Project description:Arsenic trioxide (ATO) is a potent anticancer drug agent but its clinical use is often limited by severe cardiotoxicity. However, its exact mechanism remains poorly understood. In this study, we simultaneously explored the direct effect of ATO on cardiac contraction in adult rat ventricular myocytes and its effects on Ca2+ transient in real time by using an IonOptix MyoCam system. The results showed that ATO increased the amplitude of sarcomere shortening, the maximal velocity of relengthening and shortening (-dL/dtmax and +dL/dtmax), time-to-90% relengthening (TR90), and time-to-peak shortening (TPS), resulting in abnormal cardiomyocyte contraction. Meanwhile, ATO markedly increased the resting Ca2+ ratio, amplitude/resting calcium, the maximal velocity of Ca2+ shortening and relaxation (+d[Ca2+]/dtmax and -d[Ca2+]/dtmax), time-to-50% peak [Ca2+] i and the decay rate of [Ca2+] i transients, suggesting that ATO leads to intracellular imbalance of calcium homeostasis. ATO also inhibited sarcoplasmic reticulum Ca2+-ATPase 2a (SERCA2a) activity in a time-dependent manner and activated the endoplasmic reticulum (ER) stress reaction. These results revealed that ATO dramatically aggravates Ca2+ overload and promotes ER stress, eventually causing abnormal cardiomyocyte contraction in a dose-dependent and time-dependent manner.

Project description:Title: Regulation of gene expression through mitogen-activated protein kinase cascades in cardiac myocytes.<br/> Description: The aim of this study is to identify the changes in gene expression induced in rat neonatal <br/> ventricular myocytes, a well-established cell culture model, by endothelin-1, <br/> a known hypertrophic agonist, and to determine which of the changes are <br/> mediated through the ERK cascade. This continues TKAC^Ys previous study of the <br/> effects of oxidative stress, which induces cardiac myocyte apoptosis.<br/>

Project description:BackgroundNanotoxicology is an increasingly relevant field and sound paradigms on how inhaled nanoparticles (NPs) interact with organs at the cellular level, causing harmful conditions, have yet to be established. This is particularly true in the case of the cardiovascular system, where experimental and clinical evidence shows morphological and functional damage associated with NP exposure. Giving the increasing interest on cobalt oxide (Co3O4) NPs applications in industrial and bio-medical fields, a detailed knowledge of the involved toxicological effects is required, in view of assessing health risk for subjects/workers daily exposed to nanomaterials. Specifically, it is of interest to evaluate whether NPs enter cardiac cells and interact with cell function. We addressed this issue by investigating the effect of acute exposure to Co3O4-NPs on excitation-contraction coupling in freshly isolated rat ventricular myocytes.ResultsPatch clamp analysis showed instability of resting membrane potential, decrease in membrane electrical capacitance, and dose-dependent decrease in action potential duration in cardiomyocytes acutely exposed to Co3O4-NPs. Motion detection and intracellular calcium fluorescence highlighted a parallel impairment of cell contractility in comparison with controls. Specifically, NP-treated cardiomyocytes exhibited a dose-dependent decrease in the fraction of shortening and in the maximal rate of shortening and re-lengthening, as well as a less efficient cytosolic calcium clearing and an increased tendency to develop spontaneous twitches. In addition, treatment with Co3O4-NPs strongly increased ROS accumulation and induced nuclear DNA damage in a dose dependent manner. Finally, transmission electron microscopy analysis demonstrated that acute exposure did lead to cellular internalization of NPs.ConclusionsTaken together, our observations indicate that Co3O4-NPs alter cardiomyocyte electromechanical efficiency and intracellular calcium handling, and induce ROS production resulting in oxidative stress that can be related to DNA damage and adverse effects on cardiomyocyte functionality.

Project description:Isolation and culture of ventricular cardiomyocytes from neonatal rats (NRVMs) is a powerful model to study neonatal cardiac development, cell cycle regulation, and cardiac physiology and pathology in vitro. Here, we present our modified enzymatic digestion protocol followed by two-step discontinuous Percoll gradient centrifugation to isolate a high yield of viable ventricular cardiomyocytes from neonatal rats. Finally, here we describe an immunostaining protocol for cytosolic and nuclear staining of NRVMs. For complete details on the use and execution of this protocol, please refer to Pereira et al. (2020).

