Your search keyword '"Ristić-Fira, Aleksandra"' showing total 5 results

1. The impact of autophagy on cell death modalities in CRL-5876 lung adenocarcinoma cells after their exposure to γ-rays and/or erlotinib

Author

Keta, Otilija, Bulat, Tanja, Golić, Igor, Incerti, Sebastien, Korać, Aleksandra, Petrović, Ivan, and Ristić-Fira, Aleksandra

Published

2016

2. DNA double-strand breaks in cancer cells as a function of proton linear energy transfer and its variation in time.

Author

Keta, Otilija, Petković, Vladana, Cirrone, Pablo, Petringa, Giada, Cuttone, Giacomo, Sakata, Dousatsu, Shin, Wook-Geun, Incerti, Sebastien, Petrović, Ivan, and Ristić Fira, Aleksandra

Subjects

LINEAR energy transfer, DOUBLE-strand DNA breaks, CELL physiology, PROTONS, CANCER cells, CELL death

Abstract

The complex relationship between linear energy transfer (LET) and cellular response to radiation is not yet fully elucidated. To better characterize DNA damage after irradiations with therapeutic protons, we monitored formation and disappearance of DNA double-strand breaks (DNA DSB) as a function of LET and time. Comparisons with conventional γ-rays and high LET carbon ions were also performed. In the present work, we performed immunofluorescence-based assay to determine the amount of DNA DSB induced by different LET values along the 62 MeV therapeutic proton Spread out Bragg peak (SOBP) in three cancer cell lines, i.e. HTB140 melanoma, MCF-7 breast adenocarcinoma and HTB177 non-small lung cancer cells. Time dependence of foci formation was followed as well. To determine irradiation positions, corresponding to the desired LET values, numerical simulations were carried out using Geant4 toolkit. We compared γ-H2AX foci persistence after irradiations with protons to that of γ-rays and carbon ions. With the rise of LET values along the therapeutic proton SOBP, the increase of γ-H2AX foci number is detected in the three cell lines up to the distal end of the SOBP, while there is a decrease on its distal fall-off part. With the prolonged incubation time, the number of foci gradually drops tending to attain the residual level. For the maximum number of DNA DSB, irradiation with protons attain higher level than that of γ-rays. Carbon ions produce more DNA DSB than protons but not substantially. The number of residual foci produced by γ-rays is significantly lower than that of protons and particularly carbon ions. Carbon ions do not produce considerably higher number of foci than protons, as it could be expected due to their physical properties. In situ visualization of γ-H2AX foci reveal creation of more lesions in the three cell lines by clinically relevant proton SOBP than γ-rays. The lack of significant differences in the number of γ-H2AX foci between the proton and carbon ion-irradiated samples suggests an increased complexity of DNA lesions and slower repair kinetics after carbon ions compared to protons. For all three irradiation types, there is no major difference between the three cell lines shortly after irradiations, while later on, the formation of residual foci starts to express the inherent nature of tested cells, therefore increasing discrepancy between them. [ABSTRACT FROM AUTHOR]

Published

2021

3. Biological outcomes of γ-radiation induced DNA damages in breast and lung cancer cells pretreated with free radical scavengers.

Author

Petković, Vladana D., Keta, Otilija D., Vidosavljević, Marija Z., Incerti, Sebastien, Ristić Fira, Aleksandra M., and Petrović, Ivan M.

Subjects

FREE radical scavengers, DOUBLE-strand DNA breaks, CANCER cells, DNA damage, DOSE-response relationship (Radiation), DNA repair

Abstract

Purpose: Investigation of effects on DNA of γ-irradiated human cancer cells pretreated with free radical scavengers is aimed to create reference data which would enable assessment of the relative efficiency of high linear energy transfer (LET) radiations used in hadron therapy, i.e. protons and carbon ions. Materials and methods: MCF-7 breast and HTB177 lung cancer cells are irradiated with γ-rays. To minimize indirect effects of irradiation, dimethyl sulfoxide (DMSO) or glycerol are applied as free radical scavengers. Biological response to irradiation is evaluated through clonogenic cell survival, immunocytochemical and cell cycle analysis, as well as expression of proteins involved in DNA damage response. Results: Examined cell lines reveal similar level of radioresistance. Application of scavengers leads to the rise of cell survival and decreases the number of DNA double strand breaks in irradiated cells. Differences in cell cycle and protein expression between the two cell lines are probably caused by different DNA damage repair mechanisms that are activated. Conclusion: The obtained results show that DMSO and glycerol have good scavenging capacity, and may be used to minimize DNA damage induced by free radicals. Therefore, they will be used as the reference for comparison with high LET irradiations, as well as good experimental data suitable for validation of numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2019

4. Assessment of the inhibitory effects of different radiation qualities or chemotherapeutic agents on a human melanoma cell line.

