Abstract-Cardiac myocytes have been traditionally regarded as terminally differentiated cells that adapt to increased work and compensate for disease exclusively through hypertrophy. However, in the past few years, compelling evidence has accumulated suggesting that the heart has regenerative potential. Recent studies have even surmised the existence of resident cardiac stem cells, endothelial cells generating cardiomyocytes by cell contact or extracardiac progenitors for cardiomyocytes, but these findings are still controversial. We describe the isolation of undifferentiated cells that grow as self-adherent clusters (that we have termed "cardiospheres") from subcultures of postnatal atrial or ventricular human biopsy specimens and from murine hearts. These cells are clonogenic, express stem and endothelial progenitor cell antigens/markers, and appear to have the properties of adult cardiac stem cells. They are capable of long-term self-renewal and can differentiate in vitro and after ectopic (dorsal subcutaneous connective tissue) or orthotopic (myocardial infarction) transplantation in SCID beige mouse to yield the major specialized cell types of the heart: myocytes (ie, Key Words: adult stem cell Ⅲ myocardial regeneration and angiogenesis C ardiac myocytes have been traditionally regarded as terminally differentiated cells that adapt to increased work and compensate for disease exclusively through hypertrophy. 1 In the past few years, compelling evidence has accumulated suggesting that the heart has regenerative potential. [2][3][4][5] The origin and significance of the subpopulation of replicating myocytes are unknown; these issues could be relevant to understand the for mechanisms coaxing endogenous cardiomyocytes to reenter the cell cycle and to the search for strategies to transplant cardiac progenitor cells. 6 In fact, although embryonic stem cells have an exceptional capacity for proliferation and differentiation, potential immunogenic, arrhythmogenic, and, particularly, ethical considerations limit their current use. Moreover, autologous transplantation of skeletal myoblasts has been considered because of their high proliferative potential, their commitment to a well-differentiated myogenic lineage, their resistance to ischemia, and their origin, which overcomes ethical, immunological, and availability problems. However, even if phase II clinical trials with autologous skeletal myoblasts are ongoing, several problems related to potentially life-threatening arrhythmia (perhaps reflecting cellular uncoupling with host cardiomyocytes 7 ) must be taken into account when this approach is considered. Furthermore, although cardiomyocytes can be formed, at least ex vivo, from different adult stem cells, the ability of these cells to cross lineage boundaries is currently causing heated debate in the scientific community, 8 with the majority of reports indicating neoangiogenesis as the predominant in vivo effect of bone marrow or endothelial progenitor cells. 9,10 This report describes the identification and...
The multiplicity of Notch receptors raises the question of the contribution of specific isoforms to T-cell development. Notch3 is expressed in CD4(-)8(-) thymocytes and is down-regulated across the CD4(-)8(-) to CD4(+)8(+) transition, controlled by pre-T-cell receptor signaling. To determine the effects of Notch3 on thymocyte development, transgenic mice were generated, expressing lck promoter-driven intracellular Notch3. Thymuses of young transgenics showed an increased number of thymocytes, particularly late CD4(-)8(-) cells, a failure to down-regulate CD25 in post-CD4(-)8(-) subsets and sustained activity of NF-kappaB. Subsequently, aggressive multicentric T-cell lymphomas developed with high penetrance. Tumors sustained characteristics of immature thymocytes, including expression of CD25, pTalpha and activated NF-kappaB via IKKalpha-dependent degradation of IkappaBalpha and enhancement of NF-kappaB-dependent anti-apoptotic and proliferative pathways. Together, these data identify activated Notch3 as a link between signals leading to NF-kappaB activation and T-cell tumorigenesis. The phenotypes of pre-malignant thymocytes and of lymphomas indicate a novel and particular role for Notch3 in co-ordinating growth and differentiation of thymocytes, across the pre-T/T cell transition, consistent with the normal expression pattern of Notch3.
Recent evidence indicates that natural killer (NK) cells can negatively regulateT-cell responses, but the mechanisms behind this phenomenon as a consequence of NK-T-cell interactions are poorly understood. We studied the interaction between the NKG2D receptor and its ligands (NKG2DLs), and asked whether T cells expressed NKG2DLs in response to superantigen, alloantigen, or a specific antigenic peptide, and if this rendered them susceptible to NK lysis. As evaluated by FACS, the major histocompatibility complex (MHC) class I chain-related protein A (MICA) was the ligand expressed earlier on both CD4 ؉ and CD8 ؉ T cells in 90% of the donors tested, while UL16-binding protein-1 (ULBP)1, ULBP2, and ULBP3 were induced at later times in 55%-75% of the donors. By carboxyfluorescein diacetate succinimidyl ester (CFSE) labeling, we observed that NKG2DLs were expressed mainly on T cells that had gone through at least one division. Real-time reverse-transcription polymerase chain reaction confirmed the expression of all NKG2DLs, except ULBP4. In addition, T-cell activation stimulated phosphorylation of ataxia-telangiectasia mutated (ATM), a kinase required for IntroductionThe negative regulation of adaptive immunity is relevant to maintain lymphocyte homeostasis and to prevent inappropriate T-cell activation, which can ultimately result in autoimmune or lymphoproliferative diseases. Although it is well-documented that natural killer (NK) cells are important effectors of innate immunity, and their role against virally infected and tumor cells has been studied over the years, 1,2 much attention has also been focused on their ability to promote adaptive immunity by secretion of immunomodulatory cytokines and chemokines. [3][4][5] More recently, however, a previously unappreciated negative immunoregulatory role has emerged. In fact, NK cells can downregulate T-cell-mediated immune responses by their killing capacity and by secreting inhibitory cytokines such as interleukin (IL)-10 and transforming growth factor beta (TGF)-. [6][7][8] In vitro experiments have shown that activated human NK cells can kill dendritic cells (DCs), 9,10 probably contributing to inhibition of T-cell activation in inflamed tissues. During murine cytomegalovirus (MCMV) infection, the presence of NK cells limits CD4 ϩ and CD8 ϩ IFN-␥ production and proliferation. 11 In addition, in a major histocompatibility complex (MHC) class I-positive host grafted with MHC class I-negative bone marrow, development of MHC class I-deficient thymocytes is delayed as a result of NK-cell cytotoxicity. 12 Furthermore, studies in humans and animal models have demonstrated that NK cells can prevent the initiation and progression of autoimmune diseases: 13 lack of NK cells correlates with severe forms of experimental autoimmune encephalomyelitis and CD4 ϩ T-cell-mediated colitis, suggesting that NK cells can actively inhibit proliferation and cytokine production by autoreactive T cells. 14,15 In accordance, reduced NK-cell numbers and compromised NK-cell functions are foun...
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