Involvement of the flavin si-face tyrosine on the structure and function of ferredoxin-NADP+ reductases.

In ferredoxin-NADP(+) reductase (FNR), FAD is bound outside of an anti-parallel beta-barrel with the isoalloxazine lying in a two-tyrosine pocket. To elucidate the function of the flavin si-face tyrosine (Tyr-89 in pea FNR) on the enzyme structure and catalysis, we performed ab initio molecular orbital calculations and site-directed mutagenesis. Our results indicate that the position of Tyr-89 in pea FNR is mainly governed by the energetic minimum of the pairwise interaction between the phenol ring and the flavin. Moreover, most of FNR-like proteins displayed geometries for the si-face tyrosine phenol and the flavin, which correspond to the more negative free energy theoretical value. FNR mutants were obtained replacing Tyr-89 by Phe, Trp, Ser, or Gly. Structural and functional features of purified FNR mutants indicate that aromaticity on residue 89 is essential for FAD binding and proper folding of the protein. Moreover, hydrogen bonding through the Tyr-89 hydroxyl group may be responsible of the correct positioning of FAD and the substrate NADP(+)

Interaction of the targeting sequence of chloroplast precursors with Hsp70 molecular chaperones.

We have analyzed the interaction of DnaK and plant Hsp70 proteins with the wild-type ferredoxin-NADP+ reductase precursor (preFNR) and mutants containing amino-acid replacements in the targeting sequence. Using an algorithm already developed [Rüdiger, S., Germeroth, L., Schneider-Mergener, J. & Bukau, B. (1997) EMBO J. 16, 1501-1507] we observed that 75% of the 727 plastid precursor proteins analyzed contained at least one site with high likelihood of DnaK binding in their transit peptides. Statistical analysis showed a decrease of DnaK binding site frequency within the first 15 amino-acid residues of the transit peptides. Using fusion proteins we detected the interaction of DnaK with the transit peptide of the folded preFNR but not with the mature region of the protein. Discharge of DnaK from the presequence was favored by addition of MgATP. When a putative DnaK binding site was artificially added at the N-terminus of the mature protein, we observed formation of complexes with bacterial and plant Hsp70 molecular chaperones. Reducing the likelihood of DnaK binding by directed mutagenesis of the presequence increased the release of bound DnaK. The Hsp70 proteins from plastids and plant cell cytosol also interacted with the preFNR transit peptide. Overall results are discussed in the context of the proposed models to explain the organelle protein import.

Competition between C-terminal tyrosine and nicotinamide modulates pyridine nucleotide affinity and specificity in plant ferredoxin-NADP(+) reductase.

Chloroplast ferredoxin-NADP(+) reductase has a 32,000-fold preference for NADPH over NADH, consistent with its main physiological role of NADP(+) photoreduction for de novo carbohydrate biosynthesis. Although it is distant from the 2'-phosphoryl group of NADP(+), replacement of the C-terminal tyrosine (Tyr(308) in the pea enzyme) by Trp, Phe, Gly, and Ser produced enzyme forms in which the preference for NADPH over NADH was decreased about 2-, 10-, 300-, and 400-fold, respectively. Remarkably, in the case of the Y308S mutant, the k(cat) value for the NADH-dependent activity approached that of the NADPH-dependent activity of the wild-type enzyme. Furthermore, difference spectra of the NAD(+) complexes revealed that the nicotinamide ring of NAD(+) binds at nearly full occupancy in the active site of both the Y308G and Y308S mutants. These results correlate well with the k(cat) values obtained with these mutants in the NADH-ferricyanide reaction. The data presented support the hypothesis that specific recognition of the 2'-phosphate group of NADP(H) is required but not sufficient to ensure a high degree of discrimination against NAD(H) in ferredoxin-NADP(+) reductase. Thus, the C-terminal tyrosine enhances the specificity of the reductase for NADP(H) by destabilizing the interaction of a moiety common to both coenzymes, i.e. the nicotinamide.

A productive NADP+ binding mode of ferredoxin-NADP + reductase revealed by protein engineering and crystallographic studies.

