Chronobiologic approach to beat-to-beat variations of cultured murine myocardial cells

An earlier demonstration of a circadian rhythm in rat atria by others is complemented herein by observations in culture: A single murine myocardial cell and two sets of grouped cells beating in culture for several days reveal several features of an anticipated, presumably built-in spectrum of multifrequency rhythms and trends, the chronome. Circadian and about 12-h (circasemidian) components are modulated by an approximately 84-h (circasemiseptan) component, which cannot be separated from trends in view of the brevity of the series. The circumstance under which the culture is aging and in which fibroblasts proliferate is a further complication that limits the findings to a single cycle reproduced in three separate cultures. Whether it is a rhythm that repeats itself or a response to placement into culture, an approximately 3.5-d component in the beating of myocardial cells in culture is to be aligned with a very prominent similar component found in the incidence of 85,819 human myocardial infarctions.     

Chronobiologic approach to beat-to-beat variations of cultured murine myocardial cells.

An earlier demonstration of a circadian rhythm in rat atria by others is complemented herein by observations in culture: A single murine myocardial cell and two sets of grouped cells beating in culture for several days reveal several features of an anticipated, presumably built-in spectrum of multifrequency rhythms and trends, the chronome. Circadian and about 12-h (circasemidian) components are modulated by an approximately 84-h (circasemiseptan) component, which cannot be separated from trends in view of the brevity of the series. The circumstance under which the culture is aging and in which fibroblasts proliferate is a further complication that limits the findings to a single cycle reproduced in three separate cultures. Whether it is a rhythm that repeats itself of a response to placement into culture, an approximately 3.5-d component in the beating of myocardial cells in culture is to be aligned with a very prominent similar component found in the incidence of 85,819 human myocardial infarctions.     

Secretory products from epicardial adipose tissue induce adverse myocardial remodeling after myocardial infarction by promoting reactive oxygen species accumulation

Adverse myocardial remodeling, manifesting pathologically as myocardial hypertrophy and fibrosis, often follows myocardial infarction (MI) and results in cardiac dysfunction. In this study, an obvious epicardial adipose tissue (EAT) was observed in the rat model of MI and the EAT weights were positively correlated with cardiomyocyte size and myocardial fibrosis areas in the MI 2- and 4-week groups. Then, rat cardiomyocyte cell line H9C2 and primary rat cardiac fibroblasts were cultured in conditioned media generated from EAT of rats in the MI 4-week group (EAT-CM). Functionally, EAT-CM enlarged the cell surface area of H9C2 cells and reinforced cardiac fibroblast activation into myofibroblasts by elevating intracellular reactive oxygen species (ROS) levels. Mechanistically, miR-134-5p was upregulated by EAT-CM in both H9C2 cells and primary rat cardiac fibroblasts. miR-134-5p knockdown promoted histone H3K14 acetylation of manganese superoxide dismutase and catalase by upregulating lysine acetyltransferase 7 expression, thereby decreasing ROS level. An in vivo study showed that miR-134-5p knockdown limited adverse myocardial remodeling in the rat model of MI, manifesting as alleviation of cardiomyocyte hypertrophy and fibrosis. In general, our study clarified a new pathological mechanism involving an EAT/miRNA axis that explains the adverse myocardial remodeling occurring after MI.Subject terms: Cell biology, Molecular biology     

Cardioblast-intrinsic Tinman activity controls proper diversification and differentiation of myocardial cells in Drosophila

