Transmembrane potential of liver mitochondria from hexachlorobenzene- and iron-treated rats

The respiratory parameters and the membrane of liver mitochondria from rats treated with either hexachlorobenzene, iron or hexachlorobenzene plus iron, to induce experimental porphyria, have been studied. Partial uncoupling of oxidative phosphorylation has been observed in mitochondria from hexachlorobenzen- and hexachlorobenzene plus iron-treated rats. Direct evidence has been pressented that this uncoupling is due to the action of pentochlorophenol endogenously formed by metabolism of hexachlorobenzene. No irreversible damage of mitochondrial membrane has been revealed under both these conditions. Normal oxidative phosphorylation has bee found in mitochondria from rats treated with iron alone. In contrast, they presented an anomalous membrane potential, fully restored by oligomycin. A possible involvement of lipid peroxidation process, induced by iron, in causing these abnormalities has been suggested.     

Transmembrane potential of liver mitochondria from hexachlorobenzene-and iron-treated rats

The respiratory parameters and the membrane potential of liver mitochondria from rats treated with either hexachlorobenzene, iron or hexachlorobenzene plus iron, to induce experimental porphyria, have been studied. Partial uncoupling of oxidative phosphorylation has been observed in mitochondria from hexachlorobenzene- and hexachlorobenzene plus iron-treated rats. Direct evidence has been presented that this uncoupling is due to the action of pentachlorophenol endogenously formed by metabolism of hexachlorobenzene. No irreversible damage of mitochondria membrane has been revealed under both these conditions. Normal oxidative phosphorylation has been found in mitochondria from rats treated with iron alone. In contrast, they presented an anomalous membrane potential, fully restored by oligomycin. A possible involvement of lipid peroxidation process, induced by iron, in causing these abnormalities has been suggested.     

The effect of iron overload on the mitochondrial porphyrin level in the hexachlorobenzene induced experimental porphyria

Liver mitochondria isolated from rats treated with hexachlorobenzene plus iron, present a lower content of total porphyrin in respect to that of mitochondria from rats fed hexachlorobenzene alone. The in vitro mitochondrial porphyrin accumulation processes have been studied in mitochondria from iron loaded rats. It has been found that under these conditions the active porphyrin uptake process, which is driven by the K+ transmembrane gradient, is maximally inhibited in the presence of pentachlorophenol at a concentration similar to that found in vivo in the hexachlorobenzene experimental porphyria. By contrast the same degree of inhibition is presented by control mitochondria only in the presence of pentachlorophenol plus valinomycin, a condition which collapses the transmembrane K+ gradient. A strict correlation between porphyrin uptake and K+ concentration has been found in control as well as in iron treated mitochondria. A possible involvement of peroxidative reactions in the mitochondrial membranes has been proposed as a cause of the changes in the permeability properties of the mitochondrial membranes in the experimental chronic hepatic porphyria under conditions of iron overload.     

Riboflavin-binding protein. Concentration and fractional saturation in chicken eggs as a function of dietary riboflavin.

In female rats with porphyria induced by hexachlorobenzene, the amounts of non-haem iron and porphyrins in liver mitochondrial fractions were increased almost 3-fold and greater than 500-fold respectively compared with that of untreated animals. A considerable fraction of both iron and porphyrins in this fraction was shown to be located in lysosomes. Thus mitochondrial preparations, which were further depleted of lysosomes by Percoll-density-gradient centrifugation, contained 2.78 +/- 0.75 and 2.99 +/- 0.49 nmol of non-haem iron/mg of protein when isolated from the liver of control rats and hexachlorobenzene-treated rats respectively. Mitochondria isolated from the liver of hexachlorobenzene-treated animals contained a pool of iron (about 1 nmol/mg of protein) that was available for haem synthesis in vitro. This pool is similar to that previously reported for mitochondria isolated from the liver of rats with normal haem synthesis. Hexachlorobenzene treatment, therefore, does not affect the iron status of the mitochondria.     

Effects of hexachlorobenzene and iron loading on rat liver mitochondria

The effects of hexachlorobenzene treatment and simultaneous iron-overload on the iron and porphyrin content of rat liver and rat liver mitochondria have been examined. In order to assess damages to the mitochondrial membrane occuring with these treatments, the content of malondialdehyde and selected functional properties of mitochondria were compared with those from control animals. Prolonged intake of hexachlorobenzene (8 weeks) resulted in a striking increased level of porphyrins together with a moderate increase in iron concentration. Simultaneous administration of hexachlorobenzene and iron-dextran caused the porphyrin level to reach 25% of the amount induced by hexachlorobenzene alone. The iron concentrations in liver as well as in liver mitochondria are also decreased under these conditions, as compared to the effect of iron-dextran. In contrast, the effects of hexachlorobenzene combined with iron-dextran on mitochondrial oxidative phosphorylation and malondialdehyde content are greater than those of either hexachlorobenzene or iron-dextran. These data suggest that porphyrin accumulation per se causes little deleterious effect and that both agents administered together act synergistically in causing damage to the mitochondrial membrane.     

