Inhibitor Binding within the NarI Subunit (Cytochrome bnr) of Escherichia coli Nitrate Reductase A*

Axel MagalonDagger §, Richard A. Rotheryparallel , Danielle Lemesle-Meunier**, Chantal FrixonDagger , Joel H. Weiner, and Francis BlascoDagger Dagger Dagger

From the Dagger  Laboratoire de Chimie Bactérienne, IBSM, CNRS, 31 chemin Joseph Aiguier, 13402 Marseille cedex 20, France, the ** Laboratoire de Bioénergétique et Ingénierie des Protéines, IBSM, CNRS, 31 chemin Joseph Aiguier, 13402 Marseille, France, and the  Medical Research Council Group in the Molecular Biology of Membranes, Department of Biochemistry, University of Alberta, Edmonton, Alberta T6G 2H7 Canada.

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

We have used inhibitors and site-directed mutants to investigate quinol binding to the cytochrome bnr (NarI) of Escherichia coli nitrate reductase (NarGHI). Both stigmatellin and 2-n-heptyl-4-hydroxyquinoline-N-oxide (HOQNO) inhibit menadiol:nitrate oxidoreductase activity with I50 values of 0.25 and 6 µM, respectively, and prevent the generation of a NarGHI-dependent proton electrochemical potential across the cytoplasmic membrane. These inhibitors have little effect on the rate of reduction of the two hemes of NarI (bL and bH), but have an inhibitory effect on the extent of nitrate-dependent heme reoxidation. No quinol-dependent heme bH reduction is detected in a mutant lacking heme bL (NarI-H66Y), whereas a slow but complete heme bL reduction is detected in a mutant lacking heme bH (NarI-H56R). This is consistent with physiological quinol binding and oxidation occurring at a site (QP) associated with heme bL which is located toward the periplasmic side of NarI. Optical and EPR spectroscopies performed in the presence of stigmatellin or HOQNO provide further evidence that these inhibitors bind at a heme bL-associated QP site. These results suggest a model for electron transfer through NarGHI that involves quinol binding and oxidation in the vicinity of heme bL and electron transfer through heme bH to the cytoplasmically localized membrane-extrinsic catalytic NarGH dimer.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

Nitrate reductase A (NarGHI)1 allows Escherichia coli to use nitrate as a terminal electron acceptor during anaerobic growth. This respiratory complex catalyzes quinol oxidation and proton release at the periplasmic side of the membrane and transfers electrons through various redox centers to the catalytic site where nitrate reduction and consumption of protons occurs (1). This leads to the generation of a proton electrochemical gradient across the cytoplasmic membrane (1). NarGHI comprises a catalytic subunit (NarG) containing a non-covalently bound molybdenum cofactor (2), an electron transfer subunit (NarH) containing multiple [Fe-S] clusters (3, 4), and a membrane anchor subunit (NarI) that is believed to be the location of quinol binding and oxidation (5). NarI (cytochrome bnr) is a diheme b-type cytochrome (6, 7), the polypeptide of which is predicted to traverse the membrane bilayer five times (6). Such a transmembrane topology is supported by recent studies of site-directed mutants of NarI that identified the histidine axial ligands of the two b-type hemes on helices II (His56 and His66) and V (His187 and His205) (7). In NarI, the low potential heme (heme bL, Em,7 = +10 mV) appears to be near the periplasmic surface of the membrane, whereas the high potential heme (heme bH, Em,7 = +120 mV) appears to be near the cytoplasmic surface. These positions relative to the membrane surfaces were predicted from the disposition of the coordinating histidines within the transmembrane helices and corroborated by EPR and optical studies of wild-type and site-directed NarI mutants (7). Such topological characteristics enable the NarI protein to interact directly with the membrane-embedded quinols and facilitate the transfer of electrons from the periplasmic to the cytoplasmic site of the membrane.

