Isolation and Properties of the Complex between the Enhancer Binding Protein NIFA and the Sensor NIFL

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Journal of Bacteriology, August 1999, p. 4461-4468, Vol. 181, No. 15
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Isolation and Properties of the Complex between the Enhancer Binding Protein NIFA and the Sensor NIFL

Tracy Money, Tamera Jones, Ray Dixon, and Sara Austin^*

Nitrogen Fixation Laboratory, John Innes Centre, Norwich Research Park, Colney, Norwich NR4 7UH, Norfolk, United Kingdom

Received 22 February 1999/Accepted 13 May 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

In Azotobacter vinelandii, activation of nif gene expression by the transcriptional regulatory enhancer binding protein NIFAis controlled by the sensor protein NIFL in response to changesin levels of oxygen and fixed nitrogen in vivo. NIFL is a novelredox-sensing flavoprotein which is also responsive to adenosinenucleotides in vitro. Inhibition of NIFA activity by NIFL requiresstoichiometric amounts of the two proteins, implying that themechanism of inhibition is by direct protein-protein interactionrather than by catalytic modification of the NIFA protein. Theformation of the inhibitory complex between NIFL and NIFA maybe regulated by the intracellular ATP/ADP ratio. We show thatadenosine nucleotides promote complex formation between purifiedNIFA and NIFL in vitro, allowing isolation of the NIFL-NIFA complex.The complex can also be isolated from cell extracts containingcoexpressed NIFL and NIFA in the presence of MgADP. Removal ofthe nucleotide causes dissociation of the complex. Experimentswith truncated proteins demonstrate that the amino-terminal domainof NIFA and the C-terminal region of NIFL potentiate the ADP-dependentstimulation of NIFL-NIFA complexformation.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The enhancer binding protein NIFA and the sensor protein NIFL comprise an atypical two-component regulatory system which regulatesthe expression of genes involved in nitrogen fixation in the free-livingdiazotrophs Klebsiella pneumoniae and Azotobacter vinelandii.The NIFA protein activates transcription from $sigma$ ^N-dependent nif promoters in combination with $sigma$ ^N RNA polymerase holoenzyme, and its activity is repressed by theNIFL protein in response to increases in the levels of fixed nitrogenand extracellular oxygen (6). We have shown previously thatA. vinelandii NIFL is a flavoprotein with flavin adenine dinucleotide(FAD) as the prosthetic group (13), and this has now been demonstratedfor the K. pneumoniae protein (21). The oxidized form of NIFLis competent to inhibit NIFA activity, but reduction of the flavinmoiety in NIFL abolishes its ability to inhibit NIFA. Thus, NIFLacts as a redox-sensitive molecular switch to regulate NIFA activity.The inhibitory activity of NIFL is also stimulated by adenosinenucleotides in vitro, suggesting that it may sense energy chargein vivo (8). The response to nucleotides overrides the redoxswitch. Forms of NIFL which lack the flavin moiety are still ableto inhibit NIFA activity in response to ADP (13). We have shownrecently that the C-terminal domain of NIFL binds nucleotides,and it is possible that this domain has evolved from a classicalhistidine protein kinase to a nucleotide-responsive domain (23).This domain may also contain sequences required for interactionwith NIFA, and it is possible that the formation of the inhibitorycomplex between NIFL and NIFA may be regulated by the ATP/ADPratio.

The NIFL protein is comprised of two domains tethered by a Q linker (5, 7, 26). The proposed amino-terminal domaincontains the flavin binding site and shows some homology to otheroxygen- and redox-sensing proteins (5). A motif consistingof two conserved regions termed S boxes has recently been identifiedin the amino-terminal domain of NIFL. This motif is found in thePAS domains of a wide range of sensory proteins in both prokaryoticand eukaryotic organisms and may be involved in transducing environmentalsignals to other domains of the protein (24, 27). In the caseof NIFL, the PAS domains may contain the ligands for flavinbinding.

