Effect of decreased ferrochelatase activity on iron and porphyrin content in mitochondrai of mice with porphyria induced by griseofulvin

The content of iron and protoporphyrin in liver mitochondria from mice with porphyria induced by griseofulvin was measured. The amount of porphyrin was 0.0076 ± 0.0043, 4.11 ± 0.58 and 22.2 ± 6.8 nmol/mg protein (n = 5) in mitochondria from control animals and animals treated with griseofulvin for 3 days and 4–5 weeks, respectively. The energy coupling of the mitochondia was greatly diminished after 4–5 weeks of treatment, and the ferrochelatase activity was inhibited 80–90%, compared to that of control animals. Mitochondrial preparations isolated by differential centrifugation were contaminated with iron-containing lysosomes which could be removed by Percoll density-gradient centrifugation. In purified mitochondrial preparations no change in the amount of non-heme iron was found after griseofulvin feeding, representing 3.36±0.15, 3.97±0.40 and 3.59±0.23 nmol/mg protein for control animals, 3 days- and 4–5 weeks-treated animals, respectively (n = 4). A mitochondrial iron pool previously identified in rat liver mitochondria and shown to be available for heme synthesis in vitro (Tangerås, A. (1985)) Biochim. Biophys. Acta 843 199–207) was also present in mitochondria from mice. The magnitude of this iron pool, as well as its availability for heme synthesis, was not changed after treatment of the animals with griseofulvin. The fact that porphyrin, but not iron, accumulated in the mitochondria when ferrochelatase was inhibited is discussed with regard to our understanding of the process of heme synthesis and its regulation.     

Effect of decreased ferrochelatase activity on iron and porphyrin content in mitochondria of mice with porphyria induced by griseofulvin

The content of iron and protoporphyrin in liver mitochondria from mice with porphyria induced by griseofulvin was measured. The amount of porphyrin was 0.0076 +/- 0.0043, 4.11 +/- 0.58 and 22.2 +/- 6.8 nmol/mg protein (n = 5) in mitochondria from control animals and animals treated with griseofulvin for 3 days and 4-5 weeks, respectively. The energy coupling of the mitochondria was greatly diminished after 4-5 weeks of treatment, and the ferrochelatase activity was inhibited 80-90%, compared to that of control animals. Mitochondrial preparations isolated by differential centrifugation were contaminated with iron-containing lysosomes which could be removed by Percoll density-gradient centrifugation. In purified mitochondrial preparations no change in the amount of non-heme iron was found after griseofulvin feeding, representing 3.36 +/- 0.15, 3.97 +/- 0.40 and 3.59 +/- 0.23 nmol/mg protein for control animals, 3 days- and 4-5 weeks-treated animals, respectively (n = 4). A mitochondrial iron pool previously identified in rat liver mitochondria and shown to be available for heme synthesis in vitro (Tanger?s, A. (1985) Biochim. Biophys. Acta 843, 199-207) was also present in mitochondria from mice. The magnitude of this iron pool, as well as its availability for heme synthesis, was not changed after treatment of the animals with griseofulvin. The fact that porphyrin, but not iron, accumulated in the mitochondria when ferrochelatase was inhibited is discussed with regard to our understanding of the process of heme synthesis and its regulation.     

Mitochondrial iron not bound in heme and iron-sulfur centers and its availability for heme synthesis in vitro

