The role of tryptophan residues of NADPH-adrenodoxin reductase in the formation of complex with adrenodoxin

Chemical modification of tryptophan residues by N-bromosuccinimide was used to determine the role of these residues in the NADPH-adrenodoxin-catalyzed reduction of adrenodoxin, dichlorophenolindophenol and ferricyanide. It was shown that the rate of reduction of all electron acceptors diminishes with modification of tryptophan residues. The most significant decrease of the enzyme activity is observed in case of adrenodoxin-catalyzed reactions. It was suggested that tryptophan residues are responsible for the adrenodoxin reductase interaction with adrenodoxin.     

The use of a specific fluorescence probe to study the interaction of adrenodoxin with adrenodoxin reductase and cytochrome P-450scc

The single free cysteine at residue 95 of bovine adrenodoxin was labeled with the fluorescent reagent N-iodoacetylamidoethyl-1-aminonaphthalene-5-sulfonate (1,5-I-AEDANS). The modification had no effect on the interaction with adrenodoxin reductase or cytochrome P-450scc, suggesting that the AEDANS group at Cys-95 was not located at the binding site for these molecules. Addition of adrenodoxin reductase, cytochrome P-450scc, or cytochrome c to AEDANS-adrenodoxin was found to quench the fluorescence of the AEDANS in a manner consistent with the formation of 1:1 binary complexes. F?rster energy transfer calculations indicated that the AEDANS label on adrenodoxin was 42 A from the heme group in cytochrome c, 36 A from the FAD group in adrenodoxin reductase, and 58 A from the heme group in cytochrome P-450scc in the respective binary complexes. These studies suggest that the FAD group in adrenodoxin reductase is located close to the binding domain for adrenodoxin but that the heme group in cytochrome P-450scc is deeply buried at least 26 A from the binding domain for adrenodoxin. Modification of all the lysines on adrenodoxin with maleic anhydride had no effect on the interaction with either adrenodoxin reductase or cytochrome P-450scc, suggesting that the lysines are not located at the binding site for either protein. Modification of all the arginine residues with p-hydroxyphenylglyoxal also had no effect on the interaction with adrenodoxin reductase or cytochrome P-450scc. These studies are consistent with the proposal that the binding sites on adrenodoxin for adrenodoxin reductase and cytochrome P-450scc overlap, and that adrenodoxin functions as a mobile electron carrier.     

The involvement of carboxylate groups of putidaredoxin in the reaction with putidaredoxin reductase

Modification of carboxyl groups on putidaredoxin with 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide (EDC) resulted in loss of putidaredoxin reductase activity. The modification did not affect the visible absorption spectrum of putidaredoxin, indicating that the iron-sulfur center was not perturbed. In order to identify the carboxyl groups labeled by EDC, native and EDC-treated putidaredoxin were digested with a combination of trypsin and Staphylococcus aureus protease, and the resulting peptides were separated by high pressure liquid chromatography. The most heavily modified carboxyl groups were found to be those at residues 58, 65, 67, 72, and 77. These carboxyl groups are located in the same general region of the protein as those on adrenodoxin that have been shown to be involved in binding to both adrenodoxin reductase and cytochrome P-450scc. Chemical modification was also used to compare the role of lysine, arginine, and histidine residues on putidaredoxin and adrenodoxin. Modification of lysine and arginine residues had no effect on the reductase activity of either protein. The reductase activity of adrenodoxin was unaffected by labeling with 1 eq of diethyl pyrocarbonate/histidine residue, but labeling with a second equivalent completely abolished both activity and the iron-sulfur center spectrum. In contrast, modification of the 2 histidines in putidaredoxin with 1 eq each resulted in nearly complete loss of reductase activity. There was no significant activity for adrenodoxin in the putidaredoxin reductase assay or for putidaredoxin in the adrenodoxin reductase assay, demonstrating that, in spite of the structural similarity between the two proteins, they are not interchangeable functionally.     

Modification of a lysine residue of adrenodoxin reductase, essential for complex formation with adrenodoxin

The NADPH-cytochrome c reductase activity of NADPH-adrenodoxin reductase from NADPH to cytochrome c via adrenodoxin was inhibited by pyridoxal 5'-phosphate and other reagents that modified the lysine residues. However, the NADPH-ferricyanide reductase activity was not affected. Loss of the cytochrome c reductase activity could be prevented by adrenodoxin, but not by NADP+. One lysine residue of the adrenodoxin reductase could be protected from the modification with pyridoxal 5'-phosphate by complex formation with adrenodoxin. Loss of the NADPH-cytochrome c reductase activity was not due to the conformational change of the modified adrenodoxin reductase, judging from circular dichroism spectrometric studies.     

