Observation of subpicosecond x-ray emission from laser-cluster interaction

We present the first experimental evidence of the subpicosecond duration of x-ray pulses emitted from laser-irradiated clusters, demonstrating the suitability of such a debris free target for ultrafast x-ray science applications. The K-shell emission (approximately 3 keV) from large Ar clusters (6 x 10(5) to 4 x 10(6) atoms) is time resolved, when irradiated by ultrashort (40 fs to 5 ps) and intense laser pulses (10(15-17) W/cm2). The observations are supported by hydrodynamical and collisional-radiative calculations, that reproduce the extremely short x-ray pulse duration.

[Expert opinion on the basic surgical technique for laparoscopic ventral hernia repair]

Laparoscopic ventral hernia repair is currently the subject of intense debate, even though it provides a series of advantages over open surgery and is feasible and safe. Various studies have shown this technique to be as effective as open repair with a lower recurrence rate. Despite the excellent results of laparoscopic repair of ventral hernias, there are numerous controversies associated with this procedure. These controversies concern the indications and contraindications of the procedure, and technical aspects such as how to create the pneumoperitoneum, perform adhesiolysis, manage the hernia sac, and insert and fix the mesh to the anterior abdominal wall. Also controversial are outcome, complications related to postoperative seroma, and which type and size of mesh should be used. The present article aims primarily to address many of these issues, based on the experience of distinct surgeons with expertise in this approach, in order to provide data to establish a consensus on how laparoscopic ventral hernia repair should be performed.

NarJ Chaperone Binds on Two Distinct Sites of the Aponitrate Reductase of Escherichia coli to Coordinate Molybdenum Cofactor Insertion and Assembly

Understanding when and how metal cofactor insertion occurs into a multisubunit metalloenzyme is of fundamental importance. Molybdenum cofactor insertion is a tightly controlled process that involves specific interactions between the proteins that promote cofactor delivery, enzyme-specific chaperones, and the apoenzyme. In the assembly pathway of the multisubunit molybdoenzyme, membrane-bound nitrate reductase A from Escherichia coli, a NarJ-assisted molybdenum cofactor (Moco) insertion step, must precede membrane anchoring of the apoenzyme. Here, we have shown that the NarJ chaperone interacts at two distinct binding sites of the apoenzyme, one interfering with its membrane anchoring and another one being involved in molybdenum cofactor insertion. The presence of the two NarJ-binding sites within NarG is required to ensure productive formation of active nitrate reductase. Our findings supported the view that enzyme-specific chaperones play a central role in the biogenesis of multisubunit molybdoenzymes by coordinating subunits assembly and molybdenum cofactor insertion.

Investigation of laser-irradiated Ar cluster dynamics from K-shell x-ray emission measurements

Intense (up to a few 10(17) W/ cm2) femtosecond (down to 40 fs) laser pulses are focused onto a partially clusterized argon gas jet. The target was previously characterized and optimized in order to get a homogeneous and dense jet of clusters with a well controlled size. The interaction leads to x-ray emission that is absolutely calibrated and spectrally resolved using a high resolution time-integrated spectrometer in the K-shell range (from 2.9 to 4.3 keV). X-ray spectra are investigated as a function of different laser temporal parameters such as the nanosecond prepulse contrast, the laser pulse duration, and the femtosecond delay between two different laser pulses. The cluster size ranges from 180 to 350 angstroms and irradiation by laser pulses with both linear and circular polarization is investigated. The experimental results are discussed in terms of the laser-cluster interaction dynamics. They are compared with the predictions of collision-dominated nanoplasma models. However, further interaction processes are required in order to explain the observed characteristic lines demonstrating highly charged ions up to Ar16+.

Membrane-associated maturation of the heterotetrameric nitrate reductase of Thermus thermophilus

The nar operon, coding for the respiratory nitrate reductase of Thermus thermophilus (NRT), encodes a di-heme b-type (NarJ) and a di-heme c-type (NarC) cytochrome. The role of both cytochromes and that of a putative chaperone (NarJ) in the synthesis and maturation of NRT was studied. Mutants of T. thermophilus lacking either NarI or NarC synthesized a soluble form of NarG, suggesting that a putative NarCI complex constitutes the attachment site for the enzyme. Interestingly, the NarG protein synthesized by both mutants was inactive in nitrate reduction and misfolded, showing that membrane attachment was required for enzyme maturation. Consistent with its putative role as a specific chaperone, inactive and misfolded NarG was synthesized by narJ mutants, but in contrast to its Escherichia coli homologue, NarJ was also required for the attachment of the thermophilic enzyme to the membrane. A bacterial two-hybrid system was used to demonstrate the putative interactions between the NRT proteins suggested by the analysis of the mutants. Strong interactions were detected between NarC and NarI and between NarG and NarJ. Weaker interaction signals were detected between NarI, but not NarC, and both NarG and NarH. These results lead us to conclude that the NRT is a heterotetrameric (NarC/NarI/NarG/NarH) enzyme, and we propose a model for its synthesis and maturation that is distinct from that of E. coli. In the synthesis of NRT, a NarCI membrane complex and a soluble NarGJH complex are synthesized in a first step. In a second step, both complexes interact at the cytoplasmic face of the membrane, where the enzyme is subsequently activated with the concomitant conformational change and release of the NarJ chaperone from the mature enzyme.

