Electron paramagnetic resonance studies on hepatic microsomal cytochrome P-450 from a marine teleost fish

Hepatic microsomal cytochrome P-450 from fish (Stenotomus versicolor), untreated or treated with 3-methylcholanthrene, 5, 6-benzoflavone, or tricaine methanesulfonate, exhibited an absorption maximum at 450 nm when reduced and ligated to CO. Microsomes from all groups exhibited EPR spectra with g values near 2.4, 2.24 and 1.9, yielding crystal field parameters similar to those for cytochrome P-450 from a variety of other sources. Treatment with 3-methylcholanthrene or 5, 6-benzoflavone resulted in elevated levels of aryl hydrocarbon (benzo[a]pyrene) hydroxylase activity yet produced no apparent change in the levels or optical properties of CO-ligated cytochrome P-450. Tricaine methanesulfonate, a common fish anaesthetic, caused a decrease in the levels of fish cytochrome P-450.     

Ischemic preconditioning of the rat retina: protective role of ferritin

Ischemic preconditioning (IPC) of the retina, accomplished by ischemia of short duration, is highly effective in preventing subsequent severe injury caused by iron-dependent free radical burst after prolonged ischemia. To investigate the mechanistic basis for IPC rescue, we examined changes in the levels of the retinal redox-active and labile iron pool, ferritin, and ferritin-bound iron. Prolonged ischemia severely impaired retinal function, with total loss of the full-field electroretinographic response. IPC provided marked protection against such injury. Histological examination revealed that ischemia-associated structural damage and loss of cells in the outer and inner nuclear layers were largely prevented by IPC. Ferritin levels decreased after prolonged ischemia but remained close to normal when the ischemic episode was preceded by IPC. The protective effect of IPC on retinal function and ferritin was blocked by a zinc-desferrioxamine complex known to interfere with iron signaling. The results suggest a mechanism whereby IPC activates an iron signaling pathway leading to a marked increase in ferritin levels, which mediates resistance to prolonged ischemia.     

Copper-mediated toxicity of 2,4,5-trichlorophenol: biphasic effect of the copper(I)-specific chelator neocuproine

The lipophilic copper(I)-specific chelator neocuproine has been frequently used as an inhibitor of copper-mediated damage in biological systems. In this communication we report that the copper-mediated toxicity of 2,4,5-trichlorophenol is markedly potentiated by neocuproine at levels which are near-stoichiometric with respect to the copper concentration but is inhibited at higher concentrations. However, no potentiation was observed when neocuproine was substituted by bathocuproinedisulfonic acid, a negative charged ligand with essentially the same copper-binding characteristics as neocuproine. We found that the potentiation by neocuproine was due to the formation of a lipophilic copper complex, while the inhibition by bathocuproinedisulfonic acid was due to the formation of a hydrophilic one. Caution in the use of neocuproine to study copper-mediated toxicity is advised.     

Zinc(II) Protects Against Metal-Mediated Free Radical Induced Damage: Studies on Single and Double-Strand DNA Breakage

M13 DNA was used as a source for single and double-stranded DNA. Free radical-induced damage to single and double stranded DNA was caused by asorbateliron and ascorbate/copper oxidative systems. The degree of breakage was estimated by running samples on an agarose gel and staining with ethidium bromide, followed by photographic analysis. DflA breakage was dependent on time and concentration of iron or copper ions. Zincions protected against damage caused by iron/asorbate both to single-stranded and double-stranded DNA. In contrast, in the copper/ascorbate system zinc ions protected only against the double-stranded DNA (replicative form of M13) breakage, and not against copper-mediated single-stranded DNA breakages. It seemed to amplify the efficiency of breakage. The protection provided to the replicative form in the copper/ascorbate system is much less effective than the protection to DNA in the iron/ascorbate system. These results support the notion that redox-inactive metal ions, that compete for iron or copper binding sites, could provide protection against transition metal-mediated and free radical-induced damage.     

Inverse correlation between resistance towards copper and towards the redox-cycling compound paraquat: a study in copper-tolerant hepatocytes in tissue culture

The essential mediatory role of copper or iron in the manifestation of paraquat toxicity has been demonstrated (Kohen and Chevion (1985) Free Rad. Res. Commun. 1, 79-88; Korbashi, P. et al. (1986) J. Biol. Chem. 261, 12472-12476). Several liver cell lines, characterized by their resistance to copper, were challenged with paraquat and their cross-resistance to paraquat and copper was studied. Cell growth and survival data showed that copper-resistant cells, containing elevated copper, are more sensitive towards paraquat than wild type cells. Copper-deprived resistant cells did not have this sensitivity. Paraquat was also shown to cause a marked degradation of cellular glutathione in all cell lines. Albeit the fact that the basal glutathione levels are higher in copper-resistant than in wild type cells, there is more paraquat-induced degradation of cellular glutathione (GSH + GSSG) in resistant cells. It is suggested that in copper-resistant cells which contain elevated levels of copper, paraquat-induced cellular injury is potentiated even where glutathione levels are elevated. Additionally, in vitro experiments are presented that support the in vivo findings demonstrating a role for copper in glutathione degradation.     

Membrane studies of Streptococcus pyogenes and its L-form growing in hypertonic and physiologically isotonic media. An electron spin resonance spectroscopy approach.

Electron spin resonance spectroscopy (ESR) was used to compare the lipid organization, thermal stability and the physical state of the membrane of a human pathogen, Streptococcus pyogenes and its osmotically fragile L-form with this same L-form now adapted to grow under physiologically isotonic conditions (physiological L-form). Comparison of the hyperfine splittings of a derivative of 5-ketostearic acid spin label, I(12, 3), after incorporation into the membrane, revealed that the lipid chain rigidity of these membranes is in the order physiological L-form greater than osmotically fragile L-form greater than streptococcus. The signal intensity (of the center magnetic field line) versus temperature analysis showed two transitions for these membranes. The first with melting points of 45, 26 and 36 degrees C and second transition at 70, 63 and 60 degrees C for the physiological L-form, osmotically fragile L-form and streptococcal membranes, respectively. This same order of membrane lipid chain rigidity was seen from the cooperativities obtained for each of these systems from analysis based on the expression for an n-order reaction. The I(12, 3) and other probes with the paramagnetic group close to the methyl end of the molecule suggested that this difference in lipid chain rigidity between these organisms resides in the environment closer to the lipid head group region rather than in the hydrophobic lipid core. Another major finding was the binding of I(12, 3) at two or more different sites in each of the membranes examined. This change in lipid chain rigidity now provides an explanation to account for the survival of a previously osmotically fragile L-form in physiologically isotonic media by focusing on changes in the physical nature of its membrane. In so doing, it adds to and reinforces the speculation of the potential survival in vivo and involvement in pathogenesis of osmotically fragile aberrant forms of bacteria.