双光电描记体外培养心肌细胞搏动的方法

本文阐述一种新的体外培养心肌细胞搏动双光电描记系统,能同时描记出同一视野不同细胞(簇)的搏动变化,同步分析不同生理或病理状态的心肌细胞在各种因素刺激下的各自搏动特征,准确测定出细胞搏动发生同步的时间,研究冲动在心肌细胞间传导过程及细胞之间的互相关系,并有简便、效率高、节省细胞标本之优点。     

乌头碱对人诱导多能干细胞衍生心肌细胞中钙信号的影响

该文旨在探究乌头碱对人诱导多能干细胞衍生心肌细胞(human induced pluripotent stem cells-derived cardiomyocytes, hiPSCs-CMs)中钙信号的影响。用CCK-8法测定乌头碱对hiPSCsCMs细胞存活率的影响;通过共聚焦显微镜的明场模式记录不同加药时间和浓度条件下乌头碱对心肌细胞的搏动频率的影响;通过共聚焦显微镜荧光系统记录乌头碱对细胞自发及1、2、3 Hz电刺激条件下钙信号的影响;使用咖啡因诱导心肌细胞肌质网中的钙离子,令其全部被释放出来,以探究乌头碱对钙库的影响。乌头碱在加药浓度为9μmol/L、加药时间为6 h时将产生毒性作用,可对hiPSCs-CMs细胞存活率造成显著影响;乌头碱能够明显加快hiPSCs-CMs搏动频率,最大搏动频率与加药时间和浓度相关;乌头碱能够明显降低hiPSCs-CMs自发及1、2、3 Hz电刺激条件下钙瞬变的振幅;经0.3μmol/L乌头碱作用3 h的hiPSCs-CMs的钙库总钙量下降;且乌头碱对hiPSCs-CMs搏动频率及钙信号的影响具有洗脱作用。乌头碱能够加快hiPSCs-CMs搏动频...     

细胞外间质-整合素在牵张刺激心肌细胞肥大中的作用

应用牵张刺激培养细胞的模型 ,观察胶原、纤维连接蛋白、层粘连素对牵张刺激心肌细胞肥大的影响 ,探讨细胞外间质 -整合素受体在超负荷心肌肥大的跨膜信号传导机制中的作用。结果发现 ,胶原、纤维连接蛋白、层粘连素明显有助于培养心肌细胞的贴壁、伸展。牵张刺激后 ,胶原、纤维连接蛋白基质组心肌细胞的 3H -亮氨酸掺入率和心肌细胞表面积均显著大于对照组 ,而层粘连素组无显著变化 ;可溶性纤维连接蛋白、RGD肽均可显著抑制牵张刺激诱导的培养心肌细胞 (胶原为粘附基质 )的3H -亮氨酸掺入率升高和心肌细胞表面积增大 ,而层粘连素无明显作用。结果表明 ,特异的细胞外间质 -整合素在超负荷心肌肥大机制中发挥了跨膜信号传导作用。     

起搏基因体外调控骨髓间充质干细胞分化为类起搏细胞的研究

目的本研究旨在通过体外构建起搏基因质粒pIRES2-EGFP-HCN2,电穿孔转染骨髓间充质干细胞,检测其在体外的表达情况。方法对含mHCN2 cDNA的PTR载体进行转化和扩增,将所得mHCN2基因定向克隆到含有增强型绿色荧光蛋白的真核表达载体pIRES2-EGFP中,进行双酶切来鉴定克隆的正确性。将重组质粒及空白质粒用电穿孔法转染骨髓间充质干细胞,并在体外与心肌细胞共培养,观察搏动频率变化及mHCN2的表达,并检测其电生理和组织学特征。结果构建了重组质粒pIRES2-EGFP-HCN2。荧光显微镜下可见转染后的骨髓间充质干细胞呈绿色荧光,细胞中mHCN2的阳性表达率为98.2%。免疫荧光显示转染起搏基因的骨髓间充质干细胞mHCN2的表达,而对照组无表达。实验组共培养的心肌细胞搏动频率较对照组干细胞共培养的明显增快(140±11次/分VS 100±13次/分,P0.05),动作电位显示实验组最大舒张期电位值小于对照组(-62±2mv VS-71±2mv,P0.05)。免疫荧光显示干细胞与心肌细胞间形成间隙连接。结论成功构建了重组质粒pIRES2-EGFP-HCN2,转染后的骨髓间充质干细胞可在体外成功表达功能性mH-CN2通道,提供起搏电流,具有类起搏细胞的功能,为进一步构建生物起搏器提供依据。     

