Transplantation of embryonic stem cells improves cardiac function in postinfarcted rats.

Massive loss of cardiac myocytes after myocardial infarction (MI) is a common cause of heart failure. The present study was designed to investigate the improvement of cardiac function in MI rats after embryonic stem (ES) cell transplantation. MI in rats was induced by ligation of the left anterior descending coronary artery. Cultured ES cells used for cell transplantation were transfected with the marker green fluorescent protein (GFP). Animals in the treated group received intramyocardial injection of ES cells in injured myocardium. Compared with the MI control group injected with an equivalent volume of the cell-free medium, cardiac function in ES cell-implanted MI animals was significantly improved 6 wk after cell transplantation. The characteristic phenotype of engrafted ES cells was identified in implanted myocardium by strong positive staining to sarcomeric alpha-actin, cardiac alpha-myosin heavy chain, and troponin I. GFP-positive cells in myocardium sectioned from MI hearts confirmed the survival and differentiation of engrafted cells. In addition, single cells isolated from cell-transplanted MI hearts showed rod-shaped GFP-positive myocytes with typical striations. The present data demonstrate that ES cell transplantation is a feasible and novel approach to improve ventricular function in infarcted failing hearts.     

Evidence from a genetic fate-mapping study that stem cells refresh adult mammalian cardiomyocytes after injury

An emerging concept is that the mammalian myocardium has the potential to regenerate, but that regeneration might be too inefficient to repair the extensive myocardial injury that is typical of human disease. However, the degree to which stem cells or precursor cells contribute to the renewal of adult mammalian cardiomyocytes remains controversial. Here we report evidence that stem cells or precursor cells contribute to the replacement of adult mammalian cardiomyocytes after injury but do not contribute significantly to cardiomyocyte renewal during normal aging. We generated double-transgenic mice to track the fate of adult cardiomyocytes in a 'pulse-chase' fashion: after a 4-OH-tamoxifen pulse, green fluorescent protein (GFP) expression was induced only in cardiomyocytes, with 82.7% of cardiomyocytes expressing GFP. During normal aging up to one year, the percentage of GFP+ cardiomyocytes remained unchanged, indicating that stem or precursor cells did not refresh uninjured cardiomyocytes at a significant rate during this period of time. By contrast, after myocardial infarction or pressure overload, the percentage of GFP+ cardiomyocytes decreased from 82.8% in heart tissue from sham-treated mice to 67.5% in areas bordering a myocardial infarction, 76.6% in areas away from a myocardial infarction, and 75.7% in hearts subjected to pressure overload, indicating that stem cells or precursor cells had refreshed the cardiomyocytes.     

Cocultures of fetal and adult cardiomyocytes yield rhythmically beating rod shaped heart cells from adult rats

Summary Different models of isolated cardiomyocytes are generally used for biochemical, biophysical, and pharmacological studies. Fetal cardiomyocytes can be easily cultured for several weeks regaining their ability for rhythmical and synchronous contractions. For investigations, differentiated myocytes derived from adult hearts are closer to the in situ situation. Unfortunately, these cells at best exhibit irregular and asynchronous contractions at very low frequencies. Already 1 d after seeding calcium-tolerant rod-shaped adult cardiomyocytes on a suitable substrate, the differentiated cells begin to dedifferentiate forming a confluent monolayer. After 7–10 d their beating activities are like those of fetal cells. Therefore, we tried to combine the advantages of both cell types to achieve fully differentiated cardiomyocytes, rod-shaped and rhythmically beating, isolated from adult hearts. Using contractile fetal cells as a substrate for the adult cardiomyocytes, freshly seeded differentiated adult myocytes are paced by the contraction frequency of the fetal monolayer. As a consequence, the rod-shaped adult cardiomyocytes reach frequencies of more than 140 cycles/min without external electrical stimulation. This model enables us to study cardiomyocytes in a state very similar to the in situ situation with respect to morphology, integrity, and contractile behavior. An abstract of this article was previously published in Eur. J. Cell Biol. 57 (Suppl.36): 86; 1992.     

VEGF enhances functional improvement of postinfarcted hearts by transplantation of ESC-differentiated cells.