Evidence for an EPR-Detectable Semiquinone Intermediate Stabilized in the Membrane-Bound Subunit NarI of Nitrate Reductase A (NarGHI) from Escherichia coli

Nitrate reductase A (NRA, NarGHI) is expressed in Escherichia coli by growing the bacterium in anaerobic conditions in the presence of nitrate. This enzyme reduces nitrate to nitrite and uses menaquinol (or ubiquinol) as the electron donor. The location of quinones in the enzyme, their number, and their role in the electron transfer mechanism are still controversial. In this work, we have investigated the spectroscopic and thermodynamic properties of a semiquinone (SQ) in membrane samples of overexpressed E. coli nitrate reductase poised in appropriate redox conditions. This semiquinone is highly stabilized with respect to free semiquinone. The g-values determined from the numerical simulation of its Q-band (35 GHz) EPR spectrum are equal to 2.0061, 2.0051, 2.0023. The midpoint potential of the Q/QH(2) couple is about -100 mV, and the SQ stability constant is about 100 at pH 7.5. The semiquinone EPR signal disappears completely upon addition of the quinol binding site inhibitor 2-n-nonyl-4-hydroxyquinoline N-oxide (NQNO). A semiquinone radical could also be stabilized in preparations where only the NarI membrane subunit is overexpressed in the absence of the NarGH catalytic dimer. Its thermodynamic and spectroscopic properties show only slight variations with those of the wild-type enzyme. The X-band continuous wave (cw) electron nuclear double resonance (ENDOR) spectra of the radicals display similar proton hyperfine coupling patterns in NarGHI and in NarI, showing that they arise from the same semiquinone species bound to a single site located in the NarI membrane subunit. These results are discussed with regard to the location and the potential function of quinones in the enzyme.

Structural and biochemical characterization of a quinol binding site of Escherichia coli nitrate reductase A

The crystal structure of Escherichia coli nitrate reductase A (NarGHI) in complex with pentachlorophenol has been determined to 2.0 A of resolution. We have shown that pentachlorophenol is a potent inhibitor of quinol:nitrate oxidoreductase activity and that it also perturbs the EPR spectrum of one of the hemes located in the membrane anchoring subunit (NarI). This new structural information together with site-directed mutagenesis data, biochemical analyses, and molecular modeling provide the first molecular characterization of a quinol binding and oxidation site (Q-site) in NarGHI. A possible proton conduction pathway linked to electron transfer reactions has also been defined, providing fundamental atomic details of ubiquinol oxidation by NarGHI at the bacterial membrane.

Expression profiles of a human pancreatic cancer cell line upon induction of apoptosis search for modulators in cancer therapy

We analyzed the differential gene expression in the pancreatic cancer cell line NP-18 upon induction of apoptosis caused by cyclin-dependent kinase inhibition triggered by either overexpression of the tumor suppressor gene p16(INK4A)using an adenoviral construction or incubation with the chemical inhibitors, roscovitine or olomoucine. Screening was performed using cDNA arrays from Clontech that allowed the determination of the expression of 1,176 genes specifically related with cancer. The analysis was carried out using the Atlas Image 2.01 (Clontech) and GeneSpring 4.2 (Silicon Genetics) softwares. Among the differentially expressed genes, we chose for further validation histone deacetylase 1 (HDAC1), von Hippel Lindau and decorin as upregulated genes, and Sp1, hypoxia-inducible factor-1 alpha and DNA primase as downregulated genes. The changes in the expression of these genes to mRNA were validated by quantitative RT-PCR and the final translation into protein by Western blot analysis. Inhibition of HDAC activity, Sp1 binding and DNA primase expression led to an increase in the level of apoptosis, both in parental cells and in doxorubicin-resistant cells. Therefore, these proteins could constitute possible targets to develop modulators in cancer chemotherapy that would increase or restore apoptosis.

Involvement of the Molybdenum Cofactor Biosynthetic Machinery in the Maturation of the Escherichia coli Nitrate Reductase A

The maturation of Escherichia coli nitrate reductase A requires the incorporation of the Mo-(bis-MGD) cofactor to the apoprotein. For this process, the NarJ chaperone is strictly required. We report the first description of protein interactions between molybdenum cofactor biosynthetic proteins (MogA, MoeA, MobA, and MobB) and the aponitrate reductase (NarG) using a bacterial two-hybrid approach. Two conditions have to be satisfied to allow the visualization of the interactions, (i) the presence of an active and mature molybdenum cofactor and (ii) the presence of the NarJ chaperone and of the NarG structural partner subunit, NarH. Formation of tungsten-substituted cofactor prevents the interaction between NarG and the four biosynthetic proteins. Our results suggested that the final stages of molybdenum cofactor biosynthesis occur on a complex made up by MogA, MoeA, MobA, and MobB, which is also in charge with the delivery of the mature cofactor onto the aponitrate reductase A in a NarJ-assisted process.

A New Type of NADH Dehydrogenase Specific for Nitrate Respiration in the Extreme Thermophile Thermus thermophilus

A four-gene operon (nrcDEFN) was identified within a conjugative element that allows Thermus thermophilus to use nitrate as an electron acceptor. Three of them encode homologues to components of bacterial respiratory chains: NrcD to ferredoxins; NrcF to iron-sulfur-containing subunits of succinate-quinone oxidoreductase (SQR); and NrcN to type-II NADH dehydrogenases (NDHs). The fourth gene, nrcE, encodes a membrane protein with no homologues in the protein data bank. Nitrate reduction with NADH was catalyzed by membrane fractions of the wild type strain, but was severely impaired in nrc::kat insertion mutants. A fusion to a thermophilic reporter gene was used for the first time in Thermus spp. to show that expression of nrc required the presence of nitrate and anoxic conditions. Therefore, a role for the nrc products as a new type of membrane NDH specific for nitrate respiration was deduced. Consistent with this, nrc::kat mutants grew more slowly than the wild type strain under anaerobic conditions, but not in the presence of oxygen. The oligomeric structure of this Nrc-NDH was deduced from the analysis of insertion mutants and a two-hybrid bacterial system. Attachment to the membrane of NrcD, NrcF, and NrcN was dependent on NrcE, whose cytoplasmic C terminus interacts with the three proteins. Interactions were also detected between NrcN and NrcF. Inactivation of nrcF produced solubilization of NrcN, but not of NrcD. These data lead us to conclude that the Nrc proteins form a distinct third type of bacterial respiratory NDH.

