Resposta celular associada à expressão de galectina-3 em linhagens de melanoma expostas a irradiação / Cellular response associated to galectin-3 expression in exposed irradiation melanoma cells

O câncer de pele é um dos mais frequentes entre humanos, sendo o melanoma o tipo menos comum, mas com grande importância devido à agressividade que ele apresenta. Um dos principais agentes etiológicos deste tipo de tumor é a radiação ultravioleta proveniente da luz solar. A fração de radiação ultravioleta B (UVB) gera dano no DNA e induz alterações nas células da pele após a exposição prolongada e sem proteção. A resposta à luz UVB em melanócitos e melanomas é diferente, mostrando a importância do perfil celular. O efeito genotóxico da luz UVB pode alterar a expressão de moléculas como galectina-3 e MAPKs, desencadeando respostas UVB-dependentes. Galectina-3 é uma lectina que reconhece beta-galactosídeos e está envolvida na regulação de diversos processos celulares que modificam a viabilidade celular e a proliferação. Esta molécula é ubiquamente expressa apresentando um comportamento específico dependendo da sua localização subcelular. No presente trabalho mostramos que a distribuição de galectina-3 em melanoma e melanócitos é ampla, encontrando-se tanto no núcleo como no citoplasma, podendo ser modificada após irradiação UVB ou ainda secretada para o meio extracelular. Além disso, observamos que a luz UVB ativa a via de MAPKs, proteínas quinases ativadas por mitógenos envolvidas no crescimento, sobrevivência, diferenciação e resposta a estresse, em melanócitos e em melanomas poucos minutos após a exposição à UVB. Uma maior atividade de p38 e de ERK é evidenciada em melanomas, enquanto que em melanócitos a via de p38 é a mais ativa, corroborando a noção de que a resposta celular à luz UVB difere entre melanócitos e melanoma. As moléculas p38 e JNK são proteínas quinases ativada pelo estresse (SAPK). A via de JNK não é tão responsiva em alguns melanomas, mas ativação desta molécula parece estar envolvida com a sobrevivência celular e a translocação mitocondrial após UVB...

Skin cancer is the most common cancer among humans, melanoma being the least common type but very important due to its aggressive behavior. A major etiologic agent of this type of tumor is ultraviolet radiation from the sunlight. The ultraviolet B rays (UVB) cause DNA damage and induce alterations over the skin cells after prolonged exposition without protection. The UVB response in melanocytes and melanoma cells is different. This shows the importance of the cellular profile. The genotoxic effect of UVB light can alter the expression of molecules such as galectine-3 and MAPKs and also triggers multiple responses UVB-dependent. Galectin-3 is a lectin that recognizes beta-galactosides. It is involved in the regulation of many cellular processes that modify cellular viability and proliferation and presents specific behavior depending on its subcellular localization. In the present study we showed that galectine-3 distribution in melanoma cells and melanocytes is large, lying both in the nucleus and in the cytoplasm. After UVB irradiation this distribution could be modified or even galactine-3 secreted itself into the extracellular space. Moreover, we observed that UVB light activates the mitogen-activated protein kinase pathway (MAPK) involved in growth, survival, differentiation and stress-response in melanocytes and in melanoma cells just a few minutes after exposure. An increased activity of p38 and ERK was observed in melanomas, while in melanocytes just p38 pathway was highly active, supporting the notion that the cellular response to UVB light differs between melanocytes and melanoma cells. The molecules p38 and JNK are stress-activated protein kinases (SAPK). The JNK pathway is not responsive in some melanoma cells, but the activation of this molecule appears to be involved in cell survival and mitochondrial translocation after being exposed to UVB. Inhibition of JNK leads to increased cell death in irradiated and non-irradiated melanocytic lineage...

Cell phone radiation exposure on brain and associated biological systems.

Wireless technologies are ubiquitous today and the mobile phones are one of the prodigious output of this technology. Although the familiarization and dependency of mobile phones is growing at an alarming pace, the biological effects due to the exposure of radiations have become a subject of intense debate. The present evidence on mobile phone radiation exposure is based on scientific research and public policy initiative to give an overview of what is known of biological effects that occur at radiofrequency (RF)/ electromagnetic fields (EMFs) exposure. The conflict in conclusions is mainly because of difficulty in controlling the affecting parameters. Biological effects are dependent not only on the distance and size of the object (with respect to the object) but also on the environmental parameters. Health endpoints reported to be associated with RF include childhood leukemia, brain tumors, genotoxic effects, neurological effects and neurodegenerative diseases, immune system deregulation, allergic and inflammatory responses, infertility and some cardiovascular effects. Most of the reports conclude a reasonable suspicion of mobile phone risk that exists based on clear evidence of bio-effects which with prolonged exposures may reasonably be presumed to result in health impacts. The present study summarizes the public issue based on mobile phone radiation exposure and their biological effects. This review concludes that the regular and long term use of microwave devices (mobile phone, microwave oven) at domestic level can have negative impact upon biological system especially on brain. It also suggests that increased reactive oxygen species (ROS) play an important role by enhancing the effect of microwave radiations which may cause neurodegenerative diseases.