Modification of histidine 56 in adrenodoxin with diethyl pyrocarbonate inhibited the interaction with cytochrome P-450scc and adrenodoxin reductase

Three histidine residues of bovine adrenodoxin, His-10, His-56, and His-62, were modified with diethyl pyrocarbonate. The order of the modification among the three histidines were monitored by measuring the proton NMR spectra. The modified adrenodoxin exhibited reduced affinity for adrenodoxin reductase as determined in cytochrome c reductase activity. In the presence of cholesterol, the modified adrenodoxin induced a high spin form of cytochrome P-450scc on complex formation in the same manner as native adrenodoxin. The spectral titration showed that adrenodoxin modified with diethyl pyrocarbonate exhibited a 5-fold higher Kd value than that of native adrenodoxin. These effects of the modification of adrenodoxin on the affinities for the redox partners were not proportional to the number of modified histidines determined by the optical absorbance change at 240 nm. Modification of adrenodoxin up to 2 histidine residues did not affect the affinity for the redox partners, but further modification on the third one resulted in an increase of apparent Km in cytochrome c reductase activity by 2-fold and of Kd for cytochrome P-450scc by 5-fold. The 1H NMR spectra of the modified adrenodoxin unequivocally demonstrated that histidine residues at His-10 and His-62 reacted more readily with diethyl pyrocarbonate than His-56 did, indicating that modification of His-56 was responsible for the reduction of binding affinities of adrenodoxin for redox partners. These results are consistent with the proposal that the residue of His-56 in adrenodoxin has an essential role in the electron transfer mechanism where adrenodoxin functions as a mobile shuttle.     

Covalently crosslinked complexes of bovine adrenodoxin with adrenodoxin reductase and cytochrome P450scc. Mass spectrometry and Edman degradation of complexes of the steroidogenic hydroxylase system.

NADPH-dependent adrenodoxin reductase, adrenodoxin and several diverse cytochromes P450 constitute the mitochondrial steroid hydroxylase system of vertebrates. During the reaction cycle, adrenodoxin transfers electrons from the FAD of adrenodoxin reductase to the heme iron of the catalytically active cytochrome P450 (P450scc). A shuttle model for adrenodoxin or an organized cluster model of all three components has been discussed to explain electron transfer from adrenodoxin reductase to P450. Here, we characterize new covalent, zero-length crosslinks mediated by 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide between bovine adrenodoxin and adrenodoxin reductase, and between adrenodoxin and P450scc, respectively, which allow to discriminate between the electron transfer models. Using Edman degradation, mass spectrometry and X-ray crystallography a crosslink between adrenodoxin reductase Lys27 and adrenodoxin Asp39 was detected, establishing a secondary polar interaction site between both molecules. No crosslink exists in the primary polar interaction site around the acidic residues Asp76 to Asp79 of adrenodoxin. However, in a covalent complex of adrenodoxin and P450scc, adrenodoxin Asp79 is involved in a crosslink to Lys403 of P450scc. No steroidogenic hydroxylase activity could be detected in an adrenodoxin -P450scc complex/adrenodoxin reductase test system. Because the acidic residues Asp76 and Asp79 belong to the binding site of adrenodoxin to adrenodoxin reductase, as well as to the P450scc, the covalent bond within the adrenodoxin-P450scc complex prevents electron transfer by a putative shuttle mechanism. Thus, chemical crosslinking provides evidence favoring the shuttle model over the cluster model for the steroid hydroxylase system.     

Inhibition of electron transfer from adrenodoxin to cytochrome P-450scc by chemical modification with pyridoxal 5'-phosphate: identification of adrenodoxin-binding site of cytochrome P-450scc

