From the
CNR Istituto di Biologia e Patologia Molecolare,
Department of Biochemical Sciences and Department of Chemistry, University "La Sapienza," 00185 Rome, Italy
Received for publication, February 5, 2003 , and in revised form, March 19, 2003.
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ABSTRACT |
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INTRODUCTION |
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The flavohemoglobin from Escherichia coli (HMP)1 has been the object of a large number of investigations to unveil its physiological role in the framework of bacterial resistance to nitrosative stress. HMP expression has been demonstrated to respond to the presence of nitric oxide (NO) in the culture medium, and an explicit mechanism has been proposed that involves NO scavenging and its reduction to N2O under anaerobic conditions (3). In contrast to (or together with) the anaerobic NO reductase activity, HMP has also been shown to be able to catalyze the oxidation of free NO to nitrate (nitric-oxide dioxygenase activity) both in vivo and in vitro in the presence of oxygen and NADH (47). Alternatively, an NO denitrosylase function has been proposed in which, at low oxygen tensions, HMP turns over in the ferric state with the intermediacy of an iron-bound nitroxyl anion that is subsequently transformed into nitrate in the presence of oxygen (8). It remains to be established which of these diverse enzymatic activities correspond to a physiologically relevant process.
A second set of functional hypotheses has been inferred on the basis of the structural features of the active site of HMP (9) and other closely related proteins. HMP, similar to the single chain hemoglobin from Vitreoscilla sp. (10) and the flavohemoglobin from Alcaligenes eutrophus (11), displays a structural geometry of the active site that is strongly reminiscent of that of typical peroxidases. In particular, the x-ray crystal structures of all of the above mentioned proteins show that the proximal heme pocket is characterized by a network of hydrogen-bonding interactions that comprises the N atom (hydrogen-bonding donor) of the proximal histidine, thus conferring an anionic character to the imidazole ring (9, 11). This feature allows a clear cut structural distinction between genuine hemoglobins in which the integrity of the ligand in the trans position needs to be preserved and peroxidases in which electron donation to the trans ligand is at the core of the catalytic activity (electron push effect). The spectroscopic signature of the peroxidase-like character of the active site is provided by resonance Raman measurements on the fully reduced, deoxygenated HMP derivative whose spectrum displays a very high iron histidine-stretching frequency, in line with the values observed for typical peroxidases (12). Subsequently, FTIR measurements conducted on the cyanide-bound ferric species confirmed the structural analogies between HMP and peroxidases highlighting the strong electron donation to the iron-bound ligand (13). Nevertheless, an extensive screening of possible peroxidase and/or monooxygenase activities toward a number of typical peroxidase and/or cytochrome P-450 substrates has been unfruitful (14).2 As a matter of fact, ferric HMP appears to be inert toward hydrogen peroxide and displays a complex ligand binding behavior toward typical ferric heme substrates (14).
Lastly, a number of experimental observations carried out on highly similar bacterial hemoglobins have revealed different possible scenarios. In particular, the presence of a tightly bound phospholipid within the heme pocket of A. eutrophus flavohemoglobin initially suggested the participation of the protein to lipid membrane transport and/or processing (15). This finding has been completely overlooked in subsequent investigations until very recently where HMP as well as the single chain bacterial hemoglobin from Vitreoscilla sp. (VHB) and even the truncated hemoglobin from Mycobacterium tubercolosis (HbO) have been reported to be preferentially localized in contact with the bacterial inner membrane and capable of reversible binding to liposomes obtained from bacterial lipid extracts (16, 17). HMP has also been shown to bind unsaturated and/or cyclopropanated fatty acids with high affinity within the heme pocket (14). Along the same line, the three-dimensional structures of the flavohemoglobins from A. eutrophus (FHP) and E. coli and of the single chain hemoglobin from Vitreoscilla sp. (VHB) pointed out that lipid binding contact regions are conserved (9).
All together, the ensemble of experimental observations just mentioned provides a puzzling picture whose elucidation might be achieved by merging membrane binding properties with the peroxidase-like character and eventually with the NO-induced expression of HMP. In this work, ferrous HMP has been demonstrated to possess a genuine alkylhydroperoxide reductase activity, thus suggesting that HMP itself and possibly other members of the hemoglobin-like protein family are involved in the reduction of lipid membrane hydroperoxides.
