Determination of cell types and numbers during cardiac development in the neonatal and adult rat and mouse

Cardiac fibroblasts, myocytes, endothelial cells, and vascular smooth muscle cells are the major cellular constituents of the heart. The aim of this study was to observe alterations in myocardial cell populations during early neonatal development in the adult animal and to observe any variations of the cardiac cell populations in different species, specifically, the rat and mouse. Whole hearts were isolated from either mice or rats during the neonatal and adult stages of development, and single cell suspensions were prepared via sequential collagenase digestion. Heterogeneous cell populations were immunolabeled for specific cell types and analyzed using fluorescence-activated cell sorting (FACS). In addition, the left ventricle, right ventricle, and septa were isolated, fixed, and sectioned for morphometric analyses. These same cardiac regions were also analyzed using FACS. We observed that the adult murine myocardium is composed of approximately 56% myocytes, 27% fibroblasts, 7% endothelial cells, and 10% vascular smooth muscle cells. Moreover, our morphometric and FACS data demonstrated similar percentages in the three regions examined. During murine neonatal cardiac development, we observed a marked increase in numbers of cardiac fibroblasts and a resultant decrease in percentages of myocytes in late neonatal development (day 15). Finally, FACS analyses of the rat heart during development displayed similar results in relation to increases in cardiac fibroblasts during development; however, cell populations in the rat differed markedly from those observed in the mouse. Taken together, these data enabled us to establish a homeostatic model for the myocardium that can be compared with genetic and cardiac disease models.     

Novel 3D culture system for study of cardiac myocyte development

Insufficient myocardial repair after pathological processes contributes to cardiovascular disease, which is a major health concern. Understanding the molecular mechanisms that regulate the proliferation and differentiation of cardiac myocytes will aid in designing therapies for myocardial repair. Models are needed to delineate these molecular mechanisms. Here we report the development of a model system that recapitulates many aspects of cardiac myocyte differentiation that occur during early cardiac development. A key component of this model is a novel three-dimensional tubular scaffold engineered from aligned type I collagen strands. In this model embryonic ventricular myocytes undergo a transition from a hyperplastic to a quiescent phenotype, display significant myofibrillogenesis, and form critical cell-cell connections. In addition, embryonic cardiac myocytes grown on the tubular substrate have an aligned phenotype that closely resembles in vivo neonatal ventricular myocytes. We propose that embryonic cardiac myocytes grown on the tube substrate develop into neonatal cardiac myocytes via normal in vivo mechanisms. This model will aid in the elucidation of the molecular mechanisms that regulate cardiac myocyte proliferation and differentiation, which will provide important insights into myocardial development.     

Myotrophin: purification of a novel peptide from spontaneously hypertensive rat heart that influences myocardial growth

Mechanisms involved in the development or the regression of myocardial hypertrophy cannot be fully explained as responses to blood pressure control alone. We had hypothesized that the development of hypertrophy is initiated by a signal (mechanical or humoral) to the myocardium, which in turn produces a soluble factor that triggers protein synthesis and initiates myocardial growth. Using the stimulation of protein synthesis in isolated cardiac myocytes obtained from normal rat hearts as an assay system, we have identified a soluble factor from the hypertrophied myocardium of spontaneously hypertensive rats. This factor, which has been purified to apparent homogeneity, is a protein of 12 kDa. The sequence of three internally liberated peptides containing 7-24 residues was determined. Based on the determined amino acid sequences of these peptides, this factor (designated myotrophin) appears to be a novel protein that shows no homology with any previously described growth factors. Myotrophin is present in human, dog, and rat hypertrophied hearts (28-35% stimulation of protein synthesis over control) and in small amounts in normal hearts (5-6% stimulation). Myotrophin causes two dose-dependent effects in neonatal cardiac myocytes: an increase in the surface area of the myocyte and the appearance of organized myofibrils, which become apparent within 48 h. Myotrophin may play an important role in the pathogenesis of cardiac hypertrophy as well as in the normal development of cardiac myocytes.     