Covalent modification of cytochrome P-450scc (purified from bovine adrenocortical mitochondria) with pyridoxal 5'-phosphate (PLP) was found to cause inhibition of the electron-accepting ability of this enzyme from its physiological electron donor, adrenodoxin, without conversion to the "P-420" form. Reaction conditions leading to the modification level of 0.82 and 2.85 PLP-Lys residues per cytochrome P-450scc molecule resulted in 60% and 98% inhibition, respectively, of electron-transfer rate from adrenodoxin to cytochrome P-450scc (with beta-NADPH as an electron donor via NADPH-adrenodoxin reductase and with phenyl isocyanide as the exogenous heme ligand of the cytochrome). It was found that covalent PLP modification caused a drastic decrease of cholesterol side-chain cleavage activity when the cholesterol side-chain cleavage enzyme system was reconstituted with native (or PLP-modified) cytochrome P-450scc, adrenodoxin, and NADPH-adrenodoxin reductase. Approximately 60% of the original enzymatic activity of cytochrome P-450scc was protected against inactivation by covalent PLP modification when 20% mole excess adrenodoxin was included during incubation with PLP. Binding affinity of substrate (cholesterol) to cytochrome P-450scc was found to be increased slightly upon covalent modification with PLP by analyzing a substrate-induced spectral change. The interaction of adrenodoxin with cytochrome P-450scc in the absence of substrate (cholesterol) was analyzed by difference absorption spectroscopy with a four-cuvette assembly, and the apparent dissociation constant (Ks) for adrenodoxin binding was found to be increased from 0.38 microM (native) to 33 microM (covalently PLP modified).(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative study of the C27-steroid-hydroxylating system from bovine liver mitochondria

A method for purification of C27-steroid hydroxylating cytochrome P-450 (cytochrome P-450(27)) from bovine liver mitochondria was developed. The purification procedure included enzyme extraction from submitochondrial particles with sodium cholate, ammonium sulfate fractionation and biospecific chromatography on cholate-Sepharose and adrenodoxin-Sepharose. The resulting enzyme preparation (317-fold purification, 16% yield) was not electrophoretically homogeneous but did not contain hemoprotein admixtures. The kinetic parameters of 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol 27-hydroxylation in a reconstituted system containing hepatoredoxin reductase, hepatoredoxin and cytochrome P-450(27) (Km = 23 microM, kcat = 0.3 s-1 at 25 degrees C) were determined. A reciprocal functional equivalency of hepatoredoxin reductase and adrenodoxin reductase as well as of hepatoredoxin and adrenodoxin in reconstituted systems of steroid 27-hydroxylation (liver) and cholesterol side chain cleavage (adrenal cortex) was established. This equivalency was thought to be due to the similarity in essential physico-chemical properties of reductase components which was especially well-pronounced in the case of hepatoredoxin and adrenodoxin. Estimation of the functional role of lysine, dicarboxylic acid and histidine residues in ferredoxin molecules by the chemical modification method revealed the similarity of the structural organization of their protein globules: the polar residues were shown to be essential for the maintenance of native conformation; dicarboxylic acid residues formed a binding domain for the interaction with electron transport proteins, whereas histidine residues seem to participate in electron transport. At the same time, cytochrome P-450(27) and cytochrome P-450 which split the side chain of cholesterol differ in their substrate specificity, immunochemical and catalytic properties.     

Conformational change of adrenodoxin induced by reduction of iron-sulfur cluster. Proton nuclear magnetic resonance study.

Bovine adrenodoxin in the reduced form has been measured by one- and two-dimensional 1H NMR spectroscopy. By comparing the spectrum of reduced adrenodoxin with that of the oxidized protein, resonances have been assigned for the aromatic residues. The spin-lattice relaxation time for the resonances due to histidine residues was found to depend on the reduction state of adrenodoxin. The distance from the paramagnetic center is calculated by using the Solomone-Bloembergen equation. The resonances from Tyr-82 and Ala-81 show large chemical shift changes upon reduction of adrenodoxin. The conformational change of adrenodoxin manifested by chemical shift difference between reduced and oxidized forms is found in the sequence around Tyr-82 and Ala-81. Modification with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide at Glu-74, Asp-79, and Asp-86 inhibited the interaction with both adrenodoxin reductase and cytochrome P-450scc (Lambeth, D. J., Geren, L. M., and Millett, F. (1984) J. Biol. Chem. 259, 10025-10029; Geren, L. M., O'Brien, P., Stonehuerner, J., and Millett, F. (1984) J. Biol. Chem. 259, 2155-2160). Thus, the sequence of these amino acids was assigned to the interaction site with the redox partners. The present 1H NMR investigation of adrenodoxin demonstrates that a conformational change upon reduction of the iron-sulfur cluster occurs in the sequence of negatively charged amino acids that is a putative site for interaction with redox partners. This could offer the structural basis of the electron transfer mechanism in which adrenodoxin functions as a mobile electron carrier.     