Despite considerable advances in medicine, the incidence of heart failure remains high in patients after myocardial infarction (MI). This study investigated the effects of engrafted early-differentiated cells (EDCs) from mouse embryonic stem cells, with or without transfection of vascular endothelial growth factor (VEGF) cDNA (phVEGF(165)), on cardiac function in postinfarcted mice. EDCs were transfected with green fluorescent protein (GFP) cDNA and transplanted into infarcted myocardium. Compared with the MI mice receiving cell-free medium, cardiac function was significantly improved in the MI mice 6 wk after transplantation of EDCs. Moreover, improvement of heart function was significantly greater in the mice implanted with EDCs overexpressing VEGF (EDCs-VEGF) than with EDCs alone. Frozen sections of infarcted myocardium with EDCs or EDCs-VEGF transplantation showed GFP-positive tissue. The area with positive immunostaining for cardiac troponin I and alpha-myosin heavy chain was larger in injured myocardium with EDCs or EDCs-VEGF transplantation than with medium injection. Transplantation of EDCs or EDCs-VEGF significantly increased the number of blood vessels in the MI area. However, the density of capillaries was significantly higher in the EDCs-VEGF animals than in the EDC mice. Double staining for GFP and connexin-43 was positive in injured myocardium with EDC transplantation. Our data demonstrate that engrafted EDCs or EDCs-VEGF regenerated cardiac tissue and significantly improved cardiac function in postinfarcted hearts. The novel EDCs-VEGF synergistic approach may have an important impact on future cell therapy for patients experiencing MI or heart failure.     

Is adult cardiac myocyte still able to proliferate?

Adult cardiac myocytes do not divide anymore. Mechanically overloaded hearts undergo hypertrophy and then fail. Cardiac hypertrophy is mainly caused by myocyte hypertrophy without myocyte proliferation, except during end-stage heart failure. By contrast, non muscular myocardial cells, such as the endothelial cells of the vessels, not only hypertrophy but are also able to proliferate. Recent works have suggested that these new cells are likely to be progenitor cells originating from bone marrow or vascular endothelium. These cells may form chimeras in the donor heart following heart transplantation. It is possible to mimic such an adaptative process by injecting progenitor cells either within the myocardium, or through the coronary circulation. Two type of cells have been utilised so far, namely bone marrow cells and myoblasts (or satellite cells) from skeletal muscles. The first clinical applications after myocardial infarction have been recently reported and showed the safety of the procedure and the possibility of improving myocardial function.     

Isolation, stages of differentiation, and long term maintenance of adult rat myocytes

Although a variety of techniques have been developed to isolate myocytes from adult hearts, the long term viability of such cells has only recently been investigated. In addition, relatively little is known about the stages of differentiation such cells proceed through following isolation. In the present study myocytes were isolated using two techniques, one involving retrograde perfusion via the aorta, and the other involving mechanical "shearing." In addition, several modifications were made to minimize the trauma normal associated with isolating myocytes from adult hearts. Both techniques yielded a high percentage of rod-shaped, quiescent myocytes, although myocytes isolated using the "shearing" method were less likely to remain viable for more than 24 hours. With both techniques those cells which remained viable for more than 24 hours proceeded through an identical pattern of differentiation leading to stable, attached cells which remained viable for up to four weeks. These results demonstrate that with the appropriate isolation techniques it is possible to maintain adult myocardial cells in culture for lengthy periods of time.     

Regional appearance of atrial natriuretic peptide in the ventricles of infarcted rat hearts

The appearance of atrial natriuretic peptide (ANP) in the ventricular myocardium was investigated in rat hearts subjected to severe left ventricular infarction. The left coronary artery was ligated for 1, 2, 3, 4 and 6 days and for 3 weeks, and the tissue was prepared for microscopic examination of immunoreactive ANP and for electron microscopy. In the normal and sham-operated hearts, and in hearts subjected to 1 day of coronary ligation, ANP immunoreactivity was restricted to a few ventricular myocytes of the conduction system. Following 2–3 days of coronary ligation, ANP immunoreactivity was detected in the viable myocardium of the lateral border of the infarct and in a few layers of viable cardiac myocytes located in the subendocardial areas of the ischemic left free ventricular wall. Further, during the following days and after 3 weeks of coronary ligation, a gradient of specific labeling was commonly seen across the lateral border area of the infarct. Thus, the strongest immunoreactivities were present in the cardiac myocytes located adjacent to the non-contracting myocardium. Electron microscopic examination of the immunoreactive cardiac myocytes confirmed the presence of electron-dense specific granules within these cells. The present findings suggest that the increased regional production of ANP within the ventricular myocardium is induced by increased mechanical stretch of the cardiac myocytes, and that this might contribute to the increased release of ANP in myocardial infarction.     

