Greiser Maura, Neuberger Hans-Ruprecht, Harks Erik, El-Armouche Ali, Boknik Peter, de Haan Sunniva, Verheyen Fons, Verheule Sander, Schmitz Wilhelm, Ravens Ursula, Nattel Stanley, Allessie Maurits A, Dobrev Dobromir, Schotten Ulrich
Department of Physiology, University Maastricht, PO Box 616, 6200 MD Maastricht, The Netherlands.
J Mol Cell Cardiol. 2009 Mar;46(3):385-94. doi: 10.1016/j.yjmcc.2008.11.012. Epub 2008 Nov 27.
Atrial dilatation is an independent risk factor for thromboembolism in patients with and without atrial fibrillation (AF). In many patients, atrial dilatation goes along with depressed contractile function of the dilated atria. While some mechanisms causing atrial contractile dysfunction in fibrillating atria have been addressed previously, the cellular and molecular mechanisms of atrial contractile remodeling in dilated atria are unknown. This study characterized in vivo atrial contractile function in a goat model of atrial dilatation and compared it to a goat model of AF. Differences in the underlying mechanisms were elucidated by studying contractile function, electrophysiology and sarcoplasmic reticulum (SR) Ca2+ load in atrial muscle bundles and by analyzing expression and phosphorylation levels of key Ca2+-handling proteins, myofilaments and the expression and activity of their upstream regulators. In 7 chronically instrumented, awake goats atrial contractile dysfunction was monitored during 3 weeks of progressive atrial dilatation after AV-node ablation (AV block goats (AVB)). In open chest experiments atrial work index (AWI) and refractoriness were measured (10 goats with AVB, 5 goats with ten days of AF induced by repetitive atrial burst pacing (AF), 10 controls). Isometric force of contraction (FC), transmembrane action potentials (APs) and rapid cooling contractures (RCC, a measure of SR Ca2+ load) were studied in right atrial muscle bundles. Total and phosphorylated Ca2+-handling and myofilament protein levels were quantified by Western blot. In AVB goats, atrial size increased by 18% (from 26.6+/-4.4 to 31.6+/-5.5 mm, n=7 p<0.01) while atrial fractional shortening (AFS) decreased (from 18.4+/-1.7 to 12.8+/-4.0% at 400 ms, n=7, p<0.01). In open chest experiments, AWI was reduced in AVB and in AF goats compared to controls (at 400 ms: 8.4+/-0.9, n=7, and 3.2+/-1.8, n=5, vs 18.9+/-5.3 mmxmmHg, n=7, respectively, p<0.05 vs control). FC of isolated right atrial muscle bundles was reduced in AVB (n=8) and in AF (n=5) goats compared to controls (n=9) (at 2 Hz: 2.3+/-0.5 and 0.7+/-0.2 vs 5.5+/-1.0 mN/mm2, respectively, p<0.05). APs were shorter in AF, but unchanged in AVB goats. RCCs were reduced in AVB and AF versus control (AVB, 3.4+/-0.5 and AF, 4.1+/-1.4 vs 12.2+/-3.2 mN/mm2, p<0.05). Protein levels of protein kinase A (PKA) phosphorylated phospholamban (PLB) were reduced in AVB (n=8) and AF (n=8) vs control (n=7) by 37.9+/-12.4% and 29.7+/-10.1%, respectively (p<0.01), whereas calmodulin-dependent protein kinase II (CaMKII) phosphorylated ryanodine channels (RyR2) were increased by 166+/-55% in AVB (n=8) and by 146+/-56% in AF (n=8) goats (p<0.01). PKA-phosphorylated myosin-binding protein-C and troponin-I were reduced exclusively in AVB goat atria (by 75+/-10% and 55+/-15%, respectively, n=8, p<0.05). Atrial dilatation developing during slow ventricular rhythm after complete AV block as well as AF-induced remodeling are associated with atrial contractile dysfunction. Both AVB and AF goat atria show decreased SR Ca2+ load, likely caused by PLB dephosphorylation and RYR2 hyperphosphorylation. While shorter APs further compromise contractility in AF goat atria, reduced myofilament phosphorylation may impair contractility in AVB goat atria. Thus, atrial hypocontractility appears to have distinct molecular contributors in different types of atrial remodeling.
