Determination of the topography of cytochrome b5 in lipid vesicles by fluorescence quenching

Cytochrome b5, a protein isolated from the endoplasmic reticulum by detergent extraction, interacts spontaneously with small unilamellar phosphatidylcholine vesicles. When the vesicles are made from 1-palmitoyl-2-oleoylphosphatidylcholine (POPC), the tryptophan fluorescence of the cytochrome is enhanced, and when they are made from 1-palmitoyl-2-(dibromostearoyl) phosphatidylcholine (BRPC), the fluorescence is quenched. A series of BRPC were synthesized with bromine atoms at the 6,7, 9,10, 11,12 or 15,16 positions. The vesicles synthesized from each of these lipids were similar in size to those made from POPC. The relative fluorescence intensities of the cytochrome b5 in POPC and 6,7-, 9,10-, 11,12- and 15,16- BRPC were 100, 19.4, 29.4, 37.1, and 54.0, respectively. These data suggest that the exposed tryptophan(s) is (are) at a depth of 0.7 nm below the surface of the vesicle. Bromine is a collisional quencher; hence, these data may indicate the relative position of the lipid annulus around the protein rather than the depth of the protein below the average vesicle surface. Cytochrome b5 contains three potentially fluorescent tryptophans, and determinations of fluorescent quantum yield indicate all three potentially fluorescent tryptophans, and determinations of fluorescent quantum yield indicate all three are fluorescent with an average quantum yield, when in POPC vesicles, of 0.21. Fluorescence lifetime measurements by the demodulation technique indicated heterogeneity of fluorescence lifetimes in all vesicles. The lifetimes in the BRPC vesicles ranged from 2.0 to 2.4 ns compared to a value of 3.3 ns in POPC.(ABSTRACT TRUNCATED AT 250 WORDS)     

Distribution of cytochrome b5 between small and large unilamellar phospholipid vesicles

Cytochrome b5 is an amphipathic integral membrane protein that spontaneously inserts, post-translationally, into intracellular membranes. When added to preformed phospholipid vesicles, it binds in a so-called "loose" or transferable configuration, characterized by the ability of the protein to rapidly equilibrate between vesicles. In a preliminary report we showed that the distribution of cytochrome b5 among a heterogeneous population of small sonicated phosphatidylcholine vesicles (212 to about 350 A in diameter) lies in favor of the smallest vesicles by a factor of at least 20 (Greenhut, S.F. and Roseman, M.A. (1985) J. Biol. Chem. 260, 5883-5886). In the present studies we have attempted to determine the maximal extent to which bilayer curvature can influence the intervesicle distribution of cytochrome b5, by measuring the distribution of the protein between a population of limit-size vesicles 212 A in diameter and a population of large unilamellar vesicles approximately 1000 A in diameter. (The effect of bilayer curvature on the physical properties of the lipids in the large vesicles is considered to be negligible.) The results show that cytochrome b5 favors the small vesicle population by a factor of about 200. This observation suggests that the formation of highly curved regions in biological membranes (or the formation of regions in which the physical state of the lipids is similar to that in small vesicles) may cause the accumulation of certain membrane proteins at those sites. We also observed that a significant fraction (11-20%) of the cytochrome b5, when added directly to the large vesicles, spontaneously inserts into the "tight," physiologically proper configuration. A possible mechanism is discussed.     

Fluorescence study of a mutant cytochrome b5 with a single tryptophan in the membrane-binding domain

Fluorescence studies of cytochrome b5 are complicated by the presence of three tryptophans, at positions 108, 109, and 112, in the membrane-binding domain. The cDNA for rabbit liver cytochrome b5, isolated from a lambda gt11 library, was used to generate a mutated mRNA where the codons for tryptophans-108 and -112 were replaced by codons for leucine. The sequence was expressed in Escherichia coli and the mutant protein was isolated. This mutant protein had the expected absorption spectrum, and its amino acid composition was confirmed by amino acid analysis and by DNA sequencing of the construct. The fluorescence emission spectrum of the mutant is blue-shifted and is narrower than that of the native protein. The quantum yield of the mutant protein, per molecule, is only 60% of that of the native protein, and the enhancement when bound to lipid vesicles or detergent micelles is higher for the mutant. Fluorescence anisotropy measurements and quenching studies using brominated lipids suggest that the fluorescence of the native protein is due to tryptophans-109 and -108 while tryptophan-112 does not emit but undergoes nonradiative energy transfer to tryptophan-108. With this mutant, it was shown that incomplete energy transfer from tyrosines-126 and -129 to tryptophan-109 occurs when the membrane binding domain is inserted into lipid vesicles, which suggests that the membrane-binding domain does not exist in a tight hairpin loop.     

