心肌肌钙蛋白Ⅰ基因突变与心肌病的研究进展

心肌肌钙蛋白I(cTnI)是心肌肌钙蛋白复合物的亚单位之一,与心肌肌钙蛋白T和C相互作用,与肌动蛋白-原肌球蛋白结合从而抑制肌动蛋白-肌球蛋白的收缩作用。在肥厚型、扩张型和限制型心肌病中发现30多种cTnI基因的突变,cTnI基因突变转基因小鼠也反映了心肌病的特征。本文总结了cTnI基因突变在心肌病发病机制中的研究情况。     

家族性扩张型心肌病的分子遗传研究进展

扩张型心肌病是一种以左心室和,或右心室扩大、心肌收缩功能受损为主要特征的心肌疾病,是除冠心病和高血压以外导致心力衰竭的主要病因之一。家族性扩张型心肌病约占扩张型心肌病的35％。目前为止,发现的和扩张型心肌病相关的基因突变主要是心肌蛋白基因突变和细胞骨架蛋白基因突变,此外还有线粒体DNA的突变和能量代谢相关的基因突变。本文对引起家族性扩张型心肌病的分子遗传进展进行了总结。     

心肌肌钙蛋白T分子生物学基础研究进展

心肌肌钙蛋白T(cTnT)是调节心脏肌肉收缩的肌钙蛋白复合体组成之一,在人的心脏有4种cTnT异构体,不同的发育阶段表达不同的cTnT异构体。目前发现在心力衰竭终末期cTnT4再度表达。因此,为进一步探讨心衰的发病机制,心肌肌钙蛋白T的分子生物学基因相关研究已成为热点。     

cTnT^R92Q转基因小鼠肥厚型心肌病模型的建立

目的建立cTnT^R92Q肥厚型心肌病的转基因小鼠模型。方法把cTnT^R92Q基因插入-αMHC启动子下游,构建转基因表达载体,通过显微注射法建立cTnT^R92Q转基因C57BL/6J小鼠。PCR鉴定cTnT^R92Q转基因小鼠的基因表型,RT-PCR检测基因表达,光学显微镜和超声检测cTnT^R92Q转基因小鼠心脏的病理改变。结果建立了3个不同表达水平的cTnT^R92Q转基因小鼠品系。转入的cTnT^R92Q基因在心脏组织的表达水平高于内源性cTnT。组织学分析显示cTnT^R92Q转基因小鼠心脏变大,心室壁肥厚,心腔变小,心肌细胞排列紊乱,心肌间质纤维增多。超声检查显示心室壁变厚,收缩期容积和舒张期容积显著缩小,射血分数、短轴缩短率明显增加。结论cTnT^R92Q转基因小鼠心脏变大,室壁变厚,心腔变小,心肌细胞排列紊乱,间质纤维化以及心肌舒张功能失调,说明成功建立了cTnT^R92Q转基因小鼠肥厚型心肌病模型,为研究肥厚型心肌病发病机制和药物研发提供了有价值的动物模型。     

同步纯化人心肌肌钙蛋白T、I

同步纯化人心肌肌钙蛋白Ｔ、Ｉ李志梁付朝平钱学贤陆青王素华黎梅兰（第一军医大学珠江医院心内科,广州５１０２８２）关键词心肌肌钙蛋白Ｔ;心肌肌钙蛋白Ｉ;同步纯化收稿日期：１９９６－０４－１７;接受日期：１９９６－０８－２７。心肌肌钙蛋白包括３种不同的蛋白...     

心肌肌钙蛋白T在病毒性心肌炎心肌组织中的表达及意义

目的:了解病毒性心肌炎心肌组织中肌钙蛋白T的表达情况,探讨病毒性心肌炎时心肌结构蛋白损伤的机制及意义。方法:运用免疫组化和计算机图像分析技术,观察13例明确性病毒性心肌炎和17例界限性病毒性心肌炎尸检心脏标本中心肌肌钙蛋白T的表达与分布。结果:在正常对照的心肌组织中,蛋白成强阳性表达,分布均匀,未见缺染。在明确性心肌炎及14例界限性心肌炎心肌组织中都存在着不同程度的蛋白表达缺染或脱失。缺染的范围及分布与病毒性心肌炎病变特点基本一致,但其范围往往小于炎症细胞浸润范围。计算机图像分析和数据统计结果显示缺染区域的心肌肌钙蛋白T表达量要明显小于其周边区域和正常心肌细胞(P＜0．01)。结论:病毒性心肌炎患者的心肌损害要早于炎症细胞的浸润,病毒的作用可能是心肌肌钙蛋白T脱失的主要因素。心肌肌钙蛋白T的免疫组化检查可以作为一种有效的手段,来辅助病毒性心肌炎的病理学诊断。     