Some UV-bystander effects are mediated through induction of antioxidant defense in mammalian cells.

Bystander effect is the communication of signals from irradiated to unexposed neighboring cells which is often mediated through factors released from irradiated cells. We have attempted to investigate whether UV-bystander phenomenon can modulate the sensitivity of A375 cells and its mechanism. For this purpose, the conditioned medium from UVC-irradiated cells, which contained these released factors, was used to treat non-exposed cells. These cells were then subsequently treated with UVC or another genotoxicant H2O2. Cell viability was determined by Trypan blue-exclusion assay, DNA damage by flow cytometry analysis, ROS production by flow cytometry and microscopic analysis. Lipid peroxidation and antioxidant defense were assayed biochemically. Our findings revealed that exposure of non-irradiated cells to these factors induced increased in SOD and catalase activities which reverted to normal levels by 8 h. During this period, the released factors-treated cells were resistant to killing by UVC or H2O2 and induced DNA damage and lipid peroxidation were also lowered. This protection from cell killing was not present 8 h after exposure to these released factors. Our results suggested UV-bystander effect increased viability of cells through induction of antioxidant defense. This indicated UV-bystander phenomenon triggers protective response in cells.

Estudo do reparo das lesões induzidas no DNA de Escherichia coli pela radiação ultravioleta C (UVC) / Study of repair of induced lesions in the DNA of Escherichia coli by ultraviolet C (UVC)

Didaticamente, podemos dividir o espectro da radiação ultravioleta (UV) em três faixas: UVA (400 a 320 nm), UVB (320 a 290 nm) e UVC (290 a 100 nm). Apesar do UVC ou UV-curto ser eficientemente filtrado pela camada de ozônio da Terra e sua atmosfera, este é uma das faixas do espectro de UV mais usadas para explorar as consequências de danos causados ao DNA, já que a letalidade induzida por este agente está relacionada aos danos diretos no genoma celular, como as lesões dímero de pirimidina, que são letais se não reparadas. Contudo, demonstrou-se que a radiação UVC pode gerar espécies reativas de oxigênio (ERO), como o oxigênio singleto (1O2). Embora, o radical hidroxil (•OH) cause modificações oxidativas nas bases de DNA, alguns trabalhos indicam que o 1O2 também está envolvido nos danos oxidativos no DNA. Esta ERO é produzida por vários sistemas biológicos e reações fotossensibilização, quando cromóforos são expostos à luz visível ou são excitados pela luz UV, permitindo que essa energia possa ser transferida para o oxigênio sendo convertido em 1O2, que é conhecido por modificar resíduos de guanina, gerando 8-oxoG, que caso não seja reparada pode gerar uma transversão GC-TA. O objetivo deste trabalho foi o de elucidar a participação de ERO nos efeitos genotóxicos e mutagênicos gerados pela radiação UVC, assim como as enzimas envolvidas no processo de reparação destas lesões em células de Escherichia coli. Nos ensaios as culturas foram irradiadas com o UVC (254 nm; 15W General Electric G15T8 germicidal lamp, USA). Nossos resultados mostram que o uso de quelantes de ferro não alterou a letalidade induzida pelo UVC. A azida sódica, um captador de 1O2, protegeu as cepas contra os danos genotóxicos gerados pelo UVC e também diminuiu a frequência de mutações induzidas no teste com rifampicina. A reversão específica GC-TA foi induzida mais de 2,5 vezes no ensaio de mutagênese. A cepa deficiente na proteína de reparo Fpg, enzima que corrige a lesão 8-oxoG...

