The binding of cytochrome b5 to plasma membranes of rat liver. Its implication for membrane specificity and biogenesis

The in vitro incorporation of cytochrome $\text{b}{}_5$ into purified plasma membranes was investigated by biochemical and immunological methods. Plasma membrane preparations incorporated three times less cytochrome $\text{b}{}_5$ than did microsomal preparations; 60% of this cytochrome $\text{b}{}_5$ could not be reduced by the NADH-cytochrome $\text{b}{}_5$ reductase and was considered as being bound to the plasma membrane. The morphological observations made after the immunochemical labeling of cytochrome $\text{b}{}_5$ clearly showed a good but asymmetrical distribution of the ferritin labeling: only the inner face of the plasma membrane incorporated cytochrome $\text{b}{}_5$. These results are discussed with respect to theories which concern the subcellular membrane relationships in the cell.     

A gel-electrophoretically homogeneous preparation of cytochrome P-450 from liver microsomes of phenobarbital-pretreated rabbits

Cytochrome P-450 was purified from liver microsomes of phenobarbital-pretreated rabbits to a specific content of 16 to 17 nmoles per mg of protein with a yield of about 10 %. The purified cytochrome yielded only a single protein band on sodium dodecylsulfate-urea-polyacrylamide gel electrophoresis, and an apparent molecular weight of about 45,000 was estimated for the protein. The preparation was free of cytochrome $\text{b}{}_5$, NADH-cytochrome $\text{b}{}_5$ reductase, and NADPH-cytochrome $\text{c}$ reductase activities. Aniline hydroxylase and ethylmorphine N-demethylase activities could be reconstituted upon mixing the purified cytochrome with an NADPH-cytochrome $\text{c}$ reductase preparation (purified by a detergent method) and phosphatidyl choline.     

Restoration of pool function type behavior to succinate dehydrogenase having latent reconstitutive activity in ubiquinol-cytochrome c reductase complex

Mitochondrial ubiquinol-cytochrome $\text{c}$ reductase complex contains small amounts of succinate dehydrogenase. Estimates from electrophoresis indicate there is one dehydrogenase per eight complexes. This dehydrogenase transfers electrons to the $\text{b}$-$\text{c}{}_1$ complex poorly, as judged by low succinate-ubiquinone and succinate-cytochrome $\text{c}$ reductase activities. Electron transfer to the $\text{b}$-$\text{c}{}_1$ complex is restored by reconstitution of the complex with phospholipid. This phospholipid dependent restoration of electron transfer indicates that either reconstitutive activity of the dehydrogenase is preserved under conditions where electron transfer is absent, or that addition of phospholipid allows one dehydrogenase to transfer electrons to multiple $\text{b}$-$\text{c}{}_1$ complexes.     

Immunochemical study on the participation of cytochrome b5 in drug oxidation reactions of mouse liver microsomes.

Highly purified divalent and monovalent antibodies against cytochrome $\text{b}{}_5$, anti-$\text{b}{}_5$ immunoglobulin G (IG) and anti-$\text{b}{}_5$ Fab', were used in elucidating the role of this cytochrome in the drug-oxidizing enzyme system of mouse liver microsomes. Anti-$\text{b}{}_5$ IG strongly inhibited not only NADH-supported but also NADPH-supported oxidation of 7-ethoxycoumarin and benzo(a)pyrene, but had no inhibitory action on the oxidation of aniline. Anti-$\text{b}{}_5$ Fab' also inhibited NADH-supported and NADPH-supported benzo(a)pyrene hydroxylation. These observations indicate an essential role of cytochrome $\text{b}{}_5$ in the transfer of electrons not only from NADH but also from NADPH to cytochrome P-450 in the microsomal oxidation of some drugs, but not of aniline.     

Cytochrome b5/cytochrome b5 reductase interaction in microsomes: kinetics at subzero temperature.

The cytochrome $\text{b}{}_5\text{b}{}_5$ reductase system solubilized from microsomes exhibits monophasic reduction kinetics over the temperature range 15 ° to ?25 °C in aqueous/ethylene glycol co-solvent, whereas in intact microsomes, the process becomes increasingly heterogeneous below 0 °C, reflecting heterogeneities in membrane structure observable as distributions in reaction rates and activation energies.     