Transfer of cytochrome b 5 and NADPH cytochrome c reductase between membranes

NADPH-cytochrome c reductase also reduces cytochrome b 5. The reduction is very slow when the proteins are in solution or bound to different membranes. Only when both proteins share a common membrane, is cytochrome b 5 reduced rapidly by NADPH. The difference in reaction rates indicates recombination on a common membrane of cytochrome b 5 and NADPH reductase originally bound to different vesicles. The recombination of the two proteins occurs with a variety of biological membranes (previously enriched with either reductase or cytochrome b 5) as well as with liposomes. We explain this process as protein transfer rather than vesicle fusion for several reasons: 1. The vesicles do not alter shape or size during incubation. 2. The rate of this process corresponds to the rate of incorporation of the single proteins into liposomes carrying the 'complementary' protein. 3. The exchange of proteins between biological membranes and liposomes occupied by protein does not change the density of either membrane. Protein transfer between membranes appears to be limited to those proteins which had spontaneously recombined with a preformed membrane. In contrast, proteins incorporated into liposomes by means of a detergent were not transferred, nor were endogenous cytochrome b 5 and NADPH-cytochrome c reductase transferred from microsomes to Golgi membranes or lipid vesicles. We conclude that the endogenous proteins and proteins incorporated in the presence of a detergent are linked to the membrane in another manner than the same proteins which had been inserted into a preformed membrane.     

Reduction of cytochrome b5 by NADPH-cytochrome P450 reductase

The reduction of mammalian cytochrome b5 (b5) by NADPH-cytochrome P450 (P450) reductase is involved in a number of biological reactions. The kinetics of the process have received limited consideration previously, and a combination of pre-steady-state (stopped-flow) and steady-state approaches was used to investigate the mechanism of b5 reduction. In the absence of detergent or lipid, a reductase-b5 complex is formed and rearranges slowly to an active form. Electron transfer to b5 is rapid within this complex (>30 s(-1) at 23 degrees C), as fast as to cytochrome c. With excess b5 present, a burst of reduction is observed, consistent with rapid electron transfer to one or two b5 molecules per reductase, followed by a subsequent rate-limiting event. In detergent vesicles, the reductase and b5 interact rapidly but electron transfer is slower (approximately 3 s(-1) at 23 degrees C). Experiments with dimyristyl lecithin vesicles yielded results intermediate between the non-vesicle and detergent systems. These steady-state and pre-steady-state kinetics provide views of the different natures of the reduction of b5 by the reductase in the absence and presence of vesicles. Without vesicles, the encounter of the reductase and b5 is rapid, followed by a slow reorganization of the initial complex (approximately 0.07 s(-1)), very fast reduction, and dissociation. In vesicles, encounter is rapid and the slow step (approximately 3 s(-1)) is reduction within a complex less favorable for reduction than in the non-vesicle systems.     

Quenching of tryptophan fluorescence by brominated phospholipid

Bromolipids [1-palmitoyl-2-(dibromostearoyl)phosphatidylcholine] with bromines at the 4,5-, 6,7-, 9,10-, 11,12-, and 15,16-positions were used to examine the fluorescence quenching of a synthetic, membrane-spanning peptide (Lys2-Gly-Leu8-Trp-Leu8-Lys-Ala-amide) incorporated into both small and large unilamellar vesicles. The peptide-lipid vesicles were analyzed to show that at least 75% of the peptide was in a transbilayer configuration, placing the single tryptophan in its predicted place in the center of the bilayer. Quenching profiles of the peptide in bromolipid showed maximal (90%) quenching by the 15,16-bromolipid, indicating that the bromolipids can accurately locate the position of a tryptophan in the bilayer. The quenching by the other bromolipids decreased with an r6 dependence and an apparent R0 of 9 A. In addition, indole in methanolic solution was subjected to quenching by a variety of mono- and dibrominated hydrocarbons. The quenching was analyzed, by using a modified Stern-Volmer equation, and found to be greatly dependent upon the number and positioning of the bromines. Monobromobutanes were found to have a quenching efficiency of only 7% while dibromobutanes, with bromines on adjacent carbon atoms, had efficiencies of over 80%. In addition, the dibromobutanes exhibited significant "static" quenching whereas the monobrominated butanes did not. These data suggest that the bromolipids are more appropriately defined as short-range quenchers rather than strictly contact quenchers.     

