Transcriptional response to ionizing radiation in human radiation sensitive cell lines.

BACKGROUND AND PURPOSE: Radiation is a common treatment of cancer, but some patients show severe side effects when exposed to small doses of radiation. The aim of this study was to explore the underlying cause of radiation sensitivity in a group of radiation sensitive patients. MATERIALS AND METHODS: Lymphoblastoid cell lines from 5 normal individuals, 4 Ataxia Telangiectasia (AT), and 12 non-AT radiation sensitive (RS) patients were irradiated. RNA was isolated before and after radiation and hybridized to 15k cDNA microarrays and gene expression was recorded. RESULTS AND CONCLUSION: The RS cell lines showed an expression phenotype different from both the AT and normal cell lines. Six of the RS cell lines had a distinct expression profile before radiation. This implies that the RS patients are a heterogeneous group, but that six of the patients may have a common cause of radiation sensitivity.     

AMPK regulates metabolism and survival in response to ionizing radiation

Background and purpose

AMPK is a metabolic sensor and an upstream inhibitor of mTOR activity. AMPK is phosphorylated by ionizing radiation (IR) in an ATM dependent manner, but the cellular consequences of this phosphorylation event have remained unclear. The objective of this study was to assess whether AMPK plays a functional role in regulating cellular responses to IR.

Methods

The importance of AMPK expression for radiation responses was investigated using both MEFs (mouse embryo fibroblasts) double knockout for AMPK α1/α2 subunits and human colorectal carcinoma cells (HCT 116) with AMPK α1/α2 shRNA mediated knockdown.

Results

We demonstrate here that IR results in phosphorylation of both AMPK and its substrate, ACC. IR moderately stimulated mTOR activity, and this was substantially exacerbated in the absence of AMPK. AMPK was required for IR induced expression of the mTOR inhibitor REDD1, indicating that AMPK restrains mTOR activity through multiple mechanisms. Likewise, cellular metabolism was deregulated following irradiation in the absence of AMPK, as evidenced by a substantial increase in oxygen consumption rates and lactate production. AMPK deficient cells showed impairment of the G1/S cell cycle checkpoint, and were unable to support long-term proliferation during starvation following radiation. Lastly, we show that AMPK proficiency is important for clonogenic survival after radiation during starvation.

Conclusions

These data reveal novel functional roles for AMPK in regulating mTOR signaling, cell cycle, survival and metabolic responses to IR.     

Restoration of fragile histidine triad expression restores Chk2 activity in response to ionizing radiation in oral squamous cell carcinoma cells

Early in tumorigenesis, a DNA damage-response network is activated in preneoplastic cells that delays or prevents cancer. Activation of the Chk2 G₂/M checkpoint kinase and loss of fragile histidine triad (Fhit) tumor suppressor expression increase cellular susceptibility to DNA-damaging 'oncogenic' stressors, particularly in precursor or precancerous lesions. To understand the mechanism of oral carcinogenesis, we assessed the association between phosphorylated Chk2 (pChk2) and Fhit expression in oral squamous cell carcinoma. Loss of Fhit expression was an early event during oral carcinogenesis, whereas a decrease in the number of pChk2-positive cells was associated with tumor progression. Although tyrosine 114 is known to be essential to Fhit's tumor-suppressing activity, both wild-type and tyrosine 114 mutant Fhit increased the population of subG₁ DNA-containing HSC-3 OSCC cells with elevated pChk2 levels. In particular, when cells were exposed to ionizing radiation, pChk2 levels were upregulated dramatically, as were those of its downstream target Cdc25C. Knockdown of Fhit with FHIT small interfering RNA diminished the ionizing radiation-induced Chk2 phosphorylation in HEK293 cells. Furthermore, Fhit -deficient mice demonstrated a decrease in the number of pChk2-positive cells not only in dysplastic lesions but also in N -nitrosobenzylamine-induced papilloma of the forestomach, suggesting that lack of Fhit expression and the resultant defects of the ataxia telangiectasia mutated–Chk2 pathway can cause a difference in the incidence of N -nitrosobenzylamine-induced forestomach lesions. These findings suggest that Fhit plays a key role in the regulation of the ataxia telangiectasia mutated–Chk2 DNA damage response during oral carcinogenesis. ( Cancer Sci 2008; 99: 524–530)     

