Fusion oncogenic tyrosine kinases alter DNA damage and repair after genotoxic treatment: role in drug resistance?

Fusion tyrosine kinases (FTKs) such as BCR/ABL, TEL/ABL, TEL/JAK2, TEL/PDGF beta R and NPM/ALK arise from reciprocal chromosomal translocations and cause acute and chronic myelogenous leukemias and non-Hodgkin's lymphoma. Murine hematopoietic growth factor dependent BaF3 cells and cells transformed by FTK (BaF3-FTK) were used to investigate the role of FTKs in response to DNA damage. FTK-transformed cells displayed resistance to genotoxic treatment including gamma-radiation and cytostatic agents such as idarubicin and MNNG. More FTK-transformed cells survived genotoxic treatment and were able to proliferate in comparison to parental non-transformed cells. Similar or higher levels of DNA damage was detected in gamma-irradiated in BaF3-FTK cells in comparison to BaF3 parental cells. Idarubicin induced different amounts of DNA damage in various BaF3-FTK cells. All BaF3-FTK cells treated with MNNG displayed significantly more DNA damage in comparison to BaF3 cells. Despite the extent of genotoxic effect BaF3-FTK cells were often able to repair damaged DNA more efficiently that the non-transformed counterparts. Inhibition of BCR/ABL kinase activity by STI571 (Gleevec, inatinib mesylate) abrogated the resistance to genotoxic treatment and inhibited DNA repair mechanisms. We hypothesize that facilitation of the DNA repair in FTK-positive cells may contribute to their resistance to genotoxic treatment.     

亚砷酸联合阿米福汀对HL-60细胞中Survivin表达的影响

 目的　探讨亚砷酸（As2O3）联合阿米福汀（AMI）诱导人髓系白血病细胞HL-60凋亡的可能机制。方法　不同浓度As2O3单用和联合AMI对HL-60细胞进行不同时间干预,用MTT比色法检测细胞的生长抑制作用,用半定量RT-PCR法检测抑凋亡基因Survivin mRNA的表达水平。结果　As2O3组和联合组均可显著抑制HL-60细胞的增生,呈浓度依赖性,联合组对其抑制作用明显大于As2O3组。联合组降低Survivin的表达作用比As2O3组更明显。结论　As2O3通过下调抑凋亡基因Survivin的表达诱导HL-60凋亡;AMI可增强As2O3对Survivin的下调作用,增强HL-60细胞对As2O3的敏感性,发挥促凋亡效应。     

Amifostine enhancement of the anti-cancer effects of paclitaxel in endometrial cancer is TP53-dependent

Endometrial cancer (ECa) is the fourth most common malignancy in women. Currently, there is no effective therapy for advanced and recurrent cancer. Among the poor-outcome endometrial cancers, there is a high frequency of TP53 mutations. We have previously reported that amifostine has a direct anti-cancer effect and has a significant synergistic effect with paclitaxel when used in endometrial cancer cell and xenograft models. In this report, using a cell line with knock-down p53 expression through siRNA, we found that amifostine enhancement of paclitaxel's anticancer effect is p53 status-dependent. Amifostine promotes entry into the G2-M phase through regulation of cyclin-dependent kinase-1 activity in cells with dysfunctional p53, thereby enhancing cancer cell sensitivity to paclitaxel. The synergistic effect between amifostine and paclitaxel was further confirmed in vivo using xenografts created with primary patient tumor tissue. Sensitivity to the therapeutic effect of paclitaxel in combination with amifostine was dependent upon the status of p53. A tumor with a nonsense TP53 mutation showed increased therapeutic response to paclitaxel and amifostine as measured by tumor weight compared to a tumor with wild- type TP53. Our study provides a rationale for a clinical trial of combined paclitaxel and amifostine in endometrial cancer patients whose tumors harbor TP53 mutations.     

p53 protein regulates the effects of amifostine on apoptosis,cell cycle progression,and cytoprotection

