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.     

Twin-arginine translocase may have a role in the chaperone function of NarJ from Escherichia coli

NarJ is a chaperone involved in folding, maturation, and molybdenum cofactor insertion of nitrate reductase A from Escherichia coli. It has also been shown that NarJ exhibits sequence homology to a family of chaperones involved in maturation and cofactor insertion of E. coli redox enzymes that are mediated by twin-arginine translocase (Tat) dependent translocation. In this study, we show that NarJ binds the N-terminal region of NarG through Far Western studies and isothermal titration calorimetry, and the binding event occurs towards a short peptide sequence that contains a homologous twin-arginine motif. Fractionation experiments also show that the interaction of NarJ to the cytoplasmic membrane exhibits Tat-dependence. Upon further investigation through Far Western blots, the interactome of NarJ also exhibits Tat-dependence. Together the data suggest that the Tat system may play a role in the maturation pathway of nitrate reductase A.     

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.     

Sequence analysis of bacterial redox enzyme maturation proteins (REMPs)

The twin-arginine protein transport (Tat) system is a remarkable molecular machine dedicated to the translocation of fully folded proteins across energy-transducing membranes. Complex cofactor-containing Tat substrates acquire their cofactors prior to export, and substrate proteins actually require to be folded before transport can proceed. Thus, it is very likely that mechanisms exist to prevent wasteful export of immature Tat substrates or to curb competition between immature and mature substrates for the transporter. Here we assess the primary sequence relationships between the accessory proteins implicated in this process during assembly of key respiratory enzymes in the model prokaryote Escherichia coli. For each respiratory enzyme studied, a redox enzyme maturation protein (REMP) was assigned. The main finding from this review was the hitherto unexpected link between the Tat-linked REMP DmsD and the nitrate reductase biosynthetic protein NarJ. The evolutionary link between Tat transport and cofactor insertion processes is discussed.     

A dual functional redox enzyme maturation protein for respiratory and assimilatory nitrate reductases in bacteria

Nitrate is available to microbes in many environments due to sustained use of inorganic fertilizers on agricultural soils and many bacterial and archaeal lineages have the capacity to express respiratory (Nar) and assimilatory (Nas) nitrate reductases to utilize this abundant respiratory substrate and nutrient for growth. Here, we show that in the denitrifying bacterium Paracoccus denitrificans, NarJ serves as a chaperone for both the anaerobic respiratory nitrate reductase (NarG) and the assimilatory nitrate reductase (NasC), the latter of which is active during both aerobic and anaerobic nitrate assimilation. Bioinformatic analysis suggests that the potential for this previously unrecognized role for NarJ in functional maturation of other cytoplasmic molybdenum‐dependent nitrate reductases may be phylogenetically widespread as many bacteria contain both Nar and Nas systems.     

The narJ gene product is required for biogenesis of respiratory nitrate reductase in Escherichia coli.

Respiratory nitrate reductase purified from the cell membrane of Escherichia coli is composed of three subunits, alpha, beta, and gamma, which are encoded, respectively, by the narG, narH, and narI genes of the narGHJI operon. The product of the narJ gene was deduced previously to be a highly charged, acidic protein which was not found to be associated with any of the purified preparations of the enzyme and which, in studies with putative narJ mutants, did not appear to be absolutely required for formation of the membrane-bound enzyme. To test this latter hypothesis, the narJ gene was disrupted in a plasmid which contained the complete narGHJI operon, and the operon was expressed in a narG::Tn10 insertion mutant. The chromosomal copy of the narJ gene of a wild-type strain was also replaced by the disrupted narJ gene. In both cases, when nar operon expression was induced, the alpha and beta subunits accumulated in a form which expressed only very low activity with either reduced methyl viologen (MVH) or formate as electron donors, although an alpha-beta complex separated from the gamma subunit is known to catalyze full MVH-linked activity but not the formate-linked activity associated with the membrane-bound complex. The low-activity forms of the alpha and beta subunits also accumulated in the absence of the NarJ protein when the gamma subunit (NarI) was provided from a multicopy plasmid, indicating that NarJ is essential for the formation of the active, membrane-bound complex. When both NarJ and NarI were provided from a plasmid in the narJ mutant, fully active, membrane-bound activity was formed. When NarJ only was provided from a plasmid in the narJ mutant, a cytosolic form of the alpha and beta subunits, which expressed significantly increased levels of the MVH-dependent activity, accumulated, and the alpha subunit appeared to be protected from the proteolytic clipping which occurred in the absence of NarJ. We conclude that NarJ is indispensible for the biogenesis of membrane-bound nitrate reductase and is involved either in the maturation of a soluble, active alpha-beta complex or in facilitating the interaction of the complex with the membrane-bound gamma subunit.     

