Inhibition of Siah2 ubiquitin ligase by vitamin K3 (menadione) attenuates hypoxia and MAPK signaling and blocks melanoma tumorigenesis

The E3 ubiquitin ligase Siah2 has been implicated in the regulation of the hypoxia response, as well as in the control of Ras, JNK/p38/NF‐κB signaling pathways. Both Ras/mitogen‐activated protein kinase (MAPK) and hypoxia pathways are important for melanoma development and progression, pointing to the possible use of Siah2 as target for treatment of this tumor type. In the present study, we have established a high‐throughput electro‐chemiluninescent‐based assay in order to screen and identify inhibitors of Siah2 ubiquitin ligase activity. Of 1840 compounds screened, we identified and characterized menadione (MEN) as a specific inhibitor of Siah2 ligase activity. MEN attenuated Siah2 self‐ubiquitination, and increased expression of its substrates PHD3 and Sprouty2, with concomitant decrease in levels of HIF‐1α and pERK, the respective downstream effectors. MEN treatment no longer affected PHD3 or Sprouty2 in Siah‐KO cells, pointing to its Siah‐dependent effects. Further, MEN inhibition of Siah2 was not attenuated by free radical scavenger, suggesting it is ROS‐independent. Significantly, growth of xenograft melanoma tumors was inhibited following the administration of MEN or its derivative. These findings reveal an efficient platform for the identification of Siah inhibitors while identifying and characterizing MEN as Siah inhibitor that attenuates hypoxia and MAPK signaling, and inhibits melanoma tumorigenesis.     

Interaction between vitamin K3 and benzo(a)pyrene metabolism in uninduced microsomes

1. Relationship between quinone recycling, glucuronidation and benzo(a)pyrene (BaP) oxygenation was investigated in uninduced mouse liver microsomes--native and modified by Fe3+.FeEDTA and/or superoxide (O2-.)-initiated lipid peroxidation. 2. A functional coupling between glucuronidation of reduced quinones and BaP metabolism, not discernible during BaP metabolism by native uninduced microsomes, was demonstrable in the presence of a model quinone, vitamin K3 (menadione). 3. Menadione inhibited BaP oxygenation in microsomal preparations, by siphoning off electrons from cytochrome P-450, while addition of UDPGA reversed this effect by glucuronidation of menadiol. 4. Fe3+.FeEDTA and/or O2-.-initiated lipid peroxidation decreased, to different extent, the microsomal enzymatic activities involved in quinone metabolism. The most sensitive was quinone reductase activity, which was reduced by 77%. Under peroxidative conditions menadione was a less effective inhibitor of BaP metabolism. 5. The important role of the balance between quinone reductase and UDP-glucuronyltransferase activities in the coupling with BaP oxygenation is discussed. A mechanism by which vitamin K3 could exert a regulatory effect on BaP metabolism is proposed.     

Identification of 3-dehydroretinol (vitamin A2) in mouse liver

3-Dehydroretinol (vitamin A2) and its long-chain fatty acyl esters have been isolated from hairless mouse liver by high-performance liquid chromatography (HPLC). In adult animals, these compounds amount to 1-2 micrograms/g liver, corresponding to 1-2% of the retinol (vitamin A1) concentration. Studies on the regulation of 3-dehydroretinol levels in liver showed that the age and vitamin A status of the animal affect the levels, but the relative proportions of retinol and 3-dehydroretinol are constant.     

In vitro stimulation of microsomal diethyl nitrosamine deethylase activity by vitamin K3 (menadione).

Vitamin K3 (menadione) has been found to stimulate diethyl nitrosamine (DEN)-deethylase activity in rat liver microsomes. The vitamin also takes care of the inhibitory effect of the anaerobic conditions as well as those of cytochrome poisons like sodium azide and sodium cyanide, possibly through production of active oxygen species. The enzyme was also stimulated by H2O2 and SOD and inhibited by catalase, thereby suggesting that H2O2 or some derivatives of it may be the active oxygen species involved in the reaction.     

Vitamin K3 (menadione) inhibits the growth of mammalian tumor cells in culture

The effects of vitamin K on the morphology and the growth of mouse neuroblastoma (P₂), mouse melanoma (B-16) and rat glioma (C-6) cells in culture were studied. Vitamin K₃ inhibited the growth (due to cell death and partial or complete inhibition of cell division) of all three cell types without causing any morphological differentiation. Vitamin K₃ was more effective than vitamin K₁. Neuroblastoma cells were more sensitive to vitamin K₃ than were melanoma or glioma cells. Glioma cells did not grow in hormone-supplemented serum-free medium; however, both neuroblastoma and melanoma cells grew to a level 70–80% of that found in serum-supplemented medium. Neuroblastoma cells and melanoma cells cultured in serum-free medium exhibited a 2–3 fold higher sensitivity to vitamin K₃ than those cultured in serum-supplemented medium. This suggests that serum factors attenuate the growth inhibitory effect of vitamin K₃ on tumor cells in culture, probably by reducing the availability of this vitamin to the cells. Neuroblastoma cells were more sensitive to vitamin K₃ than were melanoma cells even when they were treated in serum-free medium. The fact that micromolar concentrations of vitamin K₃ inhibit the growth of tumor cells in culture suggests that this vitamin may be a potentially useful anticancer agent.     