CUGBP1, a crucial factor for heart regeneration in mice

The mammalian heart is capable of achieving perfect regeneration following cardiac injury through sustained cardiomyocyte proliferation during the early period after birth. However, this regenerative capacity is lost by postnatal day 7 and throughout adulthood. CUGBP1 is critical for normal cardiac development but its role in heart regeneration remains unclear. Cardiac CUGBP1 levels are high in the early postnatal period and soon downregulate to adult levels within 1 week following birth in mice. The simultaneously diminished regenerative capacity and CUGBP1 levels by postnatal day lead us to hypothesize that CUGBP1 may be beneficial in heart regeneration. In this study, the function of CUGBP1 in heart regeneration was tested by a heart apex resection mouse model. We demonstrate that cardiac inactivation of CUGBP1 impairs neonatal heart regeneration at P1, in turn, replenishment of CUGBP1 levels prolong regenerative potential at P8 and P14. Furthermore, our results imply that the Wnt/β-catenin signaling and GATA4 involve in the CUGBP1 modulated neonatal heart regeneration. Altogether, our findings support CUGBP1 as a key factor promoting post-injury heart regeneration and provide a potential therapeutic method for heart disease.Subject terms: Cell proliferation, Self-renewal     

Cyclin A2 mediates cardiomyocyte mitosis in the postmitotic myocardium

Cell cycle withdrawal limits proliferation of adult mammalian cardiomyocytes. Therefore, the concept of stimulating myocyte mitotic divisions has dramatic implications for cardiomyocyte regeneration and hence, cardiovascular disease. Previous reports describing manipulation of cell cycle proteins have not shown induction of cardiomyocyte mitosis after birth. We now report that cyclin A2, normally silenced in the postnatal heart, induces cardiac enlargement because of cardiomyocyte hyperplasia when constitutively expressed from embryonic day 8 into adulthood. Cardiomyocyte hyperplasia during adulthood was coupled with an increase in cardiomyocyte mitosis, noted in transgenic hearts at all time points examined, particularly during postnatal development. Several stages of mitosis were observed within cardiomyocytes and correlated with the nuclear localization of cyclin A2. Magnetic resonance analysis confirmed cardiac enlargement. These results reveal a previously unrecognized critical role for cyclin A2 in mediating cardiomyocyte mitosis, a role that may significantly impact upon clinical treatment of damaged myocardium.     

Contemporary perspective on endogenous myocardial regeneration

Considering the complex nature of the adult heart, it is no wonder that innate regenerative processes, while maintaining adequate cardiac function, fall short in myocardial jeopardy. In spite of these enchaining limitations, cardiac rejuvenation occurs as well as restricted regeneration. In this review, the background as well as potential mechanisms of endogenous myocardial regeneration are summarized. We present and analyze the available evidence in three subsequent steps. First, we examine the experimental research data that provide insights into the mechanisms and origins of the replicating cardiac myocytes, including cell populations referred to as cardiac progenitor cells (i.e., c-kit+ cells). Second, we describe the role of clinical settings such as acute or chronic myocardial ischemia, as initiators of pathways of endogenous myocardial regeneration. Third, the hitherto conducted clinical studies that examined different approaches of initiating endogenous myocardial regeneration in failing human hearts are analyzed. In conclusion, we present the evidence in support of the notion that regaining cardiac function beyond cellular replacement of dysfunctional myocardium via initiation of innate regenerative pathways could create a new perspective and a paradigm change in heart failure therapeutics. Reinitiating cardiac morphogenesis by reintroducing developmental pathways in the adult failing heart might provide a feasible way of tissue regeneration. Based on our hypothesis “embryonic recall”, we present first supporting evidence on regenerative impulses in the myocardium, as induced by developmental processes.     

Double strand DNA breaks in C57B1 and mdx mice cardiomyocytes after dynamical stress