Substrate-dependent modulation of the enzymatic catalytic activity: Reduction of nitrate, chlorate and perchlorate by respiratory nitrate reductase from Marinobacter hydrocarbonoclasticus 617

The respiratory nitrate reductase complex (NarGHI) from Marinobacter hydrocarbonoclasticus 617 (Mh, formerly Pseudomonas nautica 617) catalyzes the reduction of nitrate to nitrite. This reaction is the first step of the denitrification pathway and is coupled to the quinone pool oxidation and proton translocation to the periplasm, which generates the proton motive force needed for ATP synthesis. The Mh NarGH water-soluble heterodimer has been purified and the kinetic and redox properties have been studied through in-solution enzyme kinetics, protein film voltammetry and spectropotentiometric redox titration. The kinetic parameters of Mh NarGH toward substrates and inhibitors are consistent with those reported for other respiratory nitrate reductases. Protein film voltammetry showed that at least two catalytically distinct forms of the enzyme, which depend on the applied potential, are responsible for substrate reduction. These two forms are affected differentially by the oxidizing substrate, as well as by pH and inhibitors. A new model for the potential dependence of the catalytic efficiency of Nars is proposed.     

Differential effects of a molybdopterin synthase sulfurylase (moeB) mutation on Escherichia coli molybdoenzyme maturation.

We have generated a chromosomal mutant of moeB (moeBA228T) that demonstrates limited molybdenum cofactor (molybdo-bis(molybdopterin guanine dinucleotide) (Mo-bisMGD)) availability in Escherichia coli and have characterized its effect on the maturation and physiological function of two well-characterized respiratory molybdoenzymes: the membrane-bound dimethylsulfoxide (DMSO) reductase (DmsABC) and the membrane-bound nitrate reductase A (NarGHI). In the moeBA228T mutant strain, E. coli F36, anaerobic respiratory growth is possible on nitrate but not on DMSO, indicating that cofactor insertion occurs into NarGHI but not into DmsABC. Fluorescence analyses of cofactor availability indicate little detectable cofactor in the moeBA228T mutant compared with the wild-type, suggesting that NarGHI is able to scavenge limiting cofactor, whereas DmsABC is not. MoeB functions to sulfurylate MoaD, and in the structure of the MoeB-MoaD complex, Ala-228 is located in the interface region between the two proteins. This suggests that the moeBA228T mutation disrupts the interaction between MoeB and MoaD. In the case of DmsABC, despite the absence of cofactor, the twin-arginine signal sequence of DmsA is cleaved in the moeBA228T mutant, indicating that maturation of the holoenzyme is not cofactor-insertion dependent.     

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.     

Conformational Selection Underlies Recognition of a Molybdoenzyme by Its Dedicated Chaperone

Molecular recognition is central to all biological processes. Understanding the key role played by dedicated chaperones in metalloprotein folding and assembly requires the knowledge of their conformational ensembles. In this study, the NarJ chaperone dedicated to the assembly of the membrane-bound respiratory nitrate reductase complex NarGHI, a molybdenum-iron containing metalloprotein, was taken as a model of dedicated chaperone. The combination of two techniques ie site-directed spin labeling followed by EPR spectroscopy and ion mobility mass spectrometry, was used to get information about the structure and conformational dynamics of the NarJ chaperone upon binding the N-terminus of the NarG metalloprotein partner. By the study of singly spin-labeled proteins, the E119 residue present in a conserved elongated hydrophobic groove of NarJ was shown to be part of the interaction site. Moreover, doubly spin-labeled proteins studied by pulsed double electron-electron resonance (DEER) spectroscopy revealed a large and composite distribution of inter-label distances that evolves into a single preexisting one upon complex formation. Additionally, ion mobility mass spectrometry experiments fully support these findings by revealing the existence of several conformers in equilibrium through the distinction of different drift time curves and the selection of one of them upon complex formation. Taken together our work provides a detailed view of the structural flexibility of a dedicated chaperone and suggests that the exquisite recognition and binding of the N-terminus of the metalloprotein is governed by a conformational selection mechanism.     