Metabolism of diphenyloxazole (PPO) by mouse liver microsomes.

2, 5-Diphenyloxazole (PPO) is an inducer and inhibitor of aryl hydrocarbon hydroxylase. We report that PPO is itself metabolized to an alkali-extractable metabolite with intense fluorescence. The fluorescence spectra of excitation and emission indicate peaks at 345 nm and 510 nm, respectively. The reaction is linear with respect to time and enzyme concentration. NADPH is required for activity and the reaction is inhibited by carbon monoxide and 7, 8-benzoflavone but not by SKF-525A or hexobarbital. The intensity of fluorescence produced is similar to that of benzo (a) pyrene. PPO may be a useful model compound in studies of drug metabolism by the mixed function oxidase.     

Inhibition of osteoporosis induced by protein deficient (PD) food intake by active vitamin D(3) and vitamin K(2) in rats

Independent use of K(2) and D(3) and simultaneous application of K(2) and D(3) inhibited the development of osteoporosis caused by PD food intake. The ALP activity of urine as a marker of bone formation osteoporosis did not rise in rats fed PD foods containing D(3), K(2) or both together. Body and womb weights fell in rats fed PD foods with D(3) K(2) and both D(3), K(2). Osteoporosis caused by PD food intake found to be very similar to type II osteoporosis in respects of inhibition by D(3) and K(2) and rising urinary ALP activity.     

Sex-related difference in vitamin D3 25-hydroxylase of rat liver microsomes

Cholecalciferol 25-hydroxylase was partially purified by polyethylene glycol fractionation and chromatographies on octylamino-Sepharose and hydroxylapatite columns starting from the liver microsomes of female rats, and compared with P-450cc25 purified from the liver microsomes of male rats (Hayashi, et al. (1986) J. Biochem. 99, 1753-1763). On octylamino-Sepharose 4B column chromatography, most of the activity was recovered in the fraction eluted with 0.08% Emulgen 913 in the case of the male enzyme, whereas the female enzyme was recovered in the fraction eluted with 0.2% Emulgen. Anti-cc25 antibodies against purified male P-450cc25 inhibited the 25-hydroxylation activity of male polyethylene glycol (PEG) fraction and partially purified male enzyme, but did not inhibit the activities of the corresponding female fractions. The antibodies formed a single precipitation line with male P-450cc25, but did not form a precipitation line with partially purified female 25-hydroxylase on immuno-diffusion. These observations indicated that the vitamin D3 25-hydroxylase in female rat liver microsomes is a different entity from that of male rats.     

Development of vitamin D3 25-hydroxylase activity in rat liver microsomes

The ontogeny of vitamin D3 25-hydroxylase activity has been determined in liver microsomes of rat fetuses and neonates. Production of 25-hydroxyvitamin D3 was low (0.11 pmol/g liver/h) 3 days prior to birth. Production rates were 1.2, 2.2, 1.8, and 2.8 pmol/g liver/h on Day 0, Day 2, Day 7, and Day 15, respectively. 25-Hydroxyvitamin D3 production in neonates increased sixfold from Day 15 to Day 22 to a value twice that of the mothers (17.6 pmol/g liver/h compared with 7.3 pmol/g liver/h). Activity in the maternal microsomes was constant (0.22 to 0.30 pmol/mg protein/h) except for the day of parturition (0.54 pmol/mg protein/h) and Day 22 postpartum (0.44 pmol/mg protein/h). A cytosolic factor, present as early as 3 days prior to birth, was required for vitamin D3 25-hydroxylase activity in the fetuses and stimulated the 25-hydroxylase reaction (up to 2.5-fold) in neonates and mothers. The ability of cytosol to prevent degradation of vitamin D3 was also present in the fetal stage. These data suggest that microsomal vitamin D3 25-hydroxylase activity in rat liver microsomes develops slowly and reaches full activity near the weaning stage. Since the cytosolic factor(s) is/are present in the fetal stage, the limiting component in the maturation of vitamin D3 25-hydroxylase activity in liver microsomes is the development of the cytochrome P-450 vitamin D3 25-hydroxylase.     

NADPH-dependent drug redox cycling and lipid peroxidation in microsomes from human term placenta

1. NADPH-dependent iron and drug redox cycling, as well as lipid peroxidation process were investigated in microsomes isolated from human term placenta. 2. Paraquat and menadione were found to undergo redox cycling, catalyzed by NADPH:cytochrome P-450 reductase in placental microsomes. 3. The drug redox cycling was able to initiate microsomal lipid peroxidation in the presence of micromolar concentrations of iron and ethylenediaminetetraacetate (EDTA). 4. Superoxide was essential for the microsomal lipid peroxidation in the presence of iron and EDTA. 5. Drastic peroxidative conditions involving superoxide and prolonged incubation in the presence of iron were found to destroy flavin nucleotides, inhibit NADPH:cytochrome P-450 reductase and inhibit propagation step of lipid peroxidation. 6. Reactive oxo-complex formed between iron and superoxide is proposed as an ultimate species for the initiation of lipid peroxidation in microsomes from human term placenta as well as for the destruction of flavin nucleotides and inhibition of NADPH:cytochrome P-450 reductase as well as for impairment of promotion of lipid peroxidation under drastic peroxidative conditions.     

