Expression of survivin and p16(INK4a)/Cdk6/pRB proteins and induction of apoptosis in response to radiation and cisplatin in meningioma cells.

Although meningiomas represent the most common class of tumors of the central nervous system, the molecular events underlying their genesis and development are still not well defined, and therapeutic approaches based on the genetics of these tumors are currently lacking. In the present study we have used the immunoblotting technique to show that the p16(INK4A), Cdk6 and pRB proteins are differentially expressed in primary meningioma cells with 20-, 30- and 36-fold difference between the lowest and the highest levels of each protein, respectively. In addition, we present evidence that the level of the anti-apoptosis survivin protein is high in these benign tumors. Moreover, the annexin V-associated flow cytometry technique was used to show that 60% of meningioma cell cultures underwent apoptosis in response to both gamma-rays and cisplatin, and 50% of these cells exhibited significant sensitivity to hydroxyurea. These agents triggered apoptosis through the mitochondrial pathway, by increasing the Bax/Bcl-2 ratio. Interestingly, the induction of apoptosis following radiation and cisplatin was significant in all cells that expressed low levels of p16(INK4A), Cdk6 and pRB proteins. These data shed more light on the molecular biology of meningioma cells and suggest that survivin and proteins of the RB pathway could play a determinant role in the development and the treatment of meningiomas.

RB1 and TP53 pathways in radiation-induced sarcomas.

The tumour suppressor genes, TP53 and RB1, and four genes involved in their regulation, INK4a, ARF, MDM2 and MDMX, were analysed in a series of 36 post-radiotherapy radiation-induced sarcomas. One-third of the tumours developed in patients carrying a germline mutation of RB1 that predisposed them to retinoblastoma and radiation-induced sarcomas. The genetic inactivation of RB1 and/or TP53 genes was frequently observed in these sarcomas. These inactivations were owing to an interplay between point mutations and losses of large chromosome segments. Radiation-induced somatic mutations were observed in TP53, but not in RB1 or in the four other genes, indicating an early role of TP53 in the radio-sarcomagenesis. RB1 and TP53 genes were biallelically coinactivated in all sarcomas developing in the context of the predisposition, indicating that both genes played a major role in the formation of these sarcomas. In the absence of predisposition, TP53 was biallelically inactivated in one-third of the sarcomas, whereas at least one allele of RB1 was wild type. In both genetic contexts, the TP53 pathway was inactivated by genetic lesions and not by the activation of the ARF/MDM2/MDMX pathway, as recently shown in retinoblastomas. Together, these findings highlight the intricate tissue- and aetiology-specific relationships between TP53 and RB1 pathways in tumorigenesis.

Active localization of the retinoblastoma protein in chromatin and its response to S phase DNA damage.

The Rb protein suppresses development of an abnormal state of endoreduplication arising after S phase DNA damage. In diploid, S phase cells, the activity of protein phosphatase 2A (PP2A) licenses the stable association of un(der)phosphorylated Rb with chromatin. After damage, chromatin-associated pRb is attracted to certain chromosomal replication initiation sites in the order in which they normally fire. Like S phase DNA damage in Rb(-/-) cells, specific interruption of PP2A function in irradiated, S phase wt cells also elicited a state of endoreduplication. Thus, PP2A normally licenses the recruitment of Rb to chromatin sites in S phase from which, after DNA damage, it relocalizes to selected replication control sites and suppresses abnormal, postdamage rereplicative activity.

UVB induced cell cycle checkpoints in an early stage human melanoma line, WM35.

The activation of cell cycle checkpoints in response to genotoxic stressors is essential for the maintenance of genomic integrity. Although most prior studies of cell cycle effects of UV irradiation have used UVC, this UV range does not penetrate the earth's atmosphere. Thus, we have investigated the mechanisms of ultraviolet B (UVB) irradiation-induced cell cycle arrest in a biologically relevant target cell type, the early stage human melanoma cell line, WM35. Irradiation of WM35 cells with UVB resulted in arrests throughout the cell cycle: at the G1/S transition, in S phase and in G2. G1 arrest was accompanied by increased association of p21 with cyclin E/cdk2 and cyclin A/cdk2, increased binding of p27 to cyclin E/cdk2 and inhibition of these kinases. A loss of Cdc25A expression was associated with an increased inhibitory phosphotyrosine content of cyclin E- and cyclin A-associated cdk2 and may also contribute to G1 arrest following UVB irradiation. The association of Cdc25A with 14-3-3 was increased by UVB. Reduced cyclin D1 protein and increased binding of p21 and p27 to cyclin D1/cdk4 complexes were also observed. The loss of cyclin D1 could not be attributed to inhibition of either MAPK or PI3K/PKB pathways, since both were activated by UVB. Cdc25B levels fell and the remaining protein showed an increased association with 14-3-3 in response to UVB. Losses in cyclin B1 expression and an increased binding of p21 to cyclin B1/cdk1 complexes also contributed to inhibition of this kinase activity, and G2/M arrest. Oncogene (2000) 19, 4480 - 4490.