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EXPERIMENTAL PROCEDURES |
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Kinetic measurements were carried out by mixing anaerobic protein solutions containing 250 mM NADH and 1 mM EDTA with solutions containing different concentrations of tert-butyl, cumyl, linoleic acid hydroperoxides (13(S)-hydroperoxy-9Z,11E-octadecadienoic acid), or hydrogen peroxide (Sigma) in an Applied Photophysics rapid mixing apparatus equipped with a diode array device (Leatherhead, United Kingdom). Stock solutions of tert-butyl, cumyl, and linoleic acid hydroperoxide were prepared in 50% water/ethanol mixtures, degassed in a tonometer, and kept at 4 °C in the dark before use. Solutions containing HMP and NADH and solution containing hydroperoxides were accurately degassed in a tonometer and anaerobically transferred to stopped-flow syringes. The syringes containing HMP and NADH were allowed to stand for 5 min before mixing to ensure the consumption of residual oxygen. Double mixing experiments were also carried out in the same stopped-flow apparatus. NADH (250 µM) reduced HMP (8 µM) was first mixed with H2O2 in the pre-mixing chamber, and after a 2-s delay, it was mixed with 201000 µM CO (oxygen-free) solutions. Alternatively, slower kinetic time courses at low protein concentrations (below 1 µM) were carried out by mixing the NADH-reduced protein with the alkylhydroperoxide solutions directly in a tonometer equipped with a 1-cm quartz cuvette and a side arm reservoir. In CO inhibition experiments, a few microliters of a CO gas-saturated solution were added to the tonometer with a microsyringe and equilibrated for 20 min with the aqueous phase before adding the substrate to yield an equilibrium CO concentration of 120 µM. Time courses were followed at 340 nm (absorption maximum of NADH) on a Jasco V-570 spectrophotometer. All of the experiments were carried out in 0.1 M phosphate buffer, pH 7.0, containing 1 mM EDTA at 25 °C. In the case of linoleic acid hydroperoxide, reaction kinetics were carried out in the presence of either 0.1% Triton X-100 or 20% v/v ethanol/water mixture.
A complete quantitative analysis of the reaction product was carried out for cumyl hydroperoxide. A 5-ml solution containing 5 µM HMP, 5 mM NADH, and 2.2 mM cumyl hydroperoxide in 0.1 M phosphate buffer was equilibrated under nitrogen for 1 h at 25 °C. A protein-free blank was also prepared under the same conditions. The reaction was quenched by the addition of 5 ml of ethyl acetate, and the organic phase was recovered and split in two aliquots. The first sample was dried under vacuum and resuspended in methanol for HPLC analysis, and the second sample was directly used for GC analysis. In both HPLC and GC analyses, 2 mM benzyl alcohol was used as an internal standard to quantify the cumyl hydroperoxide reaction products. The methanol solutions (blank and sample) were injected onto an Agilent 1100 Series HPLC system equipped with a Supelcosil LC-18DB (25 cm x 2 µm) reverse phase HPLC column. The products were eluted with 30% v/v methanol/water solution at a flow rate of 0.5 ml/min and monitored at 256 nm. Product elution peaks were identified by comparison with authentic standards under identical elution conditions. GC analysis was carried out using a Varian CP-3800 gas chromatographic apparatus equipped with a CP-Sil 5 CB column (30 cm x 0.25 mm).
For ESI mass spectrometry measurements, linoleic acid hydroperoxide or its reaction products were extracted as follows. The reaction mixture (1 ml) containing 2 µM HMP in 0.1 M phosphate, pH 7.0, and 1 mM EDTA and 20% v/v ethanol, 140 µM linoleic acid hydroperoxide, and 500 µM NADH was allowed to stand 15 min under a nitrogen gas atmosphere at 25 °C. At the end of the reaction, the solution was treated with 2 ml of ethyl acetate, vortexed, and centrifuged at 6000 rpm for 15 min. Two blank solutions were prepared in which either NADH or HMP was omitted. The ethyl acetate extracts were dried under vacuum and resuspended in 80% ethanol/water containing 0.5% v/v ammonia. The ethanolic solutions were analyzed by infusion (5 µl/min) in an electrospray ion trap mass spectrometer (model LCQ, ThermoFinnigan, San Jose, CA). Linoleic hydroperoxide standards dissolved in the same solvent were used to optimize the ESI source parameters. The mass spectra were collected over the mass range of 70700 a.m.u. in negative ion mode.