The catalytic subunit of Escherichia coli nitrate reductase A contains a novel [4Fe-4S] cluster with a high-spin ground state

We have used EPR spectroscopy, redox potentiometry, and protein crystallography to characterize the [4Fe-4S] cluster (FS0) of the Escherichia coli nitrate reductase A (NarGHI) catalytic subunit (NarG). FS0 is clearly visible in the crystal structure of NarGHI [Bertero, M. G., et al. (2003) Nat. Struct. Biol. 10, 681-687] but has novel coordination comprising one His residue and three Cys residues. At low temperatures (<15 K), reduced NarGHI exhibits a previously unobserved EPR signal comprising peaks at g = 5.023 and g = 5.556. We have assigned these features to a [4Fe-4S](+) cluster with an S = (3)/(2) ground state, with the g = 5.023 and g = 5.556 peaks corresponding to subpopulations exhibiting DeltaS = (1)/(2) and DeltaS = (3)/(2) transitions, respectively. Both peaks exhibit midpoint potentials of approximately -55 mV at pH 8.0 and are eliminated in the EPR spectrum of apomolybdo-NarGHI. The structure of apomolybdo-NarGHI reveals that FS0 is still present but that there is significant conformational disorder in a segment of residues that includes one of the Cys ligands. On the basis of these observations, we have assigned the high-spin EPR features of reduced NarGHI to FS0.

CYP175A1 from Thermus thermophilus HB27, the first �-carotene hydroxylase of the P450 superfamily

The biological function of thermostable P450 monooxygenase CYP175A1 from Thermus thermophilus HB27 was studied by functional complementation in Escherichia coli. The gene product of CYP175A1 added hydroxyl groups to both beta rings of beta-carotene to form zeaxanthin (beta,beta-carotene-3,3'-diol) in E. coli, which produces beta-carotene due to the Erwinia uredovora carotenoid biosynthesis genes. In addition, spectroscopic methods revealed that E. coli carrying CYP175A1 and the cDNA of the Haematococcus pluvialis carotene ketolase was able to synthesise hydroxyechinenone. The predicted amino acid sequence of the enzyme from T. thermophilus does not show substantial similarity with other known beta-carotene hydroxylases, but 41% with the cytochrome P450 monooxygenase from Bacillus megaterium (CYP102A1, P450 BM3). It is concluded that CYP175 A1 represents a new type of beta-carotene hydroxylase of the P450 superfamily.

Insights into the respiratory electron transfer pathway from the structure of nitrate reductase A

The facultative anaerobe Escherichia coli is able to assemble specific respiratory chains by synthesis of appropriate dehydrogenases and reductases in response to the availability of specific substrates. Under anaerobic conditions in the presence of nitrate, E. coli synthesizes the cytoplasmic membrane-bound quinol-nitrate oxidoreductase (nitrate reductase A; NarGHI), which reduces nitrate to nitrite and forms part of a redox loop generating a proton-motive force. We present here the crystal structure of NarGHI at a resolution of 1.9 A. The NarGHI structure identifies the number, coordination scheme and environment of the redox-active prosthetic groups, a unique coordination of the molybdenum atom, the first structural evidence for the role of an open bicyclic form of the molybdo-bis(molybdopterin guanine dinucleotide) (Mo-bisMGD) cofactor in the catalytic mechanism and a novel fold of the membrane anchor subunit. Our findings provide fundamental molecular details for understanding the mechanism of proton-motive force generation by a redox loop.

In vivo interactions between gene products involved in the final stages of molybdenum cofactor biosynthesis in Escherichia coli

The final stages of bacterial molybdenum cofactor (Moco) biosynthesis correspond to molybdenum chelation and nucleotide attachment onto an unique and ubiquitous structure, the molybdopterin. Using a bacterial two-hybrid approach, here we report on the in vivo interactions between MogA, MoeA, MobA, and MobB implicated in several distinct although linked steps in Escherichia coli. Numerous interactions among these proteins have been identified. Somewhat surprisingly, MobB, a GTPase with a yet unclear function, interacts with MogA, MoeA, and MobA. Probing the effects of various mo. mutations on the interaction map allowed us (i) to distinguish Moco-sensitive interactants from insensitive ones involving MobB and (ii) to demonstrate that molybdopterin is a key molecule triggering or facilitating MogA-MoeA and MoeA-MobA interactions. These results suggest that, in vivo, molybdenum cofactor biosynthesis occurs on protein complexes rather than by the separate action of molybdenum cofactor biosynthetic proteins.

Photon acceleration of ultrashort laser pulses by relativistic ionization fronts

We present experimental results from the collision of weak ultrashort pulses with relativistic ionization fronts in copropagation and counterpropagation. The observed frequency upshifts of the probe pulses provide not only information about the electron density of the ionization front but also reveal the fine structure of the front. The connection between the correlation lengths for copropagation and counterpropagation and the longitudinal and transverse dimensions of the ionization front is also demonstrated thus showing the feasibility of using the frequency upshift experienced by short probe pulses to fully characterize relativistic ionization fronts and other relativistic coherent structures in laser-produced plasmas.

Hot-electron influence on L-shell spectra of multicharged Kr ions generated in clusters irradiated by femtosecond laser pulses

Strong L-shell x-ray emission has been obtained from Kr clusters formed in gas jets and irradiated by 60-500-fs laser pulses. Spectral lines from the F-, Ne- Na-, and Mg-like charge states of Kr have been identified from highly resolved x-ray spectra. Spectral line intensities are used in conjunction with a detailed time-dependent collisional-radiative model to diagnose the electron distribution functions of plasmas formed in various gas jet nozzles with various laser pulse durations. It is shown that L-shell spectra formed by relatively long nanosecond-laser pulses can be well described by a steady-state model without hot electrons when opacity effects are included. In contrast, adequate modeling of L-shell spectra from highly transient and inhomogeneous femtosecond-laser plasmas requires including the influence of hot electrons. It is shown that femtosecond-laser interaction with gas jets from conical nozzles produces plasmas with higher ionization balances than plasmas formed by gas jets from Laval nozzles, in agreement with previous work for femtosecond laser interaction with Ar clusters.

Detection and interpretation of redox potential optima in the catalytic activity of enzymes

It is no surprise that the catalytic activity of electron-transport enzymes may be optimised at certain electrochemical potentials in ways that are analogous to observations of pH-rate optima. This property is observed clearly in experiments in which an enzyme is adsorbed on an electrode surface which can supply or receive electrons rapidly and in a highly controlled manner. In such a way, the rate of catalysis can be measured accurately as a function of the potential (driving force) that is applied. In this paper, we draw attention to a few examples in which this property has been observed in enzymes that are associated with membrane-bound respiratory chains, and we discuss its possible origins and implications for in vivo regulation.