The NK homeobox gene tinman (tin) is required for the specification of the cardiac, visceral muscle and somatic muscle progenitors in the early dorsal mesoderm of Drosophila. Like its vertebrate counterpart Nkx2.5, the expression of tin is maintained in cardiac cells during cardiac maturation and differentiation; however, owing to the complete lack of a dorsal vessel in tin mutant embryos, the function of tin in these cells has not been defined. Here we show that myocardial cells and dorsal vessels can form even though they lack Tin, and that viable adults can develop, as long as Tin is provided in the embryonic precardiac mesoderm. However, embryos in which tin expression is specifically missing from cardial cells show severe disruptions in the normal diversification of the myocardial cells, and adults exhibit severe defects in cardiac remodeling and function. Our study reveals that the normal expression and activity of Tin in four of the six bilateral cardioblasts within each hemisegment of the heart allows these cells to adopt a cell fate as ;working' myocardium, as opposed to a fate as inflow tract (ostial) cells. This function of tin involves the repression of Dorsocross (Doc) T-box genes and, hence, the restriction of Doc to the Tin-negative cells that will form ostia. We conclude that tin has a crucial role within myocardial cells that is required for the proper diversification, differentiation, and post-embryonic maturation of cardiomyocytes, and we present a pathway involving regulatory interactions among seven-up, midline, tinman and Dorsocross that establishes these developmental events upon myocardial cell specification.     

The effector cells and cellular mediators of immune system involved in cardiac inflammation and fibrosis after myocardial infarction

The cardiac repair after myocardial infarction (MI) involves two phases, namely, inflammatory response and proliferative response. The former is an inflammatory reaction, evoked by different kinds of pro-inflammatory leukocytes and molecules stimulated by myocardial necrosis, while the latter is a repair process, predominated by a magnitude of anti-inflammatory cells and cytokines, as well as fibroblasts. Cardiac remodeling post-MI is dependent on the balance of individualized intensity of the post-MI inflammation and subsequent cardiac fibrosis. During the past 30 years, enormous studies have focused on investigating immune cells and mediators involved in cardiac inflammation and fibrosis, which are two interacting processes of post-MI cardiac repair. These results contribute to revealing the mechanism of adverse cardiac remodeling after MI and alleviating the impairment of cardiac function. In this study, we will broadly discuss the role of immune cell subpopulation and the involved cytokines and chemokines during cardiac repair post-MI, particular in cardiac inflammation and fibrosis.     

Ultrastructure of the contact between interstitial cells and myocardial cells in mammalian hearts]

By combination of light, electron-microscopical and histochemical findings in the myocardium of dog and mice, the hypothesis of an intimate contact between a widely branched interstitial cell type, rich in proteoglycans, and myocardial cells could be strengthened. The branches seem to penetrate the transversal tubular system of the myocardial cells. Functionally, this interstitial (mast cell-like) cell type might influence via proteoglycans - delivered into the transversal tubuli - the excitation phenomena of the myocardial cell membrane. One of the earliest pathomorphological changes in the myocardium, as revealed by the light-microscopie, is the disengagement of these interstitial cells and the myocardial cells. From this point of view the genesis of myocardial cell necrosis has been discussed.     

Beating activity of heterokaryons between myocardial and non-myocardial cells in culture

Cultured mouse myocardial cells grown as monolayers fused upon treatment with HVJ (Sendai virus). The myocardial cells also fused with quail myocardial cells, neuroblastoma cells and non-excitable cells, such as KB cells. The beating activity of these heterokaryons was studied in the present work. Heterokaryons composed of myocardial cells from different species maintained spontaneous beating activity for 2 days or more. Those of one myocardial and one neuroblastoma cell maintained the activity for 22-26 h, while those of one myocardial and one non-excitable cell, such as KB cell, lost the activity within 2-4 h after addition of HVJ. Heterokaryons that had stopped spontaneous beating did not contract on application of electrical-field stimulation. The ration of non-myocardial cells in the heterokaryons increased in inverse proportion to the decrease in beating activity of the heterokaryons. Study of the rapid disappearance of beating activity in heterokaryons composed of one myocardial and one KB cell showed that both excitability of the cell membrane and myofibril organization were rapidly lost.     