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RESULTS |
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ESI mass spectrometric data (Fig. 2) revealed a similar trend in the case of linoleic acid hydroperoxide. Mass spectra of the ethyl acetate extracts of the blank solutions (in which either protein or NADH was absent) yielded a major peak at 311 a.m.u. (corresponding to the molecular weight of linoleic acid hydroperoxide anion), whereas the dominant feature was at 295 a.m.u. (16 a.m.u. with respect to the 311 peak) in the reaction mixture containing both protein and NADH. Spurious peaks at 334 and 317 a.m.u. (+22 with respect to 311 and 295 a.m.u., respectively, attributed to Na+ ion adducts) are apparent in the blank and in the complete reaction mixture, respectively.
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Reaction kinetics were monitored on the different substrates by means of UV-visible absorption spectroscopy in both spectrophotometric experiments at low protein concentrations (0.21 µM) and in stopped-flow rapid kinetic measurements at higher protein concentrations (46 µM). HMP activities determined upon increasing amounts of alkylhydroperoxides or H2O2 to degassed HMP solutions in the presence of excess NADH (250 µM) are depicted in Fig. 3 (panel A). Double reciprocal plots of Fig. 3 are the result of several separate experiments carried out on different protein preparations. Data linearization and fitting yielded the set of steady state kinetic parameters reported in Table I. The highest activity was observed for cumyl and linoleic acid hydroperoxides, whereas the reduction of tert-butyl hydroperoxide and hydrogen peroxide was 2- and 3-fold slower, respectively (Table I). It should be pointed out that reaction with linoleic acid hydroperoxide is strongly solvent-dependent. Data obtained in the presence of 0.1% Triton X-100 were fully reproducible and displayed nearly zeroth-order kinetics. In contrast, experiments carried out in 20% ethanol/water mixture in which substrate is soluble up to 23 mM concentration at 25 °C exhibited a slightly slower rate and displayed nearly exponential time courses.
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Carbon monoxide inhibition of the hydroperoxide reduction reaction was also determined for cumyl hydroperoxide. The data reported in Fig. 3B indicate a clear competitive inhibition mechanism by CO with an apparent Ki of 0.2 µM (calculated from the apparent
values according to a simple Michaelis-Menten formalism).
Rapid kinetic experiments carried out by mixing degassed HMP solutions (8 µM) in the presence of excess NADH (320 µM) with cumyl hydroperoxide (1 mM) solutions are depicted in Fig. 4A. The kinetic spectral profiles were characterized by a fast decay at 340 nm (t = 3 s) because of NADH oxidation while HMP remains in its fully reduced (ferrous heme, reduced flavin) deoxygenated derivative. Upon depletion of NADH-reducing equivalents (56 s), HMP undergoes complete oxidation (ferric heme, oxidized flavin). A similar trend is observed with linoleic acid hydroperoxide, whereas the formation of a spectroscopically distinct contribution characterized by an absorption peak at 420 nm was noticed under stationary state conditions in the reaction with tert-butyl hydroperoxide (data not shown). The species characterized by the 420-nm peak was the dominant feature in the reaction of ferrous HMP with hydrogen peroxide (Fig. 4B). An analysis of the time-dependent spectral profiles of Fig. 4 allowed the identification of the absorption spectra relative to each species (Fig. 5). The spectral profile 3 obtained from the data of Fig. 4 was thus attributed to an oxo-ferryl heme iron adduct by analogy with the spectra of typical Compounds II of peroxidases and must be distinguished from the ferrous heme iron dioxygen adduct (profile 4). The oxo-ferryl adduct was relatively stable (seconds to minutes) under reducing conditions (250 µM NADH) and 50250 µM hydrogen peroxide concentrations, whereas it rapidly decayed to a mixture of ferric heme and unidentified heme degradation products in the presence of H2O2 in larger excess (>2 mM). To confirm the oxo-ferryl spectrum assignment, the following set of controls was carried out. (i) The species obtained in the presence of H2O2 and NADH was mixed with CO-saturated solutions (1 mM) in a double mixing experiment (see "Experimental Procedures"), and no spectral changes were observed. (ii) The same compound could not be reduced with sodium dithionite.