Ferritin accumulation and uroporphyrin crystal formation in hepatocytes of C57BL/10 mice: a time-course study

To establish the time-sequence relationship between ferritin accumulation and uroporphyrin crystal formation in livers of C57BL/10 mice, a biochemical, morphological and morphometrical study was performed. Uroporphyria was induced by the intraperitoneal administration of hexachlorobenzene plus iron dextran and of iron dextran alone. Uroporphyrin crystal formation started in hepatocytes of mice treated with hexachlorobenzene plus iron dextran at 2 weeks and in mice treated with iron dextran alone at 9 weeks. In the course of time, uroporphyrin crystals gradually increased in size. Uroporphyrin crystals were initially formed in hepatocytes in the periportal areas of the liver, in which also ferric iron staining was first detected. The amount and the distribution of the main storage form of iron in hepatocytes, ferritin, did not differ between the two treatment groups. Ferritin accumulation preceded the formation of uroporphyrin crystals in hepatocytes in both treatment groups. Moreover, uroporphyrin crystals were nearly always found close to ferritin iron. We conclude that uroporphyrin crystals are only formed in hepatocytes in which also iron (ferritin) accumulates. Hexachlorobenzene accelerates the effects of iron in porphyrin metabolism, but does not influence the accumulation of iron into the liver.     

Pyrophosphate as a ligand for delivery of iron to isolated rat-liver mitochondria

Rat liver mitochondria accumulate iron mobilized from transferrin by pyrophosphate. The capacity of the mitochondria to accumulate iron is higher than the capacity of pyrophosphate to mobilize iron from transferrin: with ferric-iron-pyrophosphate as iron donor, iron uptake and heme synthesis are about 10-times that at corresponding concentrations of iron-transferrin plus pyrophosphate. Uptake of iron from ferric-iron-pyrophosphate depends on a functionary respiratory chain and involves reductive cleavage of the ferric-iron-pyrophosphate complex. Apotransferrin inhibits uptake of iron from ferric-iron-pyrophosphate by competing with the mitochondria for iron. The results focus on pyrophosphate as a possible candidate for intracellular iron transport.     

Studies on the utilization of ferritin iron in the ferrochelatase reaction of isolated rat liver mitochondria.

The utilization of ferritin as a source of iron for the ferrochelatase reaction has been studied in isolated rat liver mitochondria. 1. It was found that isolated rat liver mitochondria utilized ferritin as a source of iron for the ferrochelatase reaction in the presence of succinate plus FMN (or FAD). 2. Under optimal experimental conditions, i.e., approx. 50 micromol/1 FMN, 37 degrees C, pH 7.4 and 0.5 mmol/l Fe(III) (as ferritin iron), the release process, as shown by the formation of deuteroheme, amounted to approx. 0.5 nmol iron/min per mg protein. 3. The release process could not be elicited by ultrasonically treated mitochondria, lysosomes, microsomes or cytosol, i.e., the release of iron from ferritin was due to mitochondria and was a function of the in situ orientation of the mitochondrial inner membrane. 4. The release of iron from ferritin by the mitochrondria might be of relevance not only for the in situ synthesis of heme in the hepatocyte, but also with respect to the mechanism(s) by means of which iron is mobilized for transport to the erythroid tissue.     

X-ray microanalysis of aldehyde-fixed glycogen contrast-stained by OsVI . FeII and OsVI . RuIV complexes