High and low fluences of alpha-particles induce a G1 checkpoint in human diploid fibroblasts.

The effects of exposure to high and very low fluence alpha-particles on the G1 checkpoint were investigated in human diploid fibroblasts irradiated and released from density-inhibited confluent cultures by the use of the cumulative labeling index method. Transient and permanent arrests in G1 occurred in fibroblast populations exposed to mean doses as low as 1 cGy, suggesting that nontraversed bystander cells may contribute to the low dose response. In cells exposed to high fluences, the G1 checkpoint is at least as extensive as in gamma-irradiated cells. In contrast to gamma-irradiated cells, neither repair of potentially lethal damage nor a reduction in the fraction of cells transiently or permanently arrested in G1 were observed in cells held in confluence for 6 h after alpha-particle irradiation. Studies with isogenic wild-type, p53-/-, and p21Waf1-/- mouse embryo fibroblasts exposed to either gamma or alpha-particle radiation revealed a total lack of G1 arrest in either p53-/- or p21waf1-/- cells, indicating that the G1 checkpoint in wild-type cells is p53-dependent and that p21Wf1 fully mediates the role of p53 in its induction. In contrast to human cells, mouse embryo fibroblasts do not undergo a permanent G1 arrest. Except under conditions favoring potentially lethal damage repair, a comparable expression pattern of p53, p21Waf1, and other cell cycle-regulated proteins (pRb, p34cdc2, and cyclin B1) was observed in alpha-particle or gamma-irradiated human fibroblasts.

Decreased retinoblastoma protein expression in gamma-irradiated mouse ovarian follicles.

We immunohistochemically examined the effect of gamma-radiation on immature mouse ovarian follicles. Mice were Jirradiated with a dose of LD80 (8.3 Gy) in KAERI. At 0 h, 6 h, 12 h, 1 d, 2 d, 4 d and 8 d postirradiation, the ovaries were excised and fixed in neutral buffered formalin. We performed immunohistochemistry for protein retinoblastoma (pRb), terminal deoxynucleotidyl transferase-mediated dUTP-digoxigenin nick end-labeling (TUNEL) and routine hematoxylin-eosin staining in the largest cross sections. Radiation-induced follicular degeneration increased before 6 h, and most irradiated ovarian follicles became acutely atretic. The immunohistochemical staining for pRb was strong in the nuclei of granulosa cells of normal follicles and weak in atretic ones which were, conversely, strong for TUNEL staining. It was shown that pRb expression became lower with the degeneration of the ovarian follicles, which was inhibited by gamma-radiation. In the present study, pRb immunohistochemistry was proven to be a useful tool for the identification of follicular status.

Inhibition of cyclin-dependent kinase 2 by p21 is necessary for retinoblastoma protein-mediated G1 arrest after gamma-irradiation.

In mammalian cells, activation of certain checkpoint pathways as a result of exposure to genotoxic agents results in cell cycle arrest. The integrity of these arrest pathways is critical to the ability of the cell to repair mutations that otherwise might compromise viability or contribute to deregulation of cellular growth and proliferation. Here we examine the mechanism through which DNA damaging agents result in a G1 arrest that depends on the tumor suppressor p53 and its transcriptional target p21. By using primary cell lines lacking specific cell cycle regulators, we demonstrate that this pathway functions through the growth suppressive properties of the retinoblastoma protein (pRB) tumor suppressor. Specifically, gamma-irradiation inhibits the phosphorylation of pRB at cyclin-dependent kinase 2-specific, but not cyclin-dependent kinase 4-specific, sites in a p21-dependent manner. Most importantly, we show that pRB is a critical component of this DNA damage checkpoint. These data indicate that the p53 --> p21 checkpoint pathway uses the normal cell cycle regulatory machinery to induce the accumulation of the growth suppressive form of pRB and suggest that loss of pRB during the course of tumorigenesis disrupts the function of an important DNA damage checkpoint.

Detection of intracellular antigens by flow cytometry: comparison of two chemical methods and microwave heating.