To better understand the interaction of quinols with NarGHI, and more specifically with NarI, it is necessary to define functional domains and locate binding sites of inhibitors at key positions on the electron transfer pathway from quinol to nitrate. Specific inhibitors of cytochrome b-containing respiratory enzymes have been important tools for delineating the electron transfer mechanism of ubiquinol:cytochrome c oxidoreductase (cytochrome bc1, complex III) (8-10). It is noteworthy that the cytochrome b mutations of the bc1 complex that affect the inhibitor binding sites are all concentrated in four regions delineating the two quinol binding sites Qo and Qi located on the positive (outer) and negative (inner) sides, respectively, of the cytoplasmic membrane in prokaryotes or the inner mitochondrial membrane in eukaryotes (11). The recently determined crystal structure of the bc1 complex from bovine heart mitochondria clearly shows that both antimycin A and myxothiazol-binding sites partly overlap the quinone-binding site at the Qi site and the Qo site, respectively (12). 2-n-heptyl-4-hydroxyquinoline-N-oxide (HOQNO) is the most general inhibitor of the quinone-reacting cytochromes b, and its structure is reminiscent of physiological quinones. Such similarity suggests that its binding pocket may overlap quinone-interacting sites in the vicinity of the b-cytochromes. HOQNO has been shown to inhibit the quinol:nitrate oxidoreductase activity from various organisms (13-15), as well as nitrate-dependent proton extrusion into the periplasm (1). HOQNO does not inhibit the benzyl viologen:nitrate oxidoreductase activity (5), suggesting that its binding site is associated with NarI (this subunit is not essential for benzyl viologen:nitrate oxidoreductase activity). Emerging structural data on NarI (7) combined with information obtained from the effects of specific inhibitors would be of importance in delineating the electron transfer and proton release mechanism of NarGHI.

Using optical and EPR spectroscopies of both wild-type and site-directed mutants of NarI, we report herein spectral shifts caused by several inhibitors of quinol oxidation. Our results suggest that physiological quinol oxidation occurs at a stigmatellin/HOQNO binding site (QP) which is located close to the low potential heme (heme bL), near the periplasmic side of the membrane.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Bacterial Strains and Plasmids-- The E. coli strains and plasmids used in this study are listed in Table I. Plasmids pVA700 and pCD7 carry the narGHJI operon and the narI gene, respectively, under the control of the tac promoter (ptac).

                              
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Table I
Bacterial strains and plasmids
The abbreviations are: Spcr, spectinomycin-resistant; Kmr, kanamycin-resistant; Apr, ampicillin-resistant; ptac, tac promoter.

Growth of Bacteria and Preparation of E. coli Membranes Vesicles-- For studies of proton translocation, enzyme activity, and heme reduction/oxidation, cells were grown microaerobically at 37 °C as described previously (16). For EPR studies, cells were grown microaerobically overnight at 30 °C. Cultures were harvested when the A600 reached 1.0. Membrane vesicles were prepared by French pressure lysis in 100 mM MOPS buffer (pH 7.0) containing 5 mM EDTA and phenylmethanesulfonyl fluoride (0.2 mM) (16). Membranes were frozen in liquid N2 and stored at -70 °C until use.

Enzyme Assays-- The benzyl viologen:nitrate oxidoreductase activities were assayed by a method modified from Jones and Garland (17, 18). Menadiol:nitrate and duroquinol:nitrate oxidoreductase activities were measured as described by Guigliarelli et al. (16). The I50 values for inhibitors were defined as the concentration required to reduce the quinol-nitrate reductase activity by 50%. These values were deduced from the inhibitor titration curves of enzyme activity.

Quinacrine Fluorescence Quenching-- Assays were performed as described (1) with a Jobin-Yvon spectrofluorometer model JY3D, using N2-saturated buffers. The reaction was initiated with 50 µM nitrate.

Kinetics of Heme Reduction and Reoxidation-- Heme reduction and reoxidation were followed using a DW2A Chance AMINCO spectrophotometer. This instrument had a dual wavelength configuration, and heme reduction and reoxidation were followed using a wavelength of 560 nm with a reference wavelength of 575 nm. Reactions were observed at 25 °C in potassium phosphate buffer (K2HPO4/KH2PO4 50 mM, pH 7.5) with quinol analogs (menadiol or duroquinol) as electron donors (125 µM) and nitrate as electron acceptor (250 µM). Reaction conditions were as indicated in the individual figure legends.

