The identification of lung tumor-initiating cells and associated markers may be useful for optimization of therapeutic approaches and for predictive and prognostic information in lung cancer patients. CD133, a surface glycoprotein linked to organ-specific stem cells, was described as a marker of cancer-initiating cells in different tumor types. Here, we report that a CD133 ؉ , epithelial-
p21 Cip1/WAF1 inhibits cell-cycle progression by binding to G 1 cyclin/CDK complexes and proliferating cell nuclear antigen (PCNA) through its N-and C-terminal domains, respectively. The cell-cycle inhibitory activity of p21 Cip1/WAF1 is correlated with its nuclear localization. Here, we report a novel cytoplasmic localization of p21 Cip1/WAF1 in peripheral blood monocytes (PBMs) and in U937 cells undergoing monocytic differentiation by in vitro treatment with vitamin D3 or ectopic expression of p21 Cip1/WAF1 , and analyze the biological consequences of this cytoplasmic expression. U937 cells which exhibit nuclear p21 Cip1/WAF1 demonstrated G 1 cell-cycle arrest and subsequently differentiated into monocytes. The latter event was associated with a cytoplasmic expression of nuclear p21 Cip1/WAF1 , concomitantly with a resistance to various apoptogenic stimuli. Biochemical analysis showed that cytoplasmic p21 Cip1/WAF1 forms a complex with the apoptosis signalregulating kinase 1 (ASK1) and inhibits stress-activated MAP kinase cascade. Expression of a deletion mutant of p21 Cip1/WAF1 lacking the nuclear localization signal (ΔNLS-p21) did not induce cell cycle arrest nor monocytic differentiation, but led to an apoptosis-resistant phenotype, mediated by binding to and inhibition of the stress-activated ASK1 activity. Thus, cytoplasmic p21 Cip1/WAF1 itself acted as an inhibitor of apoptosis. Our findings highlight the different functional roles of p21 Cip1/WAF1 , which are determined by its intracellular distribution and are dependent on the stage of differentiation.
The serine/threonine kinase CHK2 is a key component of the DNA damage response. In human cells, following genotoxic stress, CHK2 is activated and phosphorylates >20 proteins to induce the appropriate cellular response, which, depending on the extent of damage, the cell type, and other factors, could be cell cycle checkpoint activation, induction of apoptosis or senescence, DNA repair, or tolerance of the damage. Recently, CHK2 has also been found to have cellular functions independent of the presence of nuclear DNA lesions. In particular, CHK2 participates in several molecular processes involved in DNA structure modification and cell cycle progression. In this review, we discuss the activity of CHK2 in response to DNA damage and in the maintenance of the biological functions in unstressed cells. These activities are also considered in relation to a possible role of CHK2 in tumorigenesis and, as a consequence, as a target of cancer therapy.
A murine monoclonal antibody (OKT9) raised against human leukemic cells binds to a wide variety of leukemia and tumor cell lines and to a minority of leukemia cells taken directly from patients. Fetal thymus and liver are strongly reactive as are some normal, immature hemopoietic cells and activated lymphocytes. Reactivity with OKT9 appears to correlate with proliferation status in both normal and malignant populations. Biochemical analysis indicates that this structure is a approximately equal to 180,000-dalton glycoprotein with two disulfide-bonded subunits of approximately equal to 90,000-daltons. Isolation of the transferrin receptor from a T-cell line (MOLT-4) indicates that it also has a dimeric approximately equal to 180,000-dalton structure. Radio-labeled transferrin bound to its receptors can be specifically precipitated by the monoclonal OKT9, although the latter does not bind transferrin itself, indicating that the antigenic structure defined by this antibody is likely to be the transferrin receptor.
Purpose: The existence of tumor-initiating cells in breast cancer has profound implications for cancer therapy. In this study, we investigated the sensitivity of tumor-initiating cells isolated from human epidermal growth factor receptor type 2 (HER2)-overexpressing carcinoma cell lines to trastuzumab, a compound used for the targeted therapy of breast cancer. Experimental Design: Spheres were analyzed by indirect immunofluorescence for HER2 cell surface expression and by real-time PCR for HER2 mRNA expression in the presence or absence of the Notch1signaling inhibitor (GSI) or Notch1small interfering RNA. Xenografts of HER2-overexpressing breast tumor cells were treated with trastuzumab or doxorubicin. The sphere-forming efficiency (SFE) and serial transplantability of tumors were assessed. Results: In HER2-overexpressing carcinoma cell lines, cells with tumor-initiating cell properties presented increased HER2 levels compared with the bulk cell population without modification in HER2 gene amplification. HER2 levels were controlled by Notch1 signaling, as shown by the reduction of HER2 cell surface expression and lower SFE following g-secretase inhibition or Notch1 specific silencing. We also show that trastuzumab was able to effectively target tumor-initiating cells of HER2-positive carcinoma cell lines, as indicated by the significant decrease in SFE and the loss of serial transplantability, following treatment of HER2-overexpressing xenotransplants. Conclusions: Here, we provide evidence for the therapeutic efficacy of trastuzumab in debulking and in targeting tumor-initiating cells of HER2-overexpressing tumors. We also propose that Notch signaling regulates HER2 expression, thereby representing a critical survival pathway of tumor-initiating cells.