Rat liver mitochondrial fractions have previously been shown to contain a pool of iron which was bound neither in cytochromes nor in iron-sulfur centers (Tangerås, A., Flatmark, T., Bäckström, D. and Ehrenberg, A. (1980) Biochim. Biophys. Acta 589, 162–175), and in the present study the availability of this iron pool for heme synthesis has been studied in isolated mitochondria. A minor fraction of this iron is here shown to originate from iron-rich lysosomes present as a contaminant in mitochondrial fractions isolated by differential centrifugation, and a method for the selective quantitation of this iron pool was developed. The availability of the mitochondrial iron pool for heme synthesis by mitochondria in vitro was studied using a recently developed HPLC method for the assay of ferrochelatase activity. When deuteroporphyrin was used as the substrate, 1.04±0.13 nmol/mg protein of deuteroheme was formed after 6 h incubation at 37°C when a plateau was approached, and the initial rate of heme synthesis was 0.3 nmol/h per mg protein. Heme formation from the physiological substrate protoporphyrin was also seen. The heme synthesis increased with the amount of mitochondria used and was blocked by both Fe(II) and Fe(III) chelators. The heme synthesis was independent of mitochondrial oxidizable substrates and no difference was observed between pH 7.4 and 6.5. FMN slightly stimulated the formation of heme from endogenous iron, probably by mobilization of a small amount of contaminating lysosomal iron present in the preparations. The possibility that the mitochondrial iron pool functions as the proximate iron donor for heme synthesis by ferrochelatase in vivo is discussed.     

Retinoylation Reactions are Inversely Related to the Cardiolipin Level in Testes Mitochondria from Hypothyroid Rats

The effect of hypothyroidism, induced by 6-n-propyl-2-thiouracil (PTU) administration to rats, on the retinoylation reaction and oxidative status was investigated in rat-testes mitochondria. In hypothyroid mitochondria, when compared to euthyroid controls, we found a noticeable increase in the amount of all-trans-retinoic acid (atRA) bound to mitochondrial proteins by an acylation process (34.2 ± 1.9 pmoles atRA/mg protein/360 min and 22.2 ± 1.7 pmoles atRA/mg protein/360 min, respectively). This increase, which was time- and temperature-dependent, was accompanied by a strong reduction in the cardiolipin (CL) amount in the mitochondrial membranes of hypothyroid (2.6 ± 0.2%) as compared to euthyroid rats (4.5 ± 0.5%) Conversely, a decreased retinoylation reaction was observed when CL liposomes were added to mitochondria or mitoplasts from both euthyroid and hypothyroid rats, thus confirming a role of CL in the retinoylation process. In mitochondria from the latter animals an increase of the level of oxidized CL occurred. The ATP level, which was reduced in hypothyroid mitochondria (27.3 ± 4.1 pmoles ATP/mg protein versus 67.1 ± 8.3 pmoles ATP/mg protein of euthyroid animals), was surprisingly increased in mitochondria by the retinoylation reaction in the presence of 100 nM atRA (481.5 ± 19.3 pmoles ATP/mg protein of hypothyroid animals versus 84.7 ± 7.7 pmoles ATP/mg protein of euthyroid animals). Overall, in hypothyroid rat-testes mitochondria the increase in retinoylation activity correlates with a significant depletion of the CL level, due to a peroxidation of this lipid. In addition, an enhanced production of reactive oxygen species was observed.     

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.     

Hydroperoxide specificity of plant and human tissue lipoxygenase: an in vitro evaluation using N-demethylation of phenothiazines

Since hydroperoxide specificity of lipoxygenase (LO) is poorly understood at present, we investigated the ability of cumene hydroperoxide (CHP) and tert-butyl hydroperoxide (TBHP) to support cooxidase activity of the enzyme toward the selected xenobiotics. Considering the fact that in the past, studies of xenobiotic N-demethylation have focused on heme-proteins such as P450 and peroxidases, in this study, we investigated the ability of non-heme iron proteins, namely soybean LO (SLO) and human term placental LO (HTPLO) to mediate N-demethylation of phenothiazines. In addition to being dependent on peroxide concentration, the reaction was dependent on enzyme concentration, substrate concentration, incubation time, and pH of the medium. Using Nash reagent to estimate formaldehyde production, the specific activity under optimal assay conditions for the SLO mediated N-demethylation of chlorpromazine (CPZ), a prototypic phenothiazine, in the presence of TBHP, was determined to be 117±12 nmol HCHO/min/mg protein, while that of HTPLO was 3.9±0.40 nmol HCHO/min/mg protein. Similar experiments in the presence of CHP yielded specific activities of 106±11 nmol HCHO/min/mg SLO, and 3.2±0.35 nmol HCHO/min/mg HTPLO. As expected, nordihydroguaiaretic acid and gossypol, the classical inhibitors of LOs, as well as antioxidants and free radical reducing agents, caused a marked reduction in the rate of formaldehyde production from CPZ by SLO in the reaction media fortified with either CHP or TBHP. Besides chlorpromazine, both SLO and HTPLO also mediated the N-demethylation of other phenothiazines in the presence of these organic hydroperoxides.     