Didactically, we can divide the ultraviolet radiation (UV) spectrum into three bands: UVA (400 to 320 nm), UVB (320-290 nm) and UVC (290-100 nm). Despite the UVC or far-UV be efficiently filtered by Earth´s ozone layer and its atmosphere, this is one of bands of UV spectrum used to explore the consequences of DNA damages, since the UVC-induced lethality is related to direct damage in genome cells, such as pyrimidine dimers, which are lethal if not repaired. However, it was shown that UVC radiation can generate reactive oxygen species (ROS) such as singlet oxygen (1O2). Although hydroxyl radical (•OH) cause oxidative modifications in DNA bases, some works suggests that 1O2 is also involved in oxidative DNA damage. This ROS is produced by several biological systems and photosensitivity reactions when chromophores are exposed to visible light or excited by UV light, allowing that energy can be transferred to the oxygen being converted to 1O2, which is known to modify guanine residues, generating 8-oxoG, if not repaired can lead to a GC-TA transversion. The objective of this work was to elucidate the ROS involvement in the genotoxic and mutagenic effects generated by UVC radiation, as well as the enzymes involved in the repair process of these lesions in Escherichia coli cells. In the assays, cultures were irradiated with UVC (254 nm, 15 W General Electric germicidal lamp G15T8, USA). Our results show that the use of iron chelators did not affect the UVC-induced lethality. The sodium azide, a 1O2 quencher, protected strains against the genotoxic damage produced by UVC and also decreased the frequency of mutations induced in rifampicin assay. Reversal specific GC-TA was induced more than 2.5 fold in the mutagenesis assay. The deficient strain in the repair protein Fpg, an enzyme that corrects 8-oxoG lesions, had less DNA breakage than the wild strain in electrophoresis alkaline assay. The UVC-induced lethality was increased in mutants transformed with the pFPG...

Time-course analysis of DNA damage response-related genes after in vitro radiation in H460 and H1229 lung cancer cell lines

Radiation is the most useful treatment modality for cancer patients. It initiates a series of signal cascades such as DNA damage response (DDR) signaling for repairing damaged DNA, arresting the cell cycle, and inducing cell death. Until now, few genes have been found to be regulated by radiation, which explains the molecular mechanisms of cellular responses to radiation. Although the transcriptional changes caused by radiation have been widely investigated, little is known about the direct evidence for the transcriptional control of DDR-related genes. Here, we examined the radiosensitivity of two non-small cell lung cancer cell lines (H460 and H1299), which have different p53 status. We monitored the time-dependent changes of 24 DDR-related gene expressions via microarray analysis. Based on the basal expression levels and temporal patterns, we further classified 24 DDR-related genes into four subgroups. Then, we also addressed the protein levels of several DDR-related genes such as TopBP1, Chk1 and Chk2, confirming the results of microarray analysis. Together, these results indicate that the expression patterns of DDR-related genes are associated with radiosensitivity and with the p53 statuses of H460 and H1299, which adds to the understanding of the complex biological responses to radiation.

Radiosensitivity and repair kinetics of gamma-irradiated leukocytes from sporadic prostate cancer patients and healthy individuals assessed by alkaline comet assay

Impaired DNA repair mechanism is one of the main causes of tumor genesis. Study of intrinsic radiosensitivity of cancer patients in a non-target tissue [e.g. peripheral blood] might show the extent of DNA repair deficiency of cells in affected individuals and might be used a predictor of cancer predisposition. Initial radiation-induced DNA damage [ratio of Tail DN A/Head DNA], dose-response curves and kinetics of DNA repair in leukocytes from healthy volunteers and prostate cancer patients were assessed using alkaline comet assay after exposure to [60]Co gamma rays. Results showed that higher levels of baseline and gamma rays induced DNA damage in leukocytes of prostate cancer cases than in controls. A similar dose response was obtained for both groups. After a repair time of 24 h following in vitro irradiation, samples from the healthy individuals showed no residual DNA damage in their leukocytes, whereas prostate cancer patients revealed more than 20%. Although similar initial radiosensitivity was observed for both groups, the repair kinetics of radiation induced DNA damage of leukocytes from prostate cancer cases and healthy subjects were statistically different. These results support the hypothesis that men affected by prostate cancer may have a constitutional genomic instability

Radioprotective properties of Hippophae rhamnoides [sea buckthorn] extract in vitro