Studies on NADH-cytochrome b5 reductase activities in hemolysates of human and rabbit red cells by isoelectric focusing

NADH-cytochrome $\text{b}{}_5$ reductase activities in hemolysates of young and old human erythrocytes, and in hemolysates of rabbit reticulocytes and erythrocytes were measured after the separation of the enzyme from the bulk of hemoglobin only by isoelectric focusing. In any cases, a single main peak of the enzyme activity was detected after the electrophoresis in the fraction with pH 6.8 and 8.3 for human and rabbit red cells, respectively. The rabbit enzyme showed more than 30 times higher enzyme activity than that of human erythrocytes under the standard assay conditions. Significant differences of Micahelis constants for cytochrome $\text{b}{}_5$ of the enzyme were found between young and old human erythrocytes, and also between human and rabbit red cells.     

Binding of bovine cytochrome b5 to phosphatidycholine liposomes Characterization of the reconstituted lipid-protein vesicles

Cytochrome $\text{b}{}_5$ was extracted and purified from beef liver by a detergent method (cytochrome $\text{d-b}{}_5$). The hydrophilic moiety which carries the heme group (cytochrome $\text{t-b}{}_5$) was prepared by trypsin action upon pure cytochrome $\text{d-b}{}_5$.Single-shelled lecithin liposomes form complexes with cytochromes $\text{d-b}{}_5$ up to a molar ratio of one protein for 35 phospholipids. The lipid-protein complexes were isolated by gel filtration on Sepharose 4B. They are hollow vesicles in which [³H]-glucose can be trapped. Their diameter is greater than that of the initial liposomes.Cytochrome $\text{t-b}{}_5$ does not interact with the vesicles. These results show that the hydrophobic tail is necessary for the binding and that the hydrophilic part of the protein is located on the outer face of the vesicles. This asymmetry is also proved by the action of reducing agents.Experiments with saturated phosphatidylcholines show that the protein interacts with the lipids both below the transition temperature $\text{T}{}_{\mathrm{M}}$. i.e. when the aliphatic chains are in a crystalline state, and above $\text{T}{}_{\mathrm{M}}$, when the alipathic chain are in a fluid state.¹H NMR spectra show that even at the maximum cytochrome $\text{d-b}{}_5$ concentration the presence of the proteins does not markedly change the dynamics to the phospholipid molecules. An asymmetric single-shelled vesicle structure is proposed for the complex.     

The effect of extra bound cytochrome b-5 on cytochrome P-450-dependent enzyme activities in liver microsomes

Binding of increasing amounts of detergent-purified cytochrome $\text{b}{}_5$ to rabbit liver microsomes produces a progressive inhibition of NADPH-cytochrome P-450 reductase activity which is accompanied by a similar inhibition of NADPH-supported benzphetamine demethylation. In contrast, NADH-cytochrome P-450 reductase activity in the enriched microsomes is markedly enhanced and this stimulation is accompanied by a similar increase in NADH-peroxidase activity, suggesting that cytochrome $\text{b}{}_5$ in these two reactions functions as an intermediate electron carrier to cytochrome P-450.     

Ubisemiquinone radicals from the cytochrome b-c1 complex of the mitochondrial electron transport chain--demonstration of QP-S radical formation

Stable ubisemiquinone radical(s) in the cytochrome $\text{b}\text{?}\text{c}{}_1$-II complex of bovine heart was observed following reduction by succinate in the presence of catalytic amounts of succinate dehydrogenase. The radical was abolished by addition of antimycin A, but a residual radical remained in the presence of excess exogenous Q₂. The radical showed an EPR signal of g = 2.0046 ± .003 at X band (～9.4 GHz) with no resolved hyperfine structure and had a line width of 8.1 ± .5 Gauss at 23°C. The Q band (35 GHz) spectra showed wellresolved $\text{g}$-anisotropy and had a field separation between derivative extrema of 26 ± 1 Gauss. This radical is evidently from QP-C. These observations substantiate that the radical is immobilized and bound to a protein. The QP-S radical was demonstrated in the cytochrome $\text{b}\text{-}\text{c}{}_1$-II complex only in the presence of more than a catalytic amount of succinate dehydrogenase and cytochrome $\text{b}\text{-}\text{c}{}_1$. This signal was not antimycin a inhibitory. The signal amplitude paralleled the reconstitutive enzymic activity of succinate-cytochrome $\text{c}$ reductase from succinate dehydrogenase and the cytochrome $\text{b}\text{-}\text{c}{}_1$-II complex.     

Evidence for a protonmotive Q cycle mechanism of electron transfer through the cytochrome b-c1 complex.