Distinct response to ionizing radiation of human prostate cell lines

The purpose of this study was to determine in vitro the relationship between ionizing radiation (IR) treatment, reactive oxygen species (ROS) production, lipid peroxidation, glutathione (GSH) levels, and DNA damage of the human benign prostate hyperplasia BPH-1 cell line, and two prostate cancer cell lines, LNCaP, which is androgen-sensitive, and DU-145, which is androgen non-responsive. The cells were analysed after exposure to 1.0 or 2.0 Gy of X-ray radiations. The response to IR treatment was evaluated by examining: ROS production by quantitative analysis with fluorescent probe 5 and 6-carboxy-2'7'-dichlorodihydrofluorescein diacetate bis acetomethyl ester (DCFH-DA), GSH levels by 2,2'-dinitro-5,5'-dithio-benzoic acid (DTNB), and lipoperoxidation by thiobarbituric acid reactive substances (TBARS) analysis. To study IR-induced DNA damage, Single Cell Gel Electrophoresis or comet assay was performed. DU-145 cells were characterized by higher DNA damage, more evident extent of lipid peroxidation, and slighter levels of ROS and GSH compared to BPH-1 or LNCaP. Human benign BPH-1 and cancer LNCaP and DU-145 cell lines are not equal regarding their capability of IR resistance in terms of ROS production, antioxidant potential, IR-induced lipid peroxidation and DNA damage.     

Transient inhibition of ATM kinase is sufficient to enhance cellular sensitivity to ionizing radiation

In response to DNA damage, the ATM protein kinase activates signal transduction pathways essential for coordinating cell cycle progression with DNA repair. In the human disease ataxia-telangiectasia, mutation of the ATM gene results in multiple cellular defects, including enhanced sensitivity to ionizing radiation (IR). This phenotype highlights ATM as a potential target for novel inhibitors that could be used to enhance tumor cell sensitivity to radiotherapy. A targeted compound library was screened for potential inhibitors of the ATM kinase, and CP466722 was identified. The compound is nontoxic and does not inhibit phosphatidylinositol 3-kinase (PI3K) or PI3K-like protein kinase family members in cells. CP466722 inhibited cellular ATM-dependent phosphorylation events and disruption of ATM function resulted in characteristic cell cycle checkpoint defects. Inhibition of cellular ATM kinase activity was rapidly and completely reversed by removing CP466722. Interestingly, clonogenic survival assays showed that transient inhibition of ATM is sufficient to sensitize cells to IR and suggests that therapeutic radiosensitization may only require ATM inhibition for short periods of time. The ability of CP466722 to rapidly and reversibly regulate ATM activity provides a new tool to ask questions about ATM function that could not easily be addressed using genetic models or RNA interference technologies.     

ATM-dependent phosphorylation and accumulation of endogenous BLM protein in response to ionizing radiation

Bloom's syndrome (BS), a rare genetic disease, arises through mutations in both alleles of the BLM gene which encodes a 3'-5' DNA helicase identified as a member of the RecQ family. BS patients exhibit a high predisposition to development of all types of cancer affecting the general population and BLM-deficient cells display a strong genetic instability. We recently showed that BLM protein expression is regulated during the cell cycle, accumulating to high levels in S phase, persisting in G2/M and sharply declining in G1, suggesting a possible implication of BLM in a replication (S phase) and/or post-replication (G2 phase) process. Here we show that, in response to ionizing radiation, BLM-deficient cells exhibit a normal p53 response as well as an intact G1/S cell cycle checkpoint, which indicates that ATM and p53 pathways are functional in BS cells. We also show that the BLM defect is associated with a partial escape of cells from the gamma-irradiation-induced G2/M cell cycle checkpoint. Finally, we present data demonstrating that, in response to ionizing radiation, BLM protein is phosphorylated and accumulates through an ATM-dependent pathway. Altogether, our data indicate that BLM participates in the cellular response to ionizing radiation by acting as an ATM kinase downstream effector.     

PARP-1, PARP-2, and the cellular response to low doses of ionizing radiation

PURPOSE: Poly(ADP-ribose) polymerase-1 (PARP-1) is rapidly and directly activated by single-strand breaks and is required for efficient base excision repair. These properties indicate that inhibition of PARP-1 might enhance the cellular response to low doses of radiation. We tested the effect of chemical inhibition of PARP-1 on low-dose clonogenic survival in a number of cell lines and the low-dose radiation response of a PARP-1 knockout murine cell line. METHODS AND MATERIALS: Clonogenic cell survival of V79-379A and CHO-K1 hamster fibroblasts, T98G and U373-MG human glioma cells, and 3T3 mouse embryo fibroblast PARP-1 knockout cells was measured using a precise flow cytometry-based plating assay. Chemical inhibitors of PARP enzymes were tested for their effect on clonogenic survival after a range of ionizing radiation doses. RESULTS: Chemical inhibition of PARP activity induced marked radiosensitization of V79, CHO, and exponentially growing T98G cells in the 0.05-0.3-Gy range. This effect was not seen in U373 cells or in confluent T98G populations. Low-dose radiosensitization was not apparent in PARP-1 knockout cells. CONCLUSION: Low-dose radiosensitization of actively dividing tumor cells by PARP-1 inhibitors suggests that they may have a role in enhancing the efficacy of ultrafractionated or low-dose-rate radiotherapy regimens. We hypothesize that PARP-2 compensates for the absence of PARP-1 in the knockout cell line.     

