Rapid decrease of cytochrome P-450IIE1 in primary hepatocyte culture and its maintenance by added 4-methylpyrazole

Studies were conducted to evaluate the possible induction or the maintenance of cytochrome P-450IIE1 in primary hepatocyte cultures by the inducing agent 4-methylpyrazole. Hepatocytes were isolated from control (noninduced) rats and from rats treated in vivo with either pyrazole or 4-methylpyrazole to induce P-450IIE1. The content of P-450IIE1 was determined by Western blots with antipyrazole P-450 IgG, and catalytic activity was assessed by assays of dimethylnitrosamine demethylase activity. The treatment with 4-methylpyrazole in vivo increased the content of P-450IIE1 and dimethylnitrosamine demethylase activity sevenfold and fourfold, respectively. In cultures prepared from noninduced hepatocytes, P-450IIE1 levels fell to values of 76%, 65%, 31% and 1% of freshly isolated hepatocytes after 1, 3, 6 and 9 days in culture. A similar decrease in dimethylnitrosamine demethylase was observed during this time. In cultures prepared from induced hepatocytes, the decline in P-450IIE1 was more rapid as levels fell to 77%, 31%, 3% and 3% of initial values after 1, 3, 6 and 9 days in culture. Again, the fall in dimethylnitrosamine demethylase activity paralleled the decline in content of P-450IIE1 and was more rapid with the induced hepatocytes. With cultures prepared from noninduced or induced hepatocytes, the addition of 4-methylpyrazole in vitro did not increase the content of P-450IIE1 or the activity of dimethylnitrosamine demethylase over the initial values. However, 4-methylpyrazole appeared to stabilize the P-450IIE1 and to decrease its rate of decline in culture. In noninduced cultures, the percent remaining content of P-450IIE1 after 6 days was 31% in the absence of and 52% in the presence of 5 mol/L 4-methylpyrazole. In cultures from 4-methylpyrazole-induced hepatocytes, the percent remaining P-450IIE1 after 3 days was 31% in the absence of inducer and 59% with 4-methylpyrazole added in vitro. Similarly 4-methylpyrazole helped to prevent the rapid decline of dimethylnitrosamine demethylase activity in induced and noninduced cultures. Viability of the induced and noninduced cultures in the absence or presence of added 4-methylpyrazole was similar. Levels of mRNA for P-450IIE1 were similar for livers from control rats and from rats treated in vivo with 4-methylpyrazole. The mRNA levels rapidly declined in induced and noninduced cultures, and this decline, unlike the fall in P-450IIE1 or dimethylnitrosamine demethylase activity, could not be prevented by the addition of 4-methylpyrazole in vitro to the cultures.(ABSTRACT TRUNCATED AT 400 WORDS)

Synergistic interactions between NADPH-cytochrome P-450 reductase, paraquat, and iron in the generation of active oxygen radicals

The toxicity associated with paraquat is believed to involve the generation of active oxygen radicals and the production of oxidative stress. Paraquat can be reduced by NADPH-cytochrome P-450 reductase to the paraquat radical; this results in consumption of NADPH. A variety of ferric complexes, including ferric-ATP, -citrate, -EDTA, ferric diethylenetriamine pentaacetic acid and ferric ammonium sulfate, produced a synergistic increase in the paraquat-mediated oxidation of NADPH. This synergism could be observed with very low concentrations of iron, e.g. 0.25 microM ferric-ATP. Very low rates of hydroxyl radical were generated by the reductase with paraquat alone, or with ferric-citrate or -ATP or ferric ammonium sulfate in the absence of paraquat; however, synergistic increases in the rate of hydroxyl radical generation occurred when these ferric complexes were added together with paraquat. Ferric-EDTA and -DTPA catalyzed some production of hydroxyl radicals, which was also synergistically elevated in the presence of paraquat. Ferric desferrioxamine was essentially inert in the absence or presence of paraquat. This enhancement of hydroxyl radical generation was sensitive to catalase and competitive scavengers but not to superoxide dismutase. The interaction of paraquat with NADPH-cytochrome P-450 reductase and ferric complexes resulted in an increase in oxygen radical generation, and various ferric complexes increased the catalytic effectiveness and potentiated significantly the toxicity of paraquat via this synergistic increase in oxygen radical generation by the reductase.