A protein named oxidation factor can be reversibly removed from succinate-cytochrome $\text{c}$ reductase complex and shown to be required for electron transfer between succinate and cytochrome $\text{c}$. This protein is required for reduction of cytochrome $\text{c}{}_1$ and, in the presence of antimycin, for reduction of both cytochromes $\text{b}$ and $\text{c}{}_1$. These results are consistent with a protonmotive Q cycle mechanism in which the oxidation factor catalyzes electron transfer from reduced quinone to cytochrome $\text{c}{}_1$ and thus liberates from reduced quinone one of two protons required for energy conservation during electron transfer through the cytochrome $\text{b}\text{-}\text{c}{}_1$ complex.     

Lipid-protein interactions in membrane models fluorescence polarization study of cytochrome b5-phospholipids complexes

According to previous authors, cytochrome $\text{b}{}_5$, when extracted from bovine liver by a detergent method, is called cytochrome $\text{d-b}{}_5$. On the other hand, the protein obtained after trypsin action, which eliminates an hydrophobic peptide of about 54 residues, is called cytochrome $\text{t-b}{}_5$.Fluorescence polarization of the dansyl phosphatidylethanolamine probe inserted into phospholipid vesicles is very senstive to the binding of proteins, and so is a useful method to study lipid-protein interactions.The chromophore mobility, $\text{R}$, decreases markedly when dipalmitoyl phosphatidylcholine vesicles are incubated with cytochrome $\text{d-b}{}_5$, whereas $\text{R}$ does not change for cytochrome $\text{c}$ and cytochrome $\text{t-b}{}_5$. This can be interpreted as a strengthening of the bilayer, only due to the interaction of the hydrophobic peptide tail.Interaction of dipalmitoyl phosphatidylcholine vesicles with cytochrome $\text{d-b}{}_5$ occurs either below or above the melting temperature of the aliphatic chains (41 °C). Even for a high protein to lipid molar ratio (1 molecule of protein for 40 phospholipid molecules), the melting temperature is apparently unaffected.Phosphatidylserine and phosphatidylinositol do not interact at pH 7.7 with cytochrome $\text{d-b}{}_5$, because electrostatic forces prevent formation of complexes. At low pH, the interaction with the protein occurs, but the binding is mainly of electrostatic nature.     

DNA complementary to rabbit globin mRNA made by E. coli polymerase I

Incubation of liver microsomes with cytochrome $\text{b}{}_5$, purified after solubilization with detergents, caused an effective incorporation of the cytochrome into the microsomal membranes. The incorporated cytochrome was reducible by NADH and could not be removed by repeated washing with 0.3 M KCl or 10 mM EDTA. The incorporation was much more efficient at 37°C than at 0°C. Trypsin-solubilized cytochrome $\text{b}{}_5$, which lacks the hydrophobic tail of the native protein, could not be inserted into the membranes. These findings confirm the view that the hydrophobic tail of the cytochrome molecule is responsible for its tight binding to the microsomal membranes.     

Non-sterol metabolism of mevalonate in vitro: artifacts and realities.

Commercial [5-¹⁴C]mevalonate is shown to contain several radioactive impurities, which give artifactually high amounts of Hyamine bound, volatile acidic radioactivity when incubated with killed or living rat renal cortex slices, as compared with [5-¹⁴C]mevalonate purified either by liquid-liquid partition chromatography or through the enzymically generated $\text{R}\text{-5-phospho-[5-}{}^{14}\text{C]mevalonate}$ by ion-exchange chromatography. The artifactual ${}^{14}\text{CO}{}_2$ results were not diluted by incubation with increasing amounts of unlabelled mevalonate, whereas the ${}^{14}\text{CO}{}_2$ and [${}^{14}\text{C}$]cholesterol produced by rat renal cortex slices incubated with purified [5-¹⁴C]mevalonate were both diluted to the same extent by unlabelled mevalonate. It is concluded that $\text{R}\text{[5-}{}^{14}\text{C]mevalonate}$ is genuinely oxidized to ${}^{14}\text{CO}{}_2\text{in}\text{vitro}$, and that purification of substrate before its use is necessary. Production of ${}^{14}\text{CO}{}_2$ and various [${}^{14}\text{C}$]lipids from purified [5-¹⁴C]mevalonate, as a function of time and substrate concentration, by renal cortex and liver slices, is described.     

Synthesis of a complementary DNA to rat liver albumin mRNA.

