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AIMS: Glucagon-like peptide-1 receptor agonists (GLP-1 RAs) are increasingly used to treat type 2 diabetes and obesity. Albeit cardiovascular outcomes generally improve, treatment with GLP-1 RAs is associated with increased heart rate, the mechanism of which is unclear. METHODS AND RESULTS: We employed a large animal model, the female landrace pig, and used multiple in-vivo and ex-vivo approaches including pharmacological challenges, electrophysiology and high-resolution mass spectrometry to explore how GLP-1 elicits an increase in heart rate. In anaesthetized pigs, neither cervical vagotomy, adrenergic blockers (alpha, beta or combined alpha-beta blockade), ganglionic blockade (hexamethonium) nor inhibition of hyperpolarization-activated cyclic nucleotide-gated (HCN) channels (ivabradine) abolished the marked chronotropic effect of GLP-1. GLP-1 administration to isolated perfused pig hearts also increased heart rate, which was abolished by GLP-1 receptor blockade. Electrophysiological characterization of GLP-1 effects in vivo and in isolated perfused hearts localized electrical modulation to the atria and conduction system. In isolated sinus nodes, GLP-1 administration shortened action potential cycle length of pacemaker cells and shifted the site of earliest activation. The effect was independent of HCN blockade. Collectively, these data support a direct effect of GLP-1 on GLP-1 receptors within the heart. Consistently, single nucleus RNA sequencing (snRNAseq) showed GLP-1 receptor expression in porcine pacemaker cells. Quantitative phosphoproteomics analyses of sinus node samples revealed that GLP-1 administration leads to phosphorylation changes of calcium cycling proteins of the sarcoplasmic reticulum, known to regulate heart rate. CONCLUSION: GLP-1 has direct chronotropic effects on the heart mediated by GLP-1 receptors in pacemaker cells of the sinus node, inducing changes in action potential morphology and the leading pacemaker site through a calcium signaling response characterized by PKA-dependent phosphorylation of Ca2+ cycling proteins involved in pace making. Targeting the pacemaker calcium clock may be a strategy to lower heart rate in GLP-1 RA recipients.
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A previously healthy male was rushed into a hospital critically ill with confusion, sepsis, and acute respiratory distress syndrome only 43 h after having a normal chest X-ray and with blood samples showing only minimally elevated C-reactive protein. Two days earlier, the patient had returned to his home country, the Faroe Islands, from a 10-day work trip aboard a Scandinavian ship in Colombia. The diagnosis turned out to be an influenza B infection and necrotizing pneumonia with Panton-Valentine leukocidin (PVL)-producing methicillin-sensitive Staphylococcus aureus (MSSA). It was influenza season in Colombia but not in the Faroe Islands. The frequency of MSSA with PVL-encoding genes among pediatric infection patients is very low in the Kingdom of Denmark and Faroe Islands and very high in Colombia, and the frequency generally varies highly by region. The patient in this case now suffers severe sequelae from the infection. With this case, we would like to remind clinicians of this rare but severe condition. PVL-producing S. aureus pneumonia should be considered in critically ill, previously healthy patients, especially during influenza season and if the patient has been traveling in countries with high frequencies of PVL-producing S. aureus.
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What is the central question of this study? We investigated whether intestinal vagal afferents are necessary for the insulinotropic effect of glucagon-like peptide-1 (GLP-1) infused into a mesenteric artery or a peripheral vein before and after acute truncal vagotomy. What is the main finding and its importance? We found no effect of truncal vagotomy on the insulinotropic effect of exogenous GLP-1 and speculate that high circulating concentrations of GLP-1 after i.v. and i.a. infusion might have overshadowed any neural signalling component. We propose that further investigations into the possible vagal afferent signalling of GLP-1 would best be pursued using enteral stimuli to provide high subepithelial levels of endogenous GLP-1. Glucagon-like peptide 1 (GLP-1) is secreted from the gut in response to luminal stimuli and stimulates insulin secretion in a glucose-dependent manner. As a result of rapid enzymatic degradation of GLP-1 by dipeptidyl peptidase-4, a signalling pathway involving activation of intestinal vagal afferents has been proposed. We conducted two series of experiments in α-chloralose-anaesthetized pigs. In protocol I, pigs (n = 14) were allocated for either i.v. or i.a. (mesenteric) GLP-1 infusions (1 and 2 pmol kg(-1) min(-1) , 30 min) while maintaining permissive glucose concentrations at 6 mmol l(-1) by i.v. glucose infusion. The GLP-1 infusions were repeated after acute truncal vagotomy. In protocol II, pigs (n = 27) were allocated into six groups. Glucagon-like peptide 1 was infused i.v. or i.a. (mesenteric) for 1 h at 3 or 30 pmol kg(-1) min(-1) . During the steady state (21 min into the GLP-1 infusion), glucose (0.2 g kg(-1) , i.v.) was administered over 9 min to stimulate ß-cell secretion. Thirty minutes after the glucose infusion, GLP-1 infusions were discontinued. Following a washout period, the vagal trunks were severed in four of six groups (vagal trunks were left intact in two of six groups), whereupon all infusions were repeated. We found no effect of vagotomy on insulin or glucagon secretion during administration of exogenous GLP-1 in any experiment. We speculate that the effect of exogenous GLP-1 overshadowed any effect occurring via the vagus. Within dosage groups, total GLP-1 concentrations were similar, but intact GLP-1 concentrations were much lower when infused via the mesenteric artery because of extensive degradation of GLP-1 in the splanchnic bed. This demonstrates the effectiveness with which intestinal capillary dipeptidyl peptidase-4 protects the systemic circulation from intact GLP-1, consistent with a local role for GLP-1 involving activation of vagal pathways.