Reduction of cytochrome b in mitochondria from yeast lacking coenzyme Q

Mitochondria isolated from coenzyme Q deficient yeast cells had no detectable NADH:cytochrome c reductase or succinate:cytochrome c reductase but had comparable amounts of cytochromes b and c1 as wild-type mitochondria. Addition of succinate to the mutant mitochondria resulted in a slight reduction of cytochrome b; however, the subsequent addition of antimycin resulted in a biphasic reduction of cytochrome b, leading to reduction of 68% of the total dithionite-reducible cytochrome b. No "red" shift in the absorption maximum was observed, and no cytochrome c1 was reduced. The addition of either myxothiazol or alkylhydroxynaphthoquinone blocked the reduction of cytochrome b observed with succinate and antimycin, suggesting that the reduction of cytochrome b-562 in the mitochondria lacking coenzyme Q may proceed by a pathway involving cytochrome b at center o where these inhibitors block. Cyanide did not prevent the reduction of cytochrome b by succinate and antimycin the the mutant mitochondria. These results suggest that the succinate dehydrogenase complex can transfer electrons directly to cytochrome b in the absence of coenzyme Q in a reaction that is enhanced by antimycin. Reduced dichlorophenolindophenol (DCIP) acted as an effective bypass of the antimycin block in complex III, resulting in oxygen uptake with succinate in antimycin-treated mitochondria. By contrast, reduced DCIP did not restore oxygen uptake in the mutant mitochondria, suggesting that coenzyme Q is necessary for the bypass. The addition of low concentrations of DCIP to both wild-type and mutant mitochondria reduced with succinate in the presence of antimycin resulted in a rapid oxidation of cytochrome b perhaps by the pathway involving center o, which does not require coenzyme Q.

Coenzyme Q analogues reconstitute electron transport and proton ejection but not the antimycin-induced "red shift" in mitochondria from coenzyme Q deficient mutants of the yeast Saccharomyces cerevisiae

Mitochondria isolated from coenzyme Q deficient yeast cells had no detectable NADH:cytochrome c reductase or succinate:cytochrome c reductase activity but contained normal amounts of cytochromes b and c1 by spectral analysis. Addition of the exogenous coenzyme Q derivatives including Q2, Q6, and the decyl analogue (DB) restored the rate of antimycin- and myxothiazole-sensitive cytochrome c reductase with both substrates to that observed with reduced DBH2. Similarly, addition of these coenzyme Q analogues increased 2-3-fold the rate of cytochrome c reduction in mitochondria from wild-type cells, suggesting that the pool of coenzyme Q in the membrane is limiting for electron transport in the respiratory chain. Preincubation of mitochondria from the Q-deficient yeast cells with DBH2 at 25 degrees C restored electrogenic proton ejection, resulting in a H+/2e- ratio of 3.35 as compared to a ratio of 3.22 observed in mitochondria from the wild-type cell. Addition of succinate and either coenzyme Q6 or DB to mitochondria from the Q-deficient yeast cells resulted in the initial reduction of cytochrome b followed by a slow reduction of cytochrome c1 with a reoxidation of cytochrome b. The subsequent addition of antimycin resulted in the oxidant-induced extrareduction of cytochrome b and concomitant oxidation of cytochrome c1 without the "red" shift observed in the wild-type mitochondria. Similarly, addition of antimycin to dithionite-reduced mitochondria from the mutant cells did not result in a red shift in the absorption maximum of cytochrome b as was observed in the wild-type mitochondria in the presence or absence of exogenous coenzyme Q analogues.(ABSTRACT TRUNCATED AT 250 WORDS)

Further studies on the binding of DCCD to cytochrome B and subunit VIII of complex III isolated from beef heart mitochondria