Preferential lipid association and mode of penetration of apocytochrome c in mixed model membranes as monitored by tryptophanyl fluorescence quenching using brominated phospholipids

The fluorescence of the single tryptophan residue at position 59 in apocytochrome c, the biosynthetic precursor of the inner mitochondrial membrane protein cytochrome c, was studied in small unilamellar vesicles composed of phosphatidylserine (PS) and phosphatidylcholine (PC) with or without specifically Br-labelled acyl chains at the sn-2 position. The protein has a very high affinity for PS-containing vesicles (dissociation constant Kd less than 1 microM). From the relative quenching efficiency by the brominated phospholipids, it could be concluded that the protein specifically associates with the PS component in mixed vesicles and that maximal quenching occurred with phospholipids in which the bromine was present at the 6,7-position of the 2-acyl chain suggesting that (part of) the bound protein penetrates 7-8 A deep into the hydrophobic core of the bilayer.     

Effect of cytochrome b5 on the size, density, and permeability of phosphatidylcholine vesicles.

Cytochrome b5, isolated from rabbit liver by a procedure using detergent, was incubated with phosphatidylcholine bilayer vesicles at 37 degrees for 30 min. A comparison of a number of physical properties was made between the cytochrome b5-phosphatidylcholine complex (at a molar ratio of 1:1000) and the phosphatidylcholine vesicles. The binding of the protein to the vesicle caused no aggregation and no detectable change in Stokes radius of the vesicle as monitored by gel filtration. Only small increases in s20 (from 2.67 up to 3.82 X 10(-13) s) and density (from 1.025 up to 1.042 g ml(-1)) were observed upon binding of the cytochrome b5 to phosphatidylcholine vesicles. At molar ratios of 5:1000, and above, two types of complexes could be detected by sucrose density gradient centrifugation: one had a molar ratio of approximately 1.066 g ml(-1)) the other, a more constant ratio of 20:1000 (density greater than 1.107 g ml(-1)). Cytochrome b5 was also incubated with phosphatidylcholine vesicles prepared with ferricyanide trapped inside. The leakage of the ferricyanide from inside the vesicles was increased when cytochrome b5 was present, but the vesicles, although leaking, were not completely depleted of their ferricyande, and so must still be intact. It is suggested that at molar ratios of cytochrome b5 to phosphatidylcholine below 5:1000, the binding of the protein causes minimal change in vesicle structure.     

Topography of the C terminus of cytochrome b5 tightly bound to dimyristoylphosphatidylcholine vesicles

Cytochrome b5 holoenzyme was bound asymmetrically in the tightly bound form to small unilamellar dimyristoylphosphatidylcholine vesicles. [3H]Taurine, a membrane-impermeant nucleophile, was added to the external medium and was then cross-linked to cytochrome carboxyl residues by the addition of a water-soluble carbodiimide. Nonpolar peptide was isolated after trypsin digestion of taurine-labeled apocytochrome b5 and contained 1.7-1.9 residues of taurine. The C-terminal tetrapeptide containing residues Thr130-Asn133 was generated by chymotryptic hydrolysis of radiolabeled nonpolar peptide and was purified by gel filtration and ion exchange chromatography. Amino acid analysis of the C-terminal tetrapeptide showed that about 1.6 mol of taurine was cross-linked per mol of peptide. When the experiment was performed with taurine trapped inside the vesicles, no cross-linking was observed. The results suggest that when cytochrome b5 holoenzyme is bound to vesicles in the tight binding form, the C terminus is located on the external surface of the vesicles.     