The flavoenzyme ferredoxin-NADP+ reductase (FNR) catalyzes the production of NADPH during photosynthesis. Whereas the structures of FNRs from spinach leaf and a cyanobacterium as well as many of their homologs have been solved, none of these studies has yielded a productive geometry of the flavin-nicotinamide interaction. Here, we show that this failure occurs because nicotinamide binding to wild type FNR involves the energetically unfavorable displacement of the C-terminal Tyr side chain. We used mutants of this residue (Tyr 308) of pea FNR to obtain the structures of productive NADP+ and NADPH complexes. These structures reveal a unique NADP+ binding mode in which the nicotinamide ring is not parallel to the flavin isoalloxazine ring, but lies against it at an angle of approximately 30 degrees, with the C4 atom 3 A from the flavin N5 atom.

Spectroscopic characterization of a binuclear metal site in Bacillus cereus beta-lactamase II.

The zinc metalloenzyme beta-lactamase II (betaLII) from Bacillus cereus has been overexpressed in Escherichia coli as a fusion protein with glutathione-S-transferase, and the metal binding properties of recombinant betaLII toward Zn(II) and Co(II) have been studied by fluorescence and activity measurements. The apoenzyme is able to bind two metal ion equivalents, which confer on betaLII its maximum enzymatic efficiency. The enzyme is partially active with one metal ion equivalent. The diCo(II) and a mixed Zn(II)Co(II) derivative of betaLII were obtained and probed by electronic and paramagnetic NMR spectroscopy. In the high-affinity site, the metal is bound to three His residues and a solvent molecule, adopting a tetrahedral geometry. A Cys, a His, and an Asp residue are coordinated to the low-affinity metal site, together with two or three solvent molecules. This coordination polyhedron resembles the binuclear metal site of the Bacteroides fragilis beta-lactamase [Concha, N., Rasmussen, B. A., Bush, K., and Herzberg, O. (1996) Structure 4, 823-836; Carfi, A., Duée, E., Paul-Soto, R., Galleni, M., Frère, J. M., and Dideberg, O. (1998) Acta Crystallogr. D54, 47-57] but differs from that resulting from the X-ray study of betaLII [Carfi, A., Pares, S., Duée, E., Galleni, M., Duez, C., Frère, J. M., and Dideberg, O. (1995) EMBO J. 14, 4914-4921]. These results suggest that this binuclear metal site may be a general feature of metallo-beta-lactamases.

A fully active FAD-containing precursor remains folded up to its translocation across the chloroplast membranes.

The cytosolic and two recombinant precursors, containing 10 and 30 amino acid spacers between the transit peptide and the mature region of the chloroplast flavoprotein ferredoxin-NADP+ reductase (FNR), were expressed in Escherichia coli cells. These proteins were purified rendering fully active precursors that contained bound FAD. Neither the transit peptide nor the spacers affected the formation of the tightly folded enzyme structure. Protease treatment of the folded precursors resulted in a rapid removal of the transit sequence, rendering an enzymatically active resistant core, even at high protease concentration. All three preproteins could be efficiently imported by isolated pea chloroplasts. Addition of the enzyme substrate NADP+ to the import medium slightly decreased the polypeptide translocation. The precursor bound to isolated chloroplasts in the presence or absence of leaf extracts was as resistant to proteolysis as the folded precursor in solution. In contrast, the FNR precursor unfolded by urea was rapidly digested even at the lowest protease concentration. Together, our results indicate that precursor unfolding may take place during translocation but not during binding to chloroplast envelopes or by interaction with leaf extract soluble factors, and that this process is independent of the distance between the transit peptide and the folded mature region of the protein.

Cooperation of the DnaK and GroE chaperone systems in the folding pathway of plant ferredoxin-NADP+ reductase expressed in Escherichia coli.