<Emphasis Type="Italic">Haloarcula marismortui</Emphasis> cytochrome <Emphasis Type="Italic">b-</Emphasis>561 is encoded by the <Emphasis Type="Italic">narC</Emphasis> gene in the dissimilatory nitrate reductase operon

The composition of membrane-bound electron-transferring proteins from denitrifying cells of Haloarcula marismortui was compared with that from the aerobic cells. Accompanying nitrate reductase catalytic NarGH subcomplex, cytochrome b-561, cytochrome b-552, and halocyanin-like blue copper protein were induced under denitrifying conditions. Cytochrome b-561 was purified to homogeneity and was shown to be composed of a polypeptide with a molecular mass of 40 kDa. The cytochrome was autooxidizable and its redox potential was −27 mV. The N-terminal sequence of the cytochrome was identical to the deduced amino acid sequence of the narC gene product encoded in the third ORF of the nitrate reductase operon with a unique arrangement of ORFs. The sequence of the cytochrome was homologous with that of the cytochrome b subunit of respiratory cytochrome bc. A possibility that the cytochrome bc and the NarGH constructed a supercomplex was discussed.     

‘Come into the fold’: A comparative analysis of bacterial redox enzyme maturation protein members of the NarJ subfamily

Redox enzyme maturation proteins (REMPs) are system-specific chaperones required for the maturation of complex iron sulfur molybdoenzymes that are important for anaerobic respiration in bacteria. Although they perform similar biological roles, REMPs are strikingly different in terms of sequence, structure, systems biology, and type of terminal electron acceptor that it supports for growth. Here we critically dissect current knowledge pertaining to REMPs of the nitrate reductase delta superfamily, specifically recognized in Escherichia coli to include NarJ, NarW, TorD, DmsD, and YcdY, also referred to as the NarJ REMP subfamily. We show that NarJ subfamily members share sequence homology and similar structural features as revealed by alignments performed on structurally characterized REMPs. We include an updated phylogenetic analysis of subfamily members, justifying their classification in this subfamily. The structural and functional roles of each member are presented herein and these discussions suggest that although NarJ subfamily members are related in sequence and structure, each member demonstrates remarkable uniqueness, validating the concept of system-specific chaperones.     

Catalytic protein film voltammetry from a respiratory nitrate reductase provides evidence for complex electrochemical modulation of enzyme activity

The first step in the respiratory reduction of nitrate to dinitrogen in Paracoccus pantotrophus is catalyzed by the quinol-nitrate oxidoreductase NarGHI. This membrane-anchored protein directs electrons from quinol oxidation at the membrane anchor, NarI, to the site of nitrate reduction in the membrane extrinsic [Fe-S] cluster and Mo-bis-MGD containing dimer, NarGH. Liberated from the membrane, NarGH retains its nitrate reductase activity and forms films on graphite and gold electrodes within which direct and facile exchange of electrons between the electrode and the enzyme occurs. Protein film voltammetry has been used to define the catalytic behavior of NarGH in the potential domain and a complex pattern of reversible, nitrate concentration dependent modulation of activity has been resolved. At low nitrate concentrations the local maximum observed in the catalytic current-potential profile reveals how NarGH can catalyze nitrate reduction via two pathways having distinct specificity constants, k(obs)(cat)/K(obs)(M). Catalysis is directed to occur via one of the pathways by an electrochemical event within NarGH. On increasing the nitrate concentration, the local maximum in the catalytic current becomes less distinct, and the catalytic waveform adopts an increasingly sigmoidal form. A pattern of voltammetry similar to that observed during nitrate reduction is observed during reduction of the stereochemically distinct substrate chlorate. Centers whose change of oxidation state may define the novel catalytic voltammetry of NarGH have been identified by EPR-monitored potentiometric titrations and mechanisms by which the electrochemistry of Mo-bis-MGD or [Fe-S] clusters can account for the observed behavior are discussed.     

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.     

