Sevoflurane induces developmental cardiotoxicity via AMPKα2 dysregulation in zebrafish
摘要
Sevoflurane, a widely used volatile anesthetic, has raised concerns regarding its potential developmental toxicity, particularly due to its extensive application in non-obstetric surgeries and fetal intervention procedures during pregnancy. However, its effects on heart development and function remain unclear. Using zebrafish larvae as a model, we investigated the effects of prolonged sevoflurane exposure (0.04–0.08%) from 10 to 72 h post-fertilization (hpf). Under these conditions, treated larvae exhibited dose-dependent developmental abnormalities, including reduced body length, pericardial edema, and impaired heart tube looping. Cardiac function analysis revealed significant decreases in ejection fraction, stroke volume, heart rate, and cardiac output, indicating impaired cardiac contractility and pumping efficiency. These functional impairments were accompanied by structural changes including ventricular wall thinning and chamber dilation, along with upregulation of cardiac stress markers (nppa, nppb) - characteristic features of dilated cardiomyopathy (DCM). Molecular analysis demonstrated downregulation of sarcomeric (tnnt2a, mybpc3) and calcium-handling (atp2a2a, slc8a1a) genes, suggesting disruption of sarcomere integrity and calcium homeostasis. Additionally, sevoflurane exposure elevated inflammatory cytokines (il-6, tnf-α, il-1β) and promoted leukocyte infiltration into cardiac tissue. RNA sequencing analysis implicated dysregulation of Apelin signaling pathway, with reduced prkaa2 (AMPKα2) expression and phosphorylation observed in both zebrafish and H9C2 cardiomyocytes. Critically, pharmacological activation of AMPK using A-769662 effectively mitigated sevoflurane-induced cardiotoxicity, identifying AMPKα2 as a potential therapeutic target. Collectively, these findings delineate the molecular mechanisms underlying sevoflurane-induced developmental cardiotoxicity following prolonged exposure in zebrafish and suggest that targeting AMPKα2 signaling merits investigation as a potential strategy to mitigate anesthetic-related cardiac developmental risks.