Inhibitor-induced Optical Shift Measurements-- For these experiments, the DW2A spectrophotometer was used in a dual-beam configuration. Difference spectra were recorded of membranes plus inhibitor minus membranes without inhibitor. Inhibitors were added from stock solutions made with ethanol as solvent, and equivalent volumes of this solvent were added to cuvettes that did not have inhibitor added. Membrane vesicles were first reduced by adding a few grains of sodium dithionite, and the base line was recorded. Inhibitors or ethanol were then added to the cuvettes. Experiments were carried out using a 50 mM MOPS buffer at pH 7.0.

EPR Spectroscopy and Redox Titrations-- EPR spectra were recorded using a Bruker ESP300 spectrometer equipped with an Oxford Instrument ESR-900 flowing helium cryostat. Instrument conditions and temperatures were as described in the individual figure legends.

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Inhibitor Effects on the Quinol:Nitrate Reductase Activities-- Quinol:nitrate oxidoreductase activities, using menadiol as electron donor, were measured in the presence of various potent inhibitors of electron transfer in the mitochondrial bc1 complex. It appears that of all the compounds tested, the most effective are HOQNO (I50 = 6 µM) and stigmatellin (I50 = 0.25 µM) whose structures are strongly reminiscent of quinones. DCMU and antimycin A are poor inhibitors and have measurable effects only at high concentrations (I50 > 40 µM). Finally, myxothiazol, atrazin, funiculosin, UHDBT and DBMIB appeared to have no effect on the quinol:nitrate oxidoreductase activity. Fig. 1 shows the concentration dependence of the HOQNO and stigmatellin inhibition of menadiol:nitrate reductase activity. The major part of the quinol activity is inhibited in a hyperbolic fashion, the remaining part of the activity constituting about 5 to 20% of the overall activity.


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Fig. 1.   Inhibitor titrations of menadiol:nitrate oxidoreductase activity. HOQNO (bullet ) and stigmatellin (open circle ) inhibition of the quinol:nitrate reductase activity of membrane-bound NarGHI. The measurements were carried out with approximately 0.15 mg ml-1 protein in 50 mM KH2PO4/K2HPO4 with excess concentrations of menadiol and nitrate.

Effects of Inhibitors on the Nitrate Reductase Mediated Proton Translocation-- Quinacrine hydrochloride distributes according to the transmembrane Delta pH and its accumulation within the membrane vesicles, in response to an inward translocation of protons, gives rise to a quenching of its fluorescence (19, 20). This phenomenon has been used herein to study the effects of the inhibitors on the nitrate reductase-dependent proton translocation in membrane preparations. These experiments were performed on membrane vesicles with overexpressed wild-type holoenzyme that possess an inside-out orientation with respect to the original cells.

Addition of nitrate to the reaction cuvette containing the membrane vesicles and the electron donors (formate or quinol analogs) elicits a large quenching of fluorescence in rate and extent (Fig. 2). The energy-dependent quinacrine quenching in these particles can be prevented in three ways: (i) by uncouplers like carbonyl cyanide m-chlorophenylhydrazone (2 µM) suggesting that quinacrine distributes between the inner and outer compartments of the particles in response to a pH gradient rather than a membrane potential (21); (ii) by low concentrations of azide (25 µM) sufficient to inhibit specifically the nitrate reductase activity as previously reported (22) and (iii) by adding inhibitors of quinol binding and oxidation (1, 20). As expected, inhibitors such as myxothiazol and atrazin, which have no effect on the quinol-nitrate oxidoreductase activity, do not perturb the quenching of fluorescence (Fig. 2). Effective inhibitors of the nitrate reductase activity, HOQNO, stigmatellin, DCMU and antimycin A, inhibit proton extrusion as observed by the absence of fluorescence quenching.


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Fig. 2.   Effect of inhibitors on periplasmic proton release. Energy-dependent quinacrine-fluorescence quenching in NarGHI-enriched inverted membrane particles at 0.5 mg ml-1 in the presence of saturating amounts of inhibitor. (1) none, (2) atrazin at 500 µM, (3) myxothiazol at 25 µM, (4) HOQNO at 125 µM, (5) stigmatellin at 12.5 µM, (6) DCMU at 250 µM, (7) antimycin A at 250 µM. Nitrate and carbonyl cyanide m-chlorophenylhydrazone (CCCP) were added at the indicated times.