Detection of intracellular antigens by flow cytometry requires effective fixation and permeabilization of the cell membrane. This study compares three fixation/permeabilization techniques: two commercial chemical reagents, the ORTHOPermeaFix (OPF) and the FIX&PERM Cell Permeabilization Kit (F&P), and a novel method based on microwave heating (MWH). They have been applied to the detection of two nuclear (p53 and rb/p105) and two cytoplasmic (bcl-2 and mdr-1/gp-170) antigens, using positive- and negative-control cell lines and peripheral blood mononuclear cells. Western blotting was performed as a control of protein expression. For the four antigens assessed, cellular morphology, discrimination between intact cells and debris, percentage of positive cells, and mean fluorescence intensity were examined. For this last parameter, the assessment of the MWH technique was performed using SD and a graphical approach inspired by the concepts described by Bland and Altman (Lancet 1986;346: 1085-7) as well as Petersen et al. (Clin Chem 1997;43: 2039-46). The statistical analysis shows that MWH is comparable to the commercial methods and that its reproducibility is also equivalent to OPF and F&P. As assessed for some of the most clinically relevant intracytoplasmic and intranuclear antigens, the MWH method appears to be a valuable and inexpensive alternative. It is worth noting that, unlike commercial reagents, MWH altered surface antigens. Interestingly, this feature, which would prevent cell selection on the basis of combined membrane and intracellular epitopes, is associated with a decrease of nonspecific background fluorescence.

Inhibition of Ku autoantigen binding activity to the E2F motif after ultraviolet B irradiation of melanocytic cells.

In human melanocytes and a human melanoma cell line (MM96L), the level of Ku sequence-specific binding to a 37-mer oligonucleotide containing a single E2F-1 binding site of the c-myc promoter (E2cM) significantly decreased 12 24h after cytostatic exposure to 300 J/m2 ultraviolet B radiation (UVB). No UVB-induced loss was found in fibroblasts, while HeLa cells showed an earlier (4 h) but less significant decrease than melanocytic cells. Equitoxic doses of gamma radiation, cisplatin or UVC had little effect on E2cM-specific binding. The loss of Ku binding in MM96L cells was not the result of translocation of Ku or a decrease in Ku protein or DNA-dependent protein kinase activity. The level of E2cM-specific binding in MM96L cells was increased by tunicamycin (2 microg/ml), an inhibitor of N-linked glycosylation, and decreased by the glucosidase inhibitor castanospermine (50 microg/ml). These results, which parallel the reported loss in melanocytes of the cell cycle regulator pRB after UVB, suggest that the DNA binding activity of Ku is affected by post-translational modification and may play a role in regulating the cell cycle response to UVB.

Ionizing radiation and teniposide increase p21(waf1/cip1) and promote Rb dephosphorylation but fail to suppress E2F activity in MCF-7 breast tumor cells.

Ionizing radiation and the topoisomerase II inhibitor, teniposide (VM-26) both increase levels of the cyclin dependent kinase inhibitor, p21(waf1/cip1) and promote dephosphorylation of the retinoblastoma tumor suppressor protein, Rb, in MCF-7 breast tumor cells, perturbations associated with suppression of the activity of the transcription factor, E2F. However, studies using an E2F binding site-luciferase reporter plasmid transfected into MCF-7 cells failed to demonstrate a reduction in E2F activity in response to VM-26 or to ionizing radiation. In contrast, E2F activity (both basal and E1A stimulated) could be suppressed by transfection with a plasmid expressing Rb, indicating that the capacity of E2F to bind to Rb and to be inactivated by Rb is functionally intact in MCF-7 cells. These findings in MCF-7 breast tumor cells suggest that E2F activity may not be directly susceptible to modulation by endogenous p21(waf1/cip1) and Rb.

Cell cycle dependent effects of u.v.-radiation on p53 expression and retinoblastoma protein phosphorylation.

Control of fate of cells encountered with DNA damaging agents is pivotal for normal cellular homeostasis. DNA damage leads in many cases to growth arrest of the cells ensuring sufficient time for damage repair. Growth arrest can be mediated by p53 tumor suppressor protein and loss of its function leads to inability of the cells to both growth arrest and undergo apoptosis. We show here that followed by genotoxic stress, the retinoblastoma gene product, pRB, is associated with growth arrest of cells in a p53 independent manner. In u.v.-treated human and mouse fibroblasts, pRB is rapidly dephosphorylated. pRB dephosphorylation occurs concomitant with growth arrest of cells including cells with p53 mutations (SW 480 colon carcinoma cells), cells expressing SV40 T antigen and rat-transformed cells (T-24 bladder carcinoma cells) unresponsive in regard to p53 stimulation. Furthermore, flow cytometry analysis of u.v.-radiated synchronized G1 cells indicates that the cells transiently arrest in G1 for 10-12 h with pRB dominating in its underphosphorylated form, whereas p53 accumulation occurs only after the cells have entered into S-phase. In addition, u.v.-radiation of late S- and G2/M-phase cells leads to p53 accumulation and cell cycle arrest. The results indicate that p53 accumulation upon u.v.-radiation occurs during DNA replication and is thus not involved in G1 arrest. We suggest that the events that lead to pRB dephosphorylation upon u.v.-radiation provide the cell an efficient G1 arrest which occurs prior and independently of p53.