Hepatic low-level chemiluminescence during redox cycling of menadione and the menadione-glutathione conjugate: relation to glutathione and NAD(P)H:quinone reductase (DT-diaphorase) activity

Formation of excited species such as singlet molecular oxygen during redox cycling (one-electron reduction-oxidation) was detected by low-level chemiluminescence emitted from perfused rat liver and isolated hepatocytes supplemented with the quinone, menadione (vitamin K3). Chemiluminescence was augmented when the two-electron reduction of the quinone catalyzed by NAD(P)H:quinone reductase was inhibited by dicoumarol, thus underlining the protective function of this enzyme also known as DT-diaphorase. Interference with NADPH supply by inhibition of energy-linked transhydrogenase by rhein or of mitochondrial electron transfer by antimycin A led to a depression in the level of photoemission. Unexpectedly, glutathione depletion of the liver led to a lowering of chemiluminescence elicited by menadione, whereas conversely the depletion of glutathione led to increased chemiluminescence levels when a hydroperoxide was added instead of the quinone. As the GSH conjugate of menadione, 2-methyl-3-glutathionyl-1,4-naphthoquinone, studied with microsomes, was shown also to be capable of redox cycling, we conclude that menadione-induced chemiluminescence of the perfused rat liver does not only arise from menadione itself but from the menadione-GSH conjugate as well. Therefore, the conjugation of the quinone with glutathione is not in itself of protective nature and does not abolish semiquinone formation. A biologically useful aspect of conjugate formation resides in the facilitation of biliary elimination from the liver. Nonenzymatic formation of the conjugate from menadione and GSH in vitro was found to be accompanied by the formation of aggressive oxygen species.     

Solubilization and characterization of vitamin K epoxide reductase from normal and warfarin-resistant rat liver microsomes

Two procedures have been developed for the solubilization of vitamin K epoxide reductase from rat liver microsomal membranes using the detergent Deriphat 160 at pH 10.8. The methods are applicable to both normal and Warfarin-resistant-strain rat liver microsomes and yield material suitable for further purification. The preparations retain dithiothreitol-dependent vitamin K quinone reductase activity as well as vitamin K epoxide reductase and are free of vitamin K-dependent carboxylase and epoxidase activities. Optimal epoxide reductase activity is obtained at 0.1 M KCl and pH 9 in the presence of sodium cholate. Artifactual formation of vitamin K metabolites was eliminated through the use of mercuric chloride to remove excess dithiothreitol prior to extraction and metabolite assay. Using the solubilized enzyme, valid initial velocities were measured, and reproducible kinetic data was obtained. The substrate initial velocity patterns were determined and are consistent with a ping-pong kinetic mechanism. The kinetic parameters obtained are a function of the cholate concentration, but do not vary drastically from those obtained using intact microsomal membranes. At 0.8% cholate, the enzymes solubilized from normal Warfarin-sensitive- and Warfarin-resistant-strain rat livers exhibit respective values of Vmax = 3 and 0.75 nmol/min/g liver; Km for vitamin K epoxide = 9 and 4 microM; and Km for dithiothreitol of 0.6 and 0.16 mM.     

Inhibition of biliary taurocholate excretion during menadione metabolism in perfused rat liver

In perfused rat liver menadione elicits substantial oxidation in both the NADPH and GSH redox systems. Biliary excretion of GSSG is increased several-fold. Menadione derivatives appear in the bile predominantly as the menadione-S-glutathione conjugate, thiodione (60%), or as conjugates derived therefrom (17%). About 10% appear as menadione glucuronides. The excretion of taurocholate into bile is strongly inhibited upon menadione infusion. The inhibition of taurocholate excretion is small in livers with a low content of Se-GSH-peroxidase and in glutathione-depleted livers. In these livers intracellular GSSG and biliary GSSG release remain at low values, although menadione still imposes oxidative stress as indicated by an oxidation of intracellular NADPH. Under anoxic conditions menadione has little influence on both the NADPH and GSH redox systems and also on biliary taurocholate excretion. The amount of thiodione released into bile is similar to that found under normoxia, whereas the amount of glucuronidated products almost doubled. We conclude (a) that intracellular formation of GSSG by menadione occurs via the generation of hydrogen peroxide; (b) that the inhibition of biliary taurocholate excretion by menadione is related to the increased formation of glutathione disulfide; and (c) that menadione derivatives show little, if any, contribution to the inhibition of taurocholate excretion.