Effect of Inhibitors on the Reduction and Reoxidation of the NarI Hemes-- The inhibitory effect of HOQNO, stigmatellin and, to a lesser extent DCMU, on the nitrate reductase activity was further assessed by observing NarI heme reduction by menadiol and subsequent reoxidation by nitrate. This was done to investigate which step is modified by the inhibitors in the overall steady-state electron transfer from quinol to nitrate. The results are shown in Fig. 3A. While quinol-dependent heme reduction is only slightly affected by the inhibitors, the extent of the nitrate-dependent heme reoxidation appears to be significantly decreased by HOQNO and stigmatellin (Fig. 3A), and to a lesser extent by DCMU (data not shown). Adding HOQNO and stigmatellin at the same time to the assays does not lead to further modification of the behavior of the hemes (data not shown), suggesting that both inhibitors act at the same level in the electron transfer pathway. This contrasts with what is observed in the mitochondrial cytochrome bc1 complex in which HOQNO and stigmatellin bind at separate sites on the opposite sides of the mitochondrial inner membrane (10).


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Fig. 3.   Kinetics of heme reduction and reoxidation. (A) Reduction and reoxidation kinetics of the NarI hemes with menadiol as electron donor in presence of various inhibitors. (1) without inhibitors, (2) in presence of HOQNO at 625 µM, (3) in presence of stigmatellin at 62.5 µM. The kinetics experiments were performed at 25 °C in a rapidly stirred reaction cuvette with wild-type overexpressed-containing membrane particles at 0.5 mg ml-1 in 50 mM MOPS pH 7 buffer. Both excess of menadiol and nitrate were added as indicated by the arrows. (B) Reduction and reoxidation kinetics of cytochrome bnr mutants at 0.5 mg ml-1 with menadiol as electron donor. (4) wild-type enzyme, (5) NarI-H56R mutant, (6) NarI-H66Y mutant.

To obtain further information on the location(s) of the inhibitor-binding sites, we studied heme reduction and reoxidation in a NarI-H66Y mutant devoid of heme bL, and in a NarI-H56R mutant devoid of heme bH (7). The reduction by menadiol of heme bL in the heme bH-deficient mutant is severely impaired, and there is no reduction of the heme bH in the heme bL-deficient mutant (Fig. 3B). Similar results are obtained when the reduction is carried out with formate or duroquinol (data not shown). Once reduced, the bL heme in the NarI-H56R mutant cannot be reoxidized by nitrate (Fig. 3B). The slow but total reduction of the heme bL in this mutant is not significantly impaired by HOQNO or stigmatellin (data not shown), in agreement with the results presented for the wild-type enzyme (see above). The kinetic behavior of each NarI mutant is fully in agreement with their inability to sustain anaerobic growth on nitrate and underlines the importance of the presence of both hemes for electron/proton transfer within NarGHI.

Effect of Inhibitors on the Optical Spectrum of the NarI Hemes-- It is generally accepted that in the presence of effective inhibitors, the most affected heme is that closest to the inhibitor binding site. We therefore examined the effect of inhibitors on the optical spectrum of the NarI hemes. As expected, no shifts are observed in the heme alpha -bands of reduced NarGHI in the presence of saturating amounts of myxothiazol, funiculosin, DBMIB, atrazin or UHDBT (data not shown). With the wild-type strain LCB2048/pVA700, the difference spectra observed after adding saturating amounts of HOQNO or stigmatellin to the reduced membrane vesicles are similar in shape (Fig. 4, traces 1 and 4). These S-shaped curves have maxima and minima at 555.5 nm and 550.5 nm, respectively. The difference spectrum obtained after adding antimycin A or DCMU are similar in shape but much lower in amplitude in comparison to those observed with HOQNO and stigmatellin (data not shown).