Electron transfer from heme bL to the [3Fe-4S] cluster of Escherichia coli nitrate reductase A (NarGHI)

We have investigated the functional relationship between three of the prosthetic groups of Escherichia coli nitrate reductase A (NarGHI): the two hemes of the membrane anchor subunit (NarI) and the [3Fe-4S] cluster of the electron-transfer subunit (NarH). In two site-directed mutants (NarGHI(H56R) and NarGHI(H205Y)) that lack the highest potential heme of NarI (heme b(H)), a large negative DeltaE(m,7) is elicited on the NarH [3Fe-4S] cluster, suggesting a close juxtaposition of these two centers in the holoenzyme. In a mutant retaining heme b(H), but lacking heme b(L) (NarGHI(H66Y)), there is no effect on the NarH [3Fe-4S] cluster redox properties. These results suggest a role for heme b(H) in electron transfer to the [3Fe-4S] cluster. Studies of the pH dependence of the [3Fe-4S] cluster, heme b(H), and heme b(L) E(m) values suggest that significant deprotonation is only observed during oxidation of the latter heme (a pH dependence of -36 mV pH(-1)). In NarI expressed in the absence of NarGH [NarI(DeltaGH)], apparent exposure of heme b(H) to the aqueous milieu results in both it and heme b(L) having E(m) values with pH dependencies of approximately -30 mV pH(-1). These results are consistent with heme b(H) being isolated from the aqueous milieu and pH effects in the holoenzyme. Optical spectroscopy indicates that inhibitors such as HOQNO and stigmatellin bind and inhibit oxidation of heme b(L) but do not inhibit oxidation of heme b(H). Fluorescence quench titrations indicate that HOQNO binds with higher affinity to the reduced form of NarGHI than to the oxidized form. Overall, the data support the following model for electron transfer through the NarI region of NarGHI: Q(P) site --> heme b(L) --> heme b(H) --> [3Fe-4S] cluster.

The diheme cytochrome b subunit (Narl) of Escherichia coli nitrate reductase A (NarGHI): structure, function, and interaction with quinols

Significant recent advances have been made in studies of the major dissimilatory nitrate reductase (NarGHI) of Escherichia coli. This enzyme is a complex iron-sulfur ([Fe-S]) molybdoenzyme that oxidizes menaquinol or ubiquinol at a periplasmically oriented Q-site (Qp site), and reduces nitrate at a cytoplasmically-oriented molybdo-(bismolybdopterin guanine dinucleotide) (Mo-bisMGD) cofactor. The Qp site, as well as two hemes, termed bL and bH, are localized in a hydrophobic diheme cytochrome b(Narl) that: (i) provides a conduit for electron-transfer from the periplasmically-oriented Qp-site; (ii) provides a membrane anchoring functionality for the membrane-extrinsic subunits (NarGH) that coordinate the Mo-bisMGD (NarG) and four [Fe-S] clusters (NarH); and (iii) helps ensure the separation of sites of H+-yielding and H+-consuming reactions such that enzyme turnover leads to the generation of a proton-electrochemical potential across the cytoplasmic membrane. This minireview focuses on recent advances and future prospects for the diheme cytochrome b subunit (Narl) of NarGHI.

The coordination and function of the redox centres of the membrane-bound nitrate reductases

Under anaerobic conditions and in the presence of nitrate, the facultative anaerobe Escherichia coli synthesises an electron-transport chain comprising a primary dehydrogenase and the terminal membrane-bound nitrate reductase A (NarGHI). This review focuses on recent advances obtained on the structure and function of the three protein subunits of membrane-bound nitrate reductases. We discuss a global architecture for the Mo-bisMGD-containing subunit (NarG) and a coordination model for the four [Fe-S] centres of the electron-transfer subunit (NarH) and for the two b-type haems of the anchor subunit NarI.

Large erupting complex odontoma

An unusual case of erupting complex odontoma is presented.

Heteronuclear NMR and soft docking: an experimental approach for a structural model of the cytochrome c553-ferredoxin complex

The combination of docking algorithms with NMR data has been developed extensively for the studies of protein-ligand interactions. However, to extend this development for the studies of protein-protein interactions, the intermolecular NOE constraints, which are needed, are more difficult to access. In the present work, we describe a new approach that combines an ab initio docking calculation and the mapping of an interaction site using chemical shift variation analysis. The cytochrome c553-ferredoxin complex is used as a model of numerous electron-transfer complexes. The 15N-labeling of both molecules has been obtained, and the mapping of the interacting site on each partner, respectively, has been done using HSQC experiments. 1H and 15N chemical shift analysis defines the area of both molecules involved in the recognition interface. Models of the complex were generated by an ab initio docking software, the BiGGER program (bimolecular complex generation with global evaluation and ranking). This program generates a population of protein-protein docked geometries ranked by a scoring function, combining relevant stabilization parameters such as geometric complementarity surfaces, electrostatic interactions, desolvation energy, and pairwise affinities of amino acid side chains. We have implemented a new module that includes experimental input (here, NMR mapping of the interacting site) as a filter to select the accurate models. Final structures were energy minimized using the X-PLOR software and then analyzed. The best solution has an interface area (1037.4 A2) falling close to the range of generally observed recognition interfaces, with a distance of 10.0 A between the redox centers.

