Cardiac Dysfunction in Hypertrophic Cardiomyopathy Mutant Tropomyosin Mice Is Transgene-Dependent, Hypertrophy-Independent, and Improved by &bgr;-Blockade

D. Michele, Carlen A. Gomez, Katie E. Hong, M. Westfall, J. Metzger
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引用次数: 75

Abstract

Abstract— Familial hypertrophic cardiomyopathy (FHC) has been linked to mutations in proteins of the cardiac contractile apparatus, including &agr;-tropomyosin (Tm). Mice expressing &agr;Tm in the heart were developed to determine the effects of FHC mutant Tm on cardiac structure and function from single cardiac myocytes to whole organ function in vivo. Expression of E180G mutant Tm did not produce cardiac hypertrophy or detectable changes in cardiac muscle morphology. However, E180G mutant Tm expression increased the Ca2+ sensitivity of force production in single cardiac myocytes in a transgene expression–dependent manner. Contractile dysfunction in single myocytes manifested organ level dysfunction, as conductance-micromanometry showed E180G Tm mice had significantly slowed relaxation (diastolic dysfunction) under physiological conditions. The diastolic dysfunction in E180G Tm mice was no longer evident during &bgr;-blockade because propranolol eliminated the effect of E180G Tm to slow myocardial relaxation. Cellular and organ level dysfunction were evident in E180G Tm mice in the absence of significant cardiac structural abnormalities normally associated with FHC. These findings therefore suggest that diastolic dysfunction in FHC may be a direct consequence of FHC mutant protein expression. In addition, because diastolic dysfunction in E180G Tm mice is dependent on inotropic status, cardiovascular stress may play an important role in FHC pathogenesis.
肥厚性心肌病原肌球蛋白突变小鼠的心功能障碍是转基因依赖的,肥厚不依赖的,并通过&bgr;-阻断改善
家族性肥厚性心肌病(FHC)与心脏收缩装置蛋白突变有关,包括&agr;-原肌球蛋白(Tm)。通过培养在心脏中表达&agr;Tm的小鼠,在体内研究FHC突变体Tm对单个心肌细胞到整个器官功能的心脏结构和功能的影响。表达E180G突变体Tm不产生心肌肥大或心肌形态的可检测变化。然而,E180G突变体Tm的表达以转基因表达依赖的方式增加了单个心肌细胞对力产生的Ca2+敏感性。单个肌细胞的收缩功能障碍表现为器官水平的功能障碍,电导-微压测量显示E180G Tm小鼠在生理条件下明显减慢舒张(舒张功能障碍)。在&bgr;阻断期间,E180G Tm小鼠舒张功能障碍不再明显,因为心得安消除了E180G Tm减缓心肌舒张的作用。在没有与FHC相关的明显心脏结构异常的情况下,E180G Tm小鼠的细胞和器官水平功能障碍明显。因此,这些发现表明FHC的舒张功能障碍可能是FHC突变蛋白表达的直接结果。此外,由于E180G Tm小鼠的舒张功能障碍依赖于肌力状态,心血管应激可能在FHC发病中起重要作用。
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