cTnT^（R141W）转基因小鼠扩张型心肌病模型的建立

目的建立cTnT^R141W扩张型心肌病的转基因小鼠模型。方法把cTnT^R141W基因插入-αMHC启动子下游,构建转基因表达载体,通过显微注射法建立cTnT^R141W转基因C57BL/6J小鼠。PCR鉴定cTnT^R141W转基因小鼠的基因表型,实时PCR检测基因的拷贝数,Northern blotting检测基因表达,光学显微镜和超声检测cTnT^R141W转基因小鼠心脏的病理改变。结果建立了3个系的cTnT^R141W转基因小鼠。3个系的基因拷贝数分别是15、20和59拷贝。cTnT^R141W基因在心脏组织的表达水平高于内源性cTnT。病理分析显示cTnT^R141W转基因小鼠心房心室明显大于野生型,心室壁明显变薄,心肌细胞不均匀肥大,心肌间质纤维增多。超声检查显示心室腔明显扩大,收缩期容积和舒张期容积显著增大,射血分数、短轴缩短率、室壁运动度明显降低。结论cTnT^R141W转基因小鼠的全心扩大,室壁变薄,心肌细胞肥大,间质纤维化以及心肌收缩力下降,说明成功建立了cTnT^R141W转基因小鼠扩张型心肌病模型,为研究扩张型心肌病发病机制和药物研发提供了有价值的动物模型。     

人心肌肌钙蛋白T的纯化和单克隆抗体的制备

从人左室心肌中成功纯化心肌肌钙蛋白T(cTnT). 经匀浆, 70℃加热处理, 咪唑盐酸透析, DEAE-纤维素层析, 100g心肌获取cTnT 5mg, 纯度为97.6%. 同时采用脾内免疫法, 免疫Balb/C小鼠, 经细胞融合, 筛选, 克隆化得5株稳定分泌抗人cTnT单克隆抗体(McAb)的杂交瘤细胞(G₃, G₈, G₁₀, A₅, A₇), 4株为IgM, 1株为IgG, 染色体数目92～110条. 腹水效价为3.2×10^-6～1. 6×10^-7.     

糖尿病心肌病发病机制的研究进展

糖尿病心肌病是一种特异性心肌病,病理表现为心肌肥厚和心肌纤维化。其发病机制复杂,可能涉及代谢紊乱(如葡萄糖转运子活性下降、游离脂肪酸增加、钙平衡调节异常、铜代谢紊乱、胰岛素抵抗)、心肌纤维化(与高血糖、心肌细胞凋亡、血管紧张素Ⅱ、胰岛素样生长因子-1、炎性细胞因子和基质金属蛋白酶等有关)、心脏自主神经病变和干细胞等多种因素。本文对近年来国内外有关糖尿病心肌病机制研究的进展予以综述,以期为临床有效防治提供依据。     

胰岛素及cAMP对培养人动脉平滑肌细胞HDL受体功能的影响

对胰岛素ｃＡＭＰ对培养人动脉平滑肌细胞（ＳＭＣ）ＨＤＬ受体功能的影响进行了研究,结果发现：胰岛素使ＳＭＣＨＤＬ受体的结合容量Ｂｍａｘ即受体数目显著下降,而对ＳＭＣＨＤＬ受体的Ｋｄ值亲和力无影响;ｃＡＭｐ则ＳＭＣＨＤＬ受体亲和力增加,而对受体数目无影响。     

牛心肌钙蛋白T的纯化

以小牛心肌为原料,用匀浆提取、热处理、硫酸铵沉淀、ＤＥＡＥ—纤维素柱层析纯化了牛心肌钙蛋白Ｔ（ｃＴｎＴ）。纯化的蛋白在ＳＤＳ—聚丙烯酰胺凝胶电泳上为一条带,分子量为３７,０００道尔顿。用ＴｒｏｐｏｎｉｎＴ快速半定量试纸条测定该蛋白,呈现强阳性反应。这说明我们纯化的蛋白为牛心肌钙蛋白Ｔ。     

Mutual Rescues between Two Dominant Negative Mutations in Cardiac Troponin I and Cardiac Troponin T

Troponin T (TnT) and troponin I (TnI) are two evolutionarily and functionally linked subunits of the troponin complex that regulates striated muscle contraction. We previously reported a single amino acid substitution in the highly conserved TnT-binding helix of cardiac TnI (cTnI) in wild turkey hearts in concurrence with an abnormally spliced myopathic cardiac TnT (cTnT) (Biesiadecki, B. J., Schneider, K. L., Yu, Z. B., Chong, S. M., and Jin, J. P. (2004) J. Biol. Chem. 279, 13825–13832). To investigate the functional effect of this cTnI mutation and its potential value in compensating for the cTnT abnormality, we developed transgenic mice expressing the mutant cTnI (K118C) in the heart with or without the deletion of the endogenous cTnI gene to mimic the homozygote and heterozygote of wild turkeys. Double and triple transgenic mice were created by crossing the cTnI-K118C lines with transgenic mice overexpressing the myopathic cTnT (exon 7 deletion). Functional studies of ex vivo working hearts found that cTnI-K118C alone had a dominantly negative effect on diastolic function and blunted the inotropic responses of cardiac muscle to β-adrenergic stimuli without abolishing the protein kinase A-dependent phosphorylation of cTnI. When co-expressed with the cTnT mutation, cTnI-K118C corrected the significant depression of systolic function caused by cTnT exon 7 deletion, and the co-existence of exon 7-deleted cTnT minimized the diastolic abnormality of cTnI-K118C. Characterization of this naturally selected pair of mutually rescuing mutations demonstrated that TnI-TnT interaction is a critical link in the Ca²⁺ signaling and β-adrenergic regulation in cardiac muscle, suggesting a potential target for the treatment of troponin cardiomyopathies and heart failure.     