The DnaK system is required for the productive folding of pea chloroplast ferredoxin-NADP+ reductase (FNR) expressed in Escherichia coli. The formation of a mature active enzyme was severely impaired in E. coli dnaK, dnaJ or grpE mutants expressing either the cytosolic precursor of the reductase (preFNR) or the mature apoenzyme, and these forms aggregated extensively in these cells. Coexpression of dnaK from a multicopy plasmid in the dnaK-null mutants restored preFNR processing and folding of FNR, rendering a mature-sized active enzyme. Overexpression of GroESL chaperonins failed to prevent preFNR aggregation, but it restored productive folding of FNR in dnaK-null mutants expressing the mature enzyme. Expression of preFNR in OmpT-protease-deficient E. coli cells resulted in the accumulation of the unprocessed precursor in the soluble fraction of the cells. The interaction of this soluble preFNR, but not the mature reductase, with DnaK and GroEL was evidenced by immunoprecipitation studies. We conclude that, in addition to the GroE chaperonins [Carrillo, N., Ceccarelli, E. A., Krapp, A. R., Boggio, S., Ferreyra, R. G. & Viale, A. M. (1992) J. Biol. Chem. 267, 15537-15541], the DnaK chaperone system plays a crucial role in the folding pathway of FNR.

Plant-type ferredoxin-NADP+ reductases: a basal structural framework and a multiplicity of functions.

Ferredoxin-NADP+ (oxido)reductase (EC 1.18.1.2, FNR) is an FAD-containing enzyme that catalyzes the reversible electron transfer between NADP(H) and electron carrier proteins such as ferredoxin and flavodoxin. Isoforms of this flavoprotein are present in chloroplasts, mitochondria, and bacteria in which they participate in a wide variety of redox metabolic pathways. Although ferredoxin-NADP+ reductases have been thoroughly investigated and their properties reviewed on several occasions, considerable advances in the understanding of these flavoenzymes have occurred in the last few years, including the characterization of cDNA and genomic clones encoding FNR proteins from plants, algae, vertebrates, and bacteria, determination of the atomic structure of a plant FNR at high resolution, and the expression of functional reductases in microorganisms like Escherichia coli and Saccharomyces cerevisiae. The aim of this article is to summarize information gained through these recent developments, including the phylogenetic relationships among ferredoxin reductases and the key structural features of the plant FNR family. Other aspects such as the catalytic mechanism of FNR and the molecular events underlying biogenesis, intracellular sorting, folding, and holoenzyme assembly of this important flavoenzyme are also discussed in some detail. Ferredoxin-NADP+ reductases display several outstanding properties that make them excellent model proteins to address broad biological questions.

Conformational requirements of a recombinant ferredoxin-NADP+ reductase precursor for efficient binding to and import into isolated chloroplasts.

The cytosolic precursor of the chloroplast flavoprotein ferredoxin-NADP+ reductase was expressed in Escherichia coli rendering a soluble protein that contained bound FAD and could be imported by isolated chloroplasts. The mechanism of plastid translocation was studied under defined conditions using this recombinant precursor holoprotein and intact pea chloroplasts. The first step in the import pathway, namely, binding of the reductase precursor to isolated chloroplasts, was saturable at about 2000 molecules/plastid, and showed a high-affinity interaction with a dissociation constant Kd of approximately 5 nM. Binding was not affected by the addition of soluble leaf extracts or by prior denaturation of the precursor with urea. Analysis of the initial import rates at different precursor concentrations indicated the existence of a single translocation system for this protein. Inclusion of leaf extracts in the assay resulted in a three-fold increase of the maximal import rates to 14,000 molecules . min-(1).chloroplast-(1), with a concomitant decrease in the apparent Km for the recombinant precursor, from 1 microM to 100-150 nM. Comparison of Km and Kd values under various conditions indicated that the binding step of the translocation process is largely irreversible, favouring import and processing. In the absence of extract, a denatured precursor obtained by incubation with urea was a better substrate for plastid import than the holoprotein. Treatment of the precursor with either extract or urea resulted in similar increases in import efficiency (V/Km), suggesting that stimulation by leaf extracts is probably related to unfolding of the precursor prior to translocation.

Contribution of the FAD binding site residue tyrosine 308 to the stability of pea ferredoxin-NADP+ oxidoreductase.

