Summary Background C-kit+ lineage− cardiac stem cells (CSCs) improve postinfarction left ventricular (LV) dysfunction in animals; however, their efficacy in humans is unknown. Methods In February 2009, we began SCIPIO (Stem Cell Infusion in Patients with Ischemic CardiOmyopathy), a Phase I, randomized, open-label trial of CSCs in patients with postinfarction LV dysfunction (ejection fraction [EF] ≤ 40%) who underwent coronary bypass surgery. Autologous CSCs were isolated from the right atrial appendage and re-infused intracoronarily 4 ± 1 months after surgery; controls received no treatment. In Stage A, 9 treated and 4 control patients were consecutively enrolled to assess the feasibility and short-term safety of CSCs. Then, in Stage B, patients were randomized to the treated or control arm in a 2:3 ratio using a block randomization scheme and a block size of five. Primary (safety) and secondary (efficacy) endpoints were assessed at serial times after enrollment. Findings Autologous CSCs were successfully isolated and expanded in 80 out of 81 patients. In 16 treated patients, no CSC-related adverse effects have been observed. LVEF (3D echocardiography) increased from 30.3 ± 1.9% before CSC infusion to 38.5 ± 2.8% at 4 months after infusion, (P=0.001, n=14). This was associated with an improvement in regional wall motion score index (echocardiography) (1.91 ± 0.09 vs. 1.73 ± 0.09, P=0.005), NYHA functional class (2.19 ± 0.16 vs. 1.63 ± 0.16, P=0.003), and quality of life (MLHFQ score, 46.44 ± 5.22 vs. 26.69 ± 4.92, P<0.0001). In contrast, in 7 control patients, none of these variables changed appreciably during the corresponding time-interval. Importantly, the salubrious effects of CSCs were even more pronounced at 1 year (e.g., LVEF increased by 12.3 ± 2.1% vs. pre-CSCs, P=0.0007, n=8), suggesting that CSCs continue to improve LV function beyond the first 4 months. In the 7 treated patients in whom cardiac magnetic resonance (cMR) imaging could be performed, infarct size decreased by 7.8 ± 1.7 g (23.8%) at 4 months (P=0.004) and 9.8 ± 3.5 g (30.3%) at 1 year (P=0.04). Interpretation These initial results in humans are very encouraging, and suggest that infusion of autologous CSCs is effective in improving LV systolic function and reducing infarct size in patients with heart failure.
BACKGROUND Although progenitor cells have been described in distinct anatomical regions of the lung, description of resident stem cells has remained elusive. METHODS Surgical lung-tissue specimens were studied in situ to identify and characterize human lung stem cells. We defined their phenotype and functional properties in vitro and in vivo. RESULTS Human lungs contain undifferentiated human lung stem cells nested in niches in the distal airways. These cells are self-renewing, clonogenic, and multipotent in vitro. After injection into damaged mouse lung in vivo, human lung stem cells form human bronchioles, alveoli, and pulmonary vessels integrated structurally and functionally with the damaged organ. The formation of a chimeric lung was confirmed by detection of human transcripts for epithelial and vascular genes. In addition, the self-renewal and long-term proliferation of human lung stem cells was shown in serial-transplantation assays. CONCLUSIONS Human lungs contain identifiable stem cells. In animal models, these cells participate in tissue homeostasis and regeneration. They have the undemonstrated potential to promote tissue restoration in patients with lung disease. (Funded by the National Institutes of Health.)