NADPH reduces both liver microsomal cytochrome P-450 and cytochrome $\text{b}{}_5$. In the presence of CO, ferrous cytochrome P-450 can slowly transfer electrons to amaranth, an azo dye. This reaction is followed by the reoxidation of cytochrome $\text{b}{}_5$ which proceeds at essentially the same rate as does cytochrome P-450 oxidation. It is suggested that cytochrome $\text{b}{}_5$ directly reduces cytochrome P-450 in rat liver microsomes.     

Cytochrome b5 as electron donor to rabbit liver cytochrome P-450LM2 in reconstituted phospholipid vesicles

When incorporated into phospholipid vesicles containing NADPH-cytochrome P-450 reductase and P-450_LM2, cytochrome b₅ enhanced the rate of NADPH-supported hydroxylation of 7-ethoxycoumarin or $\text{p}$-nitroanisole about 5-fold. Cytochrome b₅ did not affect the rate of NADPH-oxidation, nor the rate of NADPH-supported formation of the ferrous CO-complex of cytochrome P-450. However, the cytochrome b₅-mediated increase in product formation was found to be correlated with concomitant decreases in the production of H₂O₂ or $\text{O}{}_2{}^{\mathrm{?}}$ in the system, thus strongly indicating cytochrome b₅ being a more efficient donor of the second electron to cytochrome P-450 than is NADPH-cytochrome P-450 reductase.     

The effect of formate on cytochrome aa3 and on electron transport in the intact respiratory chain

1. Formate inhibits cytochrome $\text{c}$ oxidase activity both in intact mitochondria and submitochondrial particles, and in isolated cytochrome $\text{aa}{}_3$. The inhibition increases with decreasing pH, indicating that HCOOH may be the inhibitory species.2. Formate induces a blue shift in the absorption spectrum of oxidized cytochrome $\text{aa}{}_3\text{(a}{}^{\mathrm{3+}}\text{a}{}_3{}^{\mathrm{3+}}$) and in the half-reduced species ($\text{a}{}^{\mathrm{2+}}\text{a}{}_3{}^{\mathrm{3+}}$). Comparison with cyanide-induced spectral shifts, towards the red, indicates that formate and cyanide have opposite effects on the $\text{aa}{}_3$ spectrum, both in the fully oxidized and the half-reduced states. The formate spectra provide a new method of obtaining the difference spectrum of $\text{a}{}_3{}^{\mathrm{2+}}$ minus $\text{a}{}_3{}^{\mathrm{3+}}$, free of the difficulties with cyanide (which induces marked high → low spin spectral shifts in cytochrome $\text{a}{}_3{}^{\mathrm{3+}}$) and azide (which induces peak shifts of cytochrome $\text{a}{}^{\mathrm{2+}}$ towards the blue in both α- and Soret regions).3. The rate of formate dissociation from cytochrome $\text{a}{}^{\mathrm{2+}}\text{a}{}_3{}^{\mathrm{3+}}\text{-}\text{HCOOH}$ is faster than its rate of dissociation from $\text{a}{}^{\mathrm{3+}}\text{a}{}_3{}^{\mathrm{3+}}\text{-}\text{HCOOH}$, especially in the presence of cytochrome $\text{c}$. The $\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ for formate inhibition of respiration is a function of the reduction state of the system, varying from 30 mM (100% reduction) to 1 mM (100% oxidation) at pH 7.4, 30 °C.4. Succinate-cytochrome $\text{c}$ reductase activity is also inhibited by formate, in a reaction competitive with succinate and dependent on [formate]².5. Formate inhibition of ascorbate plus $\text{N,N,N′,N′-}\text{tetramethyl}\text{-p-}\text{phenyl-enediamine}$ oxidation by intact rat liver mitochondria is partially released by uncoupler addition. Formate is permeable through the inner mitochondrial membrane and no differences in ‘on’ or ‘off’ inhibition rates were observed when intact mitochondria were compared with submitochondrial particles.6. NADH-cytochrome $\text{c}$ reductase activity is unaffected by formate in submitochondrial particles, but mitochondrial oxidation of glutamate plus malate is subject both to terminal inhibition at the cytochrome $\text{aa}{}_3$ level and to a slow extra inhibition by formate following uncoupler addition, indicating a third site of formate action in the intact mitochondrion.     

