Ionizing Radiation-Induced DNA Damage Response in Primary Melanocytes and Keratinocytes of Human Skin.

Currently, our knowledge of how different cell types in a tissue microenvironment respond to low and high linear energy transfer (LET) radiation is highly restricted. In this study, a comparative analysis was performed on γ-ray-induced DNA damage and repair in primary human melanocytes and keratinocytes isolated from 3 donors. Our study demonstrates a modest interindividual variability in both melanocytes and keratinocytes in terms of both spontaneous and ionizing radiation (IR)-induced 53BP1 foci formation and persistence. Melanocytes, in general, showed a slightly elevated (1.66-2.79 folds more) 53BP1 foci induction relative to keratinocytes after exposure to different doses of γ-rays (0.1-2.5 Gy) radiation. To verify the influence of ATM kinase on IR-induced 53BP1 foci formation, melanocytes and keratinocytes were treated with a specific ATM kinase inhibitor (KU55993, 10 µM) for 1 h prior to radiation. ATM kinase inhibition resulted in the reduction of both spontaneous and IR-induced 53BP1 foci by 17-42% in both melanocytes and keratinocytes of all the 3 donors. Increased persistence of IR-induced 53BP1 foci number was observed in ATM-inhibited melanocytes and keratinocytes after different post exposure times (6 h and 24 h). Taken together, our study suggests that interindividual variations exist in the induction and repair of DNA double-strand breaks (DSBs) in melanocytes and keratinocytes and that ATM is crucial for an optimal DSB repair efficiency in both human skin cell types.

Analysis of ionizing radiation induced DNA damage response in human adult stem cells and differentiated neurons.

Findings of neurodegenerative features associated with human radiosensitive syndromes such as Ataxia telangiectasia suggest that DNA repair efficiency is crucial for maintaining the functional integrity of central nervous system. To gain a better understanding of ionizing radiation (IR) induced DNA damage response in undifferentiated and differentiated neural cell types and to evaluate the role of ATM in DNA double strand break (DSB) repair, an in vitro human neural cell differentiation model system was utilized in this study. As compared to adult stem cells, differentiated neurons displayed an attenuated DSB repair response (as judged by the persistence of 53BP1 foci) after IR exposure and the attenuation was even more pronounced in stem cells and neurons after suppression of ATM (Ataxia Telangiectasia Mutated) gene product suggesting the importance of ATM for an optimal DSB repair efficiency in human neural cell types. In corroboration with an attenuated DNA damage response, a sharp decline in the expression levels of several DSB repair genes was observed in neurons. Our results suggest that cellular differentiation modulates the expression of several genes thereby compromising the DSB repair fidelity in post mitotic neurons. Further studies are required to verify whether or not ATM mediated exacerbation of DNA repair deficiency in differentiated neurons leads to neurodegeneration.

N4-methylation of cytosine drastically favors the formation of (6-4) photoproducts in a TCG context.

Methylation of cytosine is a common biological process both in prokaryotic and eukaryotic cells. In addition to 5-methylcytosine (5mC), some bacterial species contain in their genome N(4) -methylcytosine (N4mC). Methylation at C5 has been shown to enhance the formation of pyrimidine dimeric photoproducts but nothing is known of the effect of N4 methylation on UV-induced DNA damage. In the present work, we compared the yield and the nature of bipyrimidine photoproducts induced in a series of trinucleotides exhibiting a TXG sequence where X is either T, C, 5mC or N4mC. HPLC associated to tandem mass spectrometry was used to quantify cyclobutane pyrimidine dimers (CPD), (6-4) photoproducts (64PP) and their Dewar valence isomer. Methylation at position N4 was found to drastically increase the reactivity of C upon exposure to both UVC and UVB and to favor the formation of 64PP. In contrast methylation at C5 increased the yield of CPD at the expense of 64PP. In addition, enhancement of photoreactivity by C5 methylation was much higher in the UVB than in the UVC range. These results show the drastic effect of the methylation site on the photochemistry of cytosine.

The significance of the Dewar valence photoisomer as a UV radiation-induced DNA photoproduct in marine microbial communities.