利用光遗传学技术构建小鼠光控心脏起搏模型

电刺激是人工控制心脏搏动频率的标准技术,但在实验研究中,这种方法有较大的局限性,如局部电解效应、刺激频率和时长受限、只能对目标范围内的所有细胞进行刺激、不能选择性作用于心肌细胞等.基于光遗传学技术,本研究构建了心肌细胞特异性表达光激活阳离子通道channelrhodopsin-2(ChR2)的转基因小鼠,采用特定频率的...     

小鼠胚胎心肌细胞的分离及电生理特性

本文旨在探索小鼠胚胎心肌细胞的分离方法并观察其电生理特性。应用胶原酶B消化法获得不同时期单个小鼠胚胎心肌细胞;利用全细胞膜片钳技术,记录胚胎心肌细胞的超极化激活的非选择性内向阳离子电流(If)和L-钙电流(ICa-L),并用电流钳记录其自发性动作电位。胚胎心肌细胞通过相差显微镜依据其形态和自发性收缩进行鉴定。本法分离所获得的胚胎心肌细胞容易进行全细胞膜片钳记录,可用于记录If,ICa-L．电流和自发性动作电位,己证实胚胎心肌细胞If和Ica-L的电生理特性与成年起搏细胞或心肌细胞相似。本实验建立的分离方法简单、稳定、有效、可靠,最早可获得8．5d的胚胎心肌细胞。胚胎心肌细胞的电生理记录为探索胚胎心肌细胞的电生理特性提供了一个可用的模型,并可能为某些心脏疾病产生的机制提供实验依据。     

细胞外间质-整合素在牵张刺激心肌细胞肥大中的作用

应用牵张刺激培养细胞的模型,观察原原、纤维连接蛋白、层粘连素对牵张刺激心肌细胞肥大的影响,探讨细胞外间质－融洽纱受体在超负荷心肌肥大的跨膜信号传导机制中的作用。发现,胶原、纤维连接蛋白、层粘连素明显有助于培养心肌细胞的贴壁、伸展。牵张刺激后,胶原、纤维连接蛋白基质组心肌细胞的＾３Ｈ－亮氨酸掺入率和心肌细胞表面积均显著大于对照组,而层粘连素组无显著变化;可溶性纤维连接蛋白、ＲＧＤ肽均可显著抑制牵张刺     

电刺激提高分化心肌细胞成熟度并改善心肌梗死大鼠心脏功能

该研究探讨了电刺激对诱导多能干细胞的心脏分化影响,并评估了分化心肌细胞对心肌梗死的治疗效果。电刺激和非电刺激促进诱导多能干细胞分化出功能性心肌细胞;qRT-PCR和细胞免疫荧光检测分化心肌细胞中心源性基因和功能成熟基因表达情况;建立心肌梗死模型SD大鼠并将其随机分为心肌梗死组、电刺激组和对照组,每组10只。心肌梗死组只结扎冠状动脉,电刺激组和对照组分别在心肌梗死边界注射电刺激和无电刺激预处理的分化心肌细胞。超声心动图和有创血流动力学检测心功能;Masson染色评估梗死面积,免疫组化检测梗死边缘区毛细血管密度。结果表明,电刺激可提高分化心肌细胞的自发搏动,并上调分化心肌细胞中心源性基因(Nkx2-5、GATA4、α-MHC和CX-43)和功能成熟基因(α-actinin和RYR2)的表达(P0.05)。电刺激明显改善心肌梗死大鼠心功能,减小梗死面积和增加梗死边缘区毛细血管密度(P0.05)。以上结果表明,电刺激可提高诱导多能干细胞的心脏分化效率并促进分化心肌细胞的成熟;经电刺激预处理的分化心肌细胞可明显改善心肌梗死大鼠心功能。     