The hemes of Escherichia coli nitrate reductase A (NarGHI): potentiometric effects of inhibitor binding to narI

We have potentiometrically characterized the two hemes of Escherichia coli nitrate reductase A (NarGHI) using EPR and optical spectroscopy. NarGHI contains two hemes, a low-potential heme b(L) (E(m,7) = 20 mV; g(z)() = 3.36) and a high-potential heme b(H) (E(m, 7) = 120 mV; g(z)() = 3.76). Potentiometric analyses of the g(z)() features of the heme EPR spectra indicate that the E(m,7) values of both hemes are sensitive to the menaquinol analogue 2-n-heptyl-4-hydroxyquinoline N-oxide (HOQNO). This inhibitor causes a potential-inversion of the two hemes (for heme b(L), E(m,7) = 120 mV; for heme b(H), E(m,7) = 60 mV). This effect is corroborated by optical spectroscopy of a heme b(H)-deficient mutant (NarGHI(H56R)) in which the heme b(L) undergoes a DeltaE(m,7) of 70 mV in the presence of HOQNO. Another potent inhibitor of NarGHI, stigmatellin, elicits a moderate heme b(L) DeltaE(m,7) of 30 mV, but has no detectable effect on heme b(H). No effect is elicited by either inhibitor on the line shape or the E(m,7) values of the [3Fe-4S] cluster coordinated by NarH. When NarI is expressed in the absence of NarGH [NarI(DeltaGH)], two hemes are detected in potentiometric titrations with E(m,7) values of 37 mV (heme b(L); g(z)() = 3.15) and -178 mV (heme b(H); g(z)() = 2.92), suggesting that heme b(H) may be exposed to the aqueous milieu in the absence of NarGH. The identity of these hemes was confirmed by recording EPR spectra of NarI(DeltaGH)(H56R). HOQNO binding titrations followed by fluorescence spectroscopy suggest that in both NarGHI and NarI(DeltaGH), this inhibitor binds to a single high-affinity site with a K(d) of approximately 0.2 microM. These data support a functional model for NarGHI in which a single dissociable quinol binding site is associated with heme b(L) and is located toward the periplasmic side of NarI.

Molybdenum cofactor properties and [Fe-S] cluster coordination in Escherichia coli nitrate reductase A: investigation by site-directed mutagenesis of the conserved his-50 residue in the NarG subunit

Most of the molybdoenzymes contain, in the amino-terminal region of their catalytic subunits, a conserved Cys group that in some cases binds an [Fe-S] cluster. In dissimilatory nitrate reductases, the first Cys residue of this motif is replaced by a conserved His residue. Site-directed mutagenesis of this residue (His-50) was performed on the NarG subunit from Escherichia coli nitrate reductase A. The results obtained by EPR spectroscopy enable us to exclude the implication of this residue in [Fe-S] binding. Additionally, we showed that the His-50 residue does not coordinate the molybdenum atom, but its substitution by Cys or Ser introduces a perturbation of the hydrogen bonding network around the molybdenum cofactor. From potentiometric studies, it is proposed that the high-pH and the low-pH forms of the Mo(V) are both involved during the redox turnover of the enzyme. Perturbation of the Mo(V) pKV value might be responsible for the low activity reported in the His-50-Cys mutant enzyme. A catalytic model is proposed in which the protonation/deprotonation of the Mo(V) species is an essential step. Thus, one of the two protons involved in the catalytic cycle could be the one coupled to the molybdenum atom in the dissimilatory nitrate reductase of E. coli.

Inhibitor binding within the NarI subunit (cytochrome bnr) of Escherichia coli nitrate reductase A

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 microM, 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.

NarJ is a specific chaperone required for molybdenum cofactor assembly in nitrate reductase A of Escherichia coli

The formation of active membrane-bound nitrate reductase A in Escherichia coli requires the presence of three subunits, NarG, NarH and NarI, as well as a fourth protein, NarJ, that is not part of the active nitrate reductase. In narJ strains, both NarG and NarH subunits are associated in an unstable and inactive NarGH complex. A significant activation of this complex was observed in vitro after adding purified NarJ-6His polypeptide to the cell supernatant of a narJ strain. Once the apo-enzyme NarGHI of a narJ mutant has become anchored to the membrane via the NarI subunit, it cannot be reactivated by NarJ in vitro. NarJ protein specifically recognizes the catalytic NarG subunit. Fluorescence, electron paramagnetic resonance (EPR) spectroscopy and molybdenum quantification based on inductively coupled plasma emission spectroscopy (ICPES) clearly indicate that, in the absence of NarJ, no molybdenum cofactor is present in the NarGH complex. We propose that NarJ is a specific chaperone that binds to NarG and may thus keep it in an appropriate competent-open conformation for the molybdenum cofactor insertion to occur, resulting in a catalytically active enzyme. Upon insertion of the molybdenum cofactor into the apo-nitrate reductase, NarJ is then dissociated from the activated enzyme.

The molybdenum cofactor of Escherichia coli nitrate reductase A (NarGHI). Effect of a mobAB mutation and interactions with [Fe-S] clusters

We have studied the effect of a mobAB mutation and tungstate on molybdo-molybdopterin-guanine dinucleotide (Mo-MGD) insertion into Escherichia coli nitrate reductase (NarGHI). Preparation of fluorescent oxidized derivatives of MGD (Form A and Form B) indicates that in a mobAB mutant there is essentially no detectable cofactor present in either the membrane-bound (NarGHI) or purified soluble (NarGH) forms of the enzyme. Electron paramagnetic resonance characterization of membrane-bound cofactor-deficient NarGHI suggests that it has altered electrochemistry with respect to the dithionite reducibility of the [Fe-S] clusters of NarH. Potentiometric titrations of membrane-bound NarGHI indicate that the NarH [Fe-S] clusters have midpoint potentials at pH 8.0 (Em,8.0 values) of +180 mV ([3Fe-4S] cluster), +130, -55, and -420 mV ([4Fe-4S] clusters) in a wild-type background and +180, +80, -35, and -420 mV in a mobAB mutant background. These data support the following conclusions: (i) a model for Mo-MGD biosynthesis and assembly into NarGHI in which both metal chelation and nucleotide addition to molybdopterin precede cofactor insertion; and (ii) the absence of Mo-MGD significantly affects Em,8.0 of the highest potential [4Fe-4S] cluster.