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.     

Mesenchymal stem cells modified with angiopoietin-1 improve remodeling in a rat model of acute myocardial infarction

We used human angiopoietin-1 (hAng1)-modified mesenchymal stem cells (MSCs) to treat acute myocardial infarction (AMI) in rats. The hAng1 gene was transfected into cultured rat MSCs using an adenoviral vector. Five million hAng-transfected MSCs (MSC(Ang1)) or green fluorescent protein transfected MSCs (MSC(GFP)) or PBS only (PBS group) were injected intramyocardially into the inbred Lewis rat hearts immediately after myocardial infarction. MSC(Ang1) survived in the infarcted myocardium, and expressed hAng1 at both mRNA and protein levels. The vascular density was higher in the MSC(Ang1) and MSC(GFP) groups than in the PBS group. The measurements of infarcted ventricular wall thickness, infarction area, and left ventricular diameter indicated that heart remodeling was inhibited and heart function was improved in both the MSC(Ang1) and MSC(GFP) groups. However, in contrast to the MSC(GFP) group, the MSC(Ang1) group showed enhanced angiogenesis and arteriogenesis (by 11-35%), infarction area was reduced by 30% and the left ventricular wall was 46% thicker (P<0.05). The results indicated that hAng1-modified MSCs improved heart function, followed by angiogenic effects in salvaging ischemic myocardium and reduced cardiac remodeling.     

Extensive scar formation and regression during heart regeneration after cryoinjury in zebrafish

The zebrafish heart has the capacity to regenerate after ventricular resection. Although this regeneration model has proved useful for the elucidation of certain regeneration mechanisms, it is based on the removal of heart tissue rather than its damage. Here, we characterize the cellular response and regenerative capacity of the zebrafish heart after cryoinjury, an alternative procedure that more closely models the pathophysiological process undergone by the human heart after myocardial infarction (MI). Localized damage was induced in 25% of the ventricle by cryocauterization (CC). During the first 24 hours post-injury, CC leads to cardiomyocyte death within the injured area and the near coronary vasculature. Cell death is followed by a rapid proliferative response in endocardium, epicardium and myocardium. During the first 3 weeks post-injury cell debris was cleared and the injured area replaced by a massive scar. The fibrotic tissue was subsequently degraded and replaced by cardiac tissue. Although animals survived CC, their hearts showed nonhomogeneous ventricular contraction and had a thickened ventricular wall, suggesting that regeneration is associated with processes resembling mammalian ventricular remodeling after acute MI. Our results provide the first evidence that, like mammalian hearts, teleost hearts undergo massive fibrosis after cardiac damage. Unlike mammals, however, the fish heart can progressively eliminate the scar and regenerate the lost myocardium, indicating that scar formation is compatible with myocardial regeneration and the existence of endogenous mechanisms of scar regression. This finding suggests that CC-induced damage in zebrafish could provide a valuable model for the study of the mechanisms of scar removal post-MI.     

Expression of cardiomyocytic markers on adipose tissue-derived cells in a murine model of acute myocardial injury

Animal and early clinical studies have provided evidence suggesting that intracoronary administration of autologous bone marrow-derived cells results in improved outcome following myocardial infarction. Animal studies with cultured marrow stromal cells (MSC) have provided similar data. Cells with properties that are similar to MSC have been identified in adipose tissue. Other groups have demonstrated in vivo differentiation of adipose tissue-derived cells (ADC) into cells exhibiting biochemical and functional markers of cardiac myocytes, including spontaneous beating.Based on these observations, the objective of the present study was to determine whether ADC might undergo similar differentiation in vivo in the context of myocardial injury.ADC were isolated from subcutaneous adipose tissue of Rosa26 mice (which express the beta-galactosidase transgene in almost every tissue) and injected into the intraventricular chamber of B6129S recipient mice immediately following induction of myocardial cryoinjury. Groups of recipients were euthanized at 24 hours, 7 and 14 days post surgery and examined for the presence of donor-derived cells within the heart.Beta-gal positive cells were identified in the infarcts of ADC-treated animals. No staining was observed in uninjured myocardium or in infarcts of control animals. Immunohistochemical analysis revealed co-expression of beta-gal with Myosin Heavy Chain, Nkx2.5 and with Troponin I. Co-expression of beta-galactosidase with Connexin 43, CD31, von Willebrand factor, MyoD or CD45 was not detected.Thus, these data indicate that adipose tissue contains a population of cells that has the ability to engraft injured myocardium and that this engraftment is associated with expression of cardiomyocytic markers by donor-derived cells.     