Che-1 is a RNA polymerase II-binding protein involved in the transcription of E2F target genes and induction of cell proliferation. Here we show that Che-1 contributes to DNA damage response and that its depletion sensitizes cells to anticancer agents. The checkpoint kinases ATM/ATR and Chk2 interact with Che-1 and promote its phosphorylation and accumulation in response to DNA damage. These Che-1 modifications induce a specific recruitment of Che-1 on the TP53 and p21 promoters. Interestingly, it has a profound effect on the basal expression of p53, which is preserved following DNA damage. Notably, Che-1 contributes to the maintenance of the G2/M checkpoint induced by DNA damage. These findings identify a mechanism by which checkpoint kinases regulate responses to DNA damage.
All seven of a set of CD34 monoclonal antibodies that recognize epitopes on an approximately 110 Kd glycoprotein on human hemopoietic progenitor cells also bind to vascular endothelium. Capillaries of most tissues are CD34 positive, as are umbilical artery and, to a lesser extent, vein, but the endothelium of most large vessels and the endothelium of placental sinuses are not. Angioblastoma cells and parafollicular mesenchymal cells in fetal skin are also CD34 positive, as are some stromal elements. An approximately 110 Kd protein can be identified by Western blot analysis with CD34 antibodies in detergent extracts of freshly isolated umbilical vessel endothelial cells, and CD34 mRNA is present in cultured umbilical vein cells as well as other tissues rich in vascular endothelium (breast, placenta). These data indicate that the binding of CD34 antibodies to vascular endothelium is to the CD34 gene product, and not to crossreactive epitopes. Despite the presence of CD34 mRNA in cultured, proliferating endothelial cells, the latter do not bind CD34 antibodies. In addition, CD34 antigen cannot be upregulated by growth factors. We conclude that under these conditions, CD34 protein is downregulated or processed into another form that is unreactive with CD34 antibodies. Electron microscopy of umbilical artery, breast, and kidney capillary vessels reveals that in all three sites, CD34 molecules are concentrated on membrane processes, many of which interdigitate between adjacent endothelial cells. However, well-established endothelial cell contacts with tight junctions are CD34 negative. CD34 may function as an adhesion molecule on both endothelial cells and hematopoietic progenitors.
Alteration of the FHIT (fragile histidine triad) gene occurs as an early and frequent event in lung carcinogenesis. FHIT gene transfer into lung cancer cell line H460 lacking Fhit protein expression resulted in reversion of tumorigenicity. To gain insight into the biological function of FHIT, we compared the H460 cell line with its Fhit transfectants (H460͞FHIT). A significant inhibition of cell growth was observed in H460͞FHIT cells. The analysis of apoptosis by in situ terminal deoxynucleotidyltransferase-mediated dUTP nick end labeling revealed a high rate of apoptosis-induced DNA strand breaks in stable clones. In situ results were confirmed by FACScan analysis that showed an apoptotic rate of 44-47% compared with a 15% level in the control H460 cells. Analysis of cell cycle-phase distribution indicated a significant G 0 ͞G 1 arrest and the presence of a sub-G 1 peak in the stable clones. No significant changes in Bcl2, BclX, and Bax protein expression level were observed in the transfected clones as compared with the control H460 cells whereas a 2-fold increase in Bak protein levels was noticed. An increased level of p21 waf protein paralleled by an up-regulation of p21 waf transcripts also was found in Fhit-expressing clones compared with the H460 cell line. No differences in p53 levels were observed in the same cells, suggesting a p53-independent effect. These data suggest that the observed growth-inhibitory effect in FHIT-reexpressing cells could be related to apoptosis and cell cycle arrest and link the tumor-suppressor activity of FHIT to its proapoptotic function.The FHIT (fragile histidine triad) gene (1), at 3p14.2, is a frequent target of deletions associated with abnormal RNA and protein expression in primary tumors and cell lines of lung, head and neck, kidney, cervix, and breast cancer (2-6). Stable FHIT-transduced clones expressing exogenous wild-type Fhit, isolated after transfection of various epithelial cell lines carrying inactivated endogenous Fhit, show reduced colonyformation efficiency in vitro and inhibition of tumor development in nude mice, indicating that FHIT acts as a tumorsuppressor gene (7). The Fhit protein is a diadenosine triphosphate (Ap 3 A) hydrolase belonging to the histidine triad superfamily (HIT) of nucleotide-binding proteins (8). Our observation that the His(96)Asn mutant, lacking hydrolytic activity, still inhibits tumor formation in vivo (7) suggests that the tumor-suppressing function of Fhit is not related to catalysis of nucleotide substrates. However, the biological mechanism of FHIT activity and the cellular pathways associated with its tumor-suppressor function are not known. Crystallographic studies suggested that Ap 3 A nucleotide binding is crucial for Fhit biological activity and that enzymesubstrate complexes may be a signaling form (9). Interestingly, it has been reported that apoptosis in human cultured cells is associated with a decrease of free Ap 3 A levels (10).To study a possible involvement of FHIT in cell growth control and apoptosis, we...
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