Complex III (the cytochrome b-c1 complex) from beef heart mitochondria was incubated with [14C]DCCD for various periods of time. The polypeptide profile of the complex was compared in both stained gels and their autoradiograms when three different methods were used to terminate the reaction. Precipitation with ammonium sulfate resulted in the formation of a new band with an apparent molecular weight of 39,000 in both incubated samples and the zero time controls. Reisolation of the complex by centrifugation through 10% sucrose or by precipitation with trichloroacetic acid did not result in any changes in the appearance of the subunit peptides of the complex. Subunit III (cytochrome b) and subunit VIII were the only bands labeled after termination of the reaction by centrifugation through sucrose, while both ammonium sulfate and trichloroacetic precipitation resulted in nonspecific labeling of several other subunits of the complex and increased labeling of subunit VIII relative to subunit III. Preincubation of the complex with antimycin prior to treatment with [14C]DCCD resulted in a 50% decrease in the binding of DCCD to both cytochrome b and subunit VIII. Furthermore, treatment of the complex III with DCCD resulted in a change in the red shift observed after antimycin or myxothiazol addition to the dithionite-reduced complex resulting in a broad peak with no sharp maximum. These results provide further confirmation that DCCD binds preferentially to cytochrome b and subunit VIII of complex III from beef heart mitochondria and suggest that cytochrome b may play a role in proton translocation.

Effect of temperature on protein synthesis and leucine transport by yeast mitochondria

Protein synthesis in yeast mitochondria shows biphasic Arrhenius plots both in vivo and in vitro, with a twofold increase in the activation energy below the transition temperature suggesting a functional association between mitochondrial protein synthesis and the inner membrane. Analysis by gel electrophoresis of mitochondrial translation products labeled in vivo showed that the same proteins are synthesized and then inserted into the membrane above and below the transition temperature of the membrane. The rate of leucine uptake into mitochondria was decreased at least fivefold in the presence of chloramphenicol, suggesting that leucine is used mainly for protein synthesis. In the absence of chloramphenicol, the rate of leucine uptake was always slightly higher but comparable to the incorporation rate of leucine into protein at all temperatures studied, suggesting that the transport of leucine into mitochondria is not rate-limiting for protein synthesis. The ionophore valinomycin or the uncoupler carbonyl phenylhydrazone (CCCP) inhibited 75-80% of the leucine uptake in the presence of chloramphenicol. In addition, the omission of respiratory chain substrates and the ATP-regenerating system led to a 93% inhibition of uptake, suggesting that leucine uptake may occur by an active transport mechanism.

Inhibition by dicyclohexylcarbodiimide of proton ejection but not electron transfer in rat liver mitochondria

The primary effect of dicyclohexylcarbodiimide (DCCD) at the cytochrome b-c1 region of the respiratory chain of rat liver mitochondria is an inhibition of proton translocation. No significant decrease was observed in the rate of electron flow from succinate to cytochrome c when measured as cytochrome c reductase, K3Fe(CN)6 reductase, or the rate of H+ release in the presence of the uncoupler carbonyl cyanide m-chlorophenylhydrazone after treatment with sufficient DCCD to abolish completely electrogenic proton ejection. The inhibitory effects of DCCD were time and concentration dependent and affected by the pH of the medium. Lowering the pH from 7.3 to 6.7 resulted in a progressively faster rate and extent of inhibition of proton ejection by DCCD. At pH 6.9, the H+/2e- decreased by 50% within 30 s after DCCD addition; however, at pH 7.3, a 50% decrease was not observed until 2 min after DCCD addition. DCCD did not act as an uncoupler as both the rate of proton ejection and back decay were decreased after incubation with DCCD. Treatment of rat liver mitochondria with DCCD under these same conditions also resulted in a broadening of the sharp spectral shift of cytochrome b observed after antimycin addition to mitochondria previously reduced with succinate suggesting that DCCD may modify cytochrome b in such a way that the binding of antimycin is altered.

Dicyclohexylcarbodiimide binds to cytochrome b and subunit VIII in soluble complex III from beef heart mitochondria