The composition of the contrast-donating complex of rat liver glycogen, nucleoplasm, erythrocytes, and mitochondria was established by X-ray microanalysis. In these compartments the presence of osmium and iron was shown qualitatively in tissue after glutaraldehyde fixation, treated with OsVIIIO4 plus K4FeII(CN)6 and in similar tissue treated with a combination of K2OsVIO4 plus K4FeII(CN)6. Osmium and ruthenium were detected in these compartments, in aldehyde-fixed tissue treated with mixtures containing K2RuIVL(CN)6 rather than K4FeII(CN)6. The iron detected in the glycogen, nucleoplasm, erythrocytes, and mitochondria of tissue treated with K2RuIV(CN)6 mixtures proved to derive from sources inside the electron microscope, and had to be considered an artifact. Quantitatively, the mean atomic ratios of osmium-to-iron and osmium-to-ruthenium were determined from spectra obtained by point analyses of the same compartments (glycogen, nucleoplasm, mitochondria, lipid droplets, and erythrocytes). After correction of the spectra for the instrumental iron contribution, the osmium-to-iron and osmium-to-ruthenium ratios in the glycogen were about 1:3 for tissue treated with those combinations including K2OsVIO4. In the other compartments, the osmium-to-iron and osmium-to-ruthenium ratios were virtually 1:0. For Os-VIIIO4 in combination with potassium ferrouscyanide however the osmium-to-iron ratio was 1:7 in the glycogen and 1:5 in all other compartments. OsVIIIO4 was combined with potassium ruthenium-cyanide, the osmium-to-ruthenium ratio was 1:2 in the glycogen and 2:1 in the other compartments. These results support our view that the selective glycogen contrast is obtained by complex formation.     

Sources of intramitochondrial malate

Liver mitochondria from rats treated with gluconeogenic hormones or subjected to vigorous exercise consume oxygen more rapidly than do mitochondria from control rats. These treatments result in elevated mitochondrial malate concentrations, which facilitate the entry of added substrate into the mitochondria. In this paper we describe experiments conducted to determine the source of the extra malate. Injections of glutamate plus alanine, two amino acids that are increased in blood after exercise and hormone treatment, caused liver mitochondrial malate to be increased. Injections of glucagon, cortisol, or both hormones elevated liver mitochondrial malate concentrations in both adrenalectomized and sham-operated rats.     

Effect of 2,3,7,8-Tetrachlorodibenzo-p-dioxin on the Hepatic Distribution of Iron,Copper, Zinc,and Magnesium in Rats

The distribution of iron, copper, zinc, and magnesium in hepatic subcellular fractions of male and female rats treated with 2,3,7,8-tetrachloro-dibenzo-p-dioxin (TCDD) was determined. Animals received 40 μg TCDD per kilogram per day for three days by mouth (PO) or the vehicle and were killed seven or nine days posttreatment. Iron, copper, zinc, and magnesium were determined by atomic absorption spectroscopy. The iron content of liver from female animals was twofold higher than male animals. The administration of TCDD increased the iron content of mitochondria in female and male rats and decreased iron content of microsomes of both sexes. Significant increases occurred in the copper content of whole liver, mitochondria, and cytosol of male rats and in whole liver and cytosol of female rats. Decreases in the copper content of the microsomes of male rats were observed following TCDD treatment; however, TCDD produced no changes in the zinc content of hepatic subcellular fractions of either sex. The magnesium content of female TCDD-treated rats increased in whole liver, mitochondria, and cytosol, while the magnesium content of microsomes was not altered. With respect to the subcellular distribution of iron, copper, zinc, and magnesium, TCDD produces differential effects. The altered distribution of some cations may contribute to the broad range of effects of TCDD.     

Iron uncouples oxidative phosphorylation in brain mitochondria isolated from vitamin E-deficient rats

Few, if any, studies have examined the effect of vitamin E deficiency on brain mitochondrial oxidative phosphorylation. The latter was studied using brain mitochondria isolated from control and vitamin E-deficient rats (13 months of deficiency) after exposure to iron, an inducer of oxidative stress. Mitochondria were treated with iron (2 to 50 microM) added as ferrous ammonium sulfate. Rates of state 3 and state 4 respiration, respiratory control ratios, and ADP/O ratios were not affected by vitamin E deficiency alone. However, iron uncoupled oxidative phosphorylation in vitamin E-deficient mitochondria, but not in controls. In vitamin E-deficient mitochondria, iron decreased ADP/O ratios and markedly stimulated state 4 respiration; iron had only a modest effect on these parameters in control mitochondria. Thus, vitamin E may have an important role in sustaining oxidative phosphorylation. Low concentrations of iron (2 to 5 microM) oxidized mitochondrial tocopherol that exists in two pools. The release of iron in brain may impair oxidative phosphorylation, which would be exacerbated by vitamin E deficiency. The results are important for understanding the pathogenesis of human brain disorders known to be associated with abnormalities in mitochondrial function as well as iron homeostasis (e.g., Parkinson's disease).     