The survival of cardiac myocytes under different physiological and pathological conditions presents pressing problem. mdx mice cardiac myocytes are a promising model of cell survival under condition of oxidative stress. Our early results have shown that some part of mdx mice cardiomyocytes is in early stage of apoptosis (Kazakov, Mikhailov, 2001). But the development of cell death with loss of apoptotical cardiac myocytes occurs only after dynamical stress (bathing during 5 min) (Mikhailov et al., 2001). DNA endonuclease activity in the myocardium and low level of cardiac myocytes death during usual being of mdx mice allowed us to suggest DNA repair to be involved in the survival of mdx mice cardiac myocytes (Mikhailov et al., 2003). To confirm the suggestion we have studied the dynamics of formation and elimination of double strand DNA breaks in mdx myocardium cells after 5 min bathing at 12 degrees C. To visualise double strand DNA breaks formation cell nuclei were stained by monoclonal antibodies to phosphorylated H2Ax histone and to mouse PAP. Double staining with monoclonal anti-H2Ax antibodies and monoclonal anti-a-actin antibodies were used to separate cardiac myocytes from other myocardial cell types. The results showed that during 40 min after stress the deal of H2Ax-positive nuclei in mdx myocardium cells grew up to 41.7 +/- 11.4 % as compared with the initial control level of 6.7 +/- 0.2 %. The number of H2Ax-positive nuclei in these cells decreased after 24 h to 5.7 +/- 0.2 %. The quantity of tagged myocardium cell nuclei in C57B1/6 mice after stress was negligible and did not go beyond 0.01%. Dynamical stress also induced the increase in the rate of 3H-Thymidine incorporation by mdx mice cardiac myocytes from 0.3 +/- 0.3 up to 2.9 +/- 0.5 %. There was not change in the rate of 3H-Thymidine incorporation by cardiac myocytes in C57B1/6 mice. The numbers of labelled nuclei before and after stress were 0.2 and 0.3 %, correspondingly. The number of 3H-Thymidine labelled mdx cardiac myocytes fell down up to 0.4 +/- 0.2 % within 24 h after stress; the level of labelled C57B1/6 cardiac myocytes did not change. We have concluded that 3H-Thymidine incorporation into cardiac myocytes nuclei and staining of these nuclei by monoclonal antiboies phosphorylated H2Ax histone after stress demonstrate rather DNA repair than cardiomyocytes entry into the cell cycle.     

Deficiency in endothelial nitric oxide synthase impairs myocardial angiogenesis

We recently demonstrated that mice deficient in endothelial nitric oxide (NO) synthase (eNOS) have congenital septal defects and postnatal heart failure. However, the mechanisms by which eNOS affects heart development are not clear. We hypothesized that deficiency in eNOS impairs myocardial angiogenesis. Myocardial capillary densities were measured morphometrically in neonatal mouse hearts. In vitro tube formation on Matrigel was investigated in cardiac endothelial cells. In vivo myocardial angiogenesis was performed by implanting Matrigel in the left ventricular myocardium. Myocardial capillary densities and VEGF mRNA expression were decreased in neonatal eNOS(-/-) compared with neonatal wild-type mice (P < 0.01). Furthermore, in vitro tube formation from cardiac endothelial cells and in vivo myocardial angiogenesis were attenuated in eNOS(-/-) compared with wild-type mice (P < 0.01). In vitro tube formation was inhibited by N(G)-nitro-l-arginine methyl ester in wild-type mice and restored by a NO donor, diethylenetriamine-NO, in eNOS(-/-) mice (P < 0.05). In conclusion, deficiency in eNOS decreases VEGF expression and impairs myocardial angiogenesis and capillary development. Decreased myocardial angiogenesis may contribute to cardiac abnormalities during heart development in eNOS(-/-) mice.     

MLP参与心肌肥大发生过程与Calcineurin/NFAT信号通路有关

心肌肥大是心肌细胞面对多种病理刺激时的共同反应,以心肌细胞体积增大和胚胎期基因的重新表达为标志.心肌发育调控基因肌肉LIM蛋白(muscle LIM protein,MLP)的表达异常与心肌肥大有关.为研究MLP参与心肌肥大发生的分子机制,采用去氧肾上腺素（phenylephrine, PE）刺激大鼠原代培养心肌细胞,建立心肌细胞肥大模型,采用RNAi技术敲减MLP的表达,分析MLP与肥大信号通路钙调神经磷酸酶（calcineurin）/活化T细胞核因子（nuclear factor of activated T-cells, NFAT）的关系.结果显示, 原代培养的心肌细胞经一定浓度的PE刺激后细胞表面积增加,肥大标志蛋白ANP、BNP表达增高,并伴有MLP表达上调. RNAi方法敲减MLP的表达则明显抑制PE诱导的心肌细胞表面积增加和BNP表达增高,并且直接 影响NFAT的转录激活活性,提示MLP与心肌肥大的发生密切相关,并且可能是通过calcineurin/NFAT信号通路而参与心肌肥大的发生.     

Mitotic activity of the myocardium in early ontogenesis of rabbits after minor mechanical injury to the heart

The data are provided on proliferative activity of myocytes in rabbit embryos and neonates. In rabbit embryos, in which myocardial regeneration is effected at the cellular level, mitoses of myocytes are largely important for myocyte proliferation. In rabbit neonates which do not show any complete regeneration of the myocardium, mitoses of myocytes are of primary importance for myocardial polyploidy. Minor mechanical injury to rabbit myocardium in early ontogenesis contributes to activation of the processes of hear muscle differentiation.     