Incubation of soluble complex III isolated from either yeast or beef heart mitochondria with 25-100 nmol of [14C]dicyclohexylcarbodiimide (DCCD)/nmol of cytochrome b followed by centrifugation through 10% sucrose or precipitation with trichloroacetic acid did not result in any changes in the appearance of the subunits of either complex. The [14C]DCCD was bound to cytochrome b and phospholipids in the yeast complex and with similar kinetics to both cytochrome b and subunit VIII (Mr = 4000-8000) plus phospholipids of the beef complex. Subunit VIII of the beef complex was partially extracted with chloroform:methanol; however, no subunit of this mobility was present in the yeast complex. Incubation of the beef complex in phosphate buffer for short times resulted in a doubling of the [14C]DCCD bound to cytochrome b relative to that to subunit VIII. Preincubation of both complexes with venturicidin prior to treatment with DCCD resulted in a 50% decrease in the binding of [14C]DCCD to cytochrome b. Reisolation of the beef complex III by precipitation with (NH4)2SO4 after incubation with [14C]DCCD resulted in the formation of a new band with an apparent molecular weight of 39,000 even in the zero time control. The [14C]DCCD was bound to subunit VIII and the core proteins but not to cytochrome b at all times, suggesting that precipitation with (NH)2SO4 in the presence of DCCD causes cross-linking of the subunits of complex III.

The preferential binding of dicyclohexylcarbodiimide to cytochrome b and phospholipids in soluble complex III from yeast mitochondria

The binding of [14C]dicyclohexylcarbodiimide (DCCD) to soluble complex III from yeast mitochondria was examined under conditions which resulted in the inhibition of proton ejection but had a minimal effect on cytochrome c reductase activity. Incubation of the complex with 50-100 nmol of [14C]DCCD/nmol of cytochrome b at 12 degrees C did not result in any changes in the appearance of the high-molecular-weight subunits (I-V) after sodium dodecyl sulfate-gel electrophoresis, although a slight broadening of the three lowest molecular-weight subunits (VI-VIII) was observed. The [14C]DCCD was bound preferentially to subunit III (cytochrome b) and a wide band with an apparent low-molecular weight ranging from 8000 to 9000 to less than 2000 depending on the gel system used. Extraction of the [14C]DCCD-treated complex III with chloroform:methanol had no effect on subunit III but completely removed the low-molecular-weight radioactive band. Thin-layer chromatography of the chloroform:methanol extract revealed that the radioactive material extracted from the [14C]DCCD-treated complex III migrated with the same apparent RF as either free [14C]DCCD or cardiolipin. Amino acids were not detectable in an acid hydrolysate of the chloroform:methanol extract, suggesting the absence of protein. Digestion of the [14C]DCCD-treated complex III with either chymotrypsin or Staphylococcus aureus V8 protease resulted in the decrease of both staining intensity and labeling in subunit III but had no effect on the radioactivity in the low-molecular-weight material. These results confirm that DCCD binds preferentially to cytochrome b in complex III from yeast mitochondria and suggest that cytochrome b may play an important role in proton translocation at this site of the respiratory chain.

Dicyclohexylcarbodiimide blocks proton ejection and affects antimycin binding but not electron transport in complex III from yeast mitochondria

Treatment of complex III with dicyclohexyldicarbodiimide (DCCD) either before or after incorporation into liposomes resulted in a loss of electrogenic proton movements; however, only minimal decreases in cytochrome c reductase activity were noted in the liposomes containing DCCD-treated complex III. Thus, DCCD appears to act by "uncoupling" proton translocation from electron transport. A decreased sensitivity of the ubiquinol:cytochrome c reductase activity to antimycin was also noted in the DCCD-treated complex III. This loss of sensitivity to antimycin was reflected in a decreased binding of antimycin to the complex after DCCD treatment from 9.5 nmol/mg of protein in the control to 3.8 nmol/mg of protein in the DCCD-treated complex. DCCD also affected the red shift observed after antimycin addition to dithionite-reduced complex III resulting in a broad peak with no sharp maximum. Similarly, DCCD treatment of yeast mitochondria resulted in a complete loss in the red shift after antimycin addition to mitochondria previously reduced with succinate. No loss in enzymatic activity was observed in the DCCD-treated mitochondria. These results suggest that DCCD concomitant with the inhibition of proton ejection in the cytochrome b-c1 region of the respiratory chain causes modifications in the properties of cytochrome b which alter the binding of antimycin without significantly affecting the electron transfer activity of this cytochrome.