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DISCUSSION |
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The alkylhydroperoxide reductase activity is widespread among diverse bacterial species and is thought to represent a major functional response of the cell to oxidative stress (18). In E. coli, oxidative stress involves among others the activation of OxyR, a hydrogen peroxide sensor and transcriptional activator that elicits the expression of a number of proteins and enzymes involved in hydrogen peroxide scavenging and/or repair of peroxidized substrates (19). Among these, the 2-Cys peroxiredoxin/flavoprotein complex (ahpCF) has been shown to be able to reduce a broad class of peroxides spanning from hydrogen peroxide to unsaturated and aromatic hydrocarbon hydroperoxides and thus has been considered as a key enzyme in the bacterial alkylhydroperoxide reductase activity (1820). Nevertheless, the structural diversity of peroxidized compounds possibly formed within the cell under oxidative stress is difficult to reconcile with the presence of a single enzyme capable of recognizing specifically the hydroperoxide moiety within complex molecular frames such as a DNA strand or a phospholipid acyl chain. So far, phospholipid-specific alkylhydroperoxidases have been identified in a number of prokaryotic and eukaryotic organisms (21, 22). Along the same line, recent observations demonstrated that AhpCF peroxiredoxin complex plays a pivotal role in removing hydrogen peroxide in E. coli cells under stationary phase conditions (in virtue of a lower Km value with respect to catalases, whereas it is less efficient as a lipid hydroperoxide scavenger (23).
HMP-catalyzed conversion of cumyl hydroperoxide to cumyl alcohol (currently used as a standard for comparing the alkylhydroperoxide reductase activity among different enzymes) occurs at a rate (2564 nmol/min/mg) that is at least two orders of magnitude higher than that measured for the E. coli AhpCF complex under similar experimental conditions (Ref. 18 and references cited therein) and 2-fold higher than that measured for the most efficient Amphibacillus xylanus peroxiredoxin reductase under saturating conditions of AhpC (24). Such a high activity corresponds to a turnover number (mol of substrate per mol of protein) of 110 min1 (see Fig. 2 and Table I). CO inhibition experiments (Fig. 3, panel B) demonstrate that the activity is heme-linked and is not a spurious effect because of the presence of the highly reactive flavin prosthetic group within the protein. The residual activity observed in HMP in the presence of CO is in fact fully compatible with a competitive inhibition mechanism in which substrate binding is limited kinetically by the rate of CO release from the heme iron.
Simple inspection of the time-dependent absorption spectra offers several interesting insights into the mechanism of the alkylhydroperoxide reductase activity. An analysis of the spectroscopic data of Figs. 4 and 5 together with previous experimental observations on lipid binding to HMP permits an un-equivocal elucidation of the early steps in the mechanism of alkylhydroperoxide reduction and establishes differences and analogies with classical heme-based peroxidase enzymes. HMP is capable of recognizing the alkylhydroperoxide moiety because of the highly hydrophobic distal heme pocket, and in the case of peroxidized phospholipids containing unsaturated fatty acids, HMP has been inferred to be able to adjust the hydrocarbon chain kink in correspondence of the cis double bond above the heme iron (14, 15). Thereafter, the binding of the hydroperoxide to the ferrous heme iron occurs with the concomitant two-electron reduction and cleavage of the dioxygen bond and consequent formation of a peroxidase-like Compound II and an alkyl alcohol. It is important to note that this first step does not imply electron transfer from the flavin to the heme iron but rather a direct two-electron iron oxidation. The fate of the ferryl-oxo compound thus generated is less obvious. Reduction of the ferryl-oxo compound to water and ferric heme with concomitant flavin oxidation and release of the hydroxyphospholipid to the membrane may be hypothesized. Most intriguingly, the active form of the protein capable of binding a new molecule of substrate is the ferrous derivative and not the ferric one. In fact, at variance with classical peroxidases, no alkylhydroperoxide and/or H2O2 binding to the heme iron can be detected when the heme iron is in the ferric state. Consistently, ferric HMP is unable to perform monooxygenations typically catalyzed by peroxidases and/or cytochrome P-450 on a broad variety of substrates (14).
