[Indications and outcomes of TAVI (transcatheter aortic valve implantation) in Iceland].

INTRODUCTION: Surgical aortic valve replacement (SAVR) has been the standard of treatment for aortic stenosis but transcatheter aortic valve implantation (TAVI) is increasingly used as treatment in Iceland and elsewhere. Our objective was to assess the outcome of TAVI in Iceland, focusing on indications, complications and survival. MATERIAL AND METHODS: This retrospective study included all TAVI-procedures performed in Iceland between January 2012 and June 2020. Patient characteristics, outcome and complications were registered, and overall estimated survival compared to an age and sex matched Icelandic reference-population. The mean follow-up was 2.4 years. RESULTS: Altogether 189 TAVI procedures (mean age 83±6 years, 41.8% females), were performed, all with a self-expanding biological valve. Most patients (81.5%) had symptoms of severe heart failure (NYHA-class III-IV) and median EuroSCORE-II was 4.9 (range: 0.9-32). Echocardiography pre-TAVI showed a mean aortic-valve area of 0.67 cm2 and a max aortic-valve gradient of 78 mmHg. One out of four patients (26.5%) needed permanent pacemaker implantation following TAVI. Other complications were mostly vascular-related (13.8%) but cardiac cardiac temponade and stroke occurred in 3.2 and 2.6% of cases, respectively and severe paravalvular aortic valve regurgitation in 0.5% cases. Thirty-day mortality was 1.6% (n=3) with one-year survival of 93.5% (95% CI: 89.8-97.3). Finally long-term survival survival of TAVI-patients was similar to the matched reference population (p=0.23). CONCLUSIONS: The outcome of TAVI-procedures in Iceland is good, especially regarding 30-day mortality and long-term survival that was comparable to a reference population. Incidence of major complications was also low.

Differential regulation of EHD3 in human and mammalian heart failure.

Electrical and structural remodeling during the progression of cardiovascular disease is associated with adverse outcomes subjecting affected patients to overt heart failure (HF) and/or sudden death. Dysfunction in integral membrane protein trafficking has long been linked with maladaptive electrical remodeling. However, little is known regarding the molecular identity or function of these intracellular targeting pathways in the heart. Eps15 homology domain-containing (EHD) gene products (EHD1-4) are polypeptides linked with endosomal trafficking, membrane protein recycling, and lipid homeostasis in a wide variety of cell types. EHD3 was recently established as a critical mediator of membrane protein trafficking in the heart. Here, we investigate the potential link between EHD3 function and heart disease. Using four different HF models including ischemic rat heart, pressure overloaded mouse heart, chronic pacing-induced canine heart, and non-ischemic failing human myocardium we provide the first evidence that EHD3 levels are consistently increased in HF. Notably, the expression of the Na/Ca exchanger (NCX1), targeted by EHD3 in heart is similarly elevated in HF. Finally, we identify a molecular pathway for EHD3 regulation in heart failure downstream of reactive oxygen species and angiotensin II signaling. Together, our new data identify EHD3 as a previously unrecognized component of the cardiac remodeling pathway.

Defects in ankyrin-based membrane protein targeting pathways underlie atrial fibrillation.

BACKGROUND: Atrial fibrillation (AF) is the most common cardiac arrhythmia, affecting >2 million patients in the United States alone. Despite decades of research, surprisingly little is known regarding the molecular pathways underlying the pathogenesis of AF. ANK2 encodes ankyrin-B, a multifunctional adapter molecule implicated in membrane targeting of ion channels, transporters, and signaling molecules in excitable cells. METHODS AND RESULTS: In the present study, we report early-onset AF in patients harboring loss-of-function mutations in ANK2. In mice, we show that ankyrin-B deficiency results in atrial electrophysiological dysfunction and increased susceptibility to AF. Moreover, ankyrin-B(+/-) atrial myocytes display shortened action potentials, consistent with human AF. Ankyrin-B is expressed in atrial myocytes, and we demonstrate its requirement for the membrane targeting and function of a subgroup of voltage-gated Ca(2+) channels (Ca(v)1.3) responsible for low voltage-activated L-type Ca(2+) current. Ankyrin-B is associated directly with Ca(v)1.3, and this interaction is regulated by a short, highly conserved motif specific to Ca(v)1.3. Moreover, loss of ankyrin-B in atrial myocytes results in decreased Ca(v)1.3 expression, membrane localization, and function sufficient to produce shortened atrial action potentials and arrhythmias. Finally, we demonstrate reduced ankyrin-B expression in atrial samples of patients with documented AF, further supporting an association between ankyrin-B and AF. CONCLUSIONS: These findings support that reduced ankyrin-B expression or mutations in ANK2 are associated with AF. Additionally, our data demonstrate a novel pathway for ankyrin-B-dependent regulation of Ca(v)1.3 channel membrane targeting and regulation in atrial myocytes.

EH domain proteins regulate cardiac membrane protein targeting.