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Fig. 4.   Effects of HOQNO and stigmatellin on the optical absorption spectrum of the reduced NarI hemes. Samples were prepared as described in the Experimental procedures. The sample and reference cells contained membranes with protein concentrations of 2 mg mL-1. Inhibitor concentrations: HOQNO, 0.9 mM and stigmatellin, 0.09 mM. (1) Wild-type in the presence of HOQNO. (2) NarI-H56R in the presence of HOQNO. (3) NarI-H66Y in the presence of HOQNO. (4) Wild-type in the presence of stigmatellin. (5) NarI-H56R in the presence of stigmatellin. (6) NarI-H66Y in the presence of stigmatellin.

The spectral shifts obtained with the NarI-H66Y and NarI-H56R site-directed mutants devoid of heme bL and heme bH, respectively, are also illustrated in Fig. 4. Similar HOQNO and stigmatellin induced-spectral shifts are obtained with both wild-type and heme bH-deficient mutants, suggesting that the heme located near the periplasmic side of the membrane (bL) is affected by the inhibitors (Fig. 4, traces 2 and 5). In the absence of heme bL, no spectral shifts are observed in the presence of HOQNO and stigmatellin (Fig. 4, traces 3 and 6). In the absence of heme bL, spectra observed in the presence of HOQNO and stigmatellin correspond to a slight oxidation of hemes due to the addition of inhibitors (Fig. 4, traces 3 and 6), suggesting that there is no interaction of the inhibitors with the remaining heme (heme bH).

EPR Spectral Shifts Caused by the Inhibitors in the Wild-type and NarI Mutant Enzymes-- Fig. 5 shows the effects of some of the inhibitors used herein on the EPR lineshapes of oxidized hemes bL and bH in the presence of HOQNO (B), stigmatellin (C), DCMU (D), and antimycin A (E). HOQNO elicits a change in the Gz of heme bL from approximately 3.36 to 3.50, whereas stigmatellin appears to have the opposite effect on this heme, moving its Gz from 3.36 to approximately 3.31. DCMU and antimycin A appear to have no detectable effect on the EPR lineshape of heme bL. None of the inhibitors tested appeared to have any effect on the Gz of heme bH at approximately 3.76. 


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Fig. 5.   Effect of inhibitors on the low spin heme EPR spectrum of NarGHI in E. coli LCB79 membranes. Spectra are: (A) without inhibitor; (B) in the presence of 0.5 mM of HOQNO; (C) in the presence of 0.5 mM of stigmatellin; (D) in presence of 0.5 mM of DCMU; (E) in presence of 0.5 mM of antimycin A. Spectra represent three accumulated scans and were subtracted from the LCB2048 membranes spectra. Membrane particles were used with protein concentrations >60 mg ml-1. Spectra were recorded under 12K, a microwave power of 20 mW, and field modulation of 10 Gpp at 100KHz.

In order to further characterize the position of the HOQNO/stigmatellin binding site(s) within NarI, we also studied the effects of these inhibitors on EPR spectra of membranes containing overexpressed NarI in the absence of the membrane-extrinsic catalytic dimer (7). Fig. 6 shows the effect of the two most potent inhibitors, HOQNO and stigmatellin, on the lineshape of heme bL, which has a Gz of 3.15 in the absence of NarGH. Neither inhibitor appears to have any effect on the Gz = 2.92 feature that we have previously attributed to conformationally relaxed or modified heme b. HOQNO elicits a change in the Gz of the remaining signal from 3.15 to approximately 3.45. In contrast to what was observed in the holoenzyme in Fig. 5, stigmatellin elicits a similar, but smaller shift in Gz to that observed with HOQNO, moving it to approximately 3.27.


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Fig. 6.   Effect of various inhibitors on the heme EPR spectrum of NarI expressed from the pCD7 plasmid in LCB2048 membranes. Spectra are of: (A) LCB2048 membranes; (B) membranes enriched in wild-type NarI; (C) as in (B) but in the presence of 0.5 mM of HOQNO; (D) as in (B) in the presence of 0.5 mM of stigmatellin. Spectra were recorded as described in Fig. 6 except that the LCB2048 membranes spectra were not subtracted.

