Sinus node dysfunction and atrial fibrillation-Relationships, clinical phenotypes, new mechanisms, and treatment approaches

Mechanisms Underlying Sinus Node Dysfunction in a Rat Model of Genetic Atrial Cardiomyopathy

BACKGROUND

Sinoatrial node (SAN) dysfunction is commonly associated with atrial dysrhythmia (tachy-brady syndrome) and is a particularly important feature of inherited atrial cardiomyopathies leading to artificial pacemaker implantation. Essential MYL4 (myosin light chain-4) is an atrial-selective protein that associates with the myosin light chain and participates importantly in cardiacmuscle contraction. MYL4 gene variants encoding dysfunctional versions of MYL4 cause familial atrial cardiomyopathy with a high incidence of early SAN dysfunction (SND) and pacemaker requirement. In this study, we used a rat line, genetically modified to express an E11K gene mutation responsible for familial atrial cardiomyopathy, to address the mechanisms underlying SND.

METHODS

Cardiac structure and function were assessed by echocardiography and in vivo telemetry recording. SAN function was studied in vivo with intracardiac electrophysiology and ex vivo with optical mapping. Mechanisms underlying SND were interrogated in vitro with the use of voltage and current clamp with tight-seal patch-clamp and Ca2+ imaging of isolated SAN cardiomyocytes. Gene expression was assessed by quantitative polymerase chain reaction, and fibrosis was determined with Masson's trichrome stain.

RESULTS

Mutant Myl4-p.E11K+/+ rats exhibited worse SAN function compared with wild-type controls. In vivo, SND was demonstrated by ≈63% increase in sinus node recovery time compared with wild type. In vitro, SAN conduction velocity was reduced by ≈ 50% for Myl4-p.E11K+/+ compared with wild type. Isolated SAN cells showed ≈50% reduction in funny current and L-type Ca2+-current densities. Dysregulation of Ca2+ homeostasis was observed in Myl4-p.E11K+/+, with ≈30% slower time to peak and Ca2+ decay. Masson's trichrome staining showed ≈45% increase in SAN region collagen deposition in Myl4-p.E11K+/+.

CONCLUSIONS

Myl4-p.E11K+/+ mutation causes progressive SND with aging, as a result of extensive abnormalities in the underlying determinants of SAN function, including ion-channel properties, Ca2+-homeostasis, and SAN structure. These observations provide new insights into the mechanisms of SAN abnormality in atrial cardiomyopathy.

Morphometric and histological changes in cardiac nodes after acute spontaneous myocardial infarction in humans and pigs

Background and Aim

The sinoatrial node is responsible for the intrinsic electrical activation that in mammals leads to coordinated rhythmic contractions of the heart, from where it is distributed through the atrial tissue to the atrioventricular node. This study aimed to conduct a histological and morphometric study of the components and cells in cardiac nodes altered by myocardial infarction (MI) and compare them with normal tissues in humans and pigs.

Materials and Methods

We analyzed 10 human hearts and 10 pig hearts that died from MI and compared them with 10 healthy control hearts from each species. Histological sections of 5 μm thickness were obtained using a microtome and stained with hematoxylin-eosin and Masson's trichrome. The identification and assessment of the percentage of connective tissue and cellularity in the cardiac nodes were performed.

Results

We observed a decreased size of cardiac nodes in humans and pigs, as well as an increased percentage of fibrosis inside the nodes, and changes in the size of the nodal cells and surrounding cardiomyocytes (decrease or hypertrophy) were observed. Cartilaginous metaplasia was also found in the cardiac skeleton of all pig samples.

Conclusion

In the present study, a significant increase in collagen fibers and a decrease in cellularity were found in cardiac nodes in samples from humans and pigs with MI. These findings would explain the presence of arrhythmias, which often lead to death.

Aging-associated atrial fibrillation: A comprehensive review focusing on the potential mechanisms

Atrial fibrillation (AF) has been receiving a lot of attention from scientists and clinicians because it is an extremely common clinical condition. Due to its special hemodynamic changes, AF has a high rate of disability and mortality. So far, although AF has some therapeutic means, it is still an incurable disease because of its complex risk factors and pathophysiologic mechanisms, which is a difficult problem for global public health. Age is an important independent risk factor for AF, and the incidence of AF increases with age. To date, there is no comprehensive review on aging-associated AF. In this review, we systematically discuss the pathophysiologic evidence for aging-associated AF, and in particular explore the pathophysiologic mechanisms of mitochondrial dysfunction, telomere attrition, cellular senescence, disabled macroautophagy, and gut dysbiosis involved in recent studies with aging-associated AF. We hope that by exploring the various dimensions of aging-associated AF, we can better understand the specific relationship between age and AF, which may be crucial for innovative treatments of aging-associated AF.