心肌细胞间的电耦联

心脏是由无数个独立的心肌细胞通过缝隙连接形成的一个功能性合胞体。心肌细胞间的电耦联是心脏“全或无”性动作电位传导和机械收缩的先决条件。缺氧、缺血、药物、细胞内外离子浓度的改变以及激素等因素可直接或间接地影响心肌细胞间的电耦联,从而导致心脏功能的改变。     

LPS诱导乳鼠心肌细胞p38蛋白激酶的激活与转位

探讨p38蛋白激酶信号传导通路在细胞中的特异性作用机制。应用共聚焦激光扫描技术观察心肌细胞中p38蛋白激酶的分布及LPS对其分布的影响。结果提示未受刺激静止的及EGF刺激的心肌细胞中,p38在胞浆和胞核中荧光强度呈散性分布。LPS刺激30分钟后,细胞核区的荧光强度明显增强,而胞浆区域的荧光强度降低,心肌细胞受LPS刺激激活后,其p38蛋白激酶由胞浆转位到胞核。     

Reentrant waves in a ring of embryonic chick ventricular cells imaged with a Ca2+ sensitive dye

According to the classic model initially formulated by Mines, reentrant cardiac arrhythmias may be associated with waves circulating in a ring geometry. This study was designed to study the dynamics of reentry in a ring geometry of cardiac tissue culture. Reentrant calcium waves in rings of cultured embryonic chick cardiac myocytes were imaged using a macroscope to monitor the fluorescence of intracellular Calcium Green-1 dye. The rings displayed a variety of stable rhythms including pacemaker activity and spontaneous reentry. Waves originating from a localized pacemaker could lead to reentry as a consequence of unidirectional block. In addition, more complex patterns were observed due to the interactions between reentrant and pacemaker rhythms. These rhythms included instances in which pacemakers accelerated the reentrant rhythm, and instances in which the excitation was blocked in the vicinity of pacemakers. During reentrant activity an appropriately timed electrical stimulus could induce resetting of activity or cause complete annihilation of the propagating waves. This experimental preparation reveals many spontaneously occuring complex rhythms. These complex rhythms are hypothesized to reflect interactions between spontaneous pacemakers, wave propagation, refractory period, and overdrive suppression. This preparation may serve as a useful model system to further investigate complex dynamics arising during reentrant rhythms in cardiac tissue.     

Evidence for the impact of BAG3 on electrophysiological activity of primary culture of neonatal cardiomyocytes

Homeostasis of proteins involved in contractility of individual cardiomyocytes and those coupling adjacent cells is of critical importance as any abnormalities in cardiac electrical conduction may result in cardiac irregular activity and heart failure. Bcl2-associated athanogene 3 (BAG3) is a stress-induced protein whose role in stabilizing myofibril proteins as well as protein quality control pathways, especially in the cardiac tissue, has captured much attention. Mutations of BAG3 have been implicated in the pathogenesis of cardiac complications such as dilated cardiomyopathy. In this study, we have used an in vitro model of neonatal rat ventricular cardiomyocytes to investigate potential impacts of BAG3 on electrophysiological activity by employing the microelectrode array (MEA) technology. Our MEA data showed that BAG3 plays an important role in the cardiac signal generation as reduced levels of BAG3 led to lower signal frequency and amplitude. Our analysis also revealed that BAG3 is essential to the signal propagation throughout the myocardium, as the MEA data-based conduction velocity, connectivity degree, activation time, and synchrony were adversely affected by BAG3 knockdown. Moreover, BAG3 deficiency was demonstrated to be connected with the emergence of independently beating clusters of cardiomyocytes. On the other hand, BAG3 overexpression improved the activity of cardiomyocytes in terms of electrical signal amplitude and connectivity degree. Overall, by providing more in-depth analyses and characterization of electrophysiological parameters, this study reveals that BAG3 is of critical importance for electrical activity of neonatal cardiomyocytes.     