Association of cytochrome b5 and cytochrome P-450 reductase with cytochrome P-450 in the membrane of reconstituted vesicles

A protein-protein association of cytochrome P-450 LM2 with NADPH-cytochrome P-450 reductase, with cytochrome b5, and with both proteins was demonstrated in reconstituted phospholipid vesicles by magnetic circular dichroism difference spectra. A 23% decrease in the absolute intensity of the Soret band of the magnetic CD spectrum of cytochrome P-450 was observed when it was reconstituted with reductase. A difference spectrum corresponding to a 7% decrease in absolute intensity was obtained when cytochrome b5 was incorporated into vesicles that already contained cytochrome P-450 and cytochrome P-450 reductase compared to a decrease of 13% in absolute intensity when cytochrome b5 was incorporated into vesicles that contained only cytochrome P-450. The use of the magnetic circular dichroism confirmed that protein-protein associations that have been detected by absorption spectroscopy between purified and detergent-solubilized proteins also exist in membranes. High ionic strength was shown to interrupt direct electron flow from cytochrome P-450 reductase to cytochrome P-450 but not the electron flow from reductase through cytochrome b5 to cytochrome P-450. Upon incorporation of cytochrome b5 into cytochrome P-450- and cytochrome P-450 reductase-containing vesicles, an increase of benzphetamine N-demethylation activity was observed. The magnitude of this increase was numerically identical to the residual activity of the reconstituted vesicles measured in the presence of 0.3 M KCl. It is concluded that there is a requirement for at least one charge pairing for electron transfer from reductase to cytochrome P-450. These observations are combined in a proposed mechanism of coupled reversible association reactions in the membrane.     

The binding of cytochrome b5 to phosphatidylcholine vesicle

Cytochrome b₅ was isolated from rabbit liver by a detergent procedure and by a proteolytic procedure. Only cytochrome b₅ isolated by the detergent procedure would bind to phosphatidylcholine vesicles and the cytochrome b₅ was not removed by 1 M KCl. The E_o′ and visible absorption spectrum of the cytochrome b₅ and its rate of reduction by NADH plus NADH-cytochrome b₅ reductase did not change appreciably upon binding. These data indicate that cytochrome b₅ is bound to phospholipid by a hydrophobic interaction which leaves the heme portion in the aqueous environment.     

Simultaneous purification and characterization of cytochrome b5 reductase and cytochrome b5 from sheep liver

Cytochrome b5 was purified from detergent solubilized sheep liver microsomes by using three successive DEAE-cellulose, and Sephadex G-100 column chromatographies. It was purified 54-fold and the yield was 23.5% with respect to microsomes. The apparent Mr of cytochrome b5 was estimated to be 16,200 +/- 500 by SDS-PAGE. Absolute absorption spectrum of the purified cytochrome b5 showed maximal absorption at 412 nm and dithionite-reduced cytochrome b5 gave peaks at 557, 526.5 and 423 nm. The ability of the purified sheep liver cytochrome b5 to transfer electrons from NADH-cytochrome b5 reductase to cytochrome c was investigated. The K(m) and Vmax values were calculated to be 0.088 microM cytochrome b5 and 315.8 microM cytochrome c reduced/min/mg enzyme, respectively. Also the reduction of cytochrome b5 by reductase was studied and K(m) and Vmax values were determined to be 5 microM cytochrome b5 and 5200 nmol cytochrome b5 reduced/min/mg enzyme, respectively. The K(m) and Vmax values for the cofactor NADH in the presence of saturating concentration of cytochrome b5 were found to be 0.0017 mM NADH and 6944 nmol cytochrome b5 reduced/min/mg enzyme, respectively. NADH-cytochrome b5 reductase was also partially purified from the same source, detergent solubilized sheep liver microsomes, by using two successive DEAE-cellulose, and 5'-ADP-agarose affinity column chromatographies. It was purified 144-fold and the yield was 7% with respect to microsomes. The apparent monomer Mr of reductase was estimated to be 34,000 by SDS-PAGE. When ferricyanide was used as an electron acceptor, reductase showed maximum activity between 6.8 and 7.5. The K(m) and Vmax values of the enzyme for ferricyanide were calculated as 0.024 mM ferricyanide and 673 mumol ferricyanide reduced/min/mg enzyme, respectively. The K(m) and Vmax values for the cofactor NADH in the presence of saturating amounts of ferricyanide were found to be 0.020 mM NADH and 699 mumol ferricyanide reduced/min/mg enzyme, respectively.     