ATM对辐射后AT细胞端粒酶活性的影响

目的:探讨ATM对电离辐射照射的毛细血管扩张共济失调症(ataxia telangiectasia,AT)患者皮肤的成纤维细胞系AT细胞(ATSBIVA)端粒酶活性的影响。方法:以源于正常人皮肤的成纤维细胞系GM细胞(GM0639)为对照,应用基于PCR的端粒重复扩增技术(telomeric repeat amplification protocal,TRAP)与高效液相色谱(HPLC)技术,定量分析细胞分别经0、1、3、5 Gy 60Coγ射线照射后以及经3 Gy 60Coγ射线照射后继续培养2、24、48、72 h,AT、空载体AT、ATM -AT和GM细胞的端粒酶活性的变化。结果:未照射时,除GM细胞外,AT、空载体AT、ATM -AT细胞均呈现较高的端粒酶活性表达,但ATM -AT细胞的端粒酶活性明显低于AT和空载体AT细胞的端粒酶活性(P<0．01),而后二者无明显差异(P> 0．05);电离辐射照射后,AT、空载体AT、ATM -AT和GM细胞的端粒酶活性均呈剂量依赖性和时间依赖性增强,且在相同剂量点与时间点,ATM -AT细胞的端粒酶活性高于GM细胞(P<0．01)(除5 Gy计量点外),但低于AT和空载体AT细胞(P<0．01),而后二者无明显差异(P>0．05)。结论:电离辐射可诱导细胞端粒酶活性表达;并且细胞端粒酶活性水平随剂量与时间的增加而增加;ATM可下调AT细胞端粒酶活性水平。推测端粒酶参与电离辐射诱导DNA损伤的修复。     

Identification and characterization of three subtypes of radiation response in normal human urothelial cultures exposed to ionizing radiation

In an attempt to assess genetic variation underlying the variation in human responses to radiation exposure, measurements of apoptosis, necrosis and induction of key proteins were made in primary explant cultures of human normal urothelium and correlated with growth post- exposure to a range of doses of (60)Co. These data were validated by similar experiments using CBA/H and C57/BL6 mouse strains, known to exhibit genetically determined differences in response to radiation. The data for human tissues show a wide variation in response with three broad categories being identifiable. The commonest had a hypersensitive response involving considerable apoptosis in the low dose region, followed by 'induction' of a survival response at higher doses involving the persistence of abnormal cells. The pattern of gene expression was consistent with suppression of apoptosis. The second category showed no induction of survival and considerable necrosis was seen in the progeny. The rarest category showed an extremely hypersensitive low dose response and despite induction of a survival response, the sensitivity to higher doses was very severe. Considerable apoptosis and necrosis were seen in these cultures. In the mouse experiments, strain CBA/H (mice known to exhibit genetic instability post-irradiation) had lower levels of delayed cell death and apoptosis than C57/BL6 mice (which exhibit significantly less instability). It is concluded that there is a variation in response to radiation between human patient cultures which is detectable in this system and which is consistent with a pattern of radiation- induced delayed death/apoptosis correlating with long-term genomic stability. The mouse experiments demonstrate the importance of genetic factors in determining these responses.     

What role do glutathione S-transferases play in the cellular response to ionizing radiation?

The glutathione S-transferases (GST's) are cytosolic dimeric proteins that are composed of three family members, alpha, pi, and mu, and a fourth microsomal member. These four family members are primarily involved in cellular detoxification of xenobiotics and hydroperoxides. Recently, a strong correlation has been found between the overexpression of GST's and resistance to chemotherapeutic drugs. In comparison to chemotherapy, little is known about the role of GST's in the cellular response to ionizing radiation. To determine which GST's may be involved in this response, we have identified Chinese hamster ovary cell lines that possess different levels of alpha and pi GST isozyme activity. The survival of these cell lines to ionizing radiation was similar to that of wild-type Chinese hamster ovary-KI cells from which they were derived. Although differences in GST levels did not affect ionizing radiation sensitivity per se, we found that ionizing radiation decreased the amount of cytosolic pi GST without affecting alpha GST levels. Taken together, these data suggest that GST's are involved in the cellular response against oxidative stress generated by ionizing radiation.     