Rapamycin reduces oxidative stress in frataxin-deficient yeast cells

Friedreich ataxia (FRDA) is a common form of ataxia caused by decreased expression of the mitochondrial protein frataxin. Oxidative damage of mitochondria is thought to play a key role in the pathogenesis of the disease. Therefore, a possible therapeutic strategy should be directed to an antioxidant protection against mitochondrial damage. Indeed, treatment of FRDA patients with the antioxidant idebenone has been shown to improve neurological functions. The yeast frataxin knock-out model of the disease shows mitochondrial iron accumulation, iron-sulfur cluster defects and high sensitivity to oxidative stress. By flow cytometry analysis we studied reactive oxygen species (ROS) production of yeast frataxin mutant cells treated with two antioxidants, N-acetyl-L-cysteine and a mitochondrially-targeted analog of vitamin E, confirming that mitochondria are the main site of ROS production in this model. Furthermore we found a significant reduction of ROS production and a decrease in the mitochondrial mass in mutant cells treated with rapamycin, an inhibitor of TOR kinases, most likely due to autophagy of damaged mitochondria.     

OXIDATIVE PHOSPHORYLATION IN MITOCHONDRIA FROM LIVERS SHOWING CLOUDY SWELLING

Using succinate and α-ketoglutarate as substrates, oxidative phosphorylation has been measured in mitochondria isolated from livers showing cloudy swelling. This cellular change was obtained by injecting rats with S. typhi murium toxin and guinea pigs with diphtheria toxin. It has been found that phosphorylation associated with the oxidation of either of these substrates was partially inhibited in mitochondria from livers showing cloudy swelling, while the oxygen consumption was unchanged. Thus, the P:O ratios for both succinate and α-ketoglutarate were lower in mitochondria from treated animals than they were in normal mitochondria. Dephosphorylation of ATP was not significantly modified in mitochondria from livers showing cloudy swelling as compared with normal controls. No dephosphorylation of AMP and G-6-P was observed either in normal mitochondria or in mitochondria from treated animals.     

Functional efficiency of mitochondrial membrane of rats with hepatic chronic iron overload

The effect of $\text{in}\text{vivo}$ hepatic iron overload, induced by two different amounts of iron, on the energy-transducing efficiency of the mitochondrial membrane has been examined. It has been found that when the epatic iron concentration is up to a threshold value mitochondria present an anomalous membrane potential. Addition of oligomycin fully restitutes it. A low content of intramitochondrial K⁺ is connected with this pathological condition. A relative lack of antioxidant capability is parallely exhibited by these mitochondria. A possible involvement of lipid peroxidation process $\text{in}\text{vivo}$ in causing the membrane potential drop and the net efflux of intramitochondrial K⁺ is suggested.     

Iron content and degree of lipid peroxidation in liver mitochondria isolated from iron-loaded rats

1.The content of non-heme iron and the degree of lipid peroxidation were measured in liver mitochondria isolated from rats injected with either Jectofer (an iron-sorbitol-citric acid complex) or iron-nitrilotriacetate. 2. The sedimentation profiles of the mitochondria from controls and iron-treated rats as revealed by analytical differential centrifugation, indicated single population of mitochondria with $\text{s}{}_{\mathrm{4,B}}$ values of 13200± 560 S and 14200±590 S for controls and iron-loaded animals, respectively. In contrast, the sedimentation profiles of the acid phosphatase activity and the non-heme iron revealed marked polydispersities with at least three populations of particles for both controls and iron-loaded animals. 3. The mitochondria and iron-rich lysosomes were separated by density-gradient centrifugation in an isotonic medium of Percoll and sucrose. With this technique, the amount of non-heme iron in a mitochondrial fraction by differential centrifugation decreased from 69±28 nmol/mg protein to 5.6±1.1 nmol/mg protein and from 19.3±5.6 nmol/mg protein to 3.3±0.6 nmol/mg protein for Jectofer and iron-nitrilotriacetate injected rats, respectively. For control rats the amount of mitochondrial non-heme iron was about 2.7 nmol/mg protein both before and following density gradient centrifugation. The extra amount of non-heme iron still present in the purified mitochondrial fraction from iron-loaded rats, as compared to controls, was further characterized by the reactivity towards bathophenanthroline sulfonate. The results suggest that the extra iron was due to a small amount of either ferritin or hemosiderin still contaminaning the mitochondrial fraction. The amount of mitochondrial heme iron was the same in iron-loaded rats and controls. 4. The degree of lipid peroxidation in the mitochondria was estimated from the amount of malondialdehyde. The thiobarbituric acid method used for the quantitation of malondialdehyde was modified so that it was insensitive to variable amounts of iron present in the samples. No difference in the degree of lipid peroxidation was observed between the mitochondria from iron-loaded rats and controls. 5. In contrast to recent proposals (Hanstein, E.G. et al. (1981) Biochim. Biophys. Acta 678, 293–299), the present study showed that the amounts of non-heme iron and the degrees of lipid peroxidation are the same in mitochondria isolated from iron-loaded and control animals.     