Effect of Dietary Iron Loading on Recognition Memory in Growing Rats

While nutritional and neurobehavioral problems are associated with both iron deficiency during growth and overload in the elderly, the effect of iron loading in growing ages on neurobehavioral performance has not been fully explored. To characterize the role of dietary iron loading in memory function in the young, weanling rats were fed iron-loading diet (10,000 mg iron/kg diet) or iron-adequate control diet (50 mg/kg) for one month, during which a battery of behavioral tests were conducted. Iron-loaded rats displayed elevated non-heme iron levels in serum and liver, indicating a condition of systemic iron overload. In the brain, non-heme iron was elevated in the prefrontal cortex of iron-loaded rats compared with controls, whereas there was no difference in iron content in other brain regions between the two diet groups. While iron loading did not alter motor coordination or anxiety-like behavior, iron-loaded rats exhibited a better recognition memory, as represented by an increased novel object recognition index (22% increase from the reference value) than control rats (12% increase; P=0.047). Western blot analysis showed an up-regulation of dopamine receptor 1 in the prefrontal cortex from iron-loaded rats (142% increase; P=0.002). Furthermore, levels of glutamate receptors (both NMDA and AMPA) and nicotinic acetylcholine receptor (nAChR) were significantly elevated in the prefrontal cortex of iron-loaded rats (62% increase in NR1; 70% increase in Glu1A; 115% increase in nAChR). Dietary iron loading also increased the expression of NMDA receptors and nAChR in the hippocampus. These results support the idea that iron is essential for learning and memory and further reveal that iron supplementation during developmental and rapidly growing periods of life improves memory performance. Our investigation also demonstrates that both cholinergic and glutamatergic neurotransmission pathways are regulated by dietary iron and provides a molecular basis for the role of iron loading in improved memory.     

Interaction between Connexin 43 and nitric oxide synthase in mice heart mitochondria

Connexin 43 (Cx43), which is highly expressed in the heart and especially in cardiomyocytes, interferes with the expression of nitric oxide synthase (NOS) isoforms. Conversely, Cx43 gene expression is down‐regulated by nitric oxide derived from the inducible NOS. Thus, a complex interplay between Cx43 and NOS expression appears to exist. As cardiac mitochondria are supposed to contain a NOS, we now investigated the expression of NOS isoforms and the nitric oxide production rate in isolated mitochondria of wild‐type and Cx43‐deficient (Cx43^{Cre‐ER(T)/fl}) mice hearts. Mitochondria were isolated from hearts using differential centrifugation and purified via Percoll gradient ultracentrifugation. Isolated mitochondria were stained with an antibody against the mitochondrial marker protein adenine‐nucleotide‐translocator (ANT) in combination with either a neuronal NOS (nNOS) or an inducible NOS (iNOS) antibody and analysed using confocal laser scanning microscopy. The nitric oxide formation was quantified in purified mitochondria using the oxyhaemoglobin assay. Co‐localization of predominantly nNOS (nNOS: 93 ± 4.1%; iNOS: 24.6 ± 7.5%) with ANT was detected in isolated mitochondria of wild‐type mice. In contrast, iNOS expression was increased in Cx43^{Cre‐ER(T)/fl} mitochondria (iNOS: 90.7 ± 3.2%; nNOS: 53.8 ± 17.5%). The mitochondrial nitric oxide formation was reduced in Cx43^{Cre‐ER(T)/fl} mitochondria (0.14 ± 0.02 nmol/min./mg protein) in comparison to wild‐type mitochondria (0.24 ± 0.02 nmol/min./mg). These are the first data demonstrating, that a reduced mitochondrial Cx43 content is associated with a switch of the mitochondrial NOS isoform and the respective mitochondrial rate of nitric oxide formation.     