Induction of pyrimidine dimers in DNA by solar UV radiation has drastic effects on microorganisms. To better define the nature of these DNA photoproducts in marine bacterioplankton and eukaryotes, a study was performed during a cruise along a latitudinal transect in the Pacific Ocean. The frequency of all possible cyclobutane pyrimidine dimers, pyrimidine (6-4) pyrimidone photoproducts (64PPs) and their related Dewar valence isomers (DEWs) was determined by high-performance liquid chromatography-mass spectrometry. Studied samples were bacterioplankton and eukaryotic fractions isolated from sea water either collected before sunrise or exposed to ambient sunlight from sunrise to sunset. Isolated DNA dosimeters were also exposed to daily sunlight for comparison purposes. A first major result was the observation in all samples of large amounts of DEWs, a class of photoproducts rarely considered outside photochemical studies. Evidence was obtained for a major role of UVA in the formation of these photoisomerization products of 64PPs. Considerations on the ratio between the different classes of photoproducts in basal and induced DNA damage suggests that photoenzymatic repair (PER) is an important DNA repair mechanism used by marine microorganisms occupying surface seawater in the open ocean. This result emphasizes the biological role of DEWs which are very poor substrate for PER.

p53-independent downregulation of histone gene expression in human cell lines by high- and low-let radiation.

Using microarrays to analyze differential gene expression as a function of p53 status and radiation quality, we observed downregulation of a large set of histone genes in p53 wild-type TK6 cells 24 h after exposure to equitoxic doses of high-LET (1.67 Gy 1 GeV/amu (56)Fe ions) or low-LET (2.5 Gy γ rays) radiation. Quantitative real-time PCR of specific subtypes of core (H2A, H2B, H3 and H4) and linker (H1) histones confirmed this result. DNA synthesis and histone gene expression are tightly coordinated during the S phase of the cell cycle, and both processes are regulated by cell cycle checkpoints in response to DNA damage caused by ionizing radiation. However, we observed similar repression of histone gene expression in both TK6 cells and their p53-null derivative NH32 after radiation exposure, although the histone gene expression was not decreased to the same extent in NH32 cells as it was in TK6 cells. We also found decreased histone gene expression that was dose- and time-dependent in the colon cancer cell line HCT116 and its p53-null derivative. These results show that both high- and low-LET radiation exposure negatively regulate histone gene expression in human lymphoblastoid and colon cancer cell lines independent of p53 status.

Human RecQL4 helicase plays critical roles in prostate carcinogenesis.

Prostate cancer is the second leading cause of cancer-associated deaths among men in the western countries. Here, we report that human RecQL4 helicase, which is implicated in the pathogenesis of a subset of cancer-prone Rothmund-Thomson syndrome, is highly elevated in metastatic prostate cancer cell lines. Increased RecQL4 expression was also detected in human prostate tumor tissues as a function of tumor grade with the highest expression level in metastatic tumor samples, suggesting that RecQL4 may be a potential prognostic factor for advanced stage of prostate cancer. Transient and stable suppression of RecQL4 by small interfering RNA and short hairpin RNA vectors drastically reduced the growth and survival of metastatic prostate cancer cells, indicating that RecQL4 is a prosurvival factor for prostate cancer cells. RecQL4 suppression led to increased poly(ADP-ribose) polymerase (PARP) synthesis and RecQL4-suppressed prostate cancer cells underwent an extensive apoptotic death in a PARP-1-dependent manner. Most notably, RecQL4 knockdown in metastatic prostate cancer cells drastically reduced their cell invasiveness in vitro and tumorigenicity in vivo, showing that RecQL4 is essential for prostate cancer promotion. Observation of a direct interaction of retinoblastoma (Rb) and E2F1 proteins with RecQL4 promoter suggests that Rb-E2F1 pathway may regulate RecQL4 expression. Collectively, our study shows that RecQL4 is an essential factor for prostate carcinogenesis.

Influence of growth temperature and starvation state on survival and DNA damage induction in the marine bacterium Sphingopyxis alaskensis exposed to UV radiation.

Despite the considerable volume of literature describing the individual effects of temperature or UV light on aquatic bacteria, little is known about their combined effects. The current study was conducted to learn about the effects of growth temperature and duration of starvation on the response of a marine bacterium, Sphingopyxis alaskensis to UV-B or simulated solar radiation. Cells grown at 12 degrees C or 24 degrees C, and harvested at early or late stationary phase, were exposed to UV-B or simulated solar radiation (>290 nm). The predominant forms of UV-induced DNA damage, namely cyclobutane pyrimidine dimers (CPDs) and (6-4) photoproducts (6-4PP s), were quantified using a HPLC-mass spectrometry. While the commonly accepted view that DNA damage induced by UV-B radiation is temperature-independent, we observed in S. alaskensis that the yield of photoproducts for 12 degrees C was generally lower than for cells grown at 24 degrees C. The relative distribution of DNA photoproducts also varied with growth temperature, with an increased formation of TC 6-4PP for late compared to early stationary phase cells. In contrast, with the exception of cultures grown at 12 degrees C exposed to simulated solar radiation, the duration of stationary phase had no effect on total photoproduct formation. Collectively, these data indicate that growth temperature has more effect than duration of starvation on the formation of photoproducts in S. alaskensis.