Rationale: The ability of the human heart to regenerate large quantities of myocytes remains controversial, and the extent of myocyte renewal claimed by different laboratories varies from none to nearly 20% per year. Objective: To address this issue, we examined the percentage of myocytes, endothelial cells, and fibroblasts labeled by iododeoxyuridine in postmortem samples obtained from cancer patients who received the thymidine analog for therapeutic purposes. Additionally, the potential contribution of DNA repair, polyploidy, and cell fusion to the measurement of myocyte regeneration was determined. Methods and Results: The fraction of myocytes labeled by iododeoxyuridine ranged from 2.5% to 46%, and similar values were found in fibroblasts and endothelial cells. An average 22%, 20%, and 13% new myocytes, fibroblasts, and endothelial cells were generated per year, suggesting that the lifespan of these cells was approximately 4.5, 5, and 8 years, respectively. The newly formed cardiac cells showed a fully differentiated adult phenotype and did not express the senescence-associated protein p16 INK4a. Moreover, measurements by confocal microscopy and flow cytometry documented that the human heart is composed predominantly of myocytes with 2n diploid DNA content and that tetraploid and octaploid nuclei constitute only a small fraction of the parenchymal cell pool. Importantly, DNA repair, ploidy formation, and cell fusion were not implicated in the assessment of myocyte regeneration. Conclusions: Our findings indicate that the human heart has a significant growth reserve and replaces its myocyte and nonmyocyte compartment several times during the course of life. (Circ Res. 2010;107:305-315.)Key Words: myocyte regeneration Ⅲ cell lifespan Ⅲ DNA repair Ⅲ ploidy Ⅲ cell fusion F or nearly a century, the adult heart has been considered a postmitotic organ in which the number of parenchymal cells is established at birth and cardiomyocytes lost with age or as a result of cardiac diseases cannot be replaced by newly formed cells. The recent explosion of the field of stem cell biology, with the recognition that the possibility exists for extrinsic and intrinsic regeneration of myocytes and coronary vessels, 1 has imposed a reevaluation of cardiac homeostasis and pathology. Several laboratories have identified resident cardiac stem cells (CSCs) in the developing, postnatal, and adult heart of animals and humans, 2-4 suggesting that myocyte turnover and tissue regeneration may be more profound than previously predicted.The documentation that CSCs reside in the myocardium, are stored in discrete niche structures, and divide symmetrically and asymmetrically in vitro and in vivo 4 makes the heart a selfrenewing organ. Cardiac cells continuously lost by wear and tear are constantly replaced by activation and commitment of CSCs. 5 Based on retrospective 14 C birth dating of cells, the claim has been made that throughout life, myocyte turnover in humans is restricted to a subset of Ϸ50% of cardiomyocytes. 6 Although the process...
Rationale:The turnover of cardiomyocytes in the aging female and male heart is currently unknown, emphasizing the need to define human myocardial biology.Objective: The effects of age and gender on the magnitude of myocyte regeneration and the origin of newly formed cardiomyocytes were determined. Methods and Results:The interaction of myocyte replacement, cellular senescence, growth inhibition, and apoptosis was measured in normal female (n)23؍ and male (n)24؍ human hearts collected from patients 19 to 104 years of age who died from causes other than cardiovascular diseases. A progressive loss of telomeric DNA in human cardiac stem cells (hCSCs) occurs with aging and the newly formed cardiomyocytes inherit short telomeres and rapidly reach the senescent phenotype. Our data provide novel information on the superior ability of the female heart to sustain the multiple variables associated with the development of the senescent myopathy. At all ages, the female heart is equipped with a larger pool of functionally competent hCSCs and younger myocytes than the male myocardium. The replicative potential is higher and telomeres are longer in female hCSCs than in male hCSCs. In the female heart, myocyte turnover occurs at a rate of 10%, 14%, and 40% per year at 20, 60, and 100 years of age, respectively. Corresponding values in the male heart are 7%, 12%, and 32% per year, documenting that cardiomyogenesis involves a large and progressively increasing number of parenchymal cells with aging. From 20 to 100 years of age, the myocyte compartment is replaced 15 times in women and 11 times in men. Conclusions:The human heart is a highly dynamic organ regulated by a pool of resident hCSCs that modulate cardiac homeostasis and condition organ aging.
Background Cardiac stem cells (CSCs) delivered to the infarcted heart generate a large number of small fetal-neonatal cardiomyocytes which fail to acquire the differentiated phenotype. However, the interaction of CSCs with post-mitotic myocytes results in the formation of cells with adult characteristics. Methods and Results Based on in vitro and in vivo assays, we report that the commitment of human CSCs (hCSCs) to the myocyte lineage and the generation of mature working cardiomyocytes are influenced by microRNA-499 (miR-499) which is barely detectable in hCSCs, but is highly expressed in post-mitotic human cardiomyocytes. miR-499 traverses gap junction channels and translocates to structurally coupled hCSCs favoring their differentiation into functionally-competent cells. Expression of miR-499 in hCSCs represses the miR-499 target genes Sox6 and Rod1, enhancing cardiomyogenesis in vitro and after infarction in vivo. Although cardiac repair was detected in all cell-treated infarcted hearts, the aggregate volume of the regenerated myocyte mass and myocyte cell volume were greater in animals injected with hCSCs overexpressing miR-499. Treatment with hCSCs resulted in an improvement in ventricular function, consisting of a better preservation of developed pressure, and positive and negative dP/dt after infarction. An additional positive effect on cardiac performance occurred with miR-499, pointing to enhanced myocyte differentiation/hypertrophy as the mechanism by which miR-499 potentiated the restoration of myocardial mass and function in the infarcted heart. Conclusions The recognition that miR-499 promotes the differentiation of hCSCs into mechanically integrated cardiomyocytes has important clinical implications for the treatment of human heart failure.