A method for the harvest,culture, and characterization of human adult atrial myocardial cells: Correlation with age of donor

Summary Myocardial cell culture methods are now well established for animal and fetal human tissue. We present here a method for harvesting and culturing adult human atrial myocardiocytes. Cells are obtained from fresh atrial tissue normally discarded after being removed to cannulate the right atrium during open heart surgery. The atrial tissue is minced and then digested using collagenase. The single cell suspension is initially cultured in serum-containing growth medium, then transferred to defined medium, selective for myocardial cell growth. The cells are characterized by immunoperoxidase stains and transmission electron microscopy. The cultured cells stain positive for myoglobin, whereas control cultured fibroblasts and endothelial cells do not. Electron microscopy shows the presence of numerous myofibrils, Z-bodies, pleomorphic mitochondria, and secretory granules. The chronological age of the donor was an important factor in culturing the adult tissue, the younger tissue correlated with a higher success rate. This method provides a means for in vitro study of human adult myocardial cells and provides guidelines for appropriate atrial tissue to use.     

Beating of multinucleated giant myocardial cells in culture

Cultured mouse myocardial cells grown as cell sheets in Petri dishes fused together and formed multinucleated giant cells on treatment with HVJ (Sendai virus). The giant cells had well organized myofibrils and beat spontaneously and rhythmically. The spontaneous beating activity of the giant cells changed in response to changes of the external potassium and calcium concentrations and on addition of ouabain in the same way as the beating of cultured myocardial cells not treated with HVJ. When a microelectrode was inserted into giant cells that exhibited spontaneous beating, action potentials were easily recorded.     

Aspirin-induced heat stress resistance in chicken myocardial cells can be suppressed by BAPTA-AM in vitro

Our recent studies have displayed the protective functions of aspirin against heat stress (HS) in chicken myocardial cells, and it may be associated with heat shock proteins (HSPs). In this study, we further investigated the potential role of HSPs in the aspirin-induced heat stress resistance. Four of the most important HSPs including HspB1 (Hsp27), Hsp60, Hsp70, and Hsp90 were induced by aspirin pretreatment and were suppressed by BAPTA-AM. When HSPs were induced by aspirin, much slighter HS injury was detected. But more serious damages were observed when HSPs were suppressed by BAPTA-AM than those cells exposed to HS without BAPTA-AM, even the myocardial cells have been treated with aspirin in prior. Comparing to other HSPs, HspB1 presented the largest increase after aspirin treatments, 86-fold higher than the baseline (the level before HS). These findings suggested that multiple HSPs participated in aspirin’s anti-heat stress function but HspB1 may contribute the most. Interestingly, during the experiments, we also found that apoptosis rate as well as the oxidative stress indicators (T-SOD and MDA) was not consistently responding to heat stress injury as expected. By selecting from a series of candidates, myocardial cell damage-related enzymes (CK-MB and LDH), cytopathological tests, and necrosis rate (measured by flow cytometry assays) are believed to be reliable indicators to evaluate heat stress injury in chicken’s myocardial cells and they will be used in our further investigations.     

Immune regulation of cardiac fibrosis post myocardial infarction

Pathological changes resulting from myocardial infarction (MI) include extracellular matrix alterations of the left ventricle, which can lead to cardiac stiffness and impair systolic and diastolic function. The signals released from necrotic tissue initiate the immune cascade, triggering an extensive inflammatory response followed by reparative fibrosis of the infarct area. Immune cells such as neutrophils, monocytes, macrophages, mast cells, T-cells, and dendritic cells play distinct roles in orchestrating this complex pathological condition, and regulate the balance between pro-fibrotic and anti-fibrotic responses. This review discusses how molecular signals between fibroblasts and immune cells mutually regulate fibrosis post-MI, and outlines the emerging pharmacological targets and therapies for modulating inflammation and cardiac fibrosis associated with MI.     