Involvement of the narJ and mob gene products in distinct steps in the biosynthesis of the molybdoenzyme nitrate reductase in Escherichia coli

The Escherichia coli mob locus is required for synthesis of active molybdenum cofactor, molybdopterin guanine dinucleotide. The mobB gene is not essential for molybdenum cofactor biosynthesis because a deletion of both mob genes can be fully complemented by just mobA. Inactive nitrate reductase, purified from a mob strain, can be activated in vitro by incubation with protein FA (the mobA gene product), GTP, MgCl₂, and a further protein fraction, factor X. Factor X activity is present in strains that lack MobB, indicating that it is not an essential component of factor X, but over-expression of MobB increases the level of factor X. MobB, therefore, can participate in nitrate reductase activation. The narJ protein is not a component of mature nitrate reductase but narJ mutants cannot express active nitrate reductase A. Extracts from narJ strains are unable to support the in vitro activation of purified mob nitrate reductase: they lack factor X activity. Although the mob gene products are necessary for the biosynthesis of all E. coli molybdoenzymes as a result of their requirement for molybdopterin guanine dinucleotide, NarJ action is specific for nitrate reductase A. The inactive nitrate reductase A derivative in a narJ strain can be activated in vitro following incubation with cell extracts containing the narJ protein. NarJ acts to activate nitrate reductase after molybdenum cofactor biosynthesis is complete.     

The succinate dehydrogenase assembly factor,SdhE, is required for the flavinylation and activation of fumarate reductase in bacteria

The activity of the respiratory enzyme fumarate reductase (FRD) is dependent on the covalent attachment of the redox cofactor flavin adenine dinucleotide (FAD). We demonstrate that the FAD assembly factor SdhE, which flavinylates and activates the respiratory enzyme succinate dehydrogenase (SDH), is also required for the complete activation and flavinylation of FRD. SdhE interacted with, and flavinylated, the flavoprotein subunit FrdA, whilst mutations in a conserved RGxxE motif impaired the complete flavinylation and activation of FRD. These results are of widespread relevance because SDH and FRD play an important role in cellular energetics and are required for virulence in many important bacterial pathogens.     

Dedicated metallochaperone connects apoenzyme and molybdenum cofactor biosynthesis components

The biogenesis of molybdenum-containing enzymes is a sophisticated process involving the insertion of a complex molybdenum cofactor into competent apoproteins. As for many molybdoenzymes, the maturation of trimethylamine-oxide reductase TorA requires a private chaperone. This chaperone (TorD) interacts with the signal peptide and the core of apo-TorA. Using random mutagenesis, we established that alpha-helix 5 of TorD plays a key role in the core binding and that this binding drives the maturation of TorA. In addition, we showed for the first time that TorD interacts with molybdenum cofactor biosynthesis components, including MobA, the last enzyme of cofactor synthesis, and Mo-molybdopterin, the precursor form of the cofactor. Finally we demonstrated that TorD also binds the mature molybdopterin-guanine dinucleotide form of the cofactor. We thus propose that TorD acts as a platform connecting the last step of the synthesis of the molybdenum cofactor just before its insertion into the catalytic site of TorA.     

Presence of the molybdenum-cofactor in nitrate reductase-deficient mutant cell lines of Nicotiana tabacum

Summary Nicotiana tabacum mutant cell cultures lacking nitrate reductase activity were assayed for the presence of the molybdenum-cofactor using its ability to restore NADPH-nitrate reductase activity in extracts of Neurospora crassa nit-1 mycelia. The molybdenum-cofactor of the tobacco wild-type line was shown to complement efficiently the N. crassa nit-1 mutant in vitro. The molybdenum-cofactor seems to exist in a bound form, as acid-treatment was required for release of cofactor activity. Molybdate (5–10 mM), ascorbic acid, and anaerobic conditions greatly increased the activity of the cofactor, demonstrating its high lability and sensitivity to oxygen. Similar results were obtained with two tobacco nia mutants, which are defective in the apoprotein of nitrate reductase. The four cnx mutants studied were shown to contain exclusively an inactive form of the molybdenum-cofactor. This inactive cofactor could be reactivated in vitro and in vivo by unphysiologically high concentrations of molybdate (1–10 mM), thereby converting the cnx cells into highly active cofactor sources in vitro, and restoring nitrate reductase and xanthine dehydrogenase in vivo to partial acitivity. Thus the defect of the cnx mutants resides in a lack of molybdenum as a catalytically active ligand metal for the cofactor, while the structural moiety of the cofactor seems not to be impaired by the mutation. The subunit assembly of the nitrate reductase was found to be independent of the molybdenum content of the cofactor.