Hippophae rhamnoides, a high altitude habitat plant, has been extremely used in traditional medicinal practices for treating a variety of aliments. Recently, an extract [RH-3] prepared from berries of Hippophae rhamnoides has been reported to exhibit significant radioprotection against whole body lethal irradiation. Present study was undertaken to elucidate the DNA biding ability of an extract [RH-3] prepared from berries of Hippophae rhamnoides and its role in modulating radiation induced frank and clustered DNA damage. Agarose gel electrophoresis was employed as method to understand DNA biding potential and DNA protective ability of RH-3. RH-3 in a dose dependent fashion interacted with plasmid DNA [pUC 18] reducing the mobility of supercoiled form and increasing the amount of the complex in the well indicating its ability to interact with plasmid DNA. Rh-3 at higher concentrations [>0.4 mg/ml] almost completely prevented the migration of supercoiled from without interfering with mobility of open circular form indicating its ability to selectively interact with supercoiled form. Studies done with supercoiled or open circular form also revealed the binding specificity of RH-3 for supercoiled form of plasmid. Both inhibited radiation induced strand breaks and DNA revealed the binding specificity of RH-3 for supercoiled form of plasmid. Both inhibited radiation induced strand breaks and DNA interaction by RH-3 were found to be dependent upon pH and the order of efficacy was found to be acidic pH> neutral pH> alkaline pH. RH-3 in a dose dependent manner inhibited radiation induced frank single, double strand breaks as well as endonuclease IV detectable abasic sites [clusters] and maximum reduction was observed at a concentration of 200 micro g/ml. Results obtained in this study suggest that the ability of RH-3 to interact with DNA could be playing a significant role in preventing radiation induced DNA damage

Antigenotoxic and antimutagenic potential of an annatto pigment (norbixin) against oxidative stress

Carotenoids are 40-carbon molecules with conjugated double bonds, making them particularly effective for quenching free radicals. They have always been believed to possess anticancer properties, which could be due to their antioxidant potential. Norbixin is an unusual dicarboxylic water-soluble carotenoid present as a component in the pericarp of the seeds of Bixa orellana L. (from the Bixaceae family), a tropical shrub commonly found in Brazil. The main carotenoids present in these seeds, bixin and norbixin, form a coloring material, known as annatto, which is mainly used in the food industry. As annatto is only used as a coloring material, most studies of annatto pigments have focused on the determination of annatto levels in food. However, little attention has been given to the biological properties of bixin and norbixin. We evaluated the effect of norbixin on the response of Escherichia coli cells to DNA damage induced by UV radiation, hydrogen peroxide (H2O2) and superoxide anions (O2*-)) and found that norbixin protects the cells against these agents. Norbixin enhanced survival at least 10 times. The SOS induction by UVC was inhibited 2.3 times more when cells were grown in the presence of norbixin. We also found that norbixin has antimutagenic properties, with a maximum inhibition of H2O2-induced mutagenic activity of 87%, based on the Salmonella mutagenicity test

Roles of nibrin and ATM/ATR kinases on the G2 checkpoint under endogenous or radio-induced DNA damage

Checkpoint response to DNA damage involves the activation of DNA repair and G2 lengthening subpathways. The roles of nibrin (NBS1) and the ATM/ATR kinases in the G2 DNA damage checkpoint, evoked by endogenous and radio-induced DNA damage, were analyzed in control, A-T and NBS lymphoblast cell lines. Short-term responses to G2 treatments were evaluated by recording changes in the yield of chromosomal aberrations in the ensuing mitosis, due to G2 checkpoint adaptation, and also in the duration of G2 itself. The role of ATM/ATR in the G2 checkpoint pathway repairing chromosomal aberrations was unveiled by caffeine inhibition of both kinases in G2. In the control cell lines, nibrin and ATM cooperated to provide optimum G2 repair for endogenous DNA damage. In the A-T cells, ATR kinase substituted successfully for ATM, even though no G2 lengthening occurred. X-ray irradiation (0.4 Gy) in G2 increased chromosomal aberrations and lengthened G2, in both mutant and control cells. However, the repair of radio-induced DNA damage took place only in the controls. It was associated with nibrin-ATM interaction, and ATR did not substitute for ATM. The absence of nibrin prevented the repair of both endogenous and radio-induced DNA damage in the NBS cells and partially affected the induction of G2 lengthening.