The contribution made by tyrosine 308 to the stability of pea ferredoxin-NADP+ reductase was investigated using site-directed mutagenesis. The phenol side chain of the invariant carboxyl terminal tyrosine is stacked coplanar to the isoalloxazine moiety of the FAD cofactor. Fluorescence measurements indicate that this interaction plays a significant role in FAD fluorescent quenching by the reductase apoprotein. Replacement of the tyrosine by tryptophan or phenylalanine caused only a minor increase in the quantum yields of bound FAD, whereas nonaromatic substitutions to serine and glycine resulted in a large fluorescent rise. Results from NADP+ titration experiments support a recent hypothesis [Karplus et al. (1991) Science 251, 60-66], suggesting that the phenol ring of Tyr 308 may fill the nicotinamide binding pocket in the absence of the nucleotide. The stability of the site-directed mutants, judged by thermal- and urea-induced denaturation studies, was lowered with respect to the wild-type enzyme. FNR variants harboring nonaromatic substitutions displayed more extensive destabilization. The decrease in thermodynamic stability correlated with the impairment of catalytic activities [Orellano et al. (1993) J. Biol. Chem 268, 19267-19273]. The results indicate that the presence of the electron-rich aromatic side chain adjacent to the isoalloxazine ring is essential for maximum stabilization of the FNR holoenzyme, resulting in a flavin conformation which optimizes electron flow between the prosthetic group and its redox partners.

The precursor of pea ferredoxin-NADP+ reductase synthesized in Escherichia coli contains bound FAD and is transported into chloroplasts.

The precursor of the chloroplast flavoprotein ferredoxin-NADP+ reductase from pea was expressed in Escherichia coli as a carboxyl-terminal fusion to glutathione S-transferase. The fused protein was soluble, and the precursor could be purified in a few steps involving affinity chromatography on glutathione-agarose, cleavage of the transferase portion by protease Xa, and ion exchange chromatography on DEAE-cellulose. The purified prereductase contained bound FAD but displayed marginally low levels of activity. Removal of the transit peptide by limited proteolysis rendered a functional protease-resistant core exhibiting enzymatic activity. The FAD-containing precursor expressed in E. coli was readily transported into isolated pea chloroplasts and was processed to the mature size, both inside the plastid and by incubation with stromal extracts in a plastid-free reaction. Import was dependent on the presence of ATP and was stimulated severalfold by the addition of plant leaf extracts.

Expression, assembly and secretion of a fully active plant ferredoxin-NADP+ reductase by Saccharomyces cerevisiae.

The flavoprotein ferredoxin-NADP+ reductase catalyzes the final step of the photosynthetic electron transport i.e., the reduction of NADP+ by ferredoxin. Expression and secretion of this enzyme was examined in Saccharomyces cerevisiae using a cDNA cloned from a pea library [Newman, B. J. & Gray, J. C. (1988) Plant Mol. Biol. 10, 511-520]. Two pea library cDNA sequences were employed, one corresponding to the mature enzyme and the other containing, in addition, the sequence of the transit peptide that directs ferredoxin-NADP+ reductase to the chloroplast. These sequences were introduced into a yeast shuttle vector in frame with the mating factor alpha 1 secretion-signal coding region under the control of its natural mating factor alpha 1 promoter. Saccharomyces cerevisiae cells transformed with the recombinant plasmids were able to synthesize and secrete fully active pea ferredoxin-NADP+ reductase. In both cases, a 35-kDa polypeptide was the major product. N-terminal sequencing of the secreted proteins indicates processing at position -1 with respect to the N-terminus of the pea mature enzyme. Yeast cells transformed with plasmid encoding the ferredoxin-NADP+ reductase precursor secrete four-times more ferredoxin-NADP+ reductase to the medium than cells transformed with the plasmid encoding the mature form of the enzyme. Ferredoxin-NADP+ reductases purified from culture medium showed structural and enzymatic properties that were identical, within the experimental error, to those of native plant ferredoxin-NADP+ reductase. The overall results indicate that pea ferredoxin-NADP+ reductase can be properly folded and its prosthetic group assembled in the yeast endoplasmic reticulum, and that its natural transit peptide favors its secretion.

One-step purification of plant ferredoxin-NADP+ oxidoreductase expressed in Escherichia coli as fusion with glutathione S-transferase.