To determine the role of p53 protein on the cellular effects of amifostine, we used molecularly engineered HCT116 colon cancer cells in which the p53 gene was inactivated by targeted homologous recombination or p53 protein was degraded by high-level expression of papillomavirus E6 protein. Amifostine induced a G1 arrest and protected against paclitaxel toxicity in p53-proficient but not in p53-deficient cells. In the absence of p53 protein, amifostine enhanced the cytotoxicity of paclitaxel. In addition, treatment of HCT116 cells with amifostine alone resulted in apoptotic cell death. Compared with p53-deficient cells, p53-proficient cells exhibited low-level resistance to amifostine-induced apoptosis. Amifostine induced the expression of p53 protein in p53-proficient cells and the expression of p21 protein in both p53-proficient and -deficient cells. These findings indicate that amifostine-induced G1 arrest and cytoprotection are mediated via a pathway that is dependent on p53 protein and that amifostine-induced expression of p21 protein is not sufficient to sustain a G1 arrest or to mediate cytoprotection. In addition, these findings identify p53 protein as a mechanism of resistance to amifostine-induced apoptosis.British     

Variable cytotoxicity of amifostine in malignant and non-malignant cell lines

Amifostine is the best known radioprotector and chemoprotector which has already been incorporated into general oncology practice. However, the data regarding its action at the cellular level remain unclear. The present study examined the effect of amifostine with and without ionizing radiation on the growth of malignant and non-malignant cell lines. Amifostine was found to have a remarkable cytotoxic effect on malignant epithelial cell lines but a modest cytotoxic effect on malignant melanoma and non-malignant cell lines. It demonstrated an additive effect with radiation therapy on the malignant cell line and a variable effect on the non-malignant cell line. Endothelial cells were not affected by amifostine, but the myoblast cells showed a synergistic effect of amifostine and radiation. These findings demonstrate that the cytotoxic as well as the radioprotective effect of amifostine are cell-specific. Thus, caution should be exercised in the use of amifostine as a radioprotector, and it should be tested for each model of disease.     

Apoptosis Induced by DNA Topoisomerase I and II Inhibitors in Human Leukemic HL-60 Cells

The induction of apoptosis following topoisomerase inhibitors proceeds in at least three distinct steps: (1) induction of cleavable complexes (potentially lethal damage), (2) topoisomerase-induced DNA damage, and (3) a presently unknown sequence of events that must either lead to cell cycle arrest (G2-block, differentiation) or apoptosis. DNA degradation provides a convenient way to quantify apoptosis in HL-60 cells. Extensive apoptosis can be induced rapidly in undifferentiated HL-60 cells without prevention by cycloheximide or actinomycin D. Therefore, HL-60 cells appear to express constitutively the apoptotic machinery that may be kept under control of a yet unknown repressor. The absence of the tumor suppressor p53 and the presence of bcl-2 are in contrast with the sensitivity of these cells to apoptosis. Agents that modify chromatin structure (zinc, poly[ADPribose] inhibitors, spermine) can block DNA fragmentation without affecting cell survival. By contrast macrophage-like differentiation by phorbol esters suppresses apoptosis without affecting topoisomerase-induced DNA damage. Better understanding of the apoptotic regulation in the widely used and characterized HL-60 cell line should allow the identification of new mechanisms and parameters of cellular sensitivity and resistance to the cytotoxic activity of anticancer agents.     

Amifostine protects against chemotherapy-induced neurotoxicity: an in vitro investigation