The presence of the iron-sulfur protein (subunit V) of complex III in mitochondria of heme-deficient yeast cells lacking iron-sulfur clusters detectable by electron paramagnetic resonance

The presence of subunit V, the iron-sulfur protein, of complex III has been demonstrated in mitochondria from a mutant of Saccharomyces cerevisiae which lacks 5-aminolevulinic acid synthase and, hence, is devoid of heme. The mature form (24 K Da) of the iron-sulfur protein was observed in equal amounts in the heme-deficient and heme-sufficient cells with antiserum against subunit V and either the sensitive immuno-transfer technique or immunoprecipitation from dodecylsulfate-solubilized mitochondria. In addition, a slight shoulder with a molecular mass 1.5 kDa larger than the mature form was present in mitochondria from the heme-deficient cells. Electron paramagnetic resonance spectroscopy revealed the absence of iron-sulfur signals due to clusters S-1, S-2 and S-3 of succinate dehydrogenase or to Rieske's iron-sulfur cluster of complex III in mitochondria from the heme-deficient cells. The lack of iron-sulfur centers in these cells may be a consequence of the absence of sulfite reductase in the cells without heme.

Topographical orientation of complex III in the yeast mitochondrial membrane

The orientation of the different subunits of complex III in the yeast inner mitochondrial membrane has been investigated by several different approaches. Immunoinhibition studies of cytochrome c reductase activity in intact mitoplasts and submitochondrial particles using IgG obtained from specific antisera against complex III, the iron-sulfur protein, core protein I, and core protein II suggested a transmembranous orientation of the complex with the antigenic sites of the iron-sulfur protein exposed on the cytoplasmic surface of the membrane. A lack of immunoinhibition was observed with the IgG against either core protein suggesting that these proteins may not be involved in catalysis. Digestion of mitoplasts with chymotrypsin indicated that the protein mass of cytochromes b and c1 protrudes from the cytoplasmic surface of the membrane; however, the hemes of cytochrome b appear to be buried within the membrane while the heme of cytochrome c1 is partially exposed on the chymotrypsin-sensitive portion of the polypeptide. By contrast, the iron-sulfur protein does not protrude from the membrane as it is completely resistant to chymotrypsin digestion. Labeling with the hydrophilic membrane-impermeant probe diazobenzenesulfonate suggests that core protein II is exposed on both sides of the membrane but protrudes into the matrix; while core protein I is within the membrane. Immunoprecipitation studies of sodium dodecyl sulfate and Triton X-100-solubilized mitochondria with subunit-specific antisera suggest that cytochromes b and c1 and core protein I are tightly associated in complex III. By contrast, the iron-sulfur protein and core protein II are loosely associated with the other subunits of the complex such that they are dissociated by low concentrations of detergent.

Orientation of complex III in the yeast mitochondrial membrane: labeling with [125I] diazobenzenesulfonate and functional studies with the decyl analogue of coenzyme Q as substrate

Mitochondria (or mitoplasts) and submitochondrial particles from yeast were treated with [125I] diazobenzenesulfonate to label selectively proteins exposed on the outer or inner surface of the inner mitochondrial membrane. Polyacrylamide gel analysis of the immunoprecipitates formed with antibodies against Complex III or cytochrome b revealed that the two core proteins and cytochrome b were labeled in both mitochondria and submitochondrial particles, suggesting that these proteins span the membrane. Cytochrome c1 and the iron sulfur protein were labeled in mitochondria but not in submitochondrial particles, suggesting that these proteins are exposed on the cytosolic side of the inner membrane. The steady-state reduction of cytochromes b and c1 was determined with succinate and the decyl analogue of coenzyme Q as substrates. Addition of the coenzyme Q analogue to mitochondria caused reduction of 15-30% of ;the total dithionite-reducible b and 100% of the cytochrome c1: Addition of the coenzyme Q analogue to submitochondrial particles led to the reduction of 70% of the total dithionite-reducible cytochrome b but insignificant amounts of cytochrome c1. A model to explain the topography of Complex III in the inner membrane is proposed based on these results.