Connexins in mammalian heart function

In heart, the propagation of electrical activity is mediated by intercellular channels, referred to as junctional channels, aggregated into gap junctions and localised between myocytes. These channels consist of structurally related transmembrane proteins, the connexins, three of which (CX43, CX40 and CX45) have been shown to be associated with the myocytes of mammalian heart; a fourth, CX37, was detected exclusively in endothelial cells. In this paper, we review the recent data dealing with the topographical heterogeneity of expression of these connexins in the different cardiac tissues and the unique conductance properties of the channels they form, and attempt to assess the role played by each connexin and the consequences of their multiplicity in the propagation of action potentials.     

Skeletal myotube integration with planar microelectrode arrays in vitro for spatially selective recording and stimulation: a comparison of neuronal and myotube extracellular action potentials

Microelectrode array (MEA) technology holds tremendous potential in the fields of biodetection, lab-on-a-chip applications, and tissue engineering by facilitating noninvasive electrical interaction with cells in vitro. To date, significant efforts at integrating the cellular component with this detection technology have worked exclusively with neurons or cardiac myocytes. We investigate the feasibility of using MEAs to record from skeletal myotubes derived from primary myoblasts as a way of introducing a third electrogenic cell type and expanding the potential end applications for MEA-based biosensors. We find that the extracellular action potentials (EAPs) produced by spontaneously contractile myotubes have similar amplitudes to neuronal EAPs. It is possible to classify myotube EAPs by biological signal source using a shape-based spike sorting process similar to that used to analyze neural spike trains. Successful spike-sorting is indicated by a low within-unit variability of myotube EAPs. Additionally, myotube activity can cause simultaneous activation of multiple electrodes, in a similar fashion to the activation of electrodes by networks of neurons. The existence of multiple electrode activation patterns indicates the presence of several large, independent myotubes. The ability to identify these patterns suggests that MEAs may provide an electrophysiological basis for examining the process by which myotube independence is maintained despite rapid myoblast fusion during differentiation. Finally, it is possible to use the underlying electrodes to selectively stimulate individual myotubes without stimulating others nearby. Potential uses of skeletal myotubes grown on MEA substrates include lab-on-a-chip applications, tissue engineering, co-cultures with motor neurons, and neural interfaces.     

Quantification of calcium entry at the T-tubules and surface membrane in rat ventricular myocytes

The action potential of cardiac ventricular myocytes is characterized by its long duration, mainly due to Ca flux through L-type Ca channels. Ca entry also serves to trigger the release of Ca from the sarcoplasmic reticulum. The aim of this study was to investigate the role of cell membrane invaginations called transverse (T)-tubules in determining Ca influx and action potential duration in cardiac ventricular myocytes. We used the whole cell patch clamp technique to record electrophysiological activity in intact rat ventricular myocytes (i.e., from the T-tubules and surface sarcolemma) and in detubulated myocytes (i.e., from the surface sarcolemma only). Action potentials were significantly shorter in detubulated cells than in control cells. In contrast, resting membrane potential and action potential amplitude were similar in control and detubulated myocytes. Experiments under voltage clamp using action potential waveforms were used to quantify Ca entry via the Ca current. Ca entry after detubulation was reduced by approximately 60%, a value similar to the decrease in action potential duration. We calculated that Ca influx at the T-tubules is 1.3 times that at the cell surface (4.9 vs. 3.8 micromol/L cytosol, respectively) during a square voltage clamp pulse. In contrast, during a cardiac action potential, Ca entry at the T-tubules is 2.2 times that at the cell surface (3.0 vs. 1.4 micromol/L cytosol, respectively). However, more Ca entry occurs per microm(2) of junctional membrane at the cell surface than in the T-tubules (in nM/microm(2): 1.43 vs. 1.06 during a cardiac action potential). This difference is unlikely to be due to a difference in the number of Ca channels/junction at each site because we estimate that the same number of Ca channels is present at cell surface and T-tubule junctions ( approximately 35). This study provides the first evidence that the T-tubules are a key site for the regulation of action potential duration in ventricular cardiac myocytes. Our data also provide the first direct measurements of T-tubular Ca influx, which are consistent with the idea that cardiac excitation-contraction coupling largely occurs at the T-tubule dyadic clefts.     