心房扩张是心房颤动(AF)患者和非AF患者发生血栓栓塞的独立危险因素。在许多患者中,心房扩张与扩张心房的收缩功能降低同时存在。虽然先前已经探讨了导致颤动心房收缩功能障碍的一些机制,但扩张心房中心房收缩重塑的细胞和分子机制尚不清楚。本研究对山羊心房扩张模型的体内心房收缩功能进行了表征,并将其与AF山羊模型进行了比较。通过研究心房肌束的收缩功能、电生理学和肌浆网(SR)Ca2+负荷,并分析关键Ca2+处理蛋白、肌丝的表达和磷酸化水平及其上游调节因子的表达和活性,阐明了潜在机制的差异。在7只长期植入仪器的清醒山羊中,在房室结消融后进行3周渐进性心房扩张期间监测心房收缩功能障碍(房室传导阻滞山羊(AVB))。在开胸实验中,测量心房作功指数(AWI)和不应期(10只AVB山羊、5只通过重复心房猝发起搏诱导AF 10天的山羊(AF)、10只对照)。研究右心房肌束的等长收缩力(FC)、跨膜动作电位(APs)和快速冷却挛缩(RCC,SR Ca2+负荷的一种测量方法)。通过蛋白质印迹法定量总Ca2+处理和肌丝蛋白水平以及磷酸化Ca2+处理和肌丝蛋白水平。在AVB山羊中,心房大小增加了18%(从26.6±4.4增加到31.6±5.5 mm,n=7,p<0.01),而心房缩短分数(AFS)降低(在400 ms时从18.4±1.7降低到12.8±4.0%,n=7,p<0.01)。在开胸实验中,与对照相比,AVB和AF山羊的AWI降低(在400 ms时:分别为8.4±0.9,n=7和3.2±1.8,n=5,而对照为18.9±5.3 mmxmmHg,n=7,p<0.05 vs对照)。与对照(n=9)相比,AVB(n=8)和AF(n=5)山羊分离的右心房肌束的FC降低(在2 Hz时:分别为2.3±0.5和0.7±0.2 vs 5.5±1.0 mN/mm2,p<0.05)。AF中APs较短,但AVB山羊中APs无变化。与对照相比,AVB和AF中的RCC降低(AVB,3.4±0.5和AF,4.1±1.4 vs 12.2±3.2 mN/mm2,p<0.05)。蛋白激酶A(PKA)磷酸化的受磷蛋白(PLB)的蛋白水平在AVB(n=8)和AF(n=8)中与对照(n=7)相比分别降低了37.9±12.4%和29.7±10.1%(p<0.01),而钙调蛋白依赖性蛋白激酶II(CaMKII)磷酸化的兰尼碱受体通道(RyR2)在AVB(n=8)山羊中增加了166±55%,在AF(n=8)山羊中增加了146±56%(p<0.01)。PKA磷酸化的肌球蛋白结合蛋白-C和肌钙蛋白-I仅在AVB山羊心房中降低(分别降低75±10%和55±15%,n=8,p<0.05)。完全性房室传导阻滞导致的缓慢心室节律期间发生的心房扩张以及AF诱导的重塑均与心房收缩功能障碍有关。AVB和AF山羊心房均显示SR Ca2+负荷降低,可能是由PLB去磷酸化和RYR2过度磷酸化引起的。虽然较短的APs进一步损害AF山羊心房中的收缩性,但肌丝磷酸化降低可能损害AVB山羊心房中的收缩性。因此,心房收缩功能减退在不同类型的心房重塑中似乎有不同的分子因素。