Spectral intermediates in the reaction of oxygen with purified liver microsomal cytochrome P-450

Stopped flow spectrophotometry has shown the occurrence of two distinct spectral intermediates in the reaction of oxygen with the reduced form of highly purified cytochrome P-450 from liver microsomes. As indicated by difference spectra, Complex I (with maxima at 430 and 450 nm) is rapidly formed and then decays to form Complex II (with a broad maximum at 440 nm), which resembles the intermediate seen in steady state experiments. In the reaction sequence, P-450_LM^red$\text{→}\text{O}{}_2$Complex I→Complex II→P-450_LM^ox the last step is rate-limiting. The rate of that step is inadequate to account for the known turnover number of the enzyme in benzphetamine hydroxylation unless NADPH-cytochrome P-450 reductase or cytochrome $\text{b}{}_5$ is added. The latter protein does not appear to function as an electron carrier in this process.     

Characterization of cytochrome P-450SCC-containing liposomes

Purified cytochrome $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ from bovine adrenocortical mitochondria was incorporated into liposomes by the cholate-dilution method utilizing either dialysis or Sephadex gel filtration. Among synthetic phospholipids tested, dioleoylglycerophosphocholine showed the best stability during the incorporation of $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ into liposomes. A maximum amount of heme was incorporated into liposomes at a molar ratio of phospholipid to the cytochrome of approx. 200. When $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ was incorporated into the dioleoylglycerophosphocholine liposomes by the cholate-filtration method, the $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}\text{-}\text{containing liposomes}$ showed two major populations on the elution pattern of the Sepharose 4B gel filtration, and were seen at a diameter of 200–600 Å and its aggregated forms. When the cytochrome was incorporated into dioleoylglycerophosphocholine liposomes or cholesterol-free adrenocortical mitochondrial liposomes, $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ was less stable than $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ in aqueous solution. Cholesterol or adrenodoxin markedly stabilized the liposomal $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$. Liposomal $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ required cholesterol for its optimum reduction with adrenodoxin, adrenodoxin reductase, and NADPH in the presence of CO. About 70% of the total heme in the dioleoylglycerophosphocholine liposomes was reduced by the enzymatic reduction in the presence of cholesterol, indicating that 70% of the total molecules are exposed to the surface of the outer monolayer. In order to see the location of the heme in membrane, the dioleoylglycerophosphocholine-liposomal $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$ was subjected to $\text{p-}\text{chloromercuriphenyl sulfonic acid}$ treatment. This reagent destroyed the liposomal $\text{P}{}_{\mathrm{<mtext>450</mtext><mtext>SCC</mtext>}}$. These results suggest that the heme is located in the proximity of the $\text{p-}\text{chloromercuriphenyl sulfonic acid}$ reacting sites which are exposed to the surface, or located on the vincinity of polar heads of the membrane.     

Asymmetric binding of cytochrome b5 to the membrane of human erythrocyte ghosts

The intact, amphipatic form of cytochrome $\text{b}{}_5$ could bind to unsealed ghosts, but not to resealed ghosts, suggesting that the cytochrome could bind only to the inner (cytoplasmic) surface of the ghost membrane. This was further confirmed by the finding that the cytochrome could bind to closed, inside-out vesicles prepared from the ghosts. This asymmetric binding was not due to the exclusive localization of sialic acid and sugar chains on the outer surface of the ghosts membrane, because the cytochrome could not bind to ghosts even after enzymatic removal of these components. Although liposomes consisting of phosphatidylcholine or both phosphatidylcholine and sphingomyelin could effectively bind the cytochrome, this binding capacity was progressively decreased as increasing amount of cholesterol was included in the composition of phosphatidylcholine liposomes. Removal of cholesterol from resealed ghosts by incubation with egg phosphatidylcholine liposomes resulted in the binding of cytochrome $\text{b}{}_5$ to the outer surface of the treated ghosts. The possibility is discussed that the asymmetric binding is due to preferential localization of cholesterol in the outer leaflet of the lipid bilayer that constitutes the ghost membrane.     

Glycosylation of rat liver cytochrome b5 on the ribosomal level

The distribution and site of synthesis of cytochrome $\text{b}{}_5$ was studied by antibody precipitation of the enzyme labeled $\text{in}\text{vivo}$. The enzyme is present in rough and smooth microsomes, Golgi and outer mitochondrial membranes. The cytochrome is synthesized only on bound ribosomes, where glucosamine and galactose moieties are also added. The enzyme seems to be devoid of mannose and sialic acid residues.