Caracterização da via dos Interferons e a via da proteína p53 em linhagens de células tumorais expostas ao dano genotóxico

O gene gbp-2 codifica uma proteína com função biológica pouco estudada, é altamente expresso após a indução de IFNγ e requer o fator de transcrição IRF-1 para sua indução. A regulação positiva de gbp-2 dependente da ativação da proteína supressora de tumor p53 foi recentemente descrita em uma linhagem de carcinoma de esôfago que expressa uma proteína mutante p53 termo-sensível. A ativação da proteína p53 por sinais de estresse, como dano ao DNA, induz genes que participam da parada do ciclo celular e apoptose. Nesse contexto, os principais objetivos dessa tese foram: (i) verificar a indução de gbp-2 após a ativação de p53 pelo dano genotóxico; (ii) correlacionar sua eventual indução com a ativação de IRF-1; (iii) correlacionar a indução de gbp-2 e de sua proteína com as respostas celulares após o dano ao DNA. Nessa tese, pela primeira vez foi demonstrado que o gene gbp-2 é induzido pelo dano genotóxico; essa indução correlacionou-se com a presença da proteína p53 selvagem em linhagens tumorais; o aumento de expressão de IRF-1 não foi suficiente para a indução de gbp-2 após o dano ao DNA; nas linhagens celulares nas quais houve a indução de gbp-2 a resposta predominante foi a de parada do ciclo celular. O estudo da relação entre a via dos IFNs e da p53 pode trazer importantes implicações do papel dos IFNs durante a carcinogênese.

The gene gbp-2 codes for a protein with an unknown biological function. Gbp-2 is highly expressed after the induction by IFNγ and requires the transcription factor IRF-1. Recently, the positive p53-dependent regulation of gbp-2 was described in an esophageal cell line, wich expresses a temperature-sensitive mutant p53. The activation of p53 by stress signal such as DNA damage is known to induce genes involved in cell cycle arrest and apoptosis. Within this context, the main objectives of this study were: (i) to evaluate gbp-2 induction upon p53 activation by genotoxic damage; (ii) to establish a correlation of an eventual gbp-2 induction with IRF-1 activation; (iii) to correlate gbp-2 induction with cellular response to DNA damage. In this study, it was demonstrated for the first time that gbp-2 may be induced by genotoxic effect and also that the induction occurred in p53wt cell lines. Furthermore it was demonstrated that an increase in the expression of IRF-1 was not sufficient to induce gbp-2 following DNA damage. In addition, within the cell lines at which a gbp-2 induction was observed the preferential response was arrest of cell cycle progression. The study of the correlation between IFN and p53 pathways may reveal important implications for the understanding of the role of IFN during carcinogenesis.

Evaluation of radioinduced damage and repair capacity in blood lymphocytes of breast cancer patients

Genetic damage caused by ionizing radiation and repair capacity of blood lymphocytes from 3 breast cancer patients and 3 healthy donors were investigated using the comet assay. The comets were analyzed by two parameters: comet tail length and visual classification. Blood samples from the donors were irradiated in vitro with a 60Co source at a dose rate of 0.722 Gy/min, with a dose range of 0.2 to 4.0 Gy and analyzed immediately after the procedure and 3 and 24 h later. The basal level of damage and the radioinduced damage were higher in lymphocytes from breast cancer patients than in lymphocytes from healthy donors. The radioinduced damage showed that the two groups had a similar response when analyzed immediately after the irradiations. Therefore, while the healthy donors presented a considerable reduction of damage after 3 h, the patients had a higher residual damage even 24 h after exposure. The repair capacity of blood lymphocytes from the patients was slower than that of lymphocytes from healthy donors. The possible influence of age, disease stage and mutations in the BRCA1 and BRCA2 genes are discussed. Both parameters adopted proved to be sensitive and reproducible: the dose-response curves for DNA migration can be used not only for the analysis of cellular response but also for monitoring therapeutic interventions. Lymphocytes from the breast cancer patients presented an initial radiosensitivity similar to that of healthy subjects but a deficient repair mechanism made them more vulnerable to the genotoxic action of ionizing radiation. However, since lymphocytes from only 3 patients and 3 normal subjects were analyzed in the present paper, additional donors will be necessary for a more accurate evaluation

Modulation of thymidine kinase activity: a biochemical strategy to enhance the activation of antineoplastic drugs

Thymidine kinase is a key enzyme responsible for the activation of several anticancer and antiviral drugs. As the first enzyme in the salvage pathway of thymidine, it is regulated by the feedback inhibition exerted by the end-product of the pathway, namely thymidine 5'-triphosphate. 5'-Aminothymidine is a non-toxic analogue of thymidine capable of interfering with this regulatory mechanism. In fact, it has been shown that 5'-aminothymidine increases the cytotoxicity and metabolism of various thymidine analogues currently in use of the clinic as antineoplastic agents. This mini-review article focuses in the evidence supporting the role of 5'-aminothymidine as a potential prototype drug for a new class of anticancer agents: drugs which affect the regulation of key metabolic pathways that determine the efficacy of agents with cytotoxic activity. The mechanism of action, antineoplastic activities and basis for selectivity in tissue culture models are also described