The C-terminal domain of A. vinelandii NIFL has significant homology to the histidine protein kinase transmitter domains,including the region containing the conserved histidine residue.However, there is no evidence for any phosphotransfer occurringbetween NIFA and NIFL, and signal transduction is believed tooccur via protein-protein interaction (2, 15). We have shownpreviously with cell extracts from K. pneumoniae that both proteinscan be immunoprecipitated by antisera to either NIFA or NIFL,implying the formation of a complex (12). This is consistentwith the requirement for a stoichiometric concentration of eachprotein for effective inhibition of NIFA activity in vivo (9-11)and in vitro (2). We have now demonstrated the existence ofthe A. vinelandii NIFL-NIFA complex by cochromatography experimentswith histidine-tagged forms of the proteins. We show here thatthe presence of adenosine nucleotides promotes the formation ofthe NIFL-NIFA complex. We have characterized the isolated complexand assessed the ability of truncated fragments and domains ofNIFA and NIFL to undergo complex formation in response toADP.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Protein purification. The native forms of NIFL and NIFA were purified as described previously (2). The C-terminal hexahistidine-tagged formsof NIFL and NIFA and the truncated derivatives were purified bynickel affinity chromatography on Hi-trap chelating columns (Pharmacia)as recommended by the manufacturer. For the native and histidine-taggedNIFA proteins, 50 mM potassium thiocyanate was routinely addedto the chromatography buffers to inhibit precipitation. Integrationhost factor (IHF) and K. pneumoniae $sigma$ ^N were purified as described previously (23). Escherichia colicore RNA polymerase was purchased from EpicentreTechnologies.

For molecular mass estimation, the preformed NIFL-NIFA complex or the individual proteins were chromatographed on a Superose12 gel filtration column (Pharmacia) which had previously beencalibrated with molecular weight standards as described in thelegend to Fig. 7.

Transcription assays. Single-round transcription assays were performed with purified proteins as described previously (2) except that 4 mM GTPwas added in the absence of the other nucleotides to allow opencomplexes to form prior to heparin challenge. The template DNA(10 nM) was pNH8, which carries the nifH promoter and upstreambinding sites for NIFA and IHF. NIFA was used at 150 nM, IHF at50 nM, core RNA polymerase at 50 nM, and $sigma$ ^N at 200nM.

NIFL-NIFA complex formation assay. Reactions were carried out in Tris acetate buffer containing containing 50 mM Tris acetate (pH 7.9), 100 mM potassium acetate,and 8 mM magnesium acetate. NIFA and NIFL and their truncatedderivatives were used at concentrations between 2 and 8 µM asstated in the figure legends. Nucleotides were used at 1 mM unlessstated otherwise. Reaction mixtures (final volume, 230 µl) werepreincubated for 5 min at 30°C and then loaded onto a 1-ml HiTrap chelating column (Pharmacia) which had been charged withNiCl₂ and equilibrated in buffer containing 50 mM Tris acetate(pH 7.9), 300 mM NaCl, 20 mM imidazole, and 5% glycerol. Wherenucleotides were present in the reaction mixtures, they were addedat the same concentrations to the chromatography buffers to preventdissociation of NIFL-NIFA complexes. Nonbinding protein was washedfrom the column with the equilibration buffer, and bound materialwas then eluted with equilibration buffer containing 500 mM imidazole.Aliquots of the fractions were either mixed directly with sodiumdodecyl sulfate (SDS)-polyacrylamide gel electrophoresis samplebuffer or pooled and concentrated before electrophoresis. Electrophoresiswas carried out with 10% polyacrylamide-SDS gels unless statedotherwise in thetext.