Heme axial ligation by the highly conserved His residues in helix II of cytochrome b (NarI) of Escherichia coli nitrate reductase A

Optical spectroscopy and EPR studies confirm the existence of two b-type hemes in the NarI subunit (cytochrome bnr) of the membrane-bound nitrate reductase (NarGHI) of Escherichia coli. Replacement of His-56 by Arg and His-66 by Tyr results in the loss of the high-potential heme and of the low-potential heme, respectively. These data support the assignment of the axial ligands to the low-potential heme (His-66 and His-187) and to the high-potential heme (His-56 and His-205). This pairing is consistent with the model proposed for NarI of the nitrate reductase of Thiosphaera pantotropha (Berks, B. C., Page, M. D., Richardson, D. J. , Reilly, A., Cavill, A., Outen, F., and Ferguson, S. J. (1995) Mol. Microbiol. 15, 319-331) in which the two bis-histidine ligated hemes are coordinated by conserved His residues of helix II and V. EPR and optical studies suggest that the low-potential heme (Em,7 = +17 mV) and the high-potential heme (Em,7 = +122 mV) are located near the periplasmic side and the cytoplasmic side of the membrane, respectively. Moreover, correct insertion of both hemes into NarI requires anchoring to NarGH.

Characterization by electron paramagnetic resonance of the role of the Escherichia coli nitrate reductase (NarGHI) iron-sulfur clusters in electron transfer to nitrate and identification of a semiquinone radical intermediate

We have used Escherichia coli cytoplasmic membrane preparations enriched in wild-type and mutant (NarH-C16A and NarH-C263A) nitrate reductase (NarGHI) to study the role of the [Fe-S] clusters of this enzyme in electron transfer from quinol to nitrate. The spectrum of dithionite-reduced membrane bound NarGHI has major features comprising peaks at g = 2.04 and g = 1.98, a peak-trough at g = 1.95, and a trough at g = 1.87. The oxidized spectrum of NarGHI in membranes comprises an axial [3Fe-4S] cluster spectrum with a peak at g = 2.02 (g(z)) and a peak-trough at g = 1.99 (g(xy)). We have shown that in two site-directed mutants of NarGHI which lack the highest potential [4Fe-4S] cluster (B. Guigliarelli, A. Magalon, P. Asso, P. Bertrand, C. Frixon, G. Giordano, and F. Blasco, Biochemistry 35:4828-4836, 1996), NarH-C16A and NarH-C263A, oxidation of the NarH [Fe-S] clusters is inhibited compared to the wild type. During enzyme turnover in the mutant enzymes, a distinct 2-n-heptyl-4-hydroxyquinoline-N-oxide-sensitive semiquinone radical species which may be located between the hemes of NarI and the [Fe-S] clusters of NarH is observed. Overall, these studies indicate (i) the importance of the highest-potential [4Fe-4S] cluster in electron transfer from NarH to the molybdenum cofactor of NarG and (ii) that a semiquinone radical species is an important intermediate in electron transfer from quinol to nitrate.

Simultaneous spectrophotometric determination of calcium and magnesium in mineral waters by means of multivariate partial least-squares regression

A method for simultaneous spectrophotometric determination of calcium and magnesium in mineral waters using multivariate calibration methods is proposed. The method is based on the development of the reaction between the analytes and Methylthymol Blue at pH 11. Two operational modes were used: static (spectral information) and flow injection (FI) (spectral and kinetic information). The selection of variables was studied. A series of synthetic solutions containing different concentrations of calcium and magnesium were used to check the prediction ability of the partial least-squares models. The method was applied to the analysis of mineral waters and the results were compared with those obtained by complexometry. No significant differences at the 95% confidence level were found. The proposed method is simple, accurate and reproducible, and it could be easily adapted as a portable (static mode) or automatic (FI) method.

Organization of the nar genes at the chlZ locus

The two membrane-bound respiratory nitrate reductases of Escherichia coli are encoded by distinct operons at two different loci, chlC and chlZ, on the chromosome. The chlZ locus includes a narK homologue, narU, encoding a nitrite extrusion protein, and narZYWV encoding nitrate reductase Z. No apparent homologue to the narXL operon has been found. Homology between narU and narK on the one hand and narZYWV and narGHJI on the other hand is limited to the coding regions.

Specific serological response by active immunization with GD3-bearing liposomes

GD3 is the most prominent ganglioside on the surface of human melanoma cells, and therefore it has been considered by several investigators as a potential tool for active immunotherapy of melanoma. The main obstacle to this goal is that GD3 is poorly immunogenic in mice and in humans. Several approaches have been described for increasing the GD3 immunogenicity. Here, the immunogenicity of GD3 ganglioside was investigated by vaccination of Balb/c x C57B1/6 F1 mice with several types of GD3-bearing liposomes. The humoral immune response was analyzed by ELISA and tumor cell recognition. Several liposome formulations were assayed in order to increase the immunogenicity of GD3. We also tested vaccinations with GD3-Salmonella minnesota, Freund's complete adjuvant and Bordetella pertussis antigen. Immunization of mice with sphingomyelin:cholesterol:dicetyl-phosphate:GD3, molar ratio 40:40:10:10, liposomes resulted in good IgM and IgG3 anti-GD3 response, with a maximum titer of 1:1200 and absence of significant cross-reactivity with other gangliosides. In immunofluorescence assays, the antisera induced showed high capacity of recognition of melanoma cells with no reactivity against other tumor cells. The results clearly showed a high positive correlation between liposomes with sphingomyelin and GD3 immunoreactivity. The incorporation of muramyl-dipeptide or Lipid A in the liposome formulation increased the secretion of IgM and IgG as well as the nonspecificity of the response.

Complete coordination of the four Fe-S centers of the beta subunit from Escherichia coli nitrate reductase. Physiological, biochemical, and EPR characterization of site-directed mutants lacking the highest or lowest potential [4Fe-4S] clusters

The beta subunit of the nitrate reductase A from Escherichia coli contains four groups of cysteine residues (I-IV) which are thought to bind the four iron-sulfur centers (1-4) of the enzyme. The fourth Cys residue of each group was replaced by Ala by site-directed mutagenesis, which led to the C26A, C196A, C227A, and C263A mutants. Physiological and biochemical effects of the mutations were investigated on both the membrane-bound and the soluble forms of the enzyme. In addition, detailed redox titrations of the mutants were monitored by EPR spectroscopy. The C196A and C227A mutations resulted in the full loss of the four Fe-S clusters and of the Mo-cofactor, leading to inactive enzymes. In contrast, the C26A and C263A mutants retained significant nitrate reductase activities. The EPR analysis showed that the highest redox potential [4Fe-4S] cluster (center 1) was selectively removed by the C263A mutation and that the C26A replacement likely eliminated the lowest potential [4Fe-4S] cluster (center 4). In both mutants, the three remaining Fe-S clusters kept the same spectral and redox properties as in the wild type enzyme. These results enabled the determination of the Cys ligands of center 1 to be completed and led to a proposed model for the coordination of the four Fe-S centers by the four Cys groups of the beta subunit. In this model, the four clusters are organized in two pairs, (center 1, center 4) and (center 2, center 3), which is in good agreement with the magnitude of intercenter magnetic interactions observed by EPR and with the stability of the different mutants. The possible implications on the intramolecular electron transfer pathway are discussed.