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

According to previous authors, cytochrome b5, when extracted from bovine liver by a detergent method, is called cytochrome d-b5. On the other hand, the protein obtained after trypsin action, which eliminates an hydrophobic peptide of about 54 residues, is called cytochrome t-b5. Fluorescence polarization of the dansyl phosphatidylethanolamine probe inserted into phospholipid vesicles is very sensitive to the binding of proteins, and so is a useful method to study lipid-protein interactions. The chromophore mobility, R, decreases markedly when dipalmitoyl phosphatidylcholine vesicles are incubated with cytochrome d-b5, whereas R does not change for cytochrome c and cytochrome t-b5. This can be interpreted as a strengthening of bilayer, only due to the interaction of the hydrophobic peptide tail. Interaction of dipalmitoly phosphatidylcholine vesicles with cytochrome d-b5 occurs either below or above the melting temperature of the aliphatic chains (41 degrees 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 d-b5, because electrostatic forces prevent formation of complexes. At low pH, the interaction with the protein occurs, but the binding is mainly of electrostatic nature.     

Ultrastructure of reconstituted rat liver microsomal membranes and cytochrome b5- or P-450-containing proteoliposomes

Thin sectioning and freeze-fracture electron microscopy have been used to show that it is possible to obtain topologically closed vesicles by means of reconstitution of rat liver microsomal membrane "ghosts." The reconstitution by 15 hr dialysis resulted in the formation of vesicles with intramembrane particles (IMP) while after 40 hr dialysis no IMP were observed in the membranes. The protein/lipid ratio and functional activity of NADPH- and NADH-linked enzyme systems were similar in both cases. Cytochrome P-450 (LM2) was incorporated into liposomes of different composition (protein: lipid ratio--1:200). IMP were observed only when the incorporation of cytochrome P-450 was performed in the presence of detergent Emulgen 913 as specific additive to the initial protein-lipid-sodium cholate mixture or in the course of incubation of proteoliposomal suspensions at 37 degrees C. After the incorporation of cytochrome b5 into azolectin liposomes vesicular membranes contain IMP if the incorporated membrane protein: lipid ratio is at least 1:50. Pronase-induced splitting off of a 11 kDa heme-containing fragment of cytochrome b5 did not affect IMP content. The conditions of IMP formation in reconstituted membranes and in microsomal ghosts are discussed.     

Intramembrane position of the fluorescent tryptophanyl residue in membrane-bound cytochrome b5

We have developed a method to measure the intramembrane position of the fluorescent tryptophanyl residue in whole cytochrome b5 and the nonpolar membrane binding segment when these molecules are bound to phospholipid vesicles [Koppel, D.E., Fleming, P., & Strittmatter, P. (1979) Biochemistry (preceding paper in this issue)]. The method utilizes excitation energy transfer from the donor tryptophanyl residue in the protein to trinitrophenyl or danysl acceptor groups on the surface of the phospholipid bilayer. It was determined that that single fluorescent tryptophanyl residue in vesicle-bound cytochrome b5 and the nonpolar segment is located approximately 20-22 A below the surface of the bilayer. This position represents a minimum depth of penetration of this portion of the cytochrome in the membrane.     

A photo-chemically induced dynamic nuclear polarization NMR study on rabbit and bovine cytochrome b5