DNA-dependent protein kinase (DNA-PK)-deficient human glioblastoma cells are preferentially sensitized by Zebularine.

Brain tumor cells respond poorly to radiotherapy and chemotherapy due to inherently efficient anti-apoptotic and DNA repair mechanisms. This necessitates the development of new strategies for brain cancer therapy. Here, we report that the DNA-demethylating agent Zebularine preferentially sensitizes the killing of human glioblastomas deficient in DNA-dependent protein kinase (DNA-PK). In contrast to DNA-PK-proficient human glioblastoma cells (MO59K), cytotoxicity assay with increasing Zebularine concentrations up to 300 microM resulted in a specific elevation of cell killing in DNA-PK-deficient MO59J cells. Further, an elevated frequency of polyploid cells observed in MO59J cells after Zebularine treatment pointed out a deficiency in mitotic checkpoint control. Existence of mitotic checkpoint deficiency in MO59J cells was confirmed by the abnormal centrosome number observed in Zebularine-treated MO59J cells. Although depletion of DNA methyltransferase 1 by Zebularine occurred at similar levels in both cell lines, MO59J cells displayed increased extent of DNA demethylation detected both at the gene promoter-specific level and at the genome overall level. Consistent with increased sensitivity, deoxy-Zebularine adduct level in the genomic DNA was 3- to 6-fold higher in MO59J than in MO59K cells. Elevated micronuclei frequency observed after Zebularine treatment in MO59J cells indicates the impairment of DNA repair response in MO59J cells. Collectively, our study suggests that DNA-PK is the major determining factor for cellular response to Zebularine.

Analysis of ionizing radiation-induced DNA damage and repair in three-dimensional human skin model system.

Knowledge of cellular responses in tissue microenvironment is crucial for the accurate prediction of human health risks following chronic or acute exposure to ionizing radiation (IR). With this objective, we investigated the radio responses for the first time in three-dimensional (3D) artificial human skin tissue microenvironment after gamma-rays radiation. IR-induced DNA damage/repair response was assessed by immunological analysis of well-known DNA double strand break (DSB) repair proteins, i.e. 53BP1 and phosphorylated ataxia telangiectasia mutated(ser1981) (ATM(ser1981)). Efficient 53BP1 and phosphorylated ATM foci formation was observed in human EpiDerm tissue constructs after low and high doses of gamma-rays. Interestingly, EpiDerm tissue constructs displayed less 53BP1 and ATM foci number at all radiation doses (0.1, 1, 2.5 and 5 Gy) than that observed for 2D human fibroblasts. DSB repair efficiency judged by the disappearance of 53BP1 foci declined with increasing doses of gamma-rays and tissue constructs irradiated with 2.5 and 5 Gy of gamma-rays displayed 53BP1 foci persisting up to 72 h of analysis. Pretreatment of EpiDerm tissue constructs with LY294002, [an inhibitor of phosphatidylinositol-3 kinase and PI-3 kinase like kinases (PIKK)] completely abolished IR-induced 53BP1 foci formation and increased the apoptotic death. This observation indicates the importance of PIKK signalling pathway for efficient radiation responses in intact tissue constructs. In summary, we have successfully demonstrated the feasibility of monitoring the DNA damage response in human skin tissue microenvironment. In this system, 53BP1 can be used as a useful marker for monitoring the DSB repair efficiency.

Sunlight-induced DNA damage in marine micro-organisms collected along a latitudinal gradient from 70 degrees N to 68 degrees S.