Complementary DNA sequences encoding the mature form of pea ferredoxin-NADP+ reductase were cloned in-frame at the 3' end of the Schistosoma japonicum glutathione S-transferase gene in the expression vector pGEX-3X (Smith and Johnson, Gene 67, 31-40, 1988). A spacer sequence linking the two genes was modified to provide a proteolytic site just before the first amino acid residue of mature pea reductase. When introduced into competent Escherichia coli cells and induced, the resulting plasmid (pGF205) directed the expression of a 60-kDa immunoreactive peptide that results from the fusion between glutathione S-transferase and ferredoxin-NADP+ reductase sequences. The fused protein could be purified in a single step by selective absorption onto glutathione-agarose beads, followed by elution with free glutathione. It showed both transferase and reductase activities. Removal of the transferase portion by cleavage with the restriction protease Xa rendered ferredoxin-NADP+ reductase electrophoretically homogeneous. The purified transgenic enzyme showed kinetic and spectroscopic properties that were similar to those reported for the plant flavoprotein, indicating that, even when fused to the 27-kDa transferase portion, the reductase was still able to assemble FAD and to acquire an active conformation in the bacterial host. The expression-purification protocol employed here allows the isolation of up to 1 mg of active ferredoxin-NADP+ reductase/g of transformed cells. The system is potentially useful for the purification of activity-impaired forms of the flavoprotein.

Probing the role of the carboxyl-terminal region of ferredoxin-NADP+ reductase by site-directed mutagenesis and deletion analysis.

The carboxyl-terminal region of plant ferredoxin-NADP+ reductases is formed by an invariant alpha-helix/loop/beta-strand, culminating in a conserved tyrosine that displays extensive interaction with the prosthetic group FAD. We have investigated the potential role of the terminal region in reductase function, by introducing mutations and deletions on pea ferredoxin-NADP+ reductase overexpressed in Escherichia coli. Replacement of the terminal tyrosine by tryptophan, phenylalanine, serine, and glycine resulted in a 2.2-, 2.0-, 22-, and 302-fold reduction, respectively, in kcat for the diaphorase reaction, whereas elimination of the tyrosine caused a 846-fold decrease in kcat. Km values were largely unaffected by the substitutions. Similar results were obtained when the mutants were assayed for cytochrome c reduction, indicating that aromaticity is the most important factor to the function of the tyrosine in catalysis. The presence of the phenol ring at the carboxyl-terminal position of wild-type reductase is important, but not an absolute requirement for enzyme function or FAD assembly. Deletion of the alpha-helix/beta-strand region prevented reductase proper folding in the bacterial host, while shortening of the terminal region by splicing 3 amino acids at the beginning of the alpha-helix produced a moderately soluble reductase, devoid of FAD and enzymatic activity.

Assembly of plant ferredoxin-NADP+ oxidoreductase in Escherichia coli requires GroE molecular chaperones.

We have recently reported the expression in Escherichia coli of an enzymatically competent ferredoxin-NADP+ oxidoreductase from cloned pea genes encoding either the mature enzyme or its precursor protein (Ceccarelli, E. A., Viale, A. M., Krapp, A. R., and Carrillo, N. (1991) J. Biol. Chem. 266, 14283-14287). Processing to the mature form by bacterial protease(s) and FAD assembly occurred in the bacterial cytosol. Expression of ferredoxin-NADP+ reductase in chaperonin-deficient (groE-) mutants of E. coli resulted in partial reductase assembly at permissive growth temperatures (i.e. 30 degrees C), and in total breakdown of holoenzyme assembly, and accumulation as aggregated inclusion bodies at non-permissive temperatures (i.e. 42 degrees C). Coexpression in these mutants of a cloned groESL operon from the phototrophic bacterium Chromatium vinosum resulted in partial or total recoveries of ferredoxin-NADP+ reductase assembly. The overall results indicate that bacterial chaperonins are required for the productive folding/assembly of eucaryotic ferredoxin-NADP+ reductase expressed in E. coli.

Expression, assembly, and processing of an active plant ferredoxin-NADP+ oxidoreductase and its precursor protein in Escherichia coli.