Fas pathway is a critical mediator of cardiac myocyte death and MI during ischemia-reperfusion in vivo

Fas is a widely expressed cell surface receptor that can initiate apoptosis when activated by its ligand (FasL). Whereas Fas abundance on cardiac myocytes increases in response to multiple pathological stimuli, direct evidence supporting its role in the pathogenesis of heart disease is lacking. Moreover, controversy exists even as to whether Fas activation induces apoptosis in cardiac myocytes. In this study, we show that adenoviral overexpression of FasL, but not beta-galactosidase, results in marked apoptosis both in cultures of primary neonatal cardiac myocytes and in the myocardium of intact adult rats. Myocyte killing by FasL is a specific event, because it does not occur in lpr (lymphoproliferative) mice that lack functional Fas. To assess the contribution of the Fas pathway to myocardial infarction (MI) in vivo, lpr mice were subjected to 30 min of ischemia followed by 24 h of reperfusion. Compared with wild-type mice, lpr mice exhibited infarcts that were 62.3% smaller with 63.8% less myocyte apoptosis. These data provide direct evidence that activation of Fas can induce apoptosis in cardiac myocytes and that Fas is a critical mediator of MI due to ischemia-reperfusion in vivo.     

Synergistic effects of prenatal hypoxia and postnatal high-fat diet in the development of cardiovascular pathology in young rats

We have previously shown that adult offspring exposed to a prenatal hypoxic insult leading to intrauterine growth restriction (IUGR) are more susceptible to cardiovascular pathologies. Our objectives were to evaluate the interaction between hypoxia-induced IUGR and postnatal diet in the early development of cardiovascular pathologies. Furthermore, we sought to determine whether the postnatal administration of resveratrol could prevent the development of cardiovascular disorders associated with hypoxia-induced IUGR. On day 15 of pregnancy, Sprague-Dawley rats were randomly assigned to hypoxia (11.5% oxygen), to induce IUGR, or normal oxygen (control) groups. For study A, male offspring (3 wk of age) were randomly assigned a low-fat (LF, <10% fat) or a high-fat (HF, 45% fat) diet. For study B, offspring were randomized to either HF or HF+resveratrol diets. After 9 wk, cardiac and vascular functions were evaluated. Prenatal hypoxia and HF diet were associated with an increased myocardial susceptibility to ischemia. Blood pressure, in vivo cardiac function, and ex vivo vascular function were not different among experimental groups; however, hypoxia-induced IUGR offspring had lower resting heart rates. Our results suggest that prenatal insults can enhance the susceptibility to a second hit such as myocardial ischemia, and that this phenomenon is exacerbated, in the early stages of life by nutritional stressors such as a HF diet. Supplementing HF diets with resveratrol improved cardiac tolerance to ischemia in offspring born IUGR but not in controls. Thus we conclude that the additive effect of prenatal (hypoxia-induced IUGR) and postnatal (HF diet) factors can lead to the earlier development of cardiovascular pathology in rats, and postnatal resveratrol supplementation prevented the deleterious cardiovascular effects of HF diet in offspring exposed to prenatal hypoxia.     

FGF-16 is released from neonatal cardiac myocytes and alters growth-related signaling: a possible role in postnatal development

FGF-16 has been reported to be preferentially expressed in the adult rat heart. We have investigated the expression of FGF-16 in the perinatal and postnatal heart and its functional significance in neonatal rat cardiac myocytes. FGF-16 mRNA accumulation was observed by quantitative RT-PCR between neonatal days 1 and 7, with this increased expression persisting into adulthood. FGF-2 has been shown to increase neonatal rat cardiac myocyte proliferative potential via PKC activation. Gene array analysis revealed that FGF-16 inhibited the upregulation by FGF-2 of cell cycle promoting genes including cyclin F and Ki67. Furthermore, the CDK4/6 inhibitor gene Arf/INK4A was upregulated with the combination of FGF-16 and FGF-2 but not with either factor on its own. The effect on Ki67 was validated by protein immunodetection, which also showed that FGF-16 significantly decreased FGF-2-induced Ki67 labeling of cardiac myocytes, although it alone had no effect on Ki67 labeling. Inhibition of p38 MAPK potentiated cardiac myocyte proliferation induced by FGF-2 but did not alter the inhibitory action of FGF-16. Receptor binding assay showed that FGF-16 can compete with FGF-2 for binding sites including FGF receptor 1. FGF-16 had no effect on activated p38, ERK1/2, or JNK/SAPK after FGF-2 treatment. However, FGF-16 inhibited PKC-alpha and PKC-epsilon activation induced by FGF-2 and, importantly, IGF-1. Collectively, these data suggest that expression and release of FGF-16 in the neonatal myocardium interfere with cardiac myocyte proliferative potential by altering the local signaling environment via modulation of PKC activation and cell cycle-related gene expression.     