    DISCUSSION
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Abstract
Introduction
Procedures
Results
Discussion
References

The sequence of NarI is remarkably conserved among the membrane-bound nitrate reductases from various organisms, and is proposed to have five transmembrane helices (I-V) with a periplasmic N terminus and a cytoplasmic C terminus (6, 23). Additional evidence for this model comes from the identification of the histidine ligands to the two hemes of this subunit (7). Both hemes bL and bH are ligated by histidines located on helices II and V (7), and heme bH is located near the cytoplasmic surface and heme bL is located near the periplasmic surface. It has previously been shown that NarGHI releases protons into the periplasm during enzyme turnover (1), raising the question of the exact location within the enzyme where proton release takes place. We have shown herein that the periplasmically localized heme bL is closely associated with a quinol binding site (QP), and this is consistent with a role for this quinol site-heme motif in proton release during enzyme turnover.

We have used inhibitors to study the location of quinol-binding site(s) within NarGHI in much the same way as has been reported for the mitochondrial cytochrome bc1 complex (24-27). In the latter enzyme in those cases where effects can be measured, the heme which is closest to the site of inhibitor binding is generally the most affected. Using a similar approach with NarGHI, we have investigated both the effects of inhibitors on the spectral properties of the hemes of NarI and their effects on heme reduction by menadiol and subsequent reoxidation by nitrate. Based on the lineshape perturbations in both EPR and optical experiments, it is clear that HOQNO and stigmatellin are able to bind at a site (QP) in close proximity to heme bL. However, HOQNO or stigmatellin binding at this location does not greatly affect the reducibility of both hemes by menadiol (see below).

In contrast to the effect of the inhibitors on heme reduction, HOQNO and stigmatellin inhibit the extent of nitrate-dependent heme reoxidation (Fig. 3A). Possible explanations for this phenomenon include the following:

HOQNO and Stigmatellin Bound to the QP Site Affects the Em,7 of Heme bL-- Inhibitor binding in the vicinity of heme bL could significantly raise the Em,7 of the heme, resulting in it becoming non-nitrate oxidizable. HOQNO and stigmatellin have been shown to cause significant shifts in the Em,7s of Q-site associated prosthetic groups in other respiratory chain enzymes. For example, in Bacillus subtilis succinate:menaquinone oxidoreductase (SQR) addition of HOQNO causes a negative shift of the Em,7 of the Q-site associated heme bL (28). In the cytochrome bc1 complex, stigmatellin induces a large positive shift in the Em,7 of the Rieske center ([2Fe-2S] cluster), but has little effect on the Em,7 of the heme bL (25). Experiments are in progress in our laboratories to determine the effects of stigmatellin and HOQNO on the Em,7s of the two hemes of NarI.

A Second Quinol Binding Site (Qnr) Could Exist between Heme bH of NarI and the [Fe-S] Clusters of NarH-- Inhibitor binding at this site would inhibit nitrate-dependent electron flow from NarI. The presence of such a site would be consistent with the effect of HOQNO on the EPR signal of a semiquinone radical species that has been observed in a previous study of mutants of NarH that lack the highest potential [4Fe-4S] cluster of this subunit (29). However, the elimination of the semiquinone radical species by HOQNO could be due to inhibition of electron transfer from the QP site (see preceding paragraph) rather than by displacement of the semiquinone species. In the B. subtilis SQR it has also been suggested that there are two quinol binding sites (30), one associated with heme bL and one located near heme bH and the S3 [3Fe-4S] cluster. Although there is evidence for the presence of a Qnr site in NarGHI (29, 31), we believe that the simplest explanation for the data presented herein is that there is a single dissociable quinol binding site (QP) and that the Qnr site is non-dissociable (29, 31).

A proposed mechanism of HOQNO-inhibition of B. subtilis SQR has been suggested by Smirnova et al. (28) in which HOQNO acts as a semiquinone anion analog that displaces the physiological Qbardot 2 intermediate arising from the succinate-dependent quinone reduction reaction at the quinone binding site. Such a proposal can be applied to the mechanism of quinol oxidation at the QP site of NarI. In the presence of HOQNO, the first oxidation step of the quinol (QH2 to Qbardot 2) might occur allowing the reduction of the hemes, whereas the second step (Qbardot 2 to Q) would be suppressed. This model for HOQNO inhibition would explain the residual enzyme activity observed at high concentrations of HOQNO (Fig. 1). The similarity between the inhibition profiles of HOQNO and stigmatellin suggests that their mechanisms of inhibition are identical.