Mitochondrial iron not bound in heme and iron-sulfur centers and its availability for heme synthesis in vitro

Rat liver mitochondrial fractions have previously been shown to contain a pool of iron which was bound neither in cytochromes nor in iron-sulfur centers (Tanger?s, A., Flatmark, T., B?ckstr?m, D. and Ehrenberg, A. (1980) Biochim. Biophys. Acta 589, 162-175), and in the present study the availability of this iron pool for heme synthesis has been studied in isolated mitochondria. A minor fraction of this iron is here shown to originate from iron-rich lysosomes present as a contaminant in mitochondrial fractions isolated by differential centrifugation, and a method for the selective quantitation of this iron pool was developed. The availability of the mitochondrial iron pool for heme synthesis by mitochondria in vitro was studied using a recently developed HPLC method for the assay of ferrochelatase activity. When deuteroporphyrin was used as the substrate, 1.04 +/- 0.13 nmol/mg protein of deuteroheme was formed after 6 h incubation at 37 degrees C when a plateau was approached, and the initial rate of heme synthesis was 0.3 nmol/h per mg protein. Heme formation from the physiological substrate protoporphyrin was also seen. The heme synthesis increased with the amount of mitochondria used and was blocked by both Fe(II) and Fe(III) chelators. The heme synthesis was independent of mitochondrial oxidizable substrates and no difference was observed between pH 7.4 and 6.5. FMN slightly stimulated the formation of heme from endogenous iron, probably by mobilization of a small amount of contaminating lysosomal iron present in the preparations. The possibility that the mitochondrial iron pool functions as the proximate iron donor for heme synthesis by ferrochelatase in vivo is discussed.     

Studies on the mobilization of iron from ferritin by isolated rat liver mitochondria

Rat liver mitochondria and rat liver mitoplasts mobilize iron from ferritin by a mechanism which depends on a respiratory substrate (preferentially succinate), a small molecular weight electron mediator (FMN, phenazine methosulphate or methylene blue) and (near) anaerobic conditions.The release process under optimized conditions (approx. 50 μmol/l FMN, 1 mmol/l succinate, 0.35 mmol/l Fe(III) (as ferritin iron), 37°C and pH 7.40) amounts to 0.9–1.2 nmol iron/mg protein per min.The results suggest that ferritin might function as an intermediate in the cytosolic transport of iron to the mitochondria.     

Perturbation in liver mitochondrial Ca2+ homeostasis in experimental iron overload: a possible factor in cell injury

The functional state of isolated mitochondria and specifically the integrity of the inner membrane, were investigated in the liver of rats made siderotic by dietary supplementation with carbonyl iron. The concentration of iron in the hepatic tissue increased progressively up to nearly 40 days and reached a steady-state level. When the iron content reached a threshold value (higher than 90 nmol/mg protein) the occurrence of in vivo lipid peroxidation in the mitochondrial membrane was detected. This process did not result in gross alterations in the mitochondrial membrane, as indicated by electron microscopy, phosphorylative capability and membrane potential measurements. On the contrary, the induction of lipoperoxidative reaction appeared to be associated with the activation of Ca2+ release from mitochondria. This was shown to occur as a consequence of rather subtle modifications in the inner membrane structure via a specific efflux route, which appeared to be linked to the oxidation level of mitochondrial pyridine nucleotides. The induction of this Ca2+ release from iron-treated mitochondria resulted in enhancement of Ca2+ cycling, a process which dissipates energy to reaccumulate into mitochondria the released Ca2+. The perturbation in mitochondrial Ca2+ homeostasis reported here may be a factor in the onset of cell damage in this experimental model of hepatic iron overload.     