Fetal myocardium in the kidney capsule: an in vivo model of repopulation of myocytes by bone marrow cells

Debate surrounds the question of whether the heart is a post-mitotic organ in part due to the lack of an in vivo model in which myocytes are able to actively regenerate. The current study describes the first such mouse model--a fetal myocardial environment grafted into the adult kidney capsule. Here it is used to test whether cells descended from bone marrow can regenerate cardiac myocytes. One week after receiving the fetal heart grafts, recipients were lethally irradiated and transplanted with marrow from green fluorescent protein (GFP)-expressing C57Bl/6J (B6) donors using normal B6 recipients and fetal donors. Levels of myocyte regeneration from GFP marrow within both fetal myocardium and adult hearts of recipients were evaluated histologically. Fetal myocardium transplants had rich neovascularization and beat regularly after 2 weeks, continuing at checkpoints of 1, 2, 4, 6, 8 and12 months after transplantation. At each time point, GFP-expressing rod-shaped myocytes were found in the fetal myocardium, but only a few were found in the adult hearts. The average count of repopulated myocardium with green rod-shaped myocytes was 996.8 cells per gram of fetal myocardial tissue, and 28.7 cells per adult heart tissue, representing a thirty-five fold increase in fetal myocardium compared to the adult heart at 12 months (when numbers of green rod-shaped myocytes were normalized to per gram of myocardial tissue). Thus, bone marrow cells can differentiate to myocytes in the fetal myocardial environment. The novel in vivo model of fetal myocardium in the kidney capsule appears to be valuable for testing repopulating abilities of potential cardiac progenitors.     

Western array analysis of cell cycle protein changes during the hyperplastic to hypertrophic transition in heart development

Cardiac myocytes proliferate most rapidly during the hyperplastic phase of heart development; however, the level of cell cycle activity is drastically down regulated after birth. Further growth of the heart is achieved by hypertrophic growth of cardiac myocytes. The mechanism that controls the switch from hyperplastic proliferation to hypertrophic growth in cardiac myocytes is unknown. Understanding this fundamental mechanism of cardiac myocyte biology would be most beneficial for studies directed towards myocardial regeneration. In this study, we identified changes in the expression of proteins involved in cell cycle regulation during the hyperplastic to hypertrophic transition of cardiac myocytes. Using a high-throughput immunoblotting technique, we examined 200+ proteins in primary cultures of cardiac myocytes at different developmental time points to determine the important regulators of this transition. In addition, we also analyzed samples from an immortalized cardiac myocyte cell line to compare expression levels of cell cycle regulatory proteins to our primary cultures. Our findings by this uncovered proteomic screen identified several potential key regulatory proteins and provide insight into the important components of cardiac myocyte cell cycle regulation.     

Over Expression of Plk1 Does Not Induce Cell Division in Rat Cardiac Myocytes In Vitro

Background

Mammalian cardiac myocytes withdraw from the cell cycle during post-natal development, resulting in a non-proliferating, fully differentiated adult phenotype that is unable to repair damage to the myocardium, such as occurs following a myocardial infarction. We and others previously have shown that forced expression of certain cell cycle molecules in adult cardiac myocytes can promote cell cycle progression and division in these cells. The mitotic serine/threonine kinase, Polo-like kinase-1 (Plk1), is known to phosphorylate and activate a number of mitotic targets, including Cdc2/Cyclin B1, and to promote cell division.

Principal Findings

The mammalian Plk family are all differentially regulated during the development of rat cardiac myocytes, with Plk1 showing the most dramatic decrease in both mRNA, protein and activity in the adult. We determined the potential of Plk1 to induce cell cycle progression and division in cultured rat cardiac myocytes. A persistent and progressive loss of Plk1 expression was observed during myocyte development that correlated with the withdrawal of adult rat cardiac myocytes from the cell cycle. Interestingly, when Plk1 was over-expressed in cardiac myocytes by adenovirus infection, it was not able to promote cell cycle progression, as determined by cell number and percent binucleation.

Conclusions

We conclude that, in contrast to Cdc2/Cyclin B1 over-expression, the forced expression of Plk1 in adult cardiac myocytes is not sufficient to induce cell division and myocardial repair.