Properties of liver mitochondria from iron-loaded rats.

The increased iron content in livers from iron-loaded rats is almost exclusively confined to the mitochondria. The ten- to twenty-fold higher level of nonheme iron in such mitochondria decreases the respiratory control with pyruvate-malate, but not with 3-hydroxybutyrate or succinate as substrates, and has no effect on the capacity for phosphorylation and substrate oxidation. Iron-loaded mitochondria have a malondialdehyde level which is about three times higher than that of control mitochondria, even after repeated washings with bovine serum albumin and EDTA. This is suggestive of an on-going process of lipid oxidation presumably catalyzed by the accumulated iron. Differences between the present in vivo data and in vitro results obtained by others are discussed.     

Oxidative phosphorylation in mitochondria isolated from small intestinal epithelium of thiamphenicol-treated rats and control rats

Treatment of rats with thiamphenicol in a dose of 125 mg/kg per day for 60–64 h causes specific inhibition of mitochondrial protein synthesis, leading to a drastic decrease of the cytochrome c oxidase activity in intestinal epithelium. At the same time the mitochondrial ATPase activity becomes resistant to inhibition by oligomycin. Experiments with isolated intestinal mitochondria revealed that respiration in state 3 is diminished by 55% with succinate (5 mM) and by 40% with pyruvate (10 mM) plus L-malate (2 mM) as the substrates, both as compared to intestinal mitochondria isolated from control rats. P : O ratios as well as respiratory control indices are comparable in the two groups of animals. Uncoupled respiration is inhibited by 35% with succinate as the substrate, while the succinate cytochrome c reductase activity remains unaltered. No inhibition of uncoupled respiration with pyruvate plus L-malate as the substrates was observed. The ATP-P_i exchange activity in the mitochondria from the treated animals is diminished by about 75%. It is concluded that in the mitochondria of the treated animals the inhibition of the coupled respiration (state 3) is caused by the limitation of the ATP-generating capacity and that electron transport is rate limiting only with the rapidly oxidized substrates such as succinate, if respiration is uncoupled.     

Investigations on the role of free radical processes in hexachlorobenzene-induced porphyria in mice

Male C57BY/10 mice were chronically fed hexachlorobenzene (HCB) (0.02% of the diet) alone or in combination with a single subcutaneous dose of iron (12.5 mg iron per mouse). After eight weeks the group of mice pretreated with the iron overload was highly sensitized to the porphyrogenic effect of HCB, as shown by liver porphyrin accumulation. A synergistic effect of iron was evident on other parameters too, such as HCB-induced hepatic damage, activation of type O of xanthine oxidase, and decreased activity of copper zinc superoxide dismutase and glutathione peroxidase(s). None of these parameters was affected by iron alone. Iron alone and in association with HCB markedly raised the level of lipid peroxides, the increase in the HCB group being smaller. The combined treatment resulted in a significant reduction of HCB's inductive effects on microsomal heme and cytochromes P-450 and b₅ and on the activity of aryl hydrocarbon hydroxylase. The content of nonprotein sulfhydryl groups was reduced to the same extent in mice treated with HCB or HCB plus iron. The results suggest that reactive intermediates such as are formed by lipid peroxidation are not sufficient on their own to create the conditions for uroporphyrinogen decarboxylase impairment, as evident in the group of mice receiving iron overload alone. Conversely, HCB administration induced a specific condition of imbalance in the liver between formation and inactivation of reactive intermediates which was associated with hepatic porphyrin accumulation and was potentiated by concomitant administration of iron.     

A difference between two strains of rats in their liver non-haem iron content and in their response to the porphyrogenic effect of hexachlorobenzene.

Female Agus rats developed hepatic porphyria at a much faster rate than female Porton-Wistar rats when fed a diet containing 0.01% of hexachlorobenzene (HCB). They also showed a greater inhibition of liver uroporphyrinogen decarboxylase [EC 4.1.1.37] activity and a marked stimulation of 5-aminolaevulinate synthetase [EC 2.3.1.37]. The difference between the two strains could not be correlated with differences in the liver concentrations of HCB. However, control Agus rats were found to possess significantly higher levels of total non-haem iron in their livers than the Porton animals. This was particularly apparent after 24 h of starvation and is further evidence for the involvement of iron in the pathogenesis of HCB-induced porphyria. The posterior lobes of the livers from the Agus rats given HCB became porphyric more slowly than the remainder with less severe inhibition of uroporphyrinogen decarboxylase. In contrast to their increased susceptibility to HCB, the Agus rats were less susceptible to another prophyrogenic agent, 3,5-diethoxycarbonyl-1,4-dihydrocollidine.