BACKGROUND: Peripheral neurotoxicity is a dose-limiting side-effect of a number of effective chemotherapeutic agents. Neuroprotective agents may help to reduce neurotoxicity, thus allowing the intensification of cytostatic therapy in patients. MATERIALS AND METHODS: In this in vitro study, using the rat pheochromocytoma cell line PC-12 neurite-outgrowth assay, the potential of amifostine to protect against cisplatin-, paclitaxel- and vincristine-induced neurotoxicity was investigated Amifostine is described as selectively protecting normal tissue and not tumour tissue. The effect of amifostine on tumour cell kill was investigated using the XTT and colony forming assay. RESULTS: Paclitaxel and vincristine both caused a significant reduction in the percentage of cells expressing neurites. Co-incubation with amifostine significantly increased this percentage of neurites in paclitaxel-induced neurotoxicity, but not in vincristine-induced neurotoxicity. Post-incubation of amifostine also proved to partly reverse already existing cisplatin-induced neurotoxicity, but not paclitaxel-, or vincristine-induced neurotoxicity. Amifostine did not protect tumour cells against cisplatin- and paclitaxel-induced tumour cytotoxicity, using the XTT assay. However, a stimulation of clonogenic capacity was observed when amifostine was coincubated with cisplatin. CONCLUSION: Amifostine protects against paclitaxel-induced neurotoxicity, but not against vincristine-induced neurotoxicity in this in vitro model. Furthermore, amifostine has potential to reverse already existing cisplatin-induced neurotoxicity. The role of amifostine in the proliferative potential of tumour cells in vitro needs further investigation.     

硫化砷对白血病细胞的生长抑制及作用机制

 目的 研究硫化砷（As4S4）通过体外培养对白血病细胞HL-60细胞的生长抑制作用及其分子机制。方法 以不同浓度（7.5 ~ 60 mmol／L）的As4S4作用于体外培养HL-60细胞12 ~ 48 h,四甲基偶氮唑蓝（MTT）法检测细胞生长抑制率,流式细胞仪观察细胞凋亡率,免疫组化法检测bcl-2、p53蛋白表达,应用RT-PCR法检测HL-60细胞中p53 mRNA表达。结果 不同浓度的As4S4作用12 ~ 48 h后,可显著抑制HL-60细胞的生长,呈时间浓度依赖性,并诱导细胞发生凋亡,凋亡率为30.18 % ~ 70.98 %,不同作用时间、不同浓度间凋亡率差异有统计学意义（P＜0.01）,RT-PCR结果显示As4S4作用24 h后,下调p53 mRNA的表达。免疫组化结果显示,bcl-2、p53蛋白表达逐渐降低,并呈浓度依赖性。结论 As4S4能够显著抑制HL-60细胞的生长。诱导其凋亡,并下调bcl-2、p53的表达,可能是其重要机制。     

Dysregulation of apoptosis and a novel mechanism of defective apoptotic signal transduction in human B-cell neoplasms

Apoptotic cell death is essential for normal B-cell development and for shaping the B-cell repertoire. Dysregulation of the Bcl-2 related proteins and alterations of the p53/p14ARF pathway are implicated in the pathogenesis and treatment resistance in human B-cell malignancies. We found a novel mechanism of dysregulated apoptosis in human B lymphoma Raji cells that differs from that of altered Bcl-2 and p53 functions. This cell line was resistant to nuclear apoptosis induced by various stimuli, and neither mitochondrial activation nor activation of caspase-3 led to DNA fragmentation. DNA in purified Raji nuclei was degraded in the presence of lysates from the apoptosis-sensitive cell line HL-60, whereas Raji cell lysates did not induce DNA fragmentation in HL-60 nuclei. Cleavage of ICAD/DFF-45 was normal. These results indicate that the apoptosis signal transduction pathway is defective downstream of caspase-3 in Raji cell cytoplasm. Therefore, exploring the molecular mechanism in this system should provide insight into apoptosis resistance in human B-cell malignancies.     

Amifostine (WR-2721) selective protection against melphalan genotoxicity.

Amifostine (WR-2721) is an aminothiol compound dephosphorylated at the tissue site by alkaline phosphatase to the active metabolite, which is able to inactivate electrophilic substances and scavenge free radicals. Amifostine effects against melphalan-induced DNA strand breaks were studied in normal human white blood cells (WBC) and K562 leukemic cells using the single cell gel electrophoresis (SCGE) or Comet assay, a reported method for measuring DNA damage in individual cells. Prior to treatment (1 h, 37 degrees C) with increasing doses of melphalan, with or without S9, the cells were treated (15 min, 37 degrees C) with a control medium or amifostine (3 mg/ml). Treatment of normal and leukemic cells with melphalan induced a dose-dependent 'comet formation'. Melphalan-induced DNA damage follows a normal distribution in WBC. On the other hand, in K562, a significant proportion of undamaged cells remains even with doses at which mean DNA damage is serious. Pretreatment with WR-2721 protects WBC, but not K562, against the genotoxic effect of melphalan. Amifostine might even strengthen the action of the antiblastic drug against K562 cells. S9 addition appears to enhance melphalan effectiveness. SCGE appears as a suitable primary screening method for in vitro and in vivo studies on drug-DNA interactions and their modulations by endogenous/exogenous factors.     