Study of the role of lysine residues of the cholesterol hydroxylating cytochrome P-450 by a method of chemical modification

Chemical modification of cytochrome P-450scc by lysine-specific reagents has been performed. Modification of the hemoprotein was shown to result in the loss of its ability to interact with adrenodoxin. With a view of identifying lysine residues involved in the interaction with adrenodoxin, cytochrome P-450scc was modified by succinic anhydride in the presence of adrenodoxin. After the removal of ferredoxin, the modification was performed with the use of a radioactively labeled reagent. Subsequent hydrolysis of the succinic hemoprotein by chymotrypsin and separation of the peptides obtained by high pressure liquid chromatography resulted in the isolation of seven chymotryptic peptides containing labeled lysine residues. These amino acid sequences were identified. The role of lysine residues of cytochrome P-450scc in complex formation with adrenodoxin is discussed.     

Structural organization of adrenodoxin using limited proteolysis

The microheterogeneity of adrenodoxin preparation was established by endogenous proteolysis. The controlled limited trypsinolysis and endogenous proteolysis result in modification of the COOH-terminus of the polypeptide chain with a formation of a protein with Mr = 10 000. The interaction of this protein and of the native protein with cholesterol-specific cytochrome P-450 and adrenodoxin reductase occurs in a similar way.     

Site-Directed Mutagenesis of Cytochrome P450scc. II. Effect of Replacement of the Arg425 and Arg426 Residues on the Structural and Functional Properties of the Cytochrome P450scc

Cytochrome P450-dependent monooxygenases, in spite of their wide distribution, can be simply divided into a few groups differing in the location of the electron transfer chain and their composition. The two main groups of cytochrome P450-dependent monooxygenases are the mitochondrial and microsomal enzymes. While in two-component microsomal cytochrome P450-dependent monooxygenases electrons are supplied to cytochrome P450 by a flavoprotein (NADPH-cytochrome P450 reductase), in three-component mitochondrial monooxygenases the electrons are supplied to cytochrome P450 by a low molecular weight protein (ferredoxin). The interaction of cytochrome P450 with NADPH-cytochrome P450 reductase and ferredoxin is the subject of intensive studies. Using chemical modification, chemical cross-linking, and sitedirected mutagenesis, we identified surface exposed positively charged residues of cytochrome P450scc which might be important for interaction with adrenodoxin. Theoretical analysis of the distribution of surface electrostatic potential in cytochrome P450 indicates that in contrast to microsomal monooxygenases, cytochromes P450 of mitochondrial type, and cholesterol side-chain cleavage cytochrome P450 (P450scc) in part, carry on the proximal surface an evidently positively charged site that is formed by residues Arg425 and Arg426. In the present work, to estimate the functional role of Arg425 and Arg426 of cytochrome P450scc, we used site-directed mutagenesis to replace these residues with glutamine. The results indicate that residues Arg425 and Arg426 are involved in the formation of a heme-binding center and electrostatic interaction of cytochrome P450scc with its physiological electron-transfer partner, adrenodoxin.     

Crystalline reduced nicotinamide adenine dinucleotide phosphate-adrenodoxin reductase from pig adrenocortical mitochondria. Essential histidyl and cysteinyl residues of the NADPH-binding site and environment of the adrenodoxin-binding site.

Pig NADPH-adrenodoxin reductase was crystallized from pig adrenocortical mitochondria and its physicochemical properties were investigated. Pig NADPH-adrenodoxin reductase is a typical flavoprotein. Its optical absorption spectrum showed peaks at 272, 377, and 450 nm in the oxidized form. The adrenodoxin reductase contained one FAD per mol. The molecular weight was 49,000. The isoelectric points of the adrenodoxin reductase and its complex with adrenodoxin were 5.3 and 4.6, respectively. Pig NADPH-adrenodoxin reductase, unlike bovine NADPH-adrenodoxin reductase, was found to be free of carbohydrate. The fluorescences of tryptophanyl residues and FAD of the adrenodoxin reductase were quenched by holo- and apo-adrenodoxins. The NADPH-binding site of the adrenodoxin reductase was examined by photooxidation and selective chemical modifications with diethyl pyrocarbonate and sulfhydryl reagents. The results indicate that a histidyl and a cysteinyl residue of the adrenodoxin reductase are essential for the NADPH-binding site. The circular dichroism spectrum of the adrenodoxin reductase showed negative ellipticity in the visible region. Spur formation was observed between pig and bovine NADPH-adrenodoxin reductases against the antibody to bovine NADPH-adrenodoxin reductase in Ouchterlony double-diffusion agar plates. The antibody did not interact with spinach ferredoxin-NADP+ reductase.     