Cobalt(II), nickel(II), and copper(II) complexes of sulfanilamide derivatives: synthesis, spectroscopic studies, and antibacterial activity. Crystal structure of [Co(sulfacetamide)2(NCS)2]

The synthesis and characterization of new coordination compounds of Co(II), Ni(II), and Cu(II) with sulfacetamide (N-[4-(amino-fenil)sulfonil]acetamide) is reported. The complex [Co(sulfacetamide)2(NCS)2] crystallizes in the triclinic space group P-1. The cell dimensions are a = 7.80(2) A, b = 8.327(9) A, c = 9.568(3) A, alpha = 90.5(1) degrees, beta = 90.5(1) degrees, gamma = 97.8(2) degrees, V = 616(1) A3, Z = 2, and Dx = 1.689 g/cm3. The final conventional R-factor = 0.039 (Rw = 0.039) for 3535 "observed" reflections and 173 variables. The Co(II) is surrounded in a regular octahedral arrangement by two Nthyocianato from the NCS, two Namino and two Oacetamido atoms from the sulfacetamide. Each sulfacetamide, acting as a bidentate ligand, chelates two Co(II) ions as a bridge through the Namino and the Oacetamido atoms. IR, Reflectance Diffuse, EPR, and magnetic properties of the obtained complexes are discussed. The complexes were screened for their activity against E. Coli and S. aureus, showing an appreciable antimicrobial activity compared with the ligands.

Kinetic studies of a soluble alpha beta complex of nitrate reductase A from Escherichia coli. Use of various alpha beta mutants with altered beta subunits

A soluble alpha beta complex of nitrate reductase can be obtained from a strain of Escherichia coli that lacks the narI gene and expresses only the alpha and beta subunits. The beta subunit contains four Fe-S centres and the alpha subunit contains the molybdenum cofactor, which is the site at which nitrate is reduced. Despite the lack of the gamma subunit of the complete enzyme, this complex can still catalyse the reduction of nitrate with artificial electron donors such as benzyl viologen, so that it is suitable for studying the transfer of electrons between these two types of redox centre. To examine whether the electrons from reduced benzyl viologen are initially delivered to the Fe-S centres, or directly to the molybdenum cofactor, or both, we have studied the steady-state kinetics and the binding of benzyl viologen to the alpha beta complex and mutants alpha beta* with altered beta subunits. Reduction of the enzyme by reduced benzyl viologen in the absence of nitrate showed that all four Fe-S centres and the molybdenum cofactor could be reduced. Two classes of site with different equilibrium constants could be distinguished. The kinetic results suggest that benzyl viologen supplies its electrons directly to the molybdenum cofactor, at a rate showing a hyperbolic dependence on the square of the concentration of the electron donor. A reaction mechanism is proposed for the reduction of nitrate catalysed by the alpha beta complex of nitrate reductase with artificial electron donors.

Synthesis and spectroscopy studies of copper(II) nitrate of sulfacetamide drug. Crystal structure of [Cu(sulfacetamide)2(NO3)2]. Antibacterial studies

The structural spectroscopic, and thermal properties of a complex of sulfacetamide (Hsacm) with Cu(II) have been investigated. The complex [Cu(Hsacm)2(NO3)2] crystallizes in the monoclinic system, space group P2(1)/n. The cell dimensions are a = 7.696(7) A, b = 8.017(7) A, c = 19.230(10), beta = 110.80(1) degree, V = 1109(1) A3, Z = 2, and Dx = 1.84 g/cm3. The structure was refined to R = 0.0776. Cu(Hsacm)2(NO3)2 molecules form a long polymeric chain extended along the b-axis. The copper(II) coordinated geometry is tetragonally distorted octahedral with two amino nitrogens from Hsacm and two oxygens from nitrato anions in the basal plane and two acetamido oxygens from neighbor Hsacm molecules in the apical position. Each sulfacetamide, acting as a bidentate ligand, links two Cu(II) ions as a bridge through the Namino and the Oacetamido atoms. The complex proved to possess higher bacteriostatic activity than the corresponding ligand.

Molecular genetic analysis of the moa operon of Escherichia coli K-12 required for molybdenum cofactor biosynthesis

A 3.2 kb chromosomal DNA fragment which complements the defects in a series of twelve moa::Mucts insertion mutants has been sequenced. Five open reading frames (ORFs) were identified and these are arranged in a manner consistent with their forming an operon. The encoded proteins (MoaA-MoaE) have predicted molecular weights of 37,346, 18,665, 17,234, 8843 and 16,981 respectively. Examination of subclones of the whole locus in an expression system demonstrated the predicted products. N-terminal amino acid sequences for the moaA, B, C and E products confirmed the translational starts. Genetic analysis distinguished four classes of moa mutants corresponding to genes moaA, C, D and E. Potential promoter sequences upstream of moaA and a possible transcription termination signal have been identified. Genetic analysis of the chlA1 and chlM mutants, which have been biochemically characterized as defective in molybdopterin biosynthesis, indicates that these carry lesions in moaA and moaD respectively. The moa locus is orientated clockwise at 17.7 minutes in the chromosome.