Bone marrow purging by photodynamic treatment in children with acute leukemia: cytoprotective action of amifostine

In order to evaluate the combined effect of Amifostine and Merocyanine 540 during photoirradiation in neoplastic cells, bone marrow cells from children with acute leukemia (AL), age-matched controls as well as HL-60 cell line were studied. Cell suspensions were incubated with Amifostine, then with MC 540 and they were subsequently exposed to different irradiation doses by Argon Laser 514 nm. Cell survival was estimated by trypan blue supravital stain following a 24-h incubation. The leukemic cell line was studied in continuous liquid cell cultures for 4 weeks. The survival of normal bone marrow progenitors has been estimated by colony formation assay in methylcellulose cultures. Our results showed that Amifostine enhances the photokilling effect of MC 540 on leukemic cells and significantly protects bone marrow nucleated and committed progenitors (BFU-E and CFU-GM) from children with AL under chemotherapy. In conclusion, Amifostine seems to be a promising cytoprotective agent in the clinical use of purging with MC 540 mediated phototherapy.     

Molecular effects of topoisomerase II inhibitors in AML cell lines: correlation of apoptosis with topoisomerase II activity but not with DNA damage.

We examined the cellular effects of topo II inhibitors in two human myeloid cell lines, HL-60 and KG-1 cells, with the purpose of finding molecular markers for the sensitivity of leukemia cells to topo II inhibitors. These cell lines are widely used, well characterized and they differ in their sensitivities to topo II inhibitors. Despite the fact that HL-60 cells are p53-negative, they are much more sensitive than KG-1 cells. Three different topo II inhibitors with distinct molecular ways of action have been used. Daunorubicin and aclarubicin are DNA intercalators that secondarily interact with topo II; etoposide, on the other hand, directly binds to the enzyme. In contrast to daunorubicin, which induces protein-associated DNA double-strand breaks due to the blockage of topo II action, aclarubicin inhibits the access of DNA by topo II. No correlation could be established between the drug-induced DNA damage and apoptosis. In fact, the amount and pattern of DNA damage examined with the 'comet assay' was characteristic for each drug in both cell lines. The DNA binding of daunorubicin was slightly higher in HL-60 cells, but there was no notable variance between the cell lines for aclarubicin. The most striking difference could be found for the nuclear topo II activity, which was about half in KG-1 cells and, additionally, less than 1% of the nuclear topo II activity was bound to the DNA in KG-1 cells when compared to HL-60 cells. This fraction of topo II interacts with the inhibitors; subsequently these findings might well explain the variance in the cellular sensitivity. Additional factors are alterations of the apoptotic pathways, eg loss of p53 in HL-60 cells. Although we found no differences in the quantity of DNA damage between the cell lines after drug treatment, the quality of DNA damage appeared to be distinct for each topo II inhibitor. The morphological appearance of the comet tails after treatment was characteristic for each drug. Further studies are necessary to decide whether these in vitro data are compatible with the clinical situation.     