Although it has been indicated that proteins with chromophoric groups are not suitable for photo-chemically induced dynamic nuclear polarization (photo-CIDNP) measurements, we have successfully obtained these spectra for a heme protein, cytochrome b5. The characteristics of the spectra differed in some points from those so far reported. The intensities of the signals in the aromatic region were very weak, while those of the beta-methylene protons of one histidine and one tryptophan were extremely strong in comparison with the aromatic protons. It was demonstrated, on the basis of the photo-CIDNP spectrum, that one of seven histidines, all three tyrosines and a single tryptophan of the rabbit soluble cytochrome b5 are exposed on the surface of the protein. The results of comparison of the photo-CIDNP spectra for the rabbit soluble and intact, and bovine intact, cytochrome b5 led us to the conclusion that the conformation of the hydrophilic, catalytic part of cytochrome b5 is quite similar among these three proteins. In the presence of Chaps micelles, bovine intact cytochrome b5 was in monomeric form and the histidine signals disappeared from its photo-CIDNP spectrum. When bovine intact cytochrome b5 was reconstituted into egg yolk phosphatidylcholine liposomes, although separate signals due to the protein part were observed in the normal 1H-NMR spectrum, no photo-CIDNP signal could be detected. The normal spectrum suggests that the conformation of the protein embedded in liposomes is similar to that of the oligomeric form without lipids or a detergent.     

Interaction of cytochrome P-450scc with cytochrome b5

Spectrophotometric, affinity chromatography and cross-linking experiments provided evidence that cytochrome P-450scc from bovine adrenocortical mitochondria forms a tight complex with cytochrome b5 from rabbit liver microsomes. In the reconstituted system cholesterol side chain activity of cytochrome P-450scc was enhanced by the addition of cytochrome b5.     

Covalent cross-linking of the active sites of vesicle-bound cytochrome b5 and NADH-cytochrome b5 reductase

A water-soluble carbodiimide has been used to promote the formation of amide bonds between carboxyl residues on cytochrome b5 and lysyl residues on cytochrome b5 reductase. The visible and UV absorption spectrum of the purified cross-linked complex was identical with the sum of the spectra of the individual enzymes, and the average apparent molecular weight of the complex, determined by sodium dodecyl sulfate-gel electrophoresis, was within 12% of the sum of the apparent molecular weights of the two monomeric enzymes, indicating that the cross-linked derivative was a dimer containing one molecule each of cytochrome b5 and cytochrome b5 reductase. When reconstituted into phospholipid vesicles, the amphipathic derivative showed substantially reduced Vmax values with the soluble electron acceptors potassium ferricyanide, cytochrome b5 heme peptide and cytochrome c, and with the membrane-bound acceptors amphipathic cytochrome b5 and stearyl-CoA desaturase. The soluble catalytic fragment of the derivative, produced by limited digestion with subtilisin Carlsberg, showed similar decreases in Vmax values with the above soluble acceptors. In contrast, intradimer electron transfer in the soluble fragment, measured by stopped flow spectrophotometry at 2 degrees C was very efficient. Ninety per cent of the cytochrome b5 in the derivative was reduced with a first order rate constant of 51 s-1 upon the addition of NADH; the transfer of electrons from NADH to the reductase FAD prosthetic group, which is known to be the rate-limiting step in the reductase reaction mechanism, proceeded with an apparent rate constant of 57 s-1 under these conditions. These kinetic data show that the enzymes in the complex are cross-linked together at the surfaces involved in protein-protein contacts during electron transfer in an orientation similar to that assumed during electron transfer between the free proteins.     

The two-domain structure of cytochrome b5 in deoxycholate solution.

The membrane protein cytochrome b5 and the polar and hydrophobic fragments into which it is cleaved by trypsin have been investigated, with major emphasis on the deoxycholate-solubilized form of the protein. Molecular weight measurements show that both the intact protein and the fragments are in a monomeric state in deoxycholate and that a small peptide of perhaps 15 residues is excised when the fragments are formed. Measurements of Stokes radius show that the major fragments are globular, but that intact cytochrome b5 has an asymmetric shape, consistent with a structure composed of two globular domains joined by a link region that may be as long as 30 to 40 A. Circular dichroism measurements were made in the far-ultraviolet and in the Soret region, and they add to previously existing data to make it virtually certain that the polar heme-containing domain is unaffected by proteolysis or by removal of deoxycholate. A significant change in the ultraviolet circular dichroism is, however, observed when proteolysis occurs and it is likely that it arises from the link between the domains, which appears to be highly structured (perhaps helical) in the intact protein, but randomly coiled after it is excised. The binding studies reported previously from this laboratory suggest that these inferences about the structure of cytochrome b5 in deoxycholate solution apply also to the protein as solubilized by detergent micelles, by phospholipid vesicles, or by the microsomal membrane.