65 research outputs found
PULEX: Influence of environment radiation background on biochemistry and biology of cultured cells and on their response to genotoxic agents
Some years ago we performed two experiments aimed at studying the influence of the background radiation on living matter by exploiting the low radiation background environment in the underground Gran Sasso Laboratory of the INFN. Their results were consistent with the hypothesis that the ânormalâ background radiation determines an adaptive response, although they cannot be considered conclusive. PULEX-3 (the third experiment of the series) is aimed at comparing the effects of different background radiation environments on metabolism of cultured mammalian cells, with substantial improvements with respect to the preceding ones. The experiment was designed to minimize variabilities, by maintaining two cultures of Chinese hamster V79 cells in exponential growth for up to ten months
in the underground Gran Sasso Laboratory (LNGS), while two other cultures were maintained in parallel in a biological laboratory installed at the LNGS outside the tunnel. Exposure due to Îł-rays was reduced by a factor of about 10 in the underground laboratory while the Rn concentration was small in both cases. After ten months the cells grown in the underground laboratory, compared to those grown in the external one, exhibited: i) a significantly lower capacity to scavenge reactive oxygen species (ROS), and ii) an increased sensitivity to the mutagenic effect of rays. Since the probability that this finding is due to casual induction of radiosensitive mutants is extremely low, it corroborates the hypothesis that cells grown in a ânormalâ background radiation environment exhibit an adaptive response when challenged with genotoxic agents, which is lost after many generations in a low background radiation environment
Charged particle effects: Experimental and theoretical studies on the mechanisms underlying the induction of molecular and cellular damage and the modulation of intercellular signalling
In this paper we present the main outcomes of a wide collaborative effort (carried out within the INFN project âEPICAâ and in part within the European projects âRISC-RADâ and âNOTEâ and the ASI project
MoMa-COUNT), both experimental and theoretical, devoted to the characterization and quantification of the induction of DNA-targeted and non-DNA-targeted molecular and cellular
biological endpoints, following irradiation of human cells with different charged particles. The work was mainly aimed at reaching a better understanding of the mechanisms
governing the physical and biophysical pathways leading from the initial energy deposition by radiation in matter to the induction of observable radiobiological damage, with particular focus on the role played by radiation quality. More specifically, we characterized the induction of DNA DSB within different fragment-size ranges outlining the effectiveness of high-LET radiation at inducing small fragments and thus clustered DNA breaks, which can evolve in terms of endpoints like chromosome aberrations (CAs). This was confirmed by the development and application of a model of CA induction based on the assumption that only clustered DNA breaks can lead to aberrations. Concerning non-DNA-targeted damage, we quantified the time-dependent induction of medium-mediated DNA damage in bystander cells and we characterized the time and dose dependence of cytokine concentration in the culture medium of
sham-irradiated and irradiated cells, since medium-mediated bystander damage is thought to arise from molecular signalling between irradiated and unirradiated cells. The mechanisms governing such signalling were investigated
developing a model and a MC code simulating cytokine release, diffusion and internalization, showing good agreement with experimental data. Non-DNA-targeted effects were further characterized by MRS investigation of the radiation effects on lipids and oxidative metabolism, which are particularly relevant also considering that they may be differently expressed in different tumors and in normal tissues
Positive Regulation of DNA Double Strand Break Repair Activity during Differentiation of Long Life Span Cells: The Example of Adipogenesis
Little information is available on the ability of terminally differentiated cells to efficiently repair DNA double strand breaks (DSBs), and one might reasonably speculate that efficient DNA repair of these threatening DNA lesions, is needed in cells of long life span with no or limited regeneration from precursor. Few tissues are available besides neurons that allow the study of DNA DSBs repair activity in very long-lived cells. Adipocytes represent a suitable model since it is generally admitted that there is a very slow turnover of adipocytes in adult. Using both Pulse Field Gel Electrophoresis (PFGE) and the disappearance of the phosphorylated form of the histone variant H2AX, we demonstrated that the ability to repair DSBs is increased during adipocyte differentiation using the murine pre-adipocyte cell line, 3T3F442A. In mammalian cells, DSBs are mainly repaired by the non-homologous end-joining pathway (NHEJ) that relies on the DNA dependent protein kinase (DNA-PK) activity. During the first 24 h following the commitment into adipogenesis, we show an increase in the expression and activity of the catalytic sub-unit of the DNA-PK complex, DNA-PKcs. The increased in DNA DSBs repair activity observed in adipocytes was due to the increase in DNA-PK activity as shown by the use of DNA-PK inhibitor or sub-clones of 3T3F442A deficient in DNA-PKcs using long term RNA interference. Interestingly, the up-regulation of DNA-PK does not regulate the differentiation program itself. Finally, similar positive regulation of DNA-PKcs expression and activity was observed during differentiation of primary culture of pre-adipocytes isolated from human sub-cutaneous adipose tissue