We examined ultraviolet radiation (UVR)-induced DNA damage in marine micro-organisms collected from surface seawater along a latitudinal transect in the Central Pacific Ocean from 70 degrees N to 68 degrees S. Samples were collected predawn and incubated under ambient UVR in transparent incubators at in situ temperatures until late afternoon at which time they were filtered into primarily bacterioplankton and eukaryotic fractions. Cyclobutane pyrimidine dimers (CPDs) and (6-4) photoproducts [(6-4)PDs] were quantified in DNA extracts using radioimmunoassays. UVB was lowest in the polar regions and highest near the equator and correlations between UVB and DNA damage were observed. The eukaryotic fraction showed significant CPDs across the entire transect; (6-4)PDs were detected only in the tropics. The bacterial fraction showed no accumulation of (6-4)PDs at any latitude, although residual (6-4)PDs were observed. Bacterial cell volumes were greatest in the sub-Arctic and northern temperate latitudes and lower in the tropics and southern hemisphere, a unique observation that parallels Bergmann's rule. A strong negative correlation was observed between cell volume and CPDs. The environmental impact of solar UVR on marine micro-organisms in the open ocean is complex and our results suggest that several factors such as DNA repair, cell size, temperature, salinity, nutrients and species composition are important in determining relative sensitivity.

Increased susceptibility of human small airway epithelial cells to apoptosis after long term arsenate treatment.

Inorganic arsenic (arsenate and arsenite) are well known human carcinogens. Apoptosis is a normal biological process that is involved in regulating cell development and differentiation, and is an important protective response to cell injury. The aim of this study was to determine the long term arsenic effect on human small airway epithelial cells (SAEC) by analyzing two distinct apoptosis-inducing agents, Fas ligand (Fas L), which evokes death receptor-mediated apoptosis, and hydrogen peroxide H2O2, which induces apoptosis mediated by reactive oxygen species (ROS). The SAEC were continuously exposed to 0.5 microg/mL arsenic for 28 weeks, and apoptosis was examined after 24 h treatment with either Fas L or H2O2. SAEC displayed decreased cell viability and increased apoptosis after treatment with Fas L and H2O2, compared to non-arsenic treated control cells. Furthermore, treatment of these arsenic-exposed SAEC with Fas L or H2O2 induced cleavage of the DNA damage recognition protein, poly (ADP-ribose) polymerase (PARP), and the 'effector' caspase, Caspase-3, both canonical indicators of apoptosis. We observed increased phosphorylation of p38, a member of the MAP kinase family, following treatment with Fas L or H2O2. To confirm the involvement of p38 in the regulation of apoptosis we pretreated cells with the p38 kinase inhibitor, SB 203580 and observed a significant decrease in apoptosis.

Effect of the GC content of DNA on the distribution of UVB-induced bipyrimidine photoproducts.

Solar UV radiation is a major mutagen that damages DNA through the formation of dimeric photoproducts between adjacent thymine and cytosine bases. A major effect of the GC content of the genome is thus anticipated, in particular in prokaryotes where this parameter significantly varies among species. We quantified the formation of UV-induced photolesions within both isolated and cellular DNA of bacteria of different GC content. First, we could unambiguously show the favored formation of cytosine-containing photoproducts with increasing GC content (from 28 to 72%) in isolated DNA. Thymine-thymine cyclobutane dimer was a minor lesion at high GC content. This trend was confirmed by an accurate and quantitative analysis of the photochemical data based on the exact dinucleotide frequencies of the studied genomes. The observation of the effect of the genome composition on the distribution of photoproducts was then confirmed in living cells, using two marine bacteria exhibiting different GC content. Because cytosine-containing photoproducts are highly mutagenic, it may be predicted that species with genomes exhibiting a high GC content are more susceptible to UV-induced mutagenesis.

Effect of stratospheric ozone depletion and enhanced ultraviolet radiation on marine bacteria at Palmer Station, Antarctica in the early austral spring.

We investigated the interactions between ozone-depleted air masses and subsequent changes in UVB on marine bacterial abundance and production at Palmer Station, Antarctica from September to November 1999. During periods of low total column ozone (TCO), bacterial cell concentrations declined by 57%. Photoinhibition of bacterial [(3)H]-leucine (Leu) and [(3)H]-thymidine (TdR) incorporation due to UVB was greatest during periods of low TCO in September and early October. During diel ( approximately 28 h) exposure experiments, light treatment samples exhibited >75-100% inhibition of TdR incorporation by mid-afternoon. Leu incorporation exhibited maximum inhibition (50-100%) at sunset and early evening hours. Leu and TdR incorporation in light treatment samples did not exhibit recovery during subsequent periods of darkness. Bacterial Leu and TdR incorporation rates were inversely related to Setlow Dose during a period of recovery from low TCO. These data further suggested a threshold exposure below which bacterial Leu and TdR incorporation recovered rapidly. Recovery of bacterial production after acute Setlow Dose exposures lagged recovery of TCO and was linearly related to TCO measured 2 days previously. This lag in recovery may have resulted from the energetically expensive repair of UVR-induced DNA damage acquired during periods of low TCO.