Project description:Efficient excitation-contraction coupling in ventricular myocytes depends critically on the presence of the t-tubular network. It has been recently demonstrated that cholesterol, a major component of the lipid bilayer, plays an important role in long-term maintenance of the integrity of t-tubular system although mechanistic understanding of underlying processes is essentially lacking. Accordingly, in this study we investigated the contribution of membrane cholesterol to t-tubule remodeling in response to acute hyposmotic stress. Experiments were performed using isolated left ventricular cardiomyocytes from adult mice. Depletion and restoration of membrane cholesterol was achieved by applying methyl-β-cyclodextrin (MβCD) and water soluble cholesterol (WSC), respectively, and t-tubule remodeling in response to acute hyposmotic stress was assessed using fluorescent dextran trapping assay and by measuring t-tubule dependent IK1 tail current (IK1,tail). The amount of dextran trapped in t-tubules sealed in response to stress was significantly increased when compared to control cells, and reintroduction of cholesterol to cells treated with MβCD restored the amount of trapped dextran to control values. Alternatively, application of WSC to normal cells significantly reduced the amount of trapped dextran further suggesting the protective effect of cholesterol. Importantly, modulation of membrane cholesterol (without osmotic stress) led to significant changes in various parameters of IK1, tail strongly suggesting significant but essentially hidden remodeling of t-tubules prior to osmotic stress. Results of this study demonstrate that modulation of the level of membrane cholesterol has significant effects on the susceptibility of cardiac t-tubules to acute hyposmotic stress.

Project description:Via the Na/Ca and Na/H exchange, intracellular Na concentration ([Na](i)) is important in regulating cardiac Ca and contractility. Functional data suggest that [Na](i) might be heterogeneous in myocytes that are not in steady state, but little direct spatial information is available. Here we used two-photon microscopy of SBFI to spatially resolve [Na](i) in rat ventricular myocytes. In vivo calibration yielded an apparent K(d) of 27 +/- 2 mM Na. Similar resting [Na](i) was found using two-photon or single-photon ratiometric measurements with SBFI (10.8 +/- 0.7 vs. 11.1 +/- 0.7 mM). To assess longitudinal [Na](i) gradients, Na/K pumps were blocked at one end of the myocyte (locally pipette-applied K-free extracellular solution) and active in the rest of the cell. This led to a marked increase in [Na](i) at sites downstream of the pipette (where Na enters the myocyte and Na/K pumps are blocked). [Na](i) rise was smaller at upstream sites. This resulted in sustained [Na](i) gradients (up to approximately 17 mM/120 microm cell length). This implies that Na diffusion in cardiac myocytes is slow with respect to trans-sarcolemmal Na transport rates, although the mechanisms responsible are unclear. A simple diffusion model indicated that such gradients require a Na diffusion coefficient of 10-12 microm(2)/s, significantly lower than in aqueous solutions.

Project description:Title: Regulation of gene expression through mitogen-activated protein kinase cascades in cardiac myocytes.<br/> Description: We aim to identify the changes in gene expression induced in rat <br/> neonatal ventricular myocytes, a well established cell culture model, <br/> by phenylepherine, a known hypertrophic agonist, and to determine which <br/> of the changes are mediated through the ERK cascade. In addition, we <br/> intend to extend the previous studies (EXP_TKAC_0102_01 and <br/> EXP_TKAC_1103_02) on endothelin-1 induced hypertrophy and the oxidative <br/> stress induced by H2O2 by using additional concentrations and timepoints.