Protective effects of glutathione against lipid peroxidation in chronically iron-loaded mice

To elucidate the protective effects of glutathione against iron-induced peroxidative injury, changes in the hepatic glutathione metabolism were studied in chronically iron-loaded mice. When the diets of the mice were supplemented with carbonyl iron, iron deposition occurred primarily in the parenchymal cells of the liver. In addition, expiratory ethane production was elevated, suggesting an enhancement in lipid peroxidation. In iron-loaded mice, the total hepatic glutathione contents were higher (6.21 +/- 0.53 mumol/g wet wt.) than in control mice (4.61 +/- 0.31 mumol/g wet wt.), primarily due to an increase in the reduced glutathione contents. The value of oxidized glutathione was also higher (98.5 +/- 8.1 nmol/g wet wt.) than in the controls (60.8 +/- 9.5 nmol/g wet wt.), and the ratio of oxidized glutathione to total glutathione increased. The excretion rate of glutathione from the hepatocytes in iron-loaded mice also increased. These observations suggest that chronic iron-loading of mice stimulates lipid peroxidation and oxidation of glutathione and that peroxidized molecules may be catabolized using reduced glutathione.     

Dietary Modulation of Plasma Bilirubin and of Hepatic Microsomal Lipid Peroxidation in the Gunn Rat

An in vitro assay for the simultaneous measurement of lipid peroxidation (LPO) and bilirubin degradation BRD) activities in rat liver microsomes has been developed; a good correlation between the 2 activities was observed (r = 0.78). In the Gunn rat a lipid free diet caused an increase in plasma bilirubin (62.4 ± 25.8%, n = 6) and a concomitant decrease in both hepatic microsomal LPO and BRD to zero. In contrast, on a 25% lipid diet there was a decrease in plasma bilirubin (46.1 ± 3.6%; n = 8) associated with an increase in LPO (1.26 ± 0.11 nmol/min/mg protein, and BRD (0.21 ± 0.6 nmol/min/mg protein). Therefore, in the absence of bilirubin glucuronidation, dietary modulation of plasma bilirubin and lipid peroxidation appear to be closely associated.     

Mitochondrial lipid peroxidation is influenced by dietary factors in early colon carcinogenesis

Oxidative damage to mitochondrial proteins, lipids, and DNA seem to influence the promotion and progression of tumors. High-fat diets and diets high in iron decrease manganese superoxide dismutase activity, a mitochondrial antioxidant, in colon mucosa. Lipid peroxidation products are low in microsomal preparations from colonic mucosa even under peroxide-inducing conditions. However, damage specific to mitochondrial membranes is unknown. This study was designed to investigate dietary lipid and iron effects on fatty acid incorporation and lipid peroxide formation in mitochondrial membranes of colonic mucosa. Male Fischer rats were fed high-fat diets containing either corn oil or menhaden oil with an iron level of either 35 or 535 mg/kg diet. Animals were given two injections of the colon carcinogen, azoxymethane, or saline. Colon tissue was collected 1 and 6 weeks after injections. Mitochondrial and microsomal fractions were prepared for fatty acid analysis and quantitation of lipid peroxidation products. Results showed that lipid composition of both subcellular fractions were influenced by diet. Fatty acid composition of mitochondria differed from microsomes, but overall saturation remained constant. Peroxidation products in mitochondrial membranes were significantly greater than in microsomal membranes. Dietary treatment significantly affected mitochondrial peroxidation in carcinogen-treated animals. Therefore, mitochondria from colon mucosa are more susceptible to peroxidation than are microsomes, dietary factors influence the degree of peroxidation, and the resulting damage may be important in early colon carcinogenesis.     

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.     

