Signaling interplay between PARP1 and ROS regulates stress-induced cell death and developmental changes in Dictyostelium discoideum.

Poly (ADP-ribose) polymerase-1 (PARP1) is a DNA damage sensor that gets activated in proportion to the damage, helping cells to determine whether to repair the damage or initiate cell death processes. We have previously shown PARP1's significance in the developmental processes of Dictyostelium discoideum in addition to its role in oxidative stress and UV-C stress induced cell death. In this study, we show the significance of ROS in PARP1 mediated responses of D. discoideum under different stress conditions. Interestingly, our results suggest differential kinetics of PARP1 activation and implications of ROS in starvation and cadmium induced cell death events. Increased accumulation of Poly (ADP-ribose), a product of PARP activation, could be detected within minutes post cadmium stress, whereas PARP1 activation was only a later event with starvation. Starvation induced PARP1 activation was supported by the depletion of ATP and NAD+, while PARP inhibitor confers protective effect during starvation. During starvation, cell death is induced in two phases, a primary ROS driven PARP1 independent early necrotic phase followed by a PARP1 driven ROS dependent paraptotic phase; both of which comprise mitochondrial changes. Cadmium (Cd) exerted a dose-dependent effect on cell death; a low dose of 0.2 mM Cd led to paraptosis and a higher dose of 0.5 mM Cd led to necrosis in D. discoideum cells within 24 h. Interestingly, glutathione (GSH) exposure could rescue cells from Cd stress mediated cell death. Besides unicellular cell death, the developmental arrest induced by cadmium and oxidative stress could be rescued by reinstating the redox equilibrium using GSH. In conclusion, we underscore the significant link between PARP1 and ROS in regulating the process of cell death and development in D. discoideum.

A paradoxical relationship between Resveratrol and copper (II) with respect to degradation of DNA and RNA.

Resveratrol (R), a plant polyphenol, is known to reduce Cu (II) to Cu (I) generating reactive oxygen species that can cleave plasmid DNA. Here we report a surprising observation of a paradoxical relationship between R and Cu whereby plasmid DNA cleaving / degrading activity of R-Cu increased progressively as the ratio of R to Cu was increased i.e., the concentration of Cu was successively reduced with respect to a fixed concentration R. Whereas cleavage of plasmid DNA occurred at low molar ratios of R to Cu, at higher ratios, complete degradation of DNA was achieved. By further increasing the ratio, whereby the concentration of Cu was reduced to very low levels, the DNA degrading activity of R-Cu was lost. This paradoxical relationship is also seen with respect to eukaryotic genomic DNA and RNA. Since R-Cu may have anti-cancer and anti-viral activities, our findings may not only help to improve the therapeutic efficacy of R-Cu but also reduce its toxic side effects with the use of low concentration of Cu.

Effect of oxidative stress and involvement of poly(ADP-ribose) polymerase (PARP) in Dictyostelium discoideum development.

Dictyostelium discoideum, a unicellular eukaryote, exhibits multicellularity upon nutrient starvation and is a good model system for developmental studies, and for the study of various signal transduction pathways. Reactive oxygen species at low doses act as signaling molecules; however, at high doses they are known to cause DNA damage that results in the activation of poly(ADP-ribose) polymerase (PARP). We have earlier reported the high resistance of the unicellular stage of D. discoideum to oxidative stress, and we now show the response of this organism to oxidative stress and the role of PARP during development. We used hydroxylamine (HA) to induce in situ generation of H(2)O(2) and monitored the effect of benzamide, a PARP inhibitor, on oxidative stress-induced changes in D. discoideum development. Interestingly, oxidative stress resulted in PARP activation within 5 min that was inhibited by benzamide. Oxidative stress-induced delay in developmental pattern was also partially restored by benzamide. We studied the long-term effects of PARP inhibition under oxidative stress, and our results demonstrated that spores formed under HA stress exhibited significant delay in germination in comparison to benzamide-pretreated HA-stressed cells. However, second-generation cells showed normal development, signifying that PARP inhibition has no deleterious effect on D. discoideum development under oxidative stress.