Abstract
Cancer cells undergo mitosis more frequently than normal cells and thus have increased metabolic needs, which in turn lead to higher than normal reactive oxygen species (ROS) production. Higher ROS production increases cancer cell dependence on ROS scavenging systems to balance the increased ROS. Selectively modulating intracellular ROS in cancers by exploiting cancer dependence on ROS scavenging systems provides a useful therapeutic approach. Essential to developing these therapeutic strategies is to maintain physiologically low ROS levels in normal tissues while inducing ROS in cancer cells. GMX1778 is a specific inhibitor of nicotinamide phosphoribosyltransferase, a rate-limiting enzyme required for the regeneration of NAD(+) from nicotinamide. We show that GMX1778 increases intracellular ROS in cancer cells by elevating the superoxide level while decreasing the intracellular NAD(+) level. Notably, GMX1778 treatment does not induce ROS in normal cells. GMX1778-induced ROS can be diminished by adding nicotinic acid (NA) in a NA phosphoribosyltransferase 1 (NAPRT1)-dependent manner, but NAPRT1 is lost in a high frequency of glioblastomas, neuroblastomas, and sarcomas. In NAPRT1-deficient cancer cells, ROS induced by GMX1778 was not susceptible to treatment with NA. GMX1778-mediated ROS induction is p53-dependent, suggesting that the status of both p53 and NAPRT1 might affect tumor apoptosis, as determined by annexin-V staining. However, as determined by colony formation, GMX1778 long term cytotoxicity in cancer cells was only prevented by the addition of NA to NAPRT1-expressing cells. Exposure to GMX1778 may be a novel way of inducing ROS selectively in NAPRT1-negative tumors without inducing cytotoxic ROS in normal tissue.
Highlights
GMX1778 is an inhibitor of nicotinamide phosphoribosyltransferase for the regeneration of NADϩ from nicotinamide
Because of the roles of NADH and NADPH as reducing equivalents in oxidative stress responses for survival of cancer and normal cells, we hypothesized that a decrease in cellular levels of NADϩ by GMX1778 would result in a decrease in the steady state levels of NADH, NADPϩ, and NADPH, which would increase reactive oxygen species (ROS) levels leading to cell damage and death
We present evidence that GMX1778 induces ROS, superoxide radicals evidenced by DHE oxidation, via decreasing the cellular level of NADϩ, NADPϩ, NADH, and NADPH
Summary
GMX1778 is an inhibitor of nicotinamide phosphoribosyltransferase for the regeneration of NADϩ from nicotinamide. The adaptive antioxidant capacity in certain cancer cells allows tumors to tightly control ROS levels while maintaining proliferative capacity [14] This oxidative stress phenotype in cancer cells may provide therapeutic opportunities and challenges for eliminating tumors by increasing ROS in tumors while maintaining ROS levels in normal tissues (14 –16). The salvage pathway operates via the two major pathways using nicotinamide phosphoryltransferase (NAMPT) and nicotinamide phosphoribosyltransferase 1 (NAPRT1), which use nicotinamide and nicotinic acid (NA), respectively, as the substrate for NADϩ recycling [18] Both pathways are employed to generate NADϩ, in cells expressing endogenous NAPRT1, only the NA added in the salvage pathway can increase cellular levels of NADϩ and reduce cytotoxicity by an oxidizing agent [18, 19]. Normal cells were more resistant to GMX1778 because most normal cells have active NAPRT1, p53, and a lower level of ROS requiring less dependence on ROS scavenging systems
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