Nicotinamide N‐methyltransferase expression in SH‐SY5Y human neuroblastoma cells decreases oxidative stress

Nicotinamide N‐methyltransferase (NNMT) plays a central role in cellular metabolism, regulating pathways including epigenetic regulation, cell signalling, and energy production. Our previous studies have shown that the expression of NNMT in the human neuroblastoma cell line SH‐SY5Y increased complex I activity and subsequent ATP synthesis. This increase in ATP synthesis was lower than the increase in complex I activity, suggesting uncoupling of the mitochondrial respiratory chain. We, therefore, hypothesised that pathways that reduce oxidative stress are also increased in NNMT‐expressing SH‐Y5Y cells. The expression of uncoupling protein‐2 messenger RNA and protein were significantly increased in NNMT‐expressing cells (57% ± 5.2% and 20.1% ± 1.5%, respectively; P = .001 for both). Total GSH (22 ± 0.3 vs 35.6 ± 1.1 nmol/mg protein), free GSH (21.9 ± 0.2 vs 33.5 ± 1 nmol/mg protein), and GSSG (0.6 ± 0.02 vs 1 ± 0.05 nmol/mg protein; P = .001 for all) concentrations were significantly increased in NNMT‐expressing cells, whereas the GSH:GSSG ratio was decreased (39.4 ± 1.8 vs 32.3 ± 2.5; P = .02). Finally, reactive oxygen species (ROS) content was decreased in NNMT‐expressing cells (0.3 ± 0.08 vs 0.12 ± 0.03; P = .039), as was the concentration of 8‐isoprostane F2α (200 ± 11.5 vs 45 ± 2.6 pg/mg protein; P = .0012). Taken together, these results suggest that NNMT expression reduced ROS generation and subsequent lipid peroxidation by uncoupling the mitochondrial membrane potential and increasing GSH buffering capacity, most likely to compensate for increased complex I activity and ATP production.     

Control of choline oxidation in rat kidney mitochondria

Choline is a quaternary amino cationic organic alcohol that is oxidized to betaine in liver and kidney mitochondria. Betaine acts as an intracellular organic osmolyte in the medulla of the kidney. Evidence is provided that kidney mitochondria have a choline transporter in their inner membrane. The transporter has a Km of 173 ± 64 μM and a Vmax of 0.4 ± 0.1 nmol/min/mg mitochondrial protein (at 10 °C). Uptake of choline is not coupled to betaine efflux. Transporter activity demonstrates a dependence on membrane potential and choline transport is inhibited by hemicholinium-3. Steady-state oxygen consumption due to choline oxidation in kidney mitochondria was measurable at 37 °C (125 ± 6 pmolO₂/min/mg mitochondrial protein), in the absence of other mitochondrial electron transport chain substrates and the choline transporter was shown to be the major site of control (96 ± 4%) over choline oxidation flux in isolated kidney mitochondria. We conclude that the choline transporter in rat kidney mitochondria is the major site of control over the production of the organic osmolyte, betaine.     

Aldose reductase,NADPH and NADP+ in normal,galactose-fed and diabetic rat lens

NADPH and NADP⁺ levels were measured in rat lens from normal controls, from galactose-fed and diabetic rats during the first week of cataract formation.The level of NADPH in normal rat lens was determined to be 12.3 ± 0.4 nmol/g wet weight, and that of NADP⁺ 4.6 ± 0.2 nmol/g wet weight. In early cataract formation NADPH levels decreased rapidly during the first 2 days and then remained stable at 76% of control for galactose-fed and 84% for diabetic rats. NADP⁺ levels increased by 38% of control for galactose-fed and 54% for diabetic rats. Calculated NADPH/NADP⁺ ratios dropped from 3.36 ± 0.21 to 1.86 ± 0.16 in galactose fed rats, and from 2.81 ± 0.15 to 1.61 ± 0.16 in diabetic rats (P < 0.001 for both experimental groups). These data are consistent with rapid NADPH oxidation during onset of lens cataracts. No significant changes in aldose reductase enzymatic activity levels were observed in either the galactosemic or the diabetic rats during the times measured.     