Adrenodoxin with a COOH-terminal deletion (des 116-128) exhibits enhanced activity

Adrenodoxin, purified from bovine adrenal cortex, was subjected to trypsin cleavage to yield a trypsin-resistant form, designated TT-adrenodoxin. Sequencing with carboxypeptidase Y identified the trypsin cleavage site as Arg-115, while Edman degradation indicated no NH2-terminal cleavage. Native adrenodoxin and TT-adrenodoxin exhibited similar affinity for adrenodoxin reductase as determined in cytochrome c reductase assays. In side chain cleavage assays using cytochrome P-450scc, however, TT-adrenodoxin demonstrated greater activity than adrenodoxin with cholesterol, (22R)-22-hydroxycholesterol, or (20R,22R)-20,22-dihydroxycholesterol as substrate. This enhanced activity is due to increased affinity of TT-adrenodoxin for cytochrome P-450scc; TT-adrenodoxin exhibits a 3.8-fold lower apparent Km for the conversion of cholesterol to pregnenolone. TT-Adrenodoxin was also more effective in coupling with cytochrome P-450(11) beta, exhibiting a 3.5-fold lower apparent Km for the 11 beta-hydroxylation of deoxycorticosterone. In the presence of partially saturating cholesterol, TT-adrenodoxin elicited a type I spectral shift with cytochrome P-450scc similar to that induced by adrenodoxin, and spectral titrations showed that oxidized TT-adrenodoxin exhibited a 1.5-fold higher affinity for cytochrome P-450scc. These results establish that COOH-terminal residues 116-128 are not essential for the electron transfer activity of bovine adrenodoxin, and the differential effects of truncation at Arg-115 on interactions with adrenodoxin reductase and cytochromes P-450 suggest that the residues involved in the interactions are not identical.     

Dual targeting property of the N-terminal signal sequence of P4501A1. Targeting of heterologous proteins to endoplasmic reticulum and mitochondria.

Recent studies from our laboratory showed that the beta-naphthoflavone-inducible cytochrome P4501A1 is targeted to both the endoplasmic reticulum (ER) and mitochondria. In the present study, we have further investigated the ability of the N-terminal signal sequence (residues 1-44) of P4501A1 to target heterologous proteins, dihydrofolate reductase, and the mature portion of the rat P450c27 to the two subcellular compartments. In vitro transport and in vivo expression experiments show that N-terminally fused 1-44 signal sequence of P4501A1 targets heterologous proteins to both the ER and mitochondria, whereas the 33-44 sequence strictly functions as a mitochondrial targeting signal. Site-specific mutations show that positively charged residues at the 34th and 39th positions are critical for mitochondrial targeting. Cholesterol 27-hydroxylase activity of the ER-associated 1-44/1A1-CYP27 fusion protein can be reconstituted with cytochrome P450 reductase, but the mitochondrial associated fusion protein is functional with adrenodoxin + adrenodoxin reductase. Consistent with these differences, the fusion protein in the two organelle compartments exhibited distinctly different membrane topology. The results on the chimeric nature of the N-terminal signal of P4501A1 coupled with interaction with different electron transport proteins suggest a co-evolutionary nature of some of the xenobiotic inducible microsomal and mitochondrial P450s.     

The effect of pH on the formal reduction potential of adrenodoxin in the presence and absence of adrenodoxin reductase: the implication in the electron transfer mechanism

We have investigated the formal reduction potentials (E degrees') of adrenodoxin with and without adrenodoxin reductase in order to elucidate the mechanism of electron transfer from adrenodoxin reductase (a flavoprotein) to adrenodoxin (an iron-sulfur protein). It was found by our spectropotentiostatic method that adrenodoxin showed no variation of E degrees' at different pH's in the absence of adrenodoxin reductase. The average E degrees' was -252 +/- 2 mV in the pH range between 6.0 and 8.3. In the presence of adrenodoxin reductase, adrenodoxin exhibited, on the other hand, a pH dependence of E degrees' at pH higher than 7.2 with a slope of -59 mV per pH unit: Adrenodoxin molecule possesses one protonation site with a pKa of 7.2. Cyclic voltammograms of adrenodoxin additionally revealed that the reoxidation reaction of reduced adrenodoxin is very slow in the absence of adrenodoxin reductase, but that it is readily reoxidized in the presence of adrenodoxin reductase.     