Removal of the high-potential [4Fe-4S] center of the beta-subunit from Escherichia coli nitrate reductase. Physiological, biochemical, and EPR characterization of site-directed mutated enzymes

The beta-subunit of the nitrate reductase of Escherichia coli contains four groups of Cys residues (I-IV) which are thought to bind the single [3Fe-4S] center and the three [4Fe-4S] centers. The first or second Cys residue of group I was substituted by site-directed mutagenesis with Ala or Ser. Physiological, biochemical, and EPR studies were performed on the mutated enzymes. With small variations, the properties of these mutant enzymes do not differ from one another. They were found to be as abundant and as stably bound to the membrane as the native enzyme, provided the gamma-subunit was present. Although physiological activity was reduced, it was sufficient to allow growth on nitrate. The study of variations in EPR intensity as a function of the redox potential indicated that these enzymes only contained three iron-sulfur centers instead of the usual four in the native enzyme. Spectral EPR analysis showed that the [4Fe-4S] center of high redox potential (center 1, +80 mV) was missing. The loss of this center did not affect the stable integration of the other three centers. The data presented here are in total contrast to those we have reported for each of the other three centers (centers 2-4), the loss of which was detrimental to the integration of all centers and to the integration of the molybdenum cofactor (Augier et al., in press). Taken together, our results demonstrated that the first and second Cys residues of group I are the ligands of the [4Fe-4S] center (center 1, +80 mV) and that this center participates in electron transfer, but is dispensable. On the basis of these results, it is proposed that the [3Fe-4S] center (center 2, +60 mV) also plays a biological role and that in the native enzyme both high-potential centers, centers 1 and 2, contribute independently and in parallel to the electron transfer to the molybdenum cofactor.

Site-directed mutagenesis of conserved cysteine residues within the beta subunit of Escherichia coli nitrate reductase. Physiological, biochemical, and EPR characterization of the mutated enzymes

We have used site-directed mutagenesis to alter the ligands to the iron-sulfur centers of Escherichia coli nitrate reductase A. The beta subunit of this enzyme contains four Cys groups which are thought to accommodate the single [3Fe-4S] center and the three [4Fe-4S] centers involved in the electron-transfer process from quinol to nitrate. The third Cys group (group III) contains a Trp at a site occupied by a Cys residue in typical ferredoxin arrangements or in the DmsB subunit of dimethyl sulfoxide (DMSO) reductase. In an attempt to determine the coordination site of the different iron-sulfur centers in the amino acid sequence, we have changed the Trp of group III to Cys, Ala, Phe, and Tyr and the first Cys residue of groups II-IV to Ala and Ser. Physiological, biochemical, and EPR studies were performed on the mutated enzymes. Substitution of Ala for either Cys184, Cys217, or Cys244 results in the full loss of all four iron-sulfur centers present in the wild-type enzyme. These inactive enzymes still possess the alpha,beta, and gamma polypeptides associated in a membrane-bound complex. These Cys have important structural roles and are very likely involved in the coordination of the iron-sulfur centers. Substitution of Cys184 with a Ser residue produces an enzyme containing the four iron-sulfur centers, but displaying reduced activity. EPR studies suggest that Cys184 is a ligand of the [4Fe-4S] center whose midpoint potential is -200 mV in the native enzyme. All substitutions performed in this study on Trp220 lead to mutant enzymes harboring the four iron-sulfur centers and a nitrate reductase activity close to that of the wild-type. In spite of the high similarity between the NarH and DmsB subunits, the Trp220-->Cys substitution does not allow the conversion of the [3Fe-4S] center of the nitrate reductase into a [4Fe-4S] center. Therefore, Trp220 does not seem to play any major role in the beta subunit.

EPR and redox characterization of iron-sulfur centers in nitrate reductases A and Z from Escherichia coli. Evidence for a high-potential and a low-potential class and their relevance in the electron-transfer mechanism

The redox properties of the iron-sulfur centers of the two nitrate reductases from Escherichia coli have been investigated by EPR spectroscopy. A detailed study of nitrate reductase A performed in the range +200 mV to -500 mV shows that the four iron-sulfur centers of the enzyme belong to two classes with markedly different redox potentials. The high-potential group comprises a [3Fe-4S] and a [4Fe-4S] cluster whose midpoint potentials are +60 mV and +80 mV, respectively. Although these centers are magnetically isolated, they are coupled by a significant anticooperative redox interaction of about 50 mV. The [4Fe-4S]1+ center occurs in two different conformations as shown by its composite EPR spectrum. The low-potential group contains two [4Fe-4S] clusters with more typical redox potentials (-200 mV and -400 mV). In the fully reduced state, the three [4Fe-4S]1+ centers are magnetically coupled, leading to a broad featureless spectrum. The redox behaviour of the high-pH EPR signal given by the molybdenum cofactor was also studied. The iron-sulfur centers of the second nitrate reductase of E. coli, nitrate reductase Z, exhibit essentially the same characteristics than those of nitrate reductase A, except that the midpoint potentials of the high-potential centers appear negatively shifted by about 100 mV. From the comparison between the redox centers of nitrate reductase and of dimethylsulfoxide reductase, a correspondence between the high-potential iron-sulfur clusters of the two enzymes can be proposed.

Formation of active heterologous nitrate reductases between nitrate reductases A and Z of Escherichia coli

Two nitrate reductases, NRA and NRZ, are present in Escherichia coli. These isoenzymes have the same alpha beta gamma, subunits composition and have similar size and genetic organization. Corresponding subunits of the complexes share at least 75% identity. By subcloning the different genes and expressing them from separate transcriptional units, we have demonstrated (i) that the translation of the subunits and their assembly are not coupled processes, since subunits produced concomitantly but independently can meet efficiently and associate to form active enzymes, and (ii) that the alpha subunit of a given complex can be replaced by its counterpart from the other isoenzyme to yield an active membrane-bound heterologous enzyme. One such heterologous enzyme, alpha A beta Z gamma Z, has been purified; it is less stable than the native enzymes, more susceptible to thermal denaturation, and shows increased sensitivity to proteolysis. It is also less stably bound to the membrane and, consequently, its activity with physiological electron donors is drastically reduced. The possibility that heterologous nitrate reductases could be formed in vivo is discussed with reference to the existence of porin heterotrimers of the outer membrane proteins OmpC, OmpF and PhoE.