Primitive cells capable of generating small resistance arterioles and capillary structures in the injured myocardium have been identified repeatedly. However, these cells do not form large conductive coronary arteries that would have important implications in the management of the ischemic heart. In the current study, we determined whether the human heart possesses a class of progenitor cells that regulates the growth of endothelial cells (ECs) and smooth muscle cells (SMCs) and vasculogenesis. The expression of vascular endothelial growth-factor receptor 2 (KDR) was used, together with the stem cell antigen c-kit, to isolate and expand a resident coronary vascular progenitor cell (VPC) from human myocardial samples. Structurally, vascular niches composed of c-kit-KDR-positive VPCs were identified within the walls of coronary vessels. The VPCs were connected by gap junctions to ECs, SMCs, and fibroblasts that operate as supporting cells. In vitro, VPCs were self-renewing and clonogenic and differentiated predominantly into ECs and SMCs and partly into cardiomyocytes. To establish the functional import of VPCs, a critical stenosis was created in immunosuppressed dogs, and tagged human VPCs were injected in proximity to the constricted artery. One month later, there was an increase in coronary blood flow (CBF) distal to the stenotic artery, resulting in functional improvement of the ischemic myocardium. Regenerated large, intermediate, and small human coronary arteries and capillaries were found. In conclusion, the human heart contains a pool of VPCs that can be implemented clinically to form functionally competent coronary vessels and improve CBF in patients with ischemic cardiomyopathy.
An analysis of the clonality of cardiac progenitor cells (CPCs) and myocyte turnover in vivo requires genetic tagging of the undifferentiated cells so that the clonal marker of individual mother cells is traced in the specialized progeny. CPC niches in the atria and apex of the mouse heart were infected with a lentivirus carrying EGFP, and the destiny of the tagged cells was determined 1-5 months later. A common integration site was identified in isolated CPCs, cardiomyocytes, endothelial cells (ECs), and fibroblasts, documenting CPC self-renewal and multipotentiality and the clonal origin of the differentiated cell populations. Subsequently, the degree of EGFP-lentiviral infection of CPCs was evaluated 2-4 days after injection, and the number of myocytes expressing the reporter gene was measured 6 months later. A BrdU pulse-chasing protocol was also introduced as an additional assay for the analysis of myocyte turnover. Over a period of 6 months, each EGFP-positive CPC divided approximately eight times generating 230 cardiomyocytes; this value was consistent with the number of newly formed cells labeled by BrdU. To determine whether, human CPCs (hCPCs) are self-renewing and multipotent, these cells were transduced with the EGFP-lentivirus and injected after acute myocardial infarction in immunosuppressed rats. hCPCs, myocytes, ECs, and fibroblasts collected from the regenerated myocardium showed common viral integration sites in the human genome. Thus, our results indicate that the adult heart contains a pool of resident stem cells that regulate cardiac homeostasis and repair.F ate mapping protocols establish a lineage relationship between ancestors carrying the reporter gene and their descendents (1, 2), but do not provide information on the self-renewing property and clonogenicity of progenitor cells or clonal origin of daughter cells in vivo (3). Because of these limitations, viral gene-tagging remains the most accurate strategy for the analysis of stem cell growth (3-8). The semi-random insertion of retroviral and lentiviral vectors represents an effective tool for genetic marking, enabling the identification of the progeny generated by stem cell differentiation. Retroviruses and lentiviruses integrate permanently in the genome of the host cells; the insertion site of the viral genome is inherited by the population derived from the parental cell (6) and can be amplified by PCR. Thus, the detection of the sites of integration constitutes a unique approach for the documentation of self-renewal, clonogenicity, and multipotentiality of stem cells in vivo. So far, this methodology has been applied to the bone marrow (4-6) and the brain (3, 7, 8) and has not been used to characterize the mechanisms regulating cardiac homeostasis and pathology.The implementation of this technique in the adult heart is relevant for the incontrovertible demonstration of resident cardiac stem cells and the ability of the myocardium to undergo spontaneous regeneration. Moreover, the notion that cardiomyocytes have a long lifespan and ...
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