Bone marrow origin of cells with capacity for homing and differentiation to esophageal squamous epithelium

Our goal was to determine whether esophageal progenitor cells could be isolated from adult mouse esophagus or bone marrow and shown to home to and proliferate in the irradiated esophagus of recipient mice. Esophageal progenitor cells were isolated from adult male C3H/HeNsd or C57BL/6J green fluorescent protein (GFP(+)) mice by a serial in vitro preplate technique or the technique of side population cell sorting. When injected intravenously (i.v.), these cells homed to the 30-Gy-irradiated esophagus of GFP(-) female recipient mice and formed donor-origin esophageal foci. GFP(+) whole murine bone marrow cells injected i.v. also formed donor-origin esophageal squamous cell foci and protected recipient GFP(-) mice from upper-body irradiation in a cell dose-dependent manner. Marrow chimeric GFP(-) mice reconstituted with GFP(+) cells showed migration of GFP(+) marrow cells to the esophagus after 30 Gy irradiation. Purified esophageal progenitor cells isolated from first-generation preplate cell recipients engrafted after i.v. injection to the esophagus of second-generation-irradiated recipient mice. These data establish that esophageal progenitor cells can home to the irradiated esophagus and show limited differentiation capacity to squamous epithelium.     

Altered interleukin-1 receptor antagonist and interleukin-18 mRNA expression in myocardial tissues of patients with dilatated cardiomyopathy

Interleukin-1 (IL-1) is a potent regulator of cell proliferation, inflammation, and contraction of cardiovascular cells. It has been proposed that the IL-1/IL-1ra (IL-1 receptor antagonist) ratio influences these functions. Other members of the IL-1 family and the related caspase-1 also contribute to regulation of IL-1-mediated functions. We determined the mRNA expression of caspase-1, caspase-3, IL-1alpha , IL-1beta , IL-18, IL-1 receptor type I (IL-1-RI), and IL-1ra in left ventricle tissue of hearts from patients with ischemic or dilated cardiomyopathy (ICM or DCM) and in control tissues from unused donor transplant hearts in RT-PCR experiments. We show that the expression of caspase-1, caspase-3, IL-1beta , and IL-1-RI mRNA was not different between patients and control tissues. Furthermore, we did not find detectable amounts of IL-1alpha mRNA in any of these adult myocardial tissues. On the other hand, expression of IL-18 RNA was lower in myocardium of both patient groups compared with control hearts. Furthermore, IL-1ra mRNA expression was significantly lower in tissues of DCM patients compared with ICM patients and controls. This was in line with a trend towards lower IL-1ra protein levels in myocardial tissues of DCM patients. In contrast with the adult tissues discussed above, which did not express IL-1alpha mRNA, commercially available human fetal tissue expressed IL-1alpha mRNA. On the other hand IL-1beta mRNA was present in fetal and in adult human heart tissue. Our data provide evidence for an altered ratio of IL-1/IL-1ra in DCM patients. This dysregulation may contribute to pathogenesis and/or progression of heart disease by modulating the otherwise balanced IL-1-mediated functions in cardiovascular cells.     

Engineered heart tissue grafts improve systolic and diastolic function in infarcted rat hearts

The concept of regenerating diseased myocardium by implantation of tissue-engineered heart muscle is intriguing, but convincing evidence is lacking that heart tissues can be generated at a size and with contractile properties that would lend considerable support to failing hearts. Here we created large (thickness/diameter, 1-4 mm/15 mm), force-generating engineered heart tissue from neonatal rat heart cells. Engineered heart tissue formed thick cardiac muscle layers when implanted on myocardial infarcts in immune-suppressed rats. When evaluated 28 d later, engineered heart tissue showed undelayed electrical coupling to the native myocardium without evidence of arrhythmia induction. Moreover, engineered heart tissue prevented further dilation, induced systolic wall thickening of infarcted myocardial segments and improved fractional area shortening of infarcted hearts compared to controls (sham operation and noncontractile constructs). Thus, our study provides evidence that large contractile cardiac tissue grafts can be constructed in vitro, can survive after implantation and can support contractile function of infarcted hearts.     