CCN1 protects cardiac myocytes from oxidative stress via beta1 integrin-Akt pathway

CCN1 (Cyr61) is a secreted matricellular protein, mediating angiogenesis and cell survival through interaction with integrins. Although CCN1 expression is induced in the heart during ischemia and pressure overload, its function in cardiac myocytes remains to be elucidated. We hypothesized that CCN1 may not only induce angiogenesis but may also have a direct effect on cardiac myocytes during ischemia. In this study, we investigated the effect of CCN1 on survival of cardiac myocytes under oxidative stress and examined a signal transduction pathway downstream of CCN1. A solid-phase binding assay demonstrated that CCN1 was bound to cardiac myocytes in a dose-dependent, saturable manner. Inactivation of beta1 integrin in cardiac myocytes inhibited binding with CCN1, indicating that CCN1 was bound to cardiac myocytes via beta1 integrin. Knockdown of endogenous CCN1 decreased the number of surviving cells under oxidative stress, while pretreatment of cardiac myocytes with recombinant CCN1 significantly increased the number of surviving cells. Moreover, TUNEL staining showed that CCN1 significantly decreased apoptotic cells. Furthermore, treatment of cardiac myocytes with CCN1 induced phosphorylation of Akt and extracellular signal-regulated kinase (ERK). Inactivation of beta1 integrin inhibited CCN1-induced phosphorylation of these kinases and abolished the protective effect of CCN1. Moreover, pretreatment of cells with wortmannin completely blocked the protective effect of CCN1 on cardiac myocytes under oxidative stress, indicating that the protective effect of CCN1 was mainly mediated by activation of Akt. The antiapoptotic effect of CCN1 on cardiac myocytes together with its proangiogenic property could be beneficial in the treatment of ischemic heart disease.     

Blebbistatin extends culture life of adult mouse cardiac myocytes and allows efficient and stable transgene expression

The characterization of cellular phenotypes of heart disorders can be achieved by isolating cardiac myocytes from mouse models or genetically modifying wild-type cells in culture. However, adult mouse cardiac myocytes show extremely low tolerance to isolation and primary culture conditions. Previous studies indicate that 2,3-butanedione monoximine (BDM), a nonspecific excitation-contraction coupling inhibitor, can improve the viability of isolated adult mouse cardiac myocytes. The mechanisms of the beneficial and unwanted nonspecific actions of BDM on cardiac myocytes are not understood. To understand what contributes to murine adult cardiac myocyte stability in primary culture and improve this model system for experimental use, the specific myosin II inhibitor blebbistatin was explored as a media supplement to inhibit mouse myocyte contraction. Enzymatically isolated adult mouse cardiac myocytes were cultured with blebbistatin or BDM as a media supplement. Micromolar concentrations of blebbistatin significantly increased the viability, membrane integrity, and morphology of adult cardiac myocytes compared with cells treated with previously described 10 mM BDM. Cells treated with blebbistatin also showed efficient adenovirus gene transfer and stable transgene expression, and unlike BDM, blebbistatin does not appear to interfere with cell adhesion. Higher concentrations of BDM actually worsened myocyte membrane integrity and transgene expression. Therefore, the specific inhibition of myosin II activity by blebbistatin has significant beneficial effects on the long-term viability of adult mouse cardiac myocytes. Furthermore, the unwanted effects of BDM on adult mouse cardiac myocytes, perhaps due to its nonspecific activities or action as a chemical phosphatase, can be avoided by using blebbistatin.     