Project description:Mammalian cardiac myocytes become postmitotic shortly after birth, and the subsequent myocardial growth in adaptation to increasing workloads becomes primarily dependent on hypertrophy of existing myocytes. Although hypertrophic growth of cardiac myocytes has been extensively studied by using both in vitro and in vivo models, the molecular mechanism controlling the switch from hyperplastic to hypertrophic growth of cardiac myocytes is largely unknown. Since the majority of terminally differentiated cardiac myocytes are growth-arrested in G1/G0 phase, it has been hypothesized that the retinoblastoma protein (Rb) or its related pocket proteins which block G1/S transition becomes constitutively active during myocardial terminal differentiation. To test this hypothesis, we studied the regulation of Rb activity by alpha-adrenergic stimulation in neonatal rat ventricular myocytes which are mostly postmitotic in culture. Our results demonstrate that Rb is predominantly in the active hypo-phosphorylated state in control neonatal ventricular myocytes. alpha-Adrenergic stimulation activates G1/S transition in foetal but not neonatal rate ventricular myocytes. Although alpha-adrenergic stimulation does not activate G1/S transition in neonatal myocytes, it induces hyperphosphorylation of Rb to the same extent as in proliferating skeletal-muscle myoblasts or foetal ventricles. Hyper- but not hypo-phosphorylated Rb in stimulated neonatal myocytes or proliferating skeletal-muscle myoblasts fails to bind to the transcription factor, E2F, suggesting that hyper-phosphorylated Rb is inactive. Therefore F1/S transition could also be blocked at steps in addition to Rb inactivation during terminal differentiation and these blockades are refractory to alpha-adrenergic stimulation.

Project description:Cardiac cells mature in the first postnatal week, concurrent with altered extracellular mechanical properties. To investigate the effects of extracellular stiffness on cardiomyocyte maturation, we plated neonatal rat ventricular myocytes for 7 days on collagen-coated polyacrylamide gels with varying elastic moduli. Cells on 10 kPa substrates developed aligned sarcomeres, whereas cells on stiffer substrates had unaligned sarcomeres and stress fibers, which are not observed in vivo. We found that cells generated greater mechanical force on gels with stiffness similar to the native myocardium, 10 kPa, than on stiffer or softer substrates. Cardiomyocytes on 10 kPa gels also had the largest calcium transients, sarcoplasmic calcium stores, and sarcoplasmic/endoplasmic reticular calcium ATPase2a expression, but no difference in contractile protein. We hypothesized that inhibition of stress fiber formation might allow myocyte maturation on stiffer substrates. Treatment of maturing cardiomyocytes with hydroxyfasudil, an inhibitor of RhoA kinase and stress fiber-formation, resulted in enhanced force generation on the stiffest gels. We conclude that extracellular stiffness near that of native myocardium significantly enhances neonatal rat ventricular myocytes maturation. Deviations from ideal stiffness result in lower expression of sarcoplasmic/endoplasmic reticular calcium ATPase, less stored calcium, smaller calcium transients, and lower force. On very stiff substrates, this adaptation seems to involve RhoA kinase.

Project description:The fluo family of indicators is frequently used in studying Ca(2+) physiology; however, choosing which fluo indicator to use is not obvious. Indicator properties are typically determined in well-defined aqueous solutions. Inside cells, however, the properties can change markedly. We have characterized each of three fluo variants (fluo-2MA, fluo-3 and fluo-4) in two forms-the acetoxymethyl (AM) ester and the K(+) salt. We loaded indicators into rat ventricular myocytes and used confocal microscopy to monitor depolarization-induced fluorescence changes and fractional shortening. Myocytes loaded with the indicator AM esters showed significantly different Ca(2+) transients and fractional shortening kinetics. Loading the K(+) salts via whole-cell patch-pipette eliminated differences between fluo-3 and fluo-4, but not fluo-2MA. Cells loaded with different indicator AM esters showed different staining patterns-suggesting differential loading into organelles. Ca(2+) dissociation constants (K(d,Ca)), measured in protein-rich buffers mimicking the cytosol were significantly higher than values determined in simple buffers. This increase in K(d,Ca) (decrease in Ca(2+) affinity) was greatest for fluo-3 and fluo-4, and least for fluo-2MA. We conclude that the structurally-similar fluo variants differ with respect to cellular loading, subcellular compartmentalization, and intracellular Ca(2+) affinity. Therefore, judicious choice of fluo indicator and loading procedure is advisable when designing experiments.