In vitro and in vivo clearance of Rose Bengal Acetate-PhotoDynamic Therapy-induced autophagic and apoptotic cells.

This study focuses on the clearance of Rose Bengal Acetate (RBAc)-PhotoDynamic Therapy (PDT)-generated apoptotic and autophagic HeLa cells by murine and human macrophages. Indeed, phagocytosis of dead cells drives the therapeutic efficacy of PDT through both efficient removal of dead/dying cells and macrophages response evoked during engulfment and, up to now, clearance of dying photosensitized cells has been less investigated than PDT mechanisms of cell death induction. RBAc-PDT ensures a long onset of cytotoxicity and a time-related cell death of HeLa cells by signals originating from or converging on almost all intracellular organelles. On this basis, to clarify whether the efficacious cell death commitment is followed by an efficient clearance mechanism, we primarily focused on the analysis of 'eat me' signals exposure and 'find me' signals release, and then investigated the migration, recognition, engulfment and response of murine Raw 264.7 and human blood isolated macrophages. Dead cells secreted 'find me' signals, i.e. fractalkine and Heat Shock Protein 70 (HSP 70), to recruit macrophages and promote their fast phagocytosis. Macrophages phagocytosed apoptotic and autophagic PDT-treated cells more efficiently than the respective positive controls, i.e. puromycin-induced apoptotic and Earle's balanced salt solution-starved autophagic cells. Phagocytosis depends on the glycans exposed on dead cells. The macrophages internalization of photokilled cells elicits the production of Interleukin-10, Transforming Growth Factor-ß and Tumour Necrosis Factor-α by macrophages. TNFα production, along with HSP70 release and plasma membrane translocation on dead cells, suggest an immunogenic impact of RBAc-PDT. In fact, macrophages, activated fibroblasts and endothelial cells colonized the inoculum site of photosensitized cells in rat calf muscles, endorsing the hypothesis of immunogenic elicitation of RBAc-PDT.

Rose bengal acetate photodynamic therapy-induced autophagy.

Photodynamic therapy (PDT), an anticancer therapy requiring the exposure of cells or tissue to a photosensitizing drug followed by irradiation with visible light of the appropriate wavelength, induces cell death by the efficient induction of apoptotic as well as non-apoptotic mechanisms, such as necrosis and autophagy, or a combination of all three mechanisms. However, the exact role of autophagy in photodynamic therapy is still a matter of debate. To understand the role of autophagy in PDT, we investigated the induction of autophagy in HeLa cells photosensitized with Rose Bengal Acetate (RBAc). After incubation with Rose Bengal Acetate (10-5 M), HeLa cells were irradiated for 90 seconds (green LED DPL 305, emitting at 530 +15 nm to obtain 1.6 J/cm2 as the total light dose) and allowed to recover for 72 h. Induction of autophagy and apoptosis were observed with peaks at 8 h and 12 h after irradiation, respectively. Autophagy was detected by biochemical (Western Blotting for the LC3B protein) and morphological criteria (TEM, cytochemistry). In addition, the pan-caspase inhibitor, z-VAD, was unable to completely prevent cell death. The simultaneous onset of apoptosis and autophagy following Rose Bengal Acetate PDT is of remarkable interest in light of the findings that autophagy can result in the class II presentation of antigens and thus, explain why low dose PDT can yield anti-tumor immune responses.

Photodynamic therapy-induced apoptosis of HeLa cells.

Photodynamic therapy (PDT), which is a treatment for cancer and certain noncancerous conditions, requires exposure of cells or tissue to a photosensitizing drug followed by irradiation with visible light of the appropriate wavelength. By using Rose Bengal Acetate (RBAc) as the photosensitizer and an innovative green light-emitting diode, we investigated the efficiency with which apoptosis is induced in HeLa cells, focusing our study on mitochondria alteration and cytochrome c release. Indeed, RBAc is a very efficient fluorogenic substrate and easily enters the cells where the original photoactive molecule is restored by specific esterases. HeLa cells after PDT underwent a consistent rate of apoptosis (peaked at 12 h of recovery post-PDT). Necrosis was observed at the longest times of recovery as a result of secondary necrosis. PDT gave rise to a series of shape modifications, mainly referable to apoptotic-related changes (i.e., extensive blebs formation) involving both F-actin and tubulin networks. Soon after PDT, mitochondria lose their potential membranes and release large quantities of cytochrome c.