RATIONALE: Cardiac membrane excitability is tightly regulated by an integrated network of membrane-associated ion channels, transporters, receptors, and signaling molecules. Membrane protein dynamics in health and disease are maintained by a complex ensemble of intracellular targeting, scaffolding, recycling, and degradation pathways. Surprisingly, despite decades of research linking dysfunction in membrane protein trafficking with human cardiovascular disease, essentially nothing is known regarding the molecular identity or function of these intracellular targeting pathways in excitable cardiomyocytes. OBJECTIVE: We sought to discover novel pathways for membrane protein targeting in primary cardiomyocytes. METHODS AND RESULTS: We report the initial characterization of a large family of membrane trafficking proteins in human heart. We used a tissue-wide screen for novel ankyrin-associated trafficking proteins and identified 4 members of a unique Eps15 homology (EH) domain-containing protein family (EHD1, EHD2, EHD3, EHD4) that serve critical roles in endosome-based membrane protein targeting in other cell types. We show that EHD1-4 directly associate with ankyrin, provide the first information on the expression and localization of these molecules in primary cardiomyocytes, and demonstrate that EHD1-4 are coexpressed with ankyrin-B in the myocyte perinuclear region. Notably, the expression of multiple EHD proteins is increased in animal models lacking ankyrin-B, and EHD3-deficient cardiomyocytes display aberrant ankyrin-B localization and selective loss of Na/Ca exchanger expression and function. Finally, we report significant modulation of EHD expression following myocardial infarction, suggesting that these proteins may play a key role in regulating membrane excitability in normal and diseased heart. CONCLUSIONS: Our findings identify and characterize a new class of cardiac trafficking proteins, define the first group of proteins associated with the ankyrin-based targeting network, and identify potential new targets to modulate membrane excitability in disease. Notably, these data provide the first link between EHD proteins and a human disease model.

RGS6, a modulator of parasympathetic activation in heart.

RATIONALE: Parasympathetic regulation of heart rate is mediated by acetylcholine binding to G protein-coupled muscarinic M2 receptors, which activate heterotrimeric G(i/o) proteins to promote G protein-coupled inwardly rectifying K(+) (GIRK) channel activation. Regulator of G protein signaling (RGS) proteins, which function to inactivate G proteins, are indispensable for normal parasympathetic control of the heart. However, it is unclear which of the more than 20 known RGS proteins function to negatively regulate and thereby ensure normal parasympathetic control of the heart. OBJECTIVE: To examine the specific contribution of RGS6 as an essential regulator of parasympathetic signaling in heart. METHODS AND RESULTS: We developed RGS6 knockout mice to determine the functional impact of loss of RGS6 on parasympathetic regulation of cardiac automaticity. RGS6 exhibited a uniquely robust expression in the heart, particularly in sinoatrial and atrioventricular nodal regions. Loss of RGS6 provoked dramatically exaggerated bradycardia in response to carbachol in mice and isolated perfused hearts and significantly enhanced the effect of carbachol on inhibition of spontaneous action potential firing in sinoatrial node cells. Consistent with a role of RGS6 in G protein inactivation, RGS6-deficient atrial myocytes exhibited a significant reduction in the time course of acetylcholine-activated potassium current (I(K)(ACh)) activation and deactivation, as well as the extent of I(K)(ACh) desensitization. CONCLUSIONS: RGS6 is a previously unrecognized, but essential, regulator of parasympathetic activation in heart, functioning to prevent parasympathetic override and severe bradycardia. These effects likely result from actions of RGS6 as a negative regulator of G protein activation of GIRK channels.

Incidence and outcome of acute phosphate nephropathy in Iceland.

BACKGROUND: Oral sodium phosphate solutions (OSPS) are widely used for bowel cleansing prior to colonoscopy and other procedures. Cases of renal failure due to acute phosphate nephropathy following OSPS ingestion have been documented in recent years, questioning the safety of OSPS. However, the magnitude of the problem remains unknown. METHODOLOGY/PRINCIPAL FINDINGS: We conducted a population based, retrospective analysis of medical records and biopsies of all cases of acute phosphate nephropathy that were diagnosed in our country in the period from January 2005 to October 2008. Utilizing the complete official sales figures of OSPS, we calculated the incidence of acute phosphate nephropathy in our country. Fifteen cases of acute phosphate nephropathy were diagnosed per 17,651 sold doses of OSPS (0.085%). Nine (60%) were women and mean age 69 years (range 56-75 years). Thirteen patients had a history of hypertension (87%) all of whom were treated with either ACE-I or ARB and/or diuretics. One patient had underlying DM type I and an active colitis and one patient had no risk factor for the development of acute phosphate nephropathy. Average baseline creatinine was 81.7 µmol/L and 180.1 at the discovery of acute renal failure, mean 4.2 months after OSPS ingestion. No patient had a full recovery of renal function, and at the end of follow-up, 26.6 months after the OSPS ingestion, the average creatinine was 184.2 µmol/L. The average eGFR declined from 73.5 ml/min/1.73 m(2) at baseline to 37.3 ml/min/1.73 m(2) at the end of follow-up. One patient reached end-stage renal disease and one patient died with progressive renal failure. CONCLUSION/SIGNIFICANCE: Acute phosphate nephropathy developed in almost one out of thousand sold doses of OSPS. The consequences for kidney function were detrimental. This information can be used in other populations to estimate the impact of OSPS. Our data suggest that acute phosphate nephropathy may be greatly underreported worldwide.

A ß(IV)-spectrin/CaMKII signaling complex is essential for membrane excitability in mice.

Ion channel function is fundamental to the existence of life. In metazoans, the coordinate activities of voltage-gated Na(+) channels underlie cellular excitability and control neuronal communication, cardiac excitation-contraction coupling, and skeletal muscle function. However, despite decades of research and linkage of Na(+) channel dysfunction with arrhythmia, epilepsy, and myotonia, little progress has been made toward understanding the fundamental processes that regulate this family of proteins. Here, we have identified ß(IV)-spectrin as a multifunctional regulatory platform for Na(+) channels in mice. We found that ß(IV)-spectrin targeted critical structural and regulatory proteins to excitable membranes in the heart and brain. Animal models harboring mutant ß(IV)-spectrin alleles displayed aberrant cellular excitability and whole animal physiology. Moreover, we identified a regulatory mechanism for Na(+) channels, via direct phosphorylation by ß(IV)-spectrin-targeted calcium/calmodulin-dependent kinase II (CaMKII). Collectively, our data define an unexpected but indispensable molecular platform that determines membrane excitability in the mouse heart and brain.