Linee guida per la garanzia di qualita' nell'irradiazione corporea totale
Consiglio Nazionale delle Ricerche - Biblioteca Centrale - P.le Aldo Moro, 7, Rome / CNR - Consiglio Nazionale delle RichercheSIGLEITItal
The European initiative on low-dose risk research From the HLEG to MELODI
International audienceThe importance of low-dose risk research for radiation protection is now widely recognised. The European Commission (EC) and five European Union (EU) Member States involved in the Euratom Programme set up in 2008 a 'High Level and Expert Group on European Low Dose Risk Research' (HLEG) aimed at identifying research needs and proposing a better integration of European efforts in the field. The HLEG revised the research challenges and proposed a European research strategy based on a 'Multidisciplinary European LOw Dose Initiative' (MELODI). In April 2009, five national organisations, with the support of the EC, created the initial core of MELODI (http//www.melodi-online.eu, http//www.melodi-online.eu) with a view to integrate the EU institutions with significant programmes in the field, while being open to other scientific organisations and stakeholders, and to develop an agreed strategic research agenda (SRA) and roadmap. Since then, open workshops have been organised yearly, exploring ideas for SRA implementation. As of October 2014, 31 institutions have been included as members of MELODI. HLEG recommendations and MELODI SRA have become important reference points in the radiation protection part of the Euratom Research Programme. MELODI has established close interactions through Memorandum of Understanding with other European platforms involved in radiation protection (Alliance, NERIS and EURADOS) and, together with EURADOS, with the relevant medical European Associations. The role of Joint Programming in priority setting, foreseen in the forthcoming EU Horizon 2020, calls for keeping MELODI an open, inclusive and transparent initiative, able to avoid redundancies and possible conflicts of interest, while promoting common initiatives in radiation protection research. An important issue is the establishment of a proper methodology for managing these initiatives, and this includes the set-up of an independent MELODI Scientific Committee recently extended to Alliance, NERIS and EURADOS, with the aim of identifying research priorities to suggest for the forthcoming Euratom research calls. © The Author 2015
Bystander Effect Studies in HL60 Human Promyelocytes
In the framework of the NOTE Integrated Project (FP6-36465, Euratom), we used for the first time HL60 human promyelocytes for bystander effects studies. This cell line is capable to differentiate in vitro towards either granulocytes or monocytes/macrophages and, therefore, one of the major interest is that it is possible to investigate the nature of signals released from the same cell type in various differentiating conditions and also to evaluate if cell differentiation can be induced through bystander mechanisms.
The experiments have been focused (i) to the characterization of the biological system using the appropriate cluster of differentiation (CD) of cell surface molecules for the different cells of interest (i.e., promyelocytes, monocyte-and macrophage-like cells) and (ii) to obtain information about the response to signalling factors from sham/irradiated HL60 promyelocytes in terms of micronuclei (MN) induction and cell killing. Experiments were also performed to characterize the basal levels of ROS and RNS in cells at different stages of differentiation.
Monocyte- and macrophage-like differentiation was obtained using vitamin D3 and phorbol diester (12-O-tetradecanoylphorbol-13-acetate, TPA) as inducers, respectively. Irradiation was performed with gamma rays and bystander experiments were carried out using the medium transfer approach.
The experiments performed to characterize the differentiation status in the HL60 clone we used show that CD11b and CD11c appear both suitable for identifying macrophage-like and monocyte-like cells. The former are negative while the latter are positive to CD14. Actively proliferating promyelocytes present some positivity to CD95 but not to CD11b and CD11c or CD14. At the present experiments are planned aimed at distinguishing promyelocytes from macrophage-like cells in a mixed population.
The results on MN induction in unirradiated promyelocytes by the medium collected from promyelocytes irradiated with 0.5 Gy and incubated for different times at 37°C show an increase after 2 h incubation that disappears at longer incubation times.
Measurements of cell killing show that incubation with conditioned medium from 1 Gy irradiated promyelocytes leads to an increase in the cloning efficiency of the bystander promyelocytes, giving surviving fractions higher than 1. However, this effect seems more related to factors physiologically released by the cells than to factors induced by irradiation, as indicated by the comparison with medium from sham-irradiated cells. These results suggest that growth stimulating factors, instead of growth inhibiting factors, are released by HL60 promyelocytes
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