The flavoprotein ferredoxin-NADP+ reductase (FNR) catalyzes the final step of the photosynthetic electron transport chain, i.e. the reduction of NADP+ by ferredoxin. A cloned FNR cDNA from a pea library (Newman, B., and Gray, J. (1988) Plant Mol. Biol. 10, 511-520) was used to construct plasmids which express the apoenzyme in Escherichia coli. Two recombinant vectors were prepared, one containing the sequence corresponding to the mature enzyme and another including, in addition, the sequence of the transit peptide that directs FNR to the chloroplast. These proteins were expressed as fusion products to the NH2-terminal portion of beta-galactosidase. In both cases, a 35-kDa immunoreactive polypeptide was the major product, suggesting that the proteins were processed in vivo. NH2-terminal sequence determination of the purified recombinant proteins indicate cleavage at positions -1/-2 with respect to the normal processing site in chloroplasts. The processed enzymes showed enzymatic activities and spectral properties that were similar or identical to those of native plant FNR. When a La protease-deficient E. coli strain was used as a host, the expressed FNR precursor was found to be poorly processed, associated to bacterial pellets, and showed no detectable FNR activity. The overall results indicate that acquisition of the native enzyme conformation and assembly of the prosthetic group takes place in the bacterial host, generating an enzyme that is, as far as studied, indistinguishable from plant FNR.

Inhibition of the bovine-heart mitochondrial F1-ATPase by cationic dyes and amphipathic peptides.

The bovine heart mitochondrial F1-ATPase is inhibited by a number of amphiphilic cations. The order of effectiveness of non-peptidyl inhibitors examined as assessed by the concentration estimated to produce 50% inhibition (I0.5) of the enzyme at pH 8.0 is: dequalinium (8 microM), rhodamine 6G (10 microM), malachite green (14 microM), rosaniline (15 microM) greater than acridine orange (180 microM) greater than rhodamine 123 (270 microM) greater than rhodamine B (475 microM), coriphosphine (480 microM) greater than safranin O (1140 microM) greater than pyronin Y (1650 microM) greater than Nile blue A (greater than 2000 microM). The ATPase activity was also inhibited by the following cationic, amphiphilic peptides: the bee venom peptide, melittin; a synthetic peptide corresponding to the presence of yeast cytochrome oxidase subunit IV (WT), and amphiphilic, synthetic peptides which have been shown (Roise, D., Franziska, T., Horvath, S.J., Tomich, J.M., Richards, J.H., Allison, D.S. and Schatz, G. (1988) EMBO J. 7, 649-653) to function in mitochondrial import when attached to dihydrofolate reductase (delta 11.12, Syn-A2, and Syn-C). The order of effectiveness of the peptide inhibitors as assessed by I0.5 values is: Syn-A2 (40 nM), Syn-C (54 nM) greater than melittin (5 microM) greater than WT (16 microM) greater than delta 11,12 (29 microM). Rhodamines B and 123, dequalinium, melittin, and Syn-A2 showed noncompetitive inhibition, whereas each of the other inhibitors examined (rhodamine 6G, rosaniline, malachite green, coriphosphine, acridine orange, and-Syn-C) showed mixed inhibition. Replots of slopes and intercepts from Lineweaver-Burk plots obtained for dequalinium were hyperbolic indicating partial inhibition. With the exception of Syn-C, for which the slope replot was hyperbolic and the intercept replot was parabolic, steady-state kinetic analyses indicated that inhibition by the other inhibitors was complete. The inhibition constants obtained by steady-state kinetic analyses were in agreement with the I0.5 values estimated for each inhibitor examined. Rhodamine 6G, rosaniline, dequalinium, melittin, Syn-A2, and Syn-C were observed to protect F1 against inactivation by the aziridinium of quinacrine mustard in accord with their experimentally determined I0.5 values.(ABSTRACT TRUNCATED AT 400 WORDS)

Selectivity of modification when latent and activated forms of the chloroplast F1-ATPase are inactivated by 7-chloro-4-nitrobenzofurazan.

