PURPOSE: To examine direct and bystander radiation-induced effects in normal umbilical-cord stromal stem cell (HCSSC) lines and in human cancer cells. MATERIALS AND METHODS: The UCSSC lines used in this study were obtained in our laboratory. Two cell lines (UCSSC 35 and UCSSC 37) and two human melanoma skin-cancer cells (A375 and G361) were exposed to ionizing radiation to measure acute radiation-dosage cell-survival curves and radiation-induced bystander cell-death response. Normal cells, although extremely sensitive to ionizing radiation, were resistant to the bystander effect whilst tumor cells were sensitive to irradiated cell-conditioned media, showing a dose-response relationship that became saturated at relatively low doses. We applied a biophysical model to describe bystander cell-death through the binding of a ligand to the cells. This model allowed us to calculate the maximum cell death (χ(max)) produced by the bystander effect together with its association constant (K(By)) in terms of dose equivalence (Gy). The values obtained for K(By) in A375 and G361 cells were 0.23 and 0.29 Gy, respectively. CONCLUSION: Our findings help to understand how anticancer therapy could have an additional decisive effect in that the response of sub-lethally hit tumor cells to damage might be required for therapy to be successful because the survival of cells communicating with irradiated cells is reduced.
PURPOSE: To examine direct and bystander radiation-induced effects in normal umbilical-cord stromal stem cell (HCSSC) lines and in humancancer cells. MATERIALS AND METHODS: The UCSSC lines used in this study were obtained in our laboratory. Two cell lines (UCSSC 35 and UCSSC 37) and two humanmelanoma skin-cancer cells (A375 and G361) were exposed to ionizing radiation to measure acute radiation-dosage cell-survival curves and radiation-induced bystander cell-death response. Normal cells, although extremely sensitive to ionizing radiation, were resistant to the bystander effect whilst tumor cells were sensitive to irradiated cell-conditioned media, showing a dose-response relationship that became saturated at relatively low doses. We applied a biophysical model to describe bystander cell-death through the binding of a ligand to the cells. This model allowed us to calculate the maximum cell death (χ(max)) produced by the bystander effect together with its association constant (K(By)) in terms of dose equivalence (Gy). The values obtained for K(By) in A375 and G361 cells were 0.23 and 0.29 Gy, respectively. CONCLUSION: Our findings help to understand how anticancer therapy could have an additional decisive effect in that the response of sub-lethally hit tumor cells to damage might be required for therapy to be successful because the survival of cells communicating with irradiated cells is reduced.
Authors: William T Turchan; Ronald H Shapiro; Garrett V Sevigny; Helen Chin-Sinex; Benjamin Pruden; Marc S Mendonca Journal: Int J Radiat Biol Date: 2016-06-03 Impact factor: 2.694
Authors: Virgínea de Araújo Farias; Francisco O'Valle; Borja Alonso Lerma; Carmen Ruiz de Almodóvar; Jesús J López-Peñalver; Ana Nieto; Ana Santos; Beatriz Irene Fernández; Ana Guerra-Librero; María Carmen Ruiz-Ruiz; Damián Guirado; Thomas Schmidt; Francisco Javier Oliver; José Mariano Ruiz de Almodóvar Journal: Oncotarget Date: 2015-10-13
Authors: Virgínea de Araujo Farias; Francisco O'Valle; Santiago Serrano-Saenz; Per Anderson; Eduardo Andrés; Jesús López-Peñalver; Isabel Tovar; Ana Nieto; Ana Santos; Francisco Martín; José Expósito; F Javier Oliver; José Mariano Ruiz de Almodóvar Journal: Mol Cancer Date: 2018-08-15 Impact factor: 27.401