Adrenodoxin reductase-adrenodexin complex.

Adrenodoxin reductase and adrenodoxin have been shown (Chu, J.-W., and Kimura, T. (1973) J. Biol. Chem. 248, 5183-5187) to form a low dissociation constant, 1:1 complex when both proteins are in the oxidized form. We have found that when adrenodoxin: adrenodoxin reductase ratios are varied by increasing the adrenodoxin concentration, with adrenodoxin reductase held constant, an increasing rate of cytochrome c reduction, with NADPH as reductant, is seen up to a ratio of 1:1, indicating that cytochrome c reduction occurs via the protein-protein complex. Spectra observed during titration of this protein-protein complex with NADH were resolved into components by the linear programming method, using a computer program written in Fortran IV. Analysis of the data has shown that the flavoprotein is reduced prior to the iron sulfur protein, and that the midpoint oxidation-reduction potentials (pH 7.5) of the two proteins are -295 and -331 mV, respectively, when both are present in the complex. Complex formation does not alter the potential of adrenodoxin reductase, but changes that of adrenodoxin by -40 mV. Equilibrium constants derived from potential measurements show that the strength of the protein-protein interaction in the complex is unaltered by reduction of adrenodoxin reductase, but is decreased by about 1 kcal due to reduction of adrenodoxin. The low dissociation constants for both oxidized reduced forms of the adrenodoxin reductase-adrenodoxin complex indicate that the complex must remain associated throughout its catalytic cycle. Titration of the adrenodoxin reductase-adrenodoxin complex with the physiologic reductant, NADPH, was followed by EPR and visible spectra, and yielded an order of reduction of the components identical with that seen when NADH was used as reductant. Reduction of the protein-protein complex with NADPH yielded a ternary complex between NADP+, flavoprotein, and iron sulfur protein, with the two electrons located in a "charge transfer" complex between flavoprotein and pyridine nucleotide.     

Effect of modification on physico-chemical and biological properties of haptoglobin. Reaction with N-bromusuccinimide and 2-hydroxy-5-nitrobenzyl bromide.

N-Bromosuccinimide and 2-hydroxy-5-nitrobenzyl bromide have been used for modification of tryptophan residues in human haptoglobin (Hp) type 2-1. Modification of three exposed tryptophan residues reduced considerably both the Hp-haemoglobin interaction and binding of the antibody against the native protein. Modification of the remaining 7-8 tryptophan residues resulted in a complete loss of those properties. Antisera directed against Hp with the modified tryptophan residues appeared to be highly specific in immunological reactions.     

Localization of tryptophan residues in NADPH-adrenodoxin reductase with respect to the NADPH-binding center

It was demonstrated that the NADPH-adrenodoxin reductase molecule contains ten tryptophan residues titrated by N-bromosuccinimide. The effectiveness of the non-radiant energy transfer was used to calculate the average distance between the NADPH-binding site of the enzyme and tryptophan residues at different steps of N-bromosuccinimide-induced modification.     

Identification and characterization of an NADPH-cytochrome P450 reductase derived peptide involved in binding to cytochrome P450

The amino acids of cytochrome P450 reductase involved in the interaction with cytochrome P450 were identified with a differential labeling technique. The water-soluble carbodiimide EDC (1-ethyl-3-[3- (dimethylamino)propyl]-carbodiimide) was used with the nucleophile methylamine to modify carboxyl residues. When the modification was performed in the presence of cytochrome P450, there was no inhibition in the ability of the modified reductase to bind to cytochrome P450. However, subsequent modification of the reductase in the absence of cytochrome P450 caused a fourfold increase in the Km and an 80% decrease in kcat/Km (relative to the reductase modified in the first step), for the interaction with cytochrome P450. These effects are attributed to the modification of approximately 3.2 mol of carboxyl residues per mole of reductase. Tryptic peptides generated from the modified reductase were purified by reverse phase high-performance liquid chromatography and characterized. Amino acid sequencing and analysis suggest that the peptide which contains approximately 40% of the labeled carboxyl residues corresponds to amino acid residues 109-130 of rat liver NADPH-cytochrome P450 reductase. One or more of the seven carboxyl containing amino acids within this peptide is presumably involved in the interaction with cytochrome P450.