Starvation-induced microautophagic vacuoles in rat myocardial cells

During prolonged starvation the heart atrophies and loses protein mass. Debate lingers over the basic mechanisms in the production of negative cardiac protein balance during starvation. The extent to which cardiac proteolysis takes place within the lysosomal vacuolar system is unknown. The present communication examines the starvation-induced changes within the lysosomal system of rat myocardial cells, as studied by means of conventional electron-microscopic techniques. Special attention has been paid to the occurrence of microautophagic vacuoles. It is concluded that during prolonged starvation microautophagic vacuoles appear in rat myocardial cells, suggesting the induction of a microautophagic pathway of lysosomal proteolysis.     

Ultrastructural and immunocharacterization of undifferentiated myocardial cells in the developing mouse heart

The recent discovery of several myogenic cardiac progenitor cells in the post-natal heart suggests that some myocardial cells may remain undifferentiated during embryonic development. In this study, we examined the subcellular characteristics of the embryonic (E) mouse ventricular myocardial cells using transmission electron microscopy (TEM). At the ultrastructural level, we identified three different cell populations within the myocardial layer of the E11.5 heart. These cells were designated as undifferentiated cells (43 +/- 6%), moderately differentiated cells (43 +/- 2%) and mature cardiomyocytes (14 +/- 4%). Undifferentiated cells contained a large nucleus and sparse cytoplasm with no myofibrillar bundles. Moderately differentiated cells contained randomly arranged myofilaments in the cytoplasm. In contrast, mature cardiomyocytes contained well-developed sarcomere structures. We also confirmed the presence of similar undifferentiated cells albeit at low levels in the E16.5 ( approximately 20%) and E18.5 ( approximately 7%) myocardium. Further we used immunogold labeling technique to test whether these distinct cell populations were also positive for markers such as Nkx2.5, ISL1 and ANF. A preponderance of anti-Nkx2.5 label was found in the undifferentiated and moderately differentiated cell types. Anti-ANF label was found only in the cytoplasmic compartment of moderately differentiated and mature myocardial cells. All of the undifferentiated cells were negative for anti-ANF labeling. We did not find immuno-gold labeling with ISL1 in any of the three myocardial cell types. Based on these results, we suggest that embryonic myocardial cell differentiation is a gradual process and undifferentiated cells expressing Nkx2.5 in post-chamber myocardium may represent a progenitor cell population while cells expressing Nkx2.5 and ANF represent differentiating myocytes.     

miRNA-711-SP1-collagen-I pathway is involved in the anti-fibrotic effect of pioglitazone in myocardial infarction

Although microRNAs(miRNAs) have been intensively studied in cardiac fibrosis,their roles in drug-mediated anti-fibrotic therapy are still unknown.Previously,Pioglitazone attenuated cardiac fibrosis and increased miR-711 experimentally.We aimed to explore the role and mechanism of miR-711 in pioglitazone-treated myocardial infarction in rats.Our results showed that pioglitazone significantly reduced collagen-I levels and increased miR-711 expression in myocardial infarction heart.Pioglitazone increased the expression of miR-711 in cardiac fibroblasts,and overexpression of miR-711 suppressed collagen-I levels in angiotensin II(Ang II)-treated or untreated cells.Transfection with antagomir-711 correspondingly abolished the pioglitazone-induced reduction in collagen-I levels.Bioinformatics analysis identified SP1,which directly promotes collagen-I synthesis,as the putative target of miR-711.This was confirmed by luciferase assay and western blot analysis.Additionally,increased SP1 expression was attenuated by pioglitazone in myocardial infarction heart.Furthermore,transfection of antagomir-711 attenuated pioglitazone-reduced SP1 expression in cardiac fibroblasts with or without Ang II stimulation.We conclude that pioglitazone up-regulated miR-711 to reduce collagen-I levels in rats with myocardial infarction.The miR-711-SP1-collagen-I pathway may be involved in the anti-fibrotic effects of pioglitazone.Our findings may provide new strategies for miRNA-based anti-fibrotic drug research.     