Adaptations in Mitochondrial Function Parallel,but Fail to Rescue,the Transition to Severe Hyperglycemia and Hyperinsulinemia: A Study in Zucker Diabetic Fatty Rats

Cross‐sectional human studies have associated mitochondrial dysfunction to type 2 diabetes. We chose Zucker diabetic fatty (ZDF) rats as a model of progressive insulin resistance to examine whether intrinsic mitochondrial defects are required for development of type 2 diabetes. Muscle mitochondrial function was examined in 6‐, 12‐, and 19‐week‐old ZDF (fa/fa) and fa/+ control rats (n = 8–10 per group) using respirometry with pyruvate, glutamate, and palmitoyl‐CoA as substrates. Six‐week‐old normoglycemic–hyperinsulinemic fa/fa rats had reduced mitochondrial fat oxidative capacity. Adenosine diphosphate (ADP)‐driven state 3 and carbonyl cyanide p‐trifluoromethoxyphenylhydrazone (FCCP)‐stimulated state uncoupled (state u) respiration on palmitoyl‐CoA were lower compared to controls (62.3 ± 9.5 vs. 119.1 ± 13.8 and 87.8 ± 13.3 vs. 141.9 ± 14.3 nmol O₂/mg/min.). Pyruvate oxidation in 6‐week‐old fa/fa rats was similar to controls. Remarkably, reduced fat oxidative capacity in 6‐week‐old fa/fa rats was compensated for by an adaptive increase in intrinsic mitochondrial function at week 12, which could not be maintained toward week 19 (140.9 ± 11.2 and 57.7 ± 9.8 nmol O₂/mg/min, weeks 12 and 19, respectively), whereas hyperglycemia had developed (13.5 ± 0.6 and 16.1 ± 0.3 mmol/l, weeks 12 and 19, respectively). This mitochondrial adaptation failed to rescue the progressive development of insulin resistance in fa/fa rats. The transition of prediabetes state toward advanced hyperglycemia and hyperinsulinemia was accompanied by a blunted increase in uncoupling protein‐3 (UCP3). Thus, in ZDF rats insulin resistance develops progressively in the absence of mitochondrial dysfunction. In fact, improved mitochondrial capacity in hyperinsulinemic hyperglycemic rats does not rescue the progression toward advanced stages of insulin resistance.     

Large-scale purification procedure of spinach leaf mitochondria —isolation and immunological studies of the F1–ATPase

A large–scale purification procedure for mitochondria from spinach ( Spinacia oteracea L, cv Medania) leaves is described. It involves differential centrifugation and density gradient centrifugation on a self–generating gradient of Percoll, From 3 kg of spinach leaves, 150 mg mitochondrial protein are obtained. The thylakoid contamination is lower than 0.2% on a chlorophyll basis. The mitochondria oxidize malate and glycine with state 3 rates of 108 and 140 nmol (mg protein)^-1 min^-1, with respiratory control ratios of 2,7 and 3,8 and ADP/O ratios of 2,0 and 2.1, respectively. The present large–scale purification procedure will facilitate further biochemical and molecular biological studies of leaf mitochondrial proteins.
A pure and active catalytic moiety of the F₁–ATPase (EC 3,6,1,3) was purified from the isolated mitochondria. The yield was 5 mg of F₁–ATPase from 150 mg mitochondria. The F₁–ATPase contained five polypeptides of apparent molecular mass 54 kDa (α), 52 kDa (β), 33 kDa (γ), 22 kDa (ω) and 11 kDa (ɛ). An additional component at 24 kDa was present in variable amounts in some preparations and was therefore not ascribed to the ATPase complex. The enzyme catalyzed ATP hydrolysis at a rate of 12.5 nmol (mg protein)^-1 min^-1. Antibodies against the spinach mitochondrial F₁–ATPase cross–reacted only with the a and β subunits of F₁–ATPases of spinach chloroplasts, photosynthetic bacteria Rhodospirillum rubrum and beef heart mitochondria.