Troponin: regulatory function and disorders

Study of the molecular biology of the calcium regulation of muscle contraction was initiated by Professor Ebashi’s discovery of a protein factor that sensitized actomyosin to calcium ions. This protein factor was separated into two proteins: tropomyosin and a novel protein named troponin. Troponin is a Ca²⁺-receptive protein for the Ca²⁺-regulation of muscle contraction and, in association with tropomyosin, sensitizes actomyosin to Ca²⁺. Troponin forms an ordered regulatory complex with tropomyosin in the thin filament. Several regulatory properties of troponin, which is composed of three different components, troponins C, I, and T, are discussed in this article. Genetic studies have revealed that many mutations of genes for troponin components, especially troponins T and I, are involved in the three types of inherited cardiomyopathy. Results of functional analyses indicate that changes in the Ca²⁺-sensitivity caused by troponin mutations are the critical functional consequences leading to these disorders. Recent results of this pathophysiological aspect of troponin are also discussed.     

Dilated Cardiomyopathy Mutations and Phosphorylation disrupt the Active Orientation of Cardiac Troponin C

Cardiac troponin (cTn) is made up of three subunits, cTnC, cTnI, and cTnT. The regulatory N-terminal domain of cTnC (cNTnC) controls cardiac muscle contraction in a calcium-dependent manner. We show that calcium-saturated cNTnC can adopt two different orientations, with the “active” orientation consistent with the 2020 cryo-EM structure of the activated cardiac thin filament by Yamada et al. Using solution NMR ¹⁵N R₂ relaxation analysis, we demonstrate that the two domains of cTnC tumble independently (average R₂ 10 s⁻¹), being connected by a flexible linker. However, upon addition of cTnI_1-77, the complex tumbles as a rigid unit (R₂ 30 s⁻¹). cTnI phosphomimetic mutants S22D/S23D, S41D/S43D and dilated cardiomyopathy- (DCM-)associated mutations cTnI K35Q, cTnC D75Y, and cTnC G159D destabilize the active orientation of cNTnC, with intermediate ¹⁵N R₂ rates (R₂ 17–23 s⁻¹). The active orientation of cNTnC is stabilized by the flexible tails of cTnI, cTnI_1-37 and cTnI_135-209. Surprisingly, when cTnC is incorporated into complexes lacking these tails (cTnC-cTnI_38-134, cTnC-cTnT_223-288, or cTnC-cTnI_38-134-cTnT_223-288), the cNTnC domain is still immobilized, revealing a new interaction between cNTnC and the IT-arm that stabilizes a “dormant” orientation. We propose that the calcium sensitivity of the cardiac troponin complex is regulated by an equilibrium between active and dormant orientations, which can be shifted through post-translational modifications or DCM-associated mutations.     

人心肌肌钙蛋白C两种突变转基因小鼠模型建立与对比分析

目的：为建立心肌组织特异性表达人cTnCD145E和cTnCG159D突变基因转基因小鼠,为对比分析两种不同心肌病的发生发展建立模型。方法利用定点突变技术分别制备人cTnC基因的cTnCD145E和cTnCG159D两个突变体,随后插入心肌特异性表达启动子α-MHC下游构建人cTnCD145E和cTnCG159D基因转基因载体。通过显微注射法建立转基因C57BL/6小鼠。利用心脏超声和病理观察对比分析不同年龄转基因小鼠心脏的结构与功能。结果建立了心肌组织高表达人cTnCD145E和cTnCG159D突变基因转基因小鼠,cTnCD145E和cTnCG159D转基因小鼠随年龄增加,有分别向HCM和DCM发展的趋势,12月龄时,cTnCD145E转基因小鼠收缩末期和舒张末期左室容积（ left ventricle end-diastolic volume and end-systolic volume,EDV and ESV）与同窝阴性小鼠相比下降,射血分数（ejection fraction, EF）和收缩末期左心室后壁厚度（left ventricle end-systolic posterior wall thickness ,ESPWT）增加,而cTnCG159D转基因小鼠EDV和ESV与同窝阴性小鼠相比上升,EF和ESPWT减少。结论心肌组织特异性表达人cTnCD145E突变基因转基因小鼠表现肥厚型心肌病病理表型,而心肌组织特异性表达人cTnCG159D突变基因转基因小鼠表现扩张型心肌病病理表型,二者可作为对比研究由不同发病机制导致的心肌病模型。