Nuclear size of myocardial cells in end-stage cardiomyopathies

OBJECTIVE: To determine the alteration of nuclear size in myocardial cells and the relationship between nuclear size and DNA ploidy classes in normal and cardiomyopathic human hearts. STUDY DESIGN: The study group consisted of 46 hearts obtained at biopsy. These patients had undergone cardiac transplantation for intractable congestive heart failure (18 cases with ischemic cardiomyopathy and 28 cases with idiopathic dilated cardiomyopathy). Another 10 hearts were collected at autopsy and used as control hearts according to preautopsy, autopsy and histology criteria. One hundred fibroblasts and 200 myocytes were evaluated in each ventricle. The nuclear area and DNA content were estimated using image cytometry. RESULTS: End-stage ischemic and dilated cardiomyopathies were characterized by an increase in nuclear size of both the myocyte and nonmyocyte population. The nuclear area of interstitial cells increased about 30% in cardiomyopathic hearts. Augmentation of average nuclear area of myocytes was 1.2-fold in the ischemic group and about 1.5-fold in the dilated group as compared with the control group. Also, a tendency was found for the coefficient of variation of average nuclear area to decrease in the interstitial cell population and increased in the myocyte population in cardiomyopathic situations. Furthermore, the nuclear area of myocytes enlarged as augmentation of nuclear DNA content. The relative nuclear areas of myocytes can be presented as: 2c:4c:8c:16c :32c:64c = 1:1.65:2.75:4.60:7.25:9.18. CONCLUSION: The increase in nuclear size follows either one of two different processes: the first does not involve an increase in DNA content, whereas the second is concomitant with an incremental increase in DNA content. In the first instance, the enlargement of nuclear size is limited. In the second, augmentation of nuclear size can become very impressive. In end-stage ischemic and dilated cardiomyopathies, the nuclear growth of myocytes and interstitial cells may be due to different mechanisms. Enlargement of the nuclear area of myocytes represents a complex process, including simple nuclear hypertrophy, polyploidization and multinucleation. The main pattern of nuclear growth of interstitial cells is nuclear hypertrophy without an increase in DNA content.     

Creation of myocardial fibrosis by transplantation of fibroblasts primed with survival factors

One of the major obstacles in the creation of myocardial fibrosis using fibroblasts is massive cell death after cell injection. To overcome this problem, a method that delivers fibroblasts primed with survival factors was studied. Cardiac fibroblasts were isolated from wild-type male C57BL/6 mice. Female mice were randomly placed into the following three groups: 1) fibroblasts transfected with β-galactosidase-containing adenovirus (control group), 2) fibroblasts treated with a necrosis inhibitor (NI group), and 3) fibroblasts transfected with Akt-containing adenovirus (Akt group). Pretreated cells were transplanted into the recipient heart by direct injection after a thoracotomy. Quantitative real-time PCR and morphometric analysis were performed to investigate the effects of survival factor priming on the induction of cell engraftment and fibrosis. In addition, a canine model was used to investigate the development of fibrosis and conduction modification using autologous dermal fibroblasts. The NI and Akt groups showed a better engraftment rate: 13 (NI group) and 7 (Akt group) times greater at 21 days compared with the control group. Increased fibrosis and conduction delay were also observed in the NI and Akt groups compared with the control group. Survival factor priming increased cellular engraftment and enhanced the efficacy of cell transplantation. Delivery of fibroblasts primed with survival factors might be a promising approach to develop conduction modification as a novel strategy to treat arrhythmias.     