Sex-specific effects of frailty on cardiac structure and function: insights from preclinical models

Advanced age is an independent risk factor for cardiovascular diseases in both sexes. This is thought to be due, in part, to age-dependent cellular, structural, and functional changes in the heart, a process known as cardiac aging. An emerging view is that cardiac aging leads to the accumulation of cellular and subcellular deficits that increase susceptibility to cardiovascular diseases. Still, people age at different rates, with those aging rapidly considered frail. Evidence suggests that frailty, rather than simply age, is a major risk factor for cardiovascular disease and predicts adverse outcomes in those affected. Recent studies in mouse models of frailty show that many adverse changes associated with cardiac aging are more prominent in mice with a high degree of frailty. This suggests that frailty sets the stage for late life cardiovascular diseases to flourish and raises the possibility that treating frailty may treat cardiovascular diseases. These studies show that ventricular dysfunction increases with frailty in males only, whereas atrial dysfunction increases with frailty in both sexes. These results may shed light on the reasons that men and women can be susceptible to different cardiovascular diseases as they age, and why frail individuals are especially vulnerable to these disorders.

Exploring the mechanisms underlying effects of bisphenol a on cardiovascular disease by network toxicology and molecular docking

Background

Globally, cardiovascular disease (CVD) has emerged as a leading cause of mortality. Bisphenol A (BPA), recognized as one of the most prevalent and widely distributed endocrine-disrupting chemicals (EDCs), has been consistently linked to the progression of CVD. This research centers on unraveling the molecular mechanisms responsible for the toxic effects of BPA exposure on CVD. Key targets and pathways involved in action of BPA on CVD were investigated by network toxicology. Binding abilities of BPA to core targets were evaluated by molecular docking.

Methods and results

Based on information retrieved from ChEMBL, DrugBank, and OMIM databases, a total of 27 potential targets were found to be associated with the influence of BPA on CVD. Furthermore, the STRING and Cytoscape software were employed to identify three central genes-ESR1, PPARG, and PTGS2-and to construct both the protein-protein interaction network and an interaction diagram of potential targets. Gene ontology (GO) and KEGG (Kyoto Encyclopedia of Genes and Genomes, KEGG) pathway enrichment analyses via WebGestalt revealed key biological processes (BP), cellular components (CC), molecular functions (MF), and pathways, such as the calcium signaling pathway, inflammatory mediator regulation of TRP channels, gap junction, adrenergic signaling in cardiomyocytes, cGMP-PKG signaling pathway, and cAMP signaling pathway, predominantly involved in BPA-induced CVD toxicity. By using molecular docking investigations, it proved that BPA binds to ESR1, PPARG, and PTGS2 steadily and strongly.

Conclusion

This study not only establishes a theoretical framework for understanding the molecular toxicity mechanism of BPA in cardiovascular disease (CVD) but also introduces an innovative network toxicology approach to methodically investigate the influence of environmental contaminants on CVD. This methodology sets the stage for drug discovery efforts targeting CVD linked to exposure to endocrine-disrupting chemicals (EDCs).

The W101C KCNJ5 Mutation Induces Slower Pacing by Constitutively Active GIRK Channels in hiPSC-Derived Cardiomyocytes

Mutations in the KCNJ5 gene, encoding one of the major subunits of cardiac G-protein-gated inwardly rectifying K+ (GIRK) channels, have been recently linked to inherited forms of sinus node dysfunction. Here, the pathogenic mechanism of the W101C KCNJ5 mutation underlying sinus bradycardia in a patient-derived cellular disease model of sinus node dysfunction (SND) was investigated. A human-induced pluripotent stem cell (hiPSCs) line of a mutation carrier was generated, and CRISPR/Cas9-based gene targeting was used to correct the familial mutation as a control line. Both cell lines were further differentiated into cardiomyocytes (hiPSC-CMs) that robustly expressed GIRK channels which underly the acetylcholine-regulated K+ current (IK,ACh). hiPSC-CMs with the W101C KCNJ5 mutation (hiPSCW101C-CM) had a constitutively active IK,ACh under baseline conditions; the application of carbachol was able to increase IK,ACh, further indicating that not all available cardiac GIRK channels were open at baseline. Additionally, hiPSCW101C-CM had a more negative maximal diastolic potential (MDP) and a slower pacing frequency confirming the bradycardic phenotype. Of note, the blockade of the constitutively active GIRK channel with XAF-1407 rescued the phenotype. These results provide further mechanistic insights and may pave the way for the treatment of SND patients with GIRK channel dysfunction.