蛋白酶体抑制剂MG132诱导HL-60细胞凋亡前G2/M期阻滞及机制

背景和目的:蛋白酶体(proteasome)抑制剂能够诱导多种肿瘤细胞凋亡,是一种潜在的有应用前景的抗肿瘤剂.本研究旨在探讨蛋白酶体抑制剂MGl32(Z-Leu-Leu-Leu-CHO)诱导白血病细胞HL-60凋亡和C2/M期阻滞的机制.方法:采用荧光显微镜观察、流式细胞术和免疫印迹研究测定MG132诱导HL-60细胞凋亡和周期阻滞及机制.结果:2μmol/L的MG132能够有效地诱导HL-60细胞凋亡,用药后24 h就显现有细胞凋亡;在MG132诱导HL-60细胞凋亡出现之前有一个明显的G2/M期阻滞,加MG132后12 h时G2/M期时相百分比为63.42±2.02;24 h时加MG132组细胞凋亡为16.67±1.48,与对照组G2/M期时相百分比为7.29±3.01及细胞凋亡为0相比,两者之间有显著性差别(P＜0.01);咖啡因CAF能够减少MG132诱导HL-60细胞出现的G2/M期阻滞,同时也减少凋亡细胞的比例;细胞周期检查点的负调控因子p21waf/cip1蛋白在加MG132处理后3 h有明显的表达,但并未能检测到p53和p27蛋白.结论:MG132诱导HL-60细胞凋亡之前有一个明显的G2/M期阻滞,p21蛋白表达明显上调提示:是p21waf/cip1而不是p53或其同源蛋白参与了其中的调控.     

Southern blot analysis of BII cell line--a putative variant of HL-60

Southern blot analysis of various genes was used to compare the human promyelocytic leukemia cell line HL-60 and the BII cell line, which reportedly arose as a spontaneous differentiation inducer-resistant variant from an HL-60 culture. Granulocyte-macrophage colony stimulating factor gene restriction fragment polymorphism, due to a partial deletion of one of the alleles of this gene in HL-60, was not observed in the BII cells. Furthermore, the p53 oncogene, most of which is deleted in the HL-60 cell line, was found to be intact in the BII cell line. Human leukocyte antigen typing revealed that the two cell lines shared the A locus but differed at the B locus. Several unique restriction fragments hybridizing to human leukocyte antigen class I and DR beta gene probes were observed in the DNA digests of each cell line. Altogether these data provide definitive evidence that BII represents a human cell line of different origin than HL-60. Further lineage determination of this cell line could add a useful member to the group of leukemic cell lines.     

Cell cycle-related expression of p120 nucleolar antigen in normal human lymphocytes and in cells of HL-60 and MOLT-4 leukemic lines: effects of methotrexate, camptothecin, and teniposide.

Expression of the proliferation-associated nucleolar antigen p120 was studied by flow cytometry in human quiescent and phytohemagglutinin-stimulated lymphocytes, as well as in human lymphocytic (MOLT-4) and promyelocytic (HL-60) cell lines. Bivariate analysis of p120 and DNA content made it possible to correlate p120 expression with cell position in the cycle. Proliferating lymphocytes and MOLT-4 and HL-60 cells had a similar pattern of p120 expression. Populations of G1 cells, in all three cell types, were very heterogenous with respect to p120, and a threshold in G1 was observed. The cells with a p120 level below the threshold value did not enter S phase. An increase in p120 was observed during progression through S phase, and the antigen was maximally expressed in G2 cells. The p120/DNA content ratio, however, was highest in late G1 cells (G1B) and was declining during S and G2. The data thus suggest that p120 may be degraded during mitosis and that the postmitotic cells inherit little, if any, of this protein; the antigen then accumulates predominantly during G1, and must reach a threshold level to enable the cells to enter S phase. Antigen p120 could not be detected in noncycling lymphocytes nor in HL-60 cells induced to myeloid differentiation by growth in the presence of dimethyl sulfoxide. Treatment of MOLT-4 cells with pharmacological concentrations of methotrexate, camptothecin, or teniposide induced cell arrest in S or G2; expression of p120 in the arrested cells was unchanged from that of untreated MOLT-4 controls at the same phase of the cycle. The level of p120 was minimal in MOLT-4 or HL-60 cells arrested in M phase by vinblastine, but vinblastine had no effect on p120 fluorescence of interphase cells. Camptothecin or teniposide induced apoptosis selectively in S phase of HL-60 cells; apoptotic cells from camptothecin-treated cultures, however, despite the marked nucleolysis, still expressed p120. The data on the drug-treated cells indicate that the p120 level in tumors of patients may be used as a marker of tumor/malignancy even in clinical samples obtained during treatment.     