Sonic hedgehog myocardial gene therapy: tissue repair through transient reconstitution of embryonic signaling

Sonic hedgehog (Shh) is a crucial regulator of organ development during embryogenesis. We investigated whether intramyocardial gene transfer of naked DNA encoding human Shh (phShh) could promote a favorable effect on recovery from acute and chronic myocardial ischemia in adult animals, not only by promoting neovascularization, but by broader effects, consistent with the role of this morphogen in embryogenesis. After Shh gene transfer, the hedgehog pathway was upregulated in mammalian fibroblasts and cardiomyocytes. This resulted in preservation of left ventricular function in both acute and chronic myocardial ischemia by enhanced neovascularization, and reduced fibrosis and cardiac apoptosis. Shh gene transfer also enhanced the contribution of bone marrow-derived endothelial progenitor cells to myocardial neovascularization. These data suggest that Shh gene therapy may have considerable therapeutic potential in individuals with acute and chronic myocardial ischemia by triggering expression of multiple trophic factors and engendering tissue repair in the adult heart.     

Human umbilical cord blood cells improve cardiac function after myocardial infarction

Human umbilical cord blood (UCB) contains an abundance of immature stem/progenitor cells and has been clinically used as an alternative to bone marrow transplantation. In addition, cord blood can be obtained non-invasively, in contrast to invasive bone marrow aspiration. We investigated the potential of human UCB CD34(+) cells to improve cardiac function following myocardial infarction. Myocardial infarction was induced in Wistar rats by ligation of the left coronary artery. Either 2x10(5) human UCB CD34(+) cells or equivalent cell-free medium was injected into the injured myocardium of the rats following induction of myocardial infarction. CD34(+) cell transplantation significantly improved ventricular function as compared to the control group. Immunofluorescence staining for human CD34, CD45, and PECAM-1 revealed surviving cells in the myocardium. Our findings suggest that transplanted human cells survived and improved cardiac function following myocardial infarction. These results may show the usefulness of UCB CD34(+) cells for myocardial infarction.     

Reanimation of cultured mammalian myocardial cells during multiple cycles of trypsinization-freezing-thawing

Summary Isolated newborn rat heart cells were cultured for several days, then subjected to a standard procedure of trypsinization, slow freezing in 10% dimethylsulfoxide, storage at −180° to −190°C for 1 to 3 days, rapid thawing, and recultivation. The same cells were recycled two more times in identical procedures. Morphological observations were made by phase-contrast optics and cinematography between each cycle and at the end of every experiment. After comparing the cellular morphology and contractile patterns of treated cells with control cultures, it was shown from the results of more than 15 experiments that most myocardial cells survived the standard procedures of trypsinization, freezing, and thawing and regained the ability to contract normally and form synchronized networks. Evidence was obtained which indicates that a cycle of the standard trypsinization-freezing-thawing procedure permits a recovery rate of 83 to 91% viable cells, with myocardial cells surviving to the same extent as endothelial cells. Of the cells which were nonviable, approximately half the deaths were a result of prior damage by trypsin and half were due to the freezing-thawing procedures. The same proportion of spontaneously contracting myocardial cells was observed after a cycle of trypsinization-freezing-thawing as before. Occasionally, there was a delay of 24 hr after thawing before myocardial cells began contracting spontaneously in vitro. An experiment using Viokase (in place of trypsin) and glycerol (in place of dimethylsulfoxide) excellent results after one cycle of freezing-thawing. It was concluded that myocardial cells exhibited a remarkable recovery from the toxic effects of trypsin and the traumatic influences of multiple freezing-thawing procedures. Endothelial cells in the cultures survived the same procedures and proliferated normally in vitro. Supported by United States Public Health Service Grants NS-09524 from the National Institute of Neurological Diseases and Stroke, CA-12067 from the National Cancer Institute, HL-15103 (Specialized Center of Research) from the National Heart and Lung Institute, and United States Public Health Service Training Grant 5-TO1-DE-0024 from the National Institute of Dental Research. A preliminary report of this paper was presented at the 24th Annual Meeting of the Tissue Culture Association, Boston, June 4–7, 1973, and appears as an abstract: Kasten, F. H. and D. Yip. 1973. Reanimation of cultured mammalian myocardial cells during multiple cycles of freeze-thawing. In Vitro 8: 409.