At present, a direct in vivo determination of the HMP-dependent alkylhydroperoxide reductase activity still needs to be explored. Nevertheless, a number of experimental observations on HMP expression in response to oxidative stress conditions provide convincing evidence for a genuine physiological role of the protein in the repair of oxidative damage. In particular, it was observed that HMP expression, controlled by the fumarate nitrate regulator transcription factor, is enhanced under conditions of prolonged oxidative stress such as those imposed by administrating paraquat and other agents generating oxygen reactive species to the culture medium (4, 25). This finding is consistent with HMP being transcribed in a later phase after the oxidative pulse. In fact, whereas the fast response to oxidative stress is governed by enzymes that are directly under the control of the transcription factor OxyR (18, 27), the late response to oxidative stress involves a web of interactions that ultimately lead to HMP transcription (25). Thus, enzymes involved in hydrogen peroxide scavenging (AhpCF and KatG/E gene products) or DNA protection (Dps gene product) are rendered available as a first barrier against peroxidation, whereas HMP and possibly other substrate-specific enzymes may play a role in the repair of diverse peroxidized species. In this framework, the link between the reported NO-induced (fumarate nitrate regulator-mediated) expression of HMP (3) and oxidative stress may reflect another facet of the complex and intimately correlated responses of the bacterial cell to NO and oxygen reactive species. NO induction of enzymes involved in the oxidative stress response is in fact well documented (28), and explicit mechanisms that envisage an increase of the alkylhydroperoxide reductase activity in the presence of NO have been proposed (29). In particular, nitroperoxide species formed at a diffusion-limited rate by the reaction of NO with superoxide anion is known to be a strong promoter of membrane lipid peroxidation (30). Accordingly, NO-induced HMP expression under low oxygen tensions might well allow a direct (fumarate nitrate regulator-mediated) mechanism for lipid hydroperoxide reduction, whereas peroxiredoxins actively scavenge nitroperoxide anions (29).
On the basis of the considerations just presented, HMP and other bacterial hemoglobins would be key enzymes in maintaining the cell membrane integrity at the aerobic/anaerobic interface. Such a hypothesis also provides a plausible explanation for the reported high growth performance of E. coli over-producing bacterial hemoglobins under microaerobic environments (31). Nevertheless, other catalytic options must also be considered in further studies. In fact, lipid-hydroperoxide reductase activity might be part of a specific reaction pathway that leads to the formation of lipid hydroperoxide-derived active compounds whose functions are yet to be established. It is worth mentioning that in chloroplasts, for instance, unsaturated fatty acid hydroperoxides are converted to signaling molecules by specific cytochrome P-450-like proteins such as hydroperoxide lyase and allene oxidase (26). Unsaturated fatty acid processing by heme-based cyclo-oxygenase enzymes is also at the basis of the eicosanoids pathway in eukaryotic cells. Intriguingly, cyclo-oxygenases have been proposed to be activated by NO (or by nitroperoxide) to trigger the catalytic cycle. In the same way, bacterial hemoglobins might be involved in the (possibly NO-driven) processing of phospholipids in the framework of a more complex physiological response.
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FOOTNOTES |
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¶ To whom correspondence should be addressed. Fax: 39-06-44-40062; E-mail: alberto.boffi{at}uniroma1.it.
1 The abbreviations used are: HMP, Escherichia coli flavohemoglobin; NO, nitric oxide; GC, gas chromatography; HPLC, high pressure liquid chromatography; ESI, electrospray ionization.
2 A. Bonamore, P. Gentili, A. Ilari, M. E. Schininà, and A. Boffi, unpublished results.
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ACKNOWLEDGMENTS |
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REFERENCES |
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