The essentially infinite expansion potential and pluripotency of human embryonic stem cells (hESCs) makes them attractive for cell-based therapeutics. In contrast to mouse embryonic stem cells (mESCs), hESCs normally undergo high rates of spontaneous apoptosis and differentiation, making them difficult to maintain in culture. Here we demonstrate that p53 protein accumulates in apoptotic hESCs induced by agents that damage DNA. However, despite the accumulation of p53, it nevertheless fails to activate the transcription of its target genes. This inability of p53 to activate its target genes has not been observed in other cell types, including mESCs. We further demonstrate that p53 induces apoptosis of hESCs through a mitochondrial pathway. Reducing p53 expression in hESCs in turn reduces both DNA damage-induced apoptosis as well as spontaneous apoptosis. Reducing p53 expression also reduces spontaneous differentiation and slows the differentiation rate of hESCs. Our studies reveal the important roles of p53 as a critical mediator of human embryonic stem cells survival and differentiation.Human embryonic stem cells (hESCs) 3 are capable of essentially unlimited self-renewal and retain the developmental potential to differentiate into almost any cell type. These characteristics of hESCs make them attractive for tissue and cellbased therapies (1, 2). Previously, basic fibroblast growth factor and activin A were identified as self-renewal factors (3-6). However, for reasons that are not clear, hESCs often display high rates of spontaneous apoptosis and differentiation in culture, thus making the process of expanding these cells highly inefficient (3, 7-10). For example, Dravid et al. (8) reported that, under routine culture conditions, Ͼ30% of hESCs undergo spontaneous apoptosis. Furthermore, Ezashi et al. (12) showed that nearly 40% of hESCs undergo spontaneous differentiation after 12 days of culture in normoxic conditions. Finally, Maitra et al. (13) reported that multiple passages of hESCs can cause genomic alterations, which may limit the therapeutic application of hESCs. In contrast to hESCs, mouse embryonic stem cells (mESCs) undergo lower rates of spontaneous apoptosis and differentiation (14). Moreover, they maintain their pluripotency and genomic stability longer than hESCs (15). The reason for these different species-specific phenotypes in embryonic stem cells is currently unknown.The p53 tumor suppressor gene is a strong candidate for playing a role in the observed phenotypes of hESCs, because it regulates various cellular processes, including apoptosis, differentiation, and genomic integrity (16). In many cell types p53 plays a crucial role in controlling apoptosis and cell cycle arrest when these cells are exposed to stress-inducing conditions (17). In response to stress, p53 accumulates and transactivates downstream target genes such as mdm2 (responsible for the feedback degradation circuitry of p53), p21 (responsible for cell cycle control), bax, noxa, and puma (responsible for DNA damage-induced ...
The capacity for self-renewal and differentiation of human embryonic stem (ES) cells makes them a potential source for generation of pancreatic beta cells for treating type I diabetes mellitus. Here, we report a newly developed and effective method, carried out in a serum-free system, which induced human ES cells to differentiate into insulin-producing cells. Activin A was used in the initial stage to induce definitive endoderm differentiation from human ES cells, as detected by the expression of the definitive endoderm markers Sox17 and Brachyury. Further, all-trans retinoic acid (RA) was used to promote pancreatic differentiation, as indicated by the expression of the early pancreatic transcription factors pdx1 and hlxb9. After maturation in DMEM/F12 serum-free medium with bFGF and nicotinamide, the differentiated cells expressed islet specific markers such as C-peptide, insulin, glucagon and glut2. The percentage of C-peptide-positive cells exceeded 15%. The secretion of insulin and C-peptide by these cells corresponded to the variations in glucose levels. When transplanted into renal capsules of Streptozotocin (STZ)-treated nude mice, these differentiated human ES cells survived and maintained the expression of beta cell marker genes, including C-peptide, pdx1, glucokinase, nkx6.1, IAPP, pax6 and Tcf1. Thirty percent of the transplanted nude mice exhibited apparent restoration of stable euglycemia; and the corrected phenotype was sustained for more than six weeks. Our new method provides a promising in vitro differentiation model for studying the mechanisms of human pancreas development and illustrates the potential of using human ES cells for the treatment of type I diabetes mellitus.
We have expressed a series of truncated spike (S) glycoproteins of SARS-CoV and found that the N-terminus 14-502 residuals were sufficient to bind to SARS-CoV susceptible Vero E6 cells. With this soluble S protein fragment as an affinity ligand, we screened HeLa cells transduced with retroviral cDNA library from Vero E6 cells and obtained a HeLa cell clone which could bind with the S protein. This cell clone was susceptible to HIV/SARS pseudovirus infection and the presence of a functional receptor for S protein in this cell clone was confirmed by the cell-cell fusion assay. Further studies showed the susceptibility of this cell was due to the expression of endogenous angiotensin-converting enzyme 2 (ACE2) which was activated by inserted LTR from retroviral vector used for expression cloning. When human ACE2 cDNA was transduced into NIH3T3 cells, the ACE2 expressing NIH3T3 cells could be infected with HIV/SARS pseudovirus. These data clearly demonstrated that ACE2 was the functional receptor for SARS-CoV.
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