The characteristics and specificity of inactivation of the chloroplast F1-ATPase (CF1) with 7-chloro-4-nitrobenzofurazan (Nbf-Cl) have been investigated. Inactivation of the octylglucoside-dependent Mg2+-ATPase activity of latent CF1 by Nbf-Cl can be correlated with the formation of about 1.2 mol of Nbf-O-Tyr per mole of enzyme. Following inactivation of CF1 with [14C]Nbf-Cl, polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate revealed that the majority of the radioactive reagent incorporated is present in the beta subunit. Treatment of the enzyme with [14C]Nbf-Cl following dithiothreitol heat activation, led to similar labeling of the beta subunit and substantial incorporation of 14C into the gamma subunit. On complete inactivation, about 4 mol of Nbf-S-Cys is formed per mole of dithiothreitol-heat-activated CF1. Incorporation of 14C into the gamma subunit is prevented by prior treatment of the latent CF1 or of the dithiothreitol-heat-activated CF1 with iodoacetamide. Following incubation of the dithiothreitol-heat-activated CF1 with iodoacetamide, complete inactivation of the octylglucoside-dependent Mg2+-ATPase activity by Nbf-Cl can be correlated with the formation of about 1.2 mol of Nbf-O-Tyr per mole of enzyme. After stabilization of the [14C]Nbf-O-Tyr derivative by treatment with sodium dithionite, a labeled peptide was purified. Automatic Edman degradation of this peptide revealed the sequence V-X-V-P-A-D-(D). The majority of the radioactivity was cleaved in the second cycle, the position occupied in CF1 by Tyr-beta-328, which is homologous to Tyr-beta-311, the residue reactive with Nbf-Cl in the beef heart mitochondrial F1-ATPase. When CF1, modified at Tyr-beta-328 with Nbf-Cl, is incubated at pH 9.0, the Nbf-O-Tyr adduct is hydrolyzed, leading to concomitant recovery of the ATPase activity. In double labeling experiments, two-dimensional isoelectric focusing in the presence of urea followed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicates that 2-azido-ADP, covalently bound at the tight ADP binding site, and the tyrosine modified by [14C]Nbf-Cl are located in different beta subunits.

Localization of sites modified during inactivation of the bovine heart mitochondrial F1-ATPase by quinacrine mustard using [3H]aniline as a probe.

The aziridinium of purified quinacrine mustard at 50 microM inactivates the bovine heart mitochondrial F1-ATPase with a pseudo-first order rate constant of 0.07 min-1 at pH 7.0 and 23 degrees C. An apparent Kd of 27 microM for the enzyme-reagent complex was estimated from the dependence of the rate of inactivation on the concentration of quinacrine mustard. The pH inactivation profile revealed that deprotonation of a group with a pKa of about 6.7 is necessary for inactivation. The amount of reagent incorporated into the protein increased linearly with the extent of inactivation. Complete inactivation was estimated to occur when 3 mol of reagent were incorporated/mol of F1. Enzyme, in which steady state ATPase was inactivated by 98% by quinacrine mustard, hydrolyzed substoichiometric ATP with zero order kinetics suggesting that residual activity is catalyzed by F1 in which at least one beta subunit is modified. By exploiting the reactivity of the aziridinium of covalently attached reagent with [3H] aniline, sites modified by quinacrine mustard were labeled with 3H. Isolation of radioactive cyanogen bromide peptides derived from F1 inactivated with the reagent in the presence of [3H]aniline which were identified by sequence analysis and sequence analyses of radioactive tryptic fragments arising from them have revealed the following. About two thirds of the radioactivity incorporated into the enzyme during inactivation is apparently esterified to one or more of the carboxylic acid side chains in a CNBr-tryptic fragment of the beta subunit with the sequence: 394DELSEEDK401. The remainder of the radioactivity is associated with at least two sites within the cyanogen bromide peptide containing residues 293-358 of the beta subunit. From these results it is concluded that inactivation of F1 by the aziridinium of quinacrine mustard is due, at least in part, to modification of one or more of the carboxylic acid side chains in the DELSEED segment of the beta subunit and possibly also to modification of unspecified amino acid side chains between residues 302-356 of the beta subunit.