Effect of deferoxamine on DNA synthesis, DNA repair, cell proliferation, and differentiation of HL-60 cells

The ribonucleotide reductase inhibitors deferoxamine and hydroxyurea induce monocyte-macrophage cell differentiation in the leukemic cell line HL-60 as judged by the expression of cell surface antigens, nonspecific esterase activity, and morphological changes. Treatment of HL-60 cells with deferoxamine results in inhibition of DNA synthesis and irreversible loss of colony-forming ability. In addition, both deferoxamine and hydroxyurea caused an increase in the number of DNA strand breaks in HL-60 cells. A DNA methylating agent, N-methyl-N'-nitro-N-nitrosoguanidine, also caused cellular differentiation in HL-60 cells associated with DNA strand breaks. These observations are consistent with a role for DNA damage or for inhibition of DNA synthesis and repair in the differentiation process of HL-60 cells.     

p53 is dispensable for UV-induced cell cycle arrest at late G(1) in mammalian cells

Genotoxic agents, including gamma-rays and UV light, induce transient arrest at different phases of the cell cycle. These arrests are required for efficient repair of DNA lesions, and employ several factors, including the product of the tumor suppressor gene p53 that plays a central role in the cellular response to DNA damage. p53 protein has a major function in the gamma-ray-induced cell cycle delay in G(1) phase. However, it remains uncertain as to whether p53 is also involved in the UV-mediated G(1) delay. This report provides evidence that p53 is not involved in UV-induced cellular growth arrest in late G(1) phase. This has been demonstrated in HeLa cells synchronized at the G(1)/S border by aphidicolin, followed by UV exposure. Interestingly, the length of this p53-independent G(1) arrest has been shown to be UV dose-dependent. Similar results were also obtained with other p53-deficient cell lines, including human promyelocytic leukemia HL-60 and mouse p53 knock-out cells. As expected, all of these cell lines were defective in gamma-ray-induced cell growth arrest at late G(1). Moreover, it is shown that in addition to cell cycle arrest, HL-60 cells undergo apoptosis in G(1) phase in response to UV light but not to gamma-rays. Together, these findings indicate that p53- compromised cells have a differential response following exposure to ionizing radiation or UV light.     

Monensin-mediated growth inhibition in acute myelogenous leukemia cells via cell cycle arrest and apoptosis

Monensin, an Na(+) ionophore, regulates many cellular functions including apoptosis. However, there has been no report about the antitumoral effect of monensin on acute myelogenous leukemia (AML). Here, we investigated the antiproliferative effect of monensin on AML cells in vitro and in vivo. Monensin efficiently inhibited the proliferation of all of 10 AML cell lines, with IC(50) of about 0.5 microM. DNA flow cytometric analysis indicated that monensin induced a G(1) and/or a G(2)-M phase arrest in these cell lines. To address the mechanism of the antiproliferative effect of monensin, we examined the effect of monensin on cell cycle-related proteins in HL-60 cells. The levels of CDK6, cyclin D1 and cyclin A were decreased. In addition, monensin not only increased the p27 level but also enhanced its binding with CDK2. Furthermore, the activities of CDK2- and CDK6-associated kinases reduced by monensin were associated with hypophosphorylation of Rb protein. Monensin also induced apoptosis in AML cells including HL-60 cells. The apoptotic process of HL-60 cells was associated with changes in Bax, caspase-3, caspase-8 and mitochondria transmembrane potential (Deltapsi(m)). In particular, monensin (i.p. at a dose of 8 mg/kg thrice weekly) significantly reduced the tumor size of BALB/c mice that were inoculated s.c. with its derived cell line, WEHI-3BD cells (69% growth inhibition relative to control group; p < 0.05). Tumors from monensin-treated mice exhibited increased apoptosis, and these tumor were immunohistochemically more stained with Bax, Fas and p53 antibodies than control tumors. In conclusion, this is the first report that monensin potently inhibits the proliferation of AML cells.