The data presented herein that suggests the presence of a QP site within NarGHI have to be reconciled with potential models for the mechanism of electron transfer and proton release. The observed midpoint potentials of the two hemes with bL (Em, 7-+17mV) located toward the periplasmic side and bH (Em, 7-+122mV) located toward the cytoplasmic side of NarI, respectively, suggests that physiological quinol oxidation occurs at the QP site, as previously suggested (6). This would account for the proton release into the periplasm reported herein and elsewhere (1). Heme bL reduction is only slightly affected in the heme bH deficient NarI-H56R mutant in comparison with the wild-type enzyme, and no reoxidation of heme bL by nitrate is observed. On the other hand, no quinol-dependent reduction of heme bH is observed in the heme bL deficient NarI-H66Y mutant enzyme, in agreement with what has been observed in B. subtilis SQR (30). These observations support a model for quinol binding and oxidation in which dissociable binding occurs only at the heme bL-associated Qp site. In this model the electron flow through NarI occurs successively via heme bL and heme bH from the periplasmic side to the cytoplasmic side of the membrane, allowing subsequent reduction of the [Fe-S] clusters of the NarH subunit.

It has been suggested that there is a second non-dissociable site of quinol binding associated with the NarGH catalytic dimer (31). This Qnr site may be located between the hemes of NarI and the [Fe-S] clusters of NarH. The quinone normally localized at this site may be functioning as an electron conduit in much the same way as the QA site of the bacterial photoreaction center. The possible presence of a Qnr site located between heme bH of NarI and the [Fe-S] clusters of NarH bears interesting comparison with results reported for a similar anaerobic reductase of E. coli, Me2SO reductase (DmsABC) (32). This enzyme has a similar subunit and prosthetic group composition to that of NarGHI, except that its membrane anchor subunit (DmsC) does not contain heme. In DmsABC, the EPR lineshape of a [3Fe-4S] cluster introduced into DmsB by site-directed mutagenesis is significantly altered by HOQNO binding. It is possible that the NarGHI Qnr site might correspond to the site observed in the [3Fe-4S] mutant of DmsABC, although in the latter case the site appears to be dissociable.

Overall, we have clearly demonstrated by kinetic, optical, and EPR measurements, the presence of a quinol binding site (QP) within NarGHI that is associated with heme bL of NarI, and is located toward the cytoplasmic side of NarI. Our results suggest that this QP site is responsible for physiological quinol oxidation and proton release into the periplasm (29 and this work). These results represent an important step in delineating the mechanisms of quinol oxidation, electron transfer, and proton release by NarGHI.

    ACKNOWLEDGEMENT

We thank Dr. Wolfgang Nitschke for helpful discussions.

    FOOTNOTES

* This work was funded by the CNRS.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ Supported by a fellowship from the Ministère de l'Education Supérieure et de la Recherche.

parallel Supported by a NATO Collaborative Research Grant (awarded to J. H. W.).

Dagger Dagger Supported by a travel grant from the Alberta Heritage Foundation for Medical Research and to whom correspondence should be addressed. Tel.: 33 4 91164431; Fax: 33 4 91718914; E-mail: blasco{at}ibsm.cnrs-mrs.fr.

1 The abbreviations used are: DBMIB, 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone; DCMU, 3-(3, 4-dichlorophenyl)-1,1-dimethylurea; EPR, electron paramagnetic resonance; HOQNO, 2-n-heptyl-4-hydroxyquinoline-N-oxide; MOPS, 4-morpholinepropane-sulfonic acid; NarGH; soluble catalytic dimer of nitrate reductase A; NarGHI, nitrate reductase A holoenzyme; NarI, cytochrome subunit of NarGHI (cytochrome bnr); SQR, succinate:quinone oxidoreductase; UHDBT, 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
References

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