al. calculated the absolute benefit increase of using exenatide once week, GLP-1R agonist, vs an oral glucose-lowering medication or insulin glargina to achieve ADA-recommended goals. Exenatide once a week assisted more patients in reaching the majority of ADA-recommended therapeutic goals than treatment with sitagliptin, pioglitazone, or insulin glargine.