ES936 stimulates DNA synthesis in HeLa cells independently on NAD(P)H:quinone oxidoreductase 1 inhibition, through a mechanism involving p38 MAPK.

The indolequinone ES936 (5-methoxy-1,2-dimethyl-3-[(4-nitrophenol)methyl]-indole-4,7-dione) is a potent mechanism-based inhibitor of NAD(P)H:quinone oxidoreductase 1 (NQO1). Here, we report that ES936 significantly stimulated thymidine incorporation in sparse cultures of human adenocarcinoma HeLa cells, but was without effect in dense cultures. Stimulation of DNA synthesis was not related with a DNA repair response because an increase in thymidine incorporation was not observed in cells treated with 2,5 bis-[1-aziridyl]-1,4 benzoquinone, a well-established antitumor quinone that causes DNA damage. Conversely, it was related with an increase of cell growth. NQO1 inhibition was not involved in ES936 stimulation of DNA synthesis, because the same response was observed in cells where NQO1 expression had been knocked down by small interfering RNA. Stimulation of DNA synthesis was reverted by treatment with ambroxol, a SOD mimetic, and by pyruvate, an efficient peroxide scavenger, supporting the involvement of alterations in cellular redox state. Pharmacological inhibition of p38 with either SB203580 or PD169316 completely abolished ES936-stimulated DNA synthesis, indicating the requirement of p38 activity. This is the first report that demonstrates the existence of an ES936-sensitive system which is separate from NQO1, modulating the redox state and cell growth in HeLa cells through a p38-dependent mechanism. Our results show that the effect ES936 exerts on DNA synthesis may be either positive or negative depending on the cellular context and growth conditions.

Dicoumarol impairs mitochondrial electron transport and pyrimidine biosynthesis in human myeloid leukemia HL-60 cells.

Dicoumarol, a competitive inhibitor of NAD(P)H:quinone oxidoreductase 1 (NQO1), increases intracellular superoxide and affects cell growth of tumor cells. This work was set to establish a mechanistic link between dicoumarol, superoxide and cell cycle alterations in HL-60 cells. Using ES936, a mechanism-based irreversible inhibitor of NQO1, we demonstrate that NQO1 inhibition is not a major factor involved in superoxide boost. Mitochondrial Complexes II, III and IV were directly inhibited by dicoumarol. Succinate, which inhibits superoxide generation by reversed electron flow in Complex II, significantly decreased superoxide boost in dicoumarol-treated cells and in isolated mitochondria incubated with dicoumarol and decylubiquinol. Superoxide generation in cells was strongly potentiated by blocking the quinone site of Complex II with thenoyltrifluoroacetone, supporting the involvement of cytochrome b560 to drive electrons for increasing superoxide. Simultaneous inhibition of the mitochondrial chain upstream ubiquinone and displacement of succinate from the Complex II active site is proposed as a major mechanism to explain how dicoumarol increases superoxide in HL-60 cells. Dicoumarol-treated cells accumulated in S phase due to the impairment of pyrimidine biosynthesis at dihydroorotate dehydrogenase step because blockade was overcome by addition of exogenous uridine or orotate, but not by dihydroorotate. We demonstrate for the first time that dicoumarol inhibits mitochondrial electron transport, induces superoxide release by reversed electron flow in Complex II, and inhibits pyrimidines biosynthesis. These actions must be taken into account when considering dicoumarol effects on cells.

Cellular density and cell type are the key factors in growth inhibition induced by 2,5bis [1-aziridinyl]-1,4 benzoquinone (DZQ).

BACKGROUND: Cell density regulates the expression of various antioxidant enzymes in cell culture. The aim of this study was to study the effect of 2,5 bis-[1-aziridinyl]-1,4 benzoquinone (DZQ), an antitumor quinone bioactivated by NQO1, on HeLa and HepG2 cells cultured at various cell densities. MATERIALS AND METHODS: Quinone toxicity was determined by a colorimetric growth inhibition assay. NQO1 and catalase activities were measured spectrophotometrically in soluble fractions, and NQO1 polypeptide was quantified by immunostaining with a commercial polyclonal antiserum. RESULTS: As reported previously, NQO1 activity was much higher in confluent HeLa cells than in sparse cells. However, HepG2 cultures showed an opposite pattern in the regulation of this antioxidant enzyme, sparse cell cultures showing higher NQO1 activity similar to that found in confluent HeLa cells. The expression pattern of catalase activity was similar to that of NQO1 in HeLa cells, but this activity was constant and cell density-independent in HepG2. The growth inhibition effect of DZQ, correlated with NQO1 activity within a given cell type, but HepG2 was always much more sensitive to DZQ than HeLa cells, even under conditions where NQO1 activity was high in HeLa but low in HepG2. CONCLUSION: These results suggest that NQO1 activity is a major factor for DZQ bioactivation, but this enzyme is not likely the sole factor involved in the growth inhibition mediated by DZQ. Since part of the cytotoxic effect of DZQ is mediated by H2O2, other antioxidant enzymes, mainly catalase, could modulate the different growth inhibition found between HeLa and HepG2 cells. In confluent HeLa cells, the higher activity of NQO1 coincides with an increment of catalase activity, thus, reducing the oxidative stress produced by the H2O2 formed.

Coenzyme Q and the regulation of intracellular steady-state levels of superoxide in HL-60 cells.

The present work was set to study how CoQ concentrations affected steady-state levels of superoxide in a cellular model of partial CoQ(10) deficiency in cultured human myeloid leukemia HL-60 cells. Culturing HL-60 cells in the presence of p-aminobenzoate, a competitive inhibitor of polyprenyl-4-hydroxybenzoate transferase (Coq2p), produced a significant decrease of CoQ(10) levels without affecting cell viability. Concomitant decreases in CoQ-dependent electron transport activity and mitochondrial membrane potential were observed under these conditions. Intracellular superoxide was significantly elevated in cells treated with p-aminobenzoate, both under serum-containing and serum-free conditions, and this effect was reversed by exogenous CoQ(10). A slight increase of superoxide was also observed in CoQ(10)-supplemented cells in the absence of serum. Our results support a requirement for CoQ(10) to control superoxide levels in HL-60 cells. The importance of extramitochondrial sources of superoxide in cells with impaired CoQ(10) biosynthesis is discussed.