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.     

Cardiac tissue engineering: regeneration of the wounded heart

New solutions are needed to regenerate hearts damaged by myocardial infarction, to overcome bad prognosis of patients with heart failure, and to address the shortage of heart donors. In the past few years, cardiac tissue engineering has emerged as a new and ambitious approach that combines knowledge from material chemistry with cell biology and medicine. In this short review, we present an overview on the most promising materials and cell-therapy strategies used in the past few years for the regeneration of the wounded heart.     

Changes in the contractile state, fine structure and metabolism of cardiac muscle cells during the development of rigor mortis

Transmural slices from the left anterior papillary muscle of dog hearts were maintained for 120 min in a moist atmosphere at 37 degrees C. At 15-min intervals tissue samples were taken for estimation of adenosine triphosphate (ATP) and glucose-6-phosphate (G6P) and for electron microscopic examination. At the same time the deformability under standard load of comparable regions of an adjacent slice of tissue was measured. ATP levels fell rapidly during the first 45 to 75 min after excision of the heart. During a subsequent further decline in ATP, the mean deformability of myocardium fell from 30 to 12% indicating the development of rigor mortis. Conversely, G6P levels increased during the first decline in adenosine triphosphate but remained relatively steady thereafter. Whereas many of the myocardial cells fixed after 5 min contracted on contact with glutaraldehyde, all cells examined after 15 to 40 min were relaxed. A progressive increase in the proportion of contracted cells was observed during the rapid increase in myocardial rigidity. During this late contraction the cells showed morphological evidence of irreversible injury. These findings suggest that ischaemic myocytes contract just before actin and myosin become strongly linked to maintain the state of rigor mortis.     

Apoptosis in heart failure: a tale of heightened expectations, unfulfilled promises and broken hearts...

Although apoptosis contributes significantly to remodeling of the fetal heart during evolution of cardiac chambers and correct routing of the great vessels, it has been believed that apoptosis does not occur in terminally differentiated adult cardiac muscle cells. However, apoptosis has recently been demonstrated in animal models of heart failure as well as in explanted hearts from patients with end-stage heart failure undergoing cardiac transplantation. Ventricular dilatation and neurohormonal activation, the hall-marks of heart failure, lead to upregulation of transctription factors, induce muscle cell hypertrophy and prepare cells for entry into the cell-division cycle. However, since terminally differentiated myocytes cannot divide, they die by apoptosis. It has been proposed that low-grade apoptosis in failing heart may be responsible for inexorable decline in left ventricular function. Better understanding of the molecular and cellular basis of apoptosis in the failing myocardium may lead to development of strategies aimed at preventing progressive myocyte loss and deterioration in left ventricular function.     

Neovascularization of ischemic myocardium by human bone-marrow-derived angioblasts prevents cardiomyocyte apoptosis, reduces remodeling and improves cardiac function

Left ventricular remodeling is a major cause of progressive heart failure and death after myocardial infarction. Although neoangiogenesis within the infarcted tissue is an integral component of the remodeling process, the capillary network is unable to support the greater demands of the hypertrophied myocardium, resulting in progressive loss of viable tissue, infarct extension and fibrous replacement. Here we show that bone marrow from adult humans contains endothelial precursors with phenotypic and functional characteristics of embryonic hemangioblasts, and that these can be used to directly induce new blood vessel formation in the infarct-bed (vasculogenesis) and proliferation of preexisting vasculature (angiogenesis) after experimental myocardial infarction. The neoangiogenesis resulted in decreased apoptosis of hypertrophied myocytes in the peri-infarct region, long-term salvage and survival of viable myocardium, reduction in collagen deposition and sustained improvement in cardiac function. The use of cytokine-mobilized autologous human bone-marrow-derived angioblasts for revascularization of infarcted myocardium (alone or in conjunction with currently used therapies) has the potential to significantly reduce morbidity and mortality associated with left ventricular remodeling.     

Stem cell transplantation: potential impact on heart failure

Cell transplantation is a promising new modality in treating damaged myocardium after myocardial infarction and in preventing postmyocardial infarction LV remodelling. Two strategies are plausible: the first uses adult tissue stem cells to replace the scar tissues and amend the lost myocardium, whilst the second strategy uses embryonic stem cells in an attempt to regenerate myocardium and/or blood vessels.