Author

Ristić-Fira, Aleksandra M., Petrović, Ivan M., Korićanac, Lela B., Valastro, Lucia M., Privitera, Giuseppe, and Cuttone, Giacomo

Subjects

DRUG therapy, ALKYLATING agents, MELANOMA, CELL lines, RELATIVE biological effectiveness (Radiobiology), PROTONS, STATISTICAL correlation

Abstract

Abstract: The correlation between time dependent viabilities, after applying two radiation qualities and two alkylating agents on HTB140 melanoma cells, has been studied. Irradiations were performed with γ-rays and 62MeV protons, close to the Bragg peak maximum, delivering doses of 8–24Gy. Treatments with fotemustine (FM) and dacarbazine (DTIC) were carried out with concentrations of 0.05–2mM. High radio-resistance of HTB140 cells revealed by a clonogenic assay was confirmed by microtetrasolium and sulforhodamine B, through the surviving fraction at 2Gy (SF2), being 0.961–0.956 for γ-rays and 0.931–0.887 for protons. A better efficiency of protons was illustrated by relative biological effectiveness at 2Gy (RBE), ranging from 1.69 to 1.89. A kinetic study of concentration dependent cytotoxicity indicated that the best effect of the drugs, estimated as the concentration that produces 50% of growth inhibition (IC50), was obtained at 48h, having values of 76μM for DTIC and 145μM for FM. The cytostatic ability of the drugs pointed out that the presence of DTIC at 24h, compared to FM, was insufficient to produce an effect. Protons and FM demonstrated their pro apoptotic capacity. Cross-resistance between treatments applied to the HTB140 cells was observed, protons being the most efficient, while DTIC, FM and γ-rays demonstrated a lower level of cell inactivation. [Copyright &y& Elsevier]

Published

2008

5. Radiobiological analysis of human melanoma cells on the 62 MeV CATANA proton beam.

Author

Petrović, Ivan, Ristić-Fira, Aleksandra, Todorović, Danijela, Valastro, Lucia, Cirrone, Pablo, and Cuttone, Giacomo

Subjects

*RADIOBIOLOGY, *MELANOMA, *CANCER cells, *PROTON beams, *PROTONS, *IRRADIATION

Abstract

Purpose: To measure the ability of protons and γ-rays to effect cell viability and cell survival of human HTB140 melanoma cells. Materials and methods: Exponentially growing HTB140 cells were irradiated close to the Bragg peak maximum of the 62 MeV protons or with 60 Co γ-rays with single doses, ranging from 8 – 24 Gy. Cell viability using the 3-(4,5-dimethylthiazol-2yl)-2,5-diphenyltetrazolium bromide (MTT) assay was evaluated at 6 h, 24 h, 48 h or 7 days after irradiation and clonogenic survival was assessed at 7 days after irradiation. Cell cycle phase redistribution and the level of apoptosis were evaluated at 6 h and 48 h after irradiation. Results: The study of cell viability as a function of time (cell survival progression) and cell survival, using a clonal assay, demonstrated the considerably stronger inactivation effect of protons compared to γ-rays with a relative biological effectiveness (RBE) of ∼⃒1.64. Cell cycle phase distribution and apoptosis levels with time enabled us to investigate the development and the character of the damage induced by irradiation. Due to the high radio-resistance of HTB140 cells, cell cycle phase redistribution exhibited only a modest cell accumulation in G2/M phase. Protons but not γ-rays induced apoptosis. Conclusions: It appears that protons reduce the number of HTB140 cells by apoptosis as well as by severe DNA damage, while γ-rays eliminate viable cells primarily by the production of irreparable DNA damage. Protons have an increased RBE relative to γ-rays. [ABSTRACT FROM AUTHOR]

Published

2006