Aggregates of yeast mitochondrial cytochrome b observed after electrophoresis

Mitochondrial translation produces obtained from yeast cells labeled in vivo in the presence of cycloheximide were separated by dodecylsulfate polyacrylamide gel electrophoresis. The labeled band, with a molecular weight of 30,000 corresponding to cytochrome b, was excised and subsequently transferred to a second gel. After electrophoretic separation, two labeled polypetides with apparent molecular weights of 67,000 and 27,000 became visible in addition to the cytochrome b band of 30,000 molecular weight. Heating of the cytochrome b band prior to transfer resulted in an increase in the amount of the labeled polypeptides migrating with a molecular weight of 67,000. Longer exposure during autoradiography of the gels of mitochondrial translation products resulted in the appearance of a double band with an apparent molecular weight of 67,000. Limited proteolysis of this 67,000 dalton protein with Staphylococcus aureus V8 protease revealed a peptide map similar to that obtained after proteolysis of cytochrome b. These results suggest that the polypeptide with an apparent molecular weight of 67,000 represents an aggregate of cytochrome b that is either present as such in the membrane or is formed in vitro during the experimental manipulation to prepare mitochondria for gel electrophoresis.

Synthesis of the apoprotein of cytochrome b in heme-deficient yeast cells

The presence of the apoprotein of cytochrome b has been demonstrated in a mutant of Sacchromyces cerevisiae lacking delta-aminolevulinic acid synthase and, hence, devoid of heme. The apoprotein of cytochrome b present in the mutant was identical with cytochrome b of control cells (mutant cells grown in the presence of delta-aminolevulinic acid) by the following criteria: similar apparent molecular weights in dodecyl sulfate-polyacrylamide gel electrophoresis; anomalous migration behavior during electrophoresis in polyacrylamide gels of different porosities; identical gel pattern obtained after immunoprecipitation with specific antiserum against cytochrome b; and identical fingerprints obtained after limited proteolysis with Staphylococcus aureus V8 protease. The kinetics of incorporation in vivo of [35S]methionine into apoprotein of cytochrome b in the mutant suggested that heme deficiency may affect assembly into the membrane of subunits of the cytochrome b.c1 complex rather than synthesis of cytochrome b.

The synthesis of cytochrome b on mitochondrial ribosomes in baker's yeast

Antiserum against a major cytochrome b peptide isolated from yeast mitochondria as described previously (Lin, L.-F.H., and Beattie, D.S., J. Biol. Chem. 1978, 253, 2412--2418) was raised in rabbits and shown to be monospecific against the pure antigen. Mitochondria were isolated from yeast cells grown in [3H]leucine, extracted with Lubrol and treated with antiserum to cytochrome b. Analysis of the immunoprecipitates by sodium dodecyl sulfate/polyacrylamide gel electrophoresis revealed the presence of a single major band of molecular weight 31 000 corresponding to cytochrome b. In order to determine the intracellular site of translation of cytochrome b, yeast cells were labeled in vivo under non-growing conditions with [3H]leucine in the absence or presence of inhibitors of cytoplasmic and mitochondrial protein synthesis. The incorporation of radioactive leucine into the apoprotein of cytochrome b isolated by immunoprecipitation followed by gel electrophoresis was insensitive to cycloheximide (an inhibitor of cytoplasmic protein synthesis) and sensitive to acriflavin, erythromycin, and chloramphenicol (inhibitors of mitochondrial protein synthesis). Furthermore, no cytochrome b apoprotein was present in a cytoplasmic petite mutant which lacked mitochondrial protein synthesis. Cytochrome b is thus a product of protein synthesis on mitochondrial ribosomes.

Binding of deoxyribonucleic acid to the surface of human platelets

It was demonstrated that washed human platelets can bind minute amounts of 14C-DNA on their surface during short-term incubation. The binding was specific and firm in the described experimental conditions. Washed platelets bound also 14C-DNA anti-DNA antibody complexes, although to a lesser amount than 14C-DNA alone. The possible significance of these findings is briefly discussed.

Haemoglobin G-Szuhu, beta80 Asn-Lys, in the homozygous state in a patient with abetalipoproteinaemia

An 11-year-old Jewish girl of Turkish extraction with abetalipoproteinaemia was found to be homozygous for haemoglobin Szuhu (beta80 Asn leads to Lys). Except for the abnormal haemoglobin, no other haematological or biochemical abnormalities were found in her consanguineous parents and one sister. In the propositus, erythrocyte morphology showed the acanthocytosis known to be in association with abetalipoproteinaemia. Increased autohaemolysis was also found, which reverted to normal after treatment with vitamin E. This case represents the first reported association of abetalipoproteinaemia with an abnormal haemoglobin, and the first homozygous Hb G-Szuhu.