Differential response to ablative ionizing radiation in genetically distinct non-small cell lung cancer cells

Stereotactic ablative radiotherapy (SABR) has emerged as a highly promising treatment for medically inoperable early-stage non-small cell lung cancer patients. Treatment outcomes after SABR have been excellent compared to conventional fractionated radiotherapy (CFRT). However, the biological determinants of the response to ablative doses of radiation remain poorly characterized. Furthermore, there's little data on the cellular and molecular response of genetically distinct NSCLC subtypes to radiation. We assessed the response of 3 genetically distinct lung adenocarcinoma cell lines to ablative and fractionated ionizing radiation (AIR and FIR). We studied clonogenic survival, cell proliferation, migration, invasion, apoptosis and senescence. We also investigated the effect of AIR and FIR on the expression of pro-invasive proteins, epithelial-to-mesenchymal transition (EMT), extracellular signal-regulated kinases (ERK1/2) and the transmembrane receptor cMET. Our findings reveal that AIR significantly reduced cell proliferation and clonogenic survival compared to FIR in A549 cells only. This differential response was not observed in HCC827 or H1975 cells. AIR significantly enhanced the invasiveness of A549 cells, but not HCC827 or H1975 cells compared to FIR. Molecular analysis of pathways involved in cell proliferation and invasion revealed that AIR significantly reduced phosphorylation of ERK1/2 and upregulated cMET expression in A549 cells. Our results show a differential proliferative and invasive response to AIR that is dependent on genetic subtype and independent of intrinsic radioresistance. Further examination of these findings in a larger panel of NSCLC cell lines and in pre-clinical models is warranted for identification of biomarkers of tumor response to AIR.     

Increased sensitivity of EBNA2-transformed rat fibroblasts to ionizing radiation

To clarify whether expression of Epstein-Barr virus (EBV) nuclear antigen 2 (EBNA2) correlates with sensitivity to ionizing radiation, we tested EBNA2-transformed rat fibroblast clones for their radiosensitivity to X-rays. These transformed clones reproducibly generated tumors in mice. X-irradiation suppressed the growth of the tumors, and irradiated mice survived longer than non-irradiated ones. In contrast, tumors formed by activated H-ras or E6-E7 genes of human papillomavirus type 16 (HPV16) were strongly resistant to the same dose of X-irradiation. In in vitro culture, these EBNA2-expressing clones also showed higher radiosensitivity than cell lines transformed by activated H-ras and E6-E7 genes. The averaged D_o of EBNA2-expressing clones was 2.3 times lower than that of nonexpressing and control clones. These results suggest that expression EBNA2 is responsible for the radiosensitivity. © 1996 Wiley-Liss, Inc.     

Typical cell signaling response to ionizing radiation: DNA damage and extranuclear damage

To treat many types of cancer, ionizing radiation (IR) is primarily used as external‐beam radiotherapy, brachytherapy, and targeted radionuclide therapy. Exposure of tumor cells to IR can induce DNA damage as well as generation of reactive oxygen species (ROS) and reactive nitrogen species (RNS) which can cause non‐DNA lesions or extracellular damage like lipid perioxidation. The initial radiation‐induced cell responses to DNA damage and ROS like the proteolytic processing, as well as synthesis and releasing ligands (such as growth factors, cytokines, and hormone) can cause the delayed secondary responses in irradiated and unirradiated bystander cells through paracrine and autocrine pathways.     

Phosphatidylinositol 3-kinase/Akt signaling in the response of vascular endothelium to ionizing radiation

Growth factor enhancement of endothelial cell viability occurs through phosphatidylinositol 3-kinase (PI3K)/Akt-mediated inhibition of apoptosis. The PI3K/Akt signal transduction pathway was activated by both vascular endothelial growth factor and ionizing radiation. Radiation- and vascular endothelial growth factor-induced phosphorylation of Akt was inhibited by PI3K antagonists. To determine whether this signal transduction pathway represents a therapeutic target in tumor vascular endothelium, we examined the effects of the PI3K inhibitors wortmannin and LY294002 on irradiated endothelium. Wortmannin and LY294002 enhanced radiation-induced apoptosis and cytotoxicity in endothelial cells. Tumor vascular window and Doppler ultrasound showed that PI3K antagonists enhanced radiation-induced destruction of tumor blood vessels. Tumor growth delay was significantly increased after treatment with LY294002 followed by irradiation as compared with either agent alone. PI3K in tumor vascular endothelium is a potential therapeutic target to enhance the efficacy of ionizing radiation.