Tissue engineering of functional cardiac muscle: molecular, structural, and electrophysiological studies

The primary aim of this study was to relate molecular and structural properties of in vitro reconstructed cardiac muscle with its electrophysiological function using an in vitro model system based on neonatal rat cardiac myocytes, three-dimensional polymeric scaffolds, and bioreactors. After 1 wk of cultivation, we found that engineered cardiac muscle contained a 120- to 160-microm-thick peripheral region with cardiac myocytes that were electrically connected through gap junctions and sustained macroscopically continuous impulse propagation over a distance of 5 mm. Molecular, structural, and electrophysiological properties were found to be interrelated and depended on specific model system parameters such as the tissue culture substrate, bioreactor, and culture medium. Native tissue and the best experimental group (engineered cardiac muscle cultivated using laminin-coated scaffolds, rotating bioreactors, and low-serum medium) were comparable with respect to the conduction velocity of propagated electrical impulses and spatial distribution of connexin43. Furthermore, the structural and electrophysiological properties of the engineered cardiac muscle, such as cellularity, conduction velocity, maximum signal amplitude, capture rate, and excitation threshold, were significantly improved compared with our previous studies.     

Empirical Study of an Adaptive Multiscale Model for Simulating Cardiac Conduction

We modify and empirically study an adaptive multiscale model for simulating cardiac action potential propagation along a strand of cardiomyocytes. The model involves microscale partial differential equations posed over cells near the action potential upstroke and macroscale partial differential equations posed over the remainder of the tissue. An important advantage of the modified model of this paper is that, unlike our original model, it does not require perfect alignment between myocytes and the macroscale computational grid. We study the effects of gap-junctional coupling, ephaptic coupling, and macroscale grid spacing on the accuracy of the multiscale model. Our simulations reveal that the multiscale method accurately reproduces both the wavespeed and the waveform, including both upstroke and recovery, of fully microscale models. They also reveal that perfect alignment between myocytes and the macroscale grid is not necessary to reproduce the dynamics of a traveling action potential. Further, our simulations suggest that the macroscale grid spacing used in an adaptive multiscale model need not be much finer than the spatial width of an action potential. These results are demonstrated to hold under high, low, and zero gap-junctional coupling regimes.     

Hepatocyte growth factor protects cardiac myocytes against oxidative stress-induced apoptosis

Hepatocyte growth factor (HGF) has been proposed as an endogenous cardioprotective agent against oxidative stress. The mechanism of HGF action in the heart, however, has not yet been elucidated. The present study demonstrates that HGF protects adult cardiac myocytes against oxidative stress-induced apoptosis. HGF, at the concentrations which can be detected in the plasma of humans subsequent to myocardial infarction, effectively attenuated death of isolated adult rat cardiac myocytes and cultured HL-1 cardiac muscle cells induced by apoptosis-inducing oxidative stress stimuli such as daunorubicin, serum deprivation, and hydrogen peroxide. We identified expression of c-Met HGF receptor in adult cardiac myocytes, which can be rapidly tyrosine phosphorylated in response to HGF treatment. HGF also activated MEK, p44/42 MAPK, and p90RSK. To determine if MEK-MAPK pathway may be involved in the mechanism of HGF-mediated cardiac myocyte protection, effects of a specific MEK inhibitor, PD98059, were studied. Pretreatment of cells with PD98059 partially blocked HGF signaling for protection against hydrogen peroxide-induced cell death. Thus, HGF protects cardiac myocytes against oxidative stress, in part, via activating MEK-MAPK pathway.