Isolation of the NIFL-NIFA complex from cell extracts. Expression of nifL and nifA was induced in 1-liter cultures of aerobically grown E. coli BL21(DE3)(pLysS) carrying plasmidpPR38 (23). Addition of 1 mM IPTG (isopropyl- $beta$ -D-galactopyranoside)for 3 h at 28°C resulted in synthesis of approximately stoichiometricamounts of NIFL and NIFA. Crude cell extract was obtained by Frenchpressure cell disruption in a buffer containing 50 mM Tris-Cl(pH 8), 300 mM NaCl, 1 mM MgADP, 50 mM potassium thiocyanate,5% (wt/vol) glycerol, and 1 mM Pefabloc, followed by low-speedcentrifugation of the resultant lysate. Under these conditions,at least 50% of the overexpressed protein stayed in the supernatantfraction. This was loaded onto a 1-ml Hitrap chelating affinitycolumn which had been charged with NiCl₂ and equilibrated in startbuffer containing 50 mM Tris-Cl (pH 8), 300 mM NaCl, 20 mM imidazole,5% (wt/vol) glycerol, 50 mM potassium thiocyanate, and 1 mM MgADP.The nonbinding protein was washed from the column with start buffer,and the bound fractions were eluted with start buffer containing500 mM imidazole. The fractions containing the NIFL-NIFA complexwere pooled and dialyzed into storage buffer containing 10 mMTris-Cl (pH 8), 50% glycerol, 0.1 mM EDTA, 0.1 mM dithiothreitol,50 mM NaCl, 500 µM MgADP, and 50 mM potassium thiocyanate. Thedialyzed protein was stored in small aliquots in liquid N₂.

Molecular mass estimation of the NIFL-NIFA complex. Approximately 250 µg of either preformed NIFL-NIFA complex or purified NIFA or NIFL alone were chromatographed on a Superose12 column equilibrated in 10 mM Tris-Cl (pH 8), 10% glycerol,0.1 mM EDTA, 0.1 mM dithiothreitol, and 150 mM NaCl. MgADP waspresent in the buffers where indicated at 500 µM. The in vitro-formedcomplex was prepared by mixing equimolar amounts of purified NIFLand NIFA with 500 µM MgADP prior to loading it on the column.NIFA and NIFL were also mixed separately with 500 µM MgADP andchromatographed as controls. A duplicate set of samples were thenchromatographed in the absence of nucleotide. The NIFL-NIFA complexisolated from cell extract in the presence of 1 mM MgADP was dividedinto two aliquots and briefly dialyzed in the presence and absenceof 500 µM MgADP before application to the column. The chromatographicbehavior of these samples was compared to that of NIFL and NIFA,which had been dissociated from each other on the nickel columnby removal of thenucleotide.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

The complex between NIFL and NIFA formed in vitro is stimulated by the presence of adenosine nucleotides. A binding assay with metal chelate affinity chromatography on nickel columns and histidine-tagged forms of purified NIFA orNIFL was employed to determine conditions which allowed coelutionof the tagged version of one protein with its nontagged partnerfrom the column. Equimolar concentrations of the proteins wereused in the assays, assuming that both proteins are tetramersin solution (23) (Table 1). The proteins were incubated togetherin Tris acetate buffer consistent with the conditions used tomeasure inhibition of NIFA activity by NIFL. Reactions were carriedout as described in Materials and Methods in the presence or absenceof nucleotide with the native nontagged form of NIFA and C-terminalNIFL_6his. In control experiments in the absence of NIFL_6his, nontaggedNIFA was eluted from the column in the wash fractions. However,the NIFA protein showed a tendency to bind nonspecifically tothe column and required extensive washing with 20 mM imidazolebuffer to eliminate it completely. The presence of nucleotidesdid not affect the chromatographic behavior of the individualproteins. In the absence of nucleotide, most of the NIFA did notform a stable complex with NIFL_6his and was eluted in the washfractions (Fig. 1a). A small amount of NIFA coeluted with NIFLin the absence of nucleotides in some experiments. This may bedue to the tendency of nontagged NIFA to bind nonspecificallyto the column as described above or may result from the formationof unstable NIFL-NIFA complex in the absence of nucleotides. Theaddition of 1 mM MgADP to the reaction mixture and column buffersresulted in NIFA binding to NIFL and the proteins coeluting at500 mM imidazole (Fig. 1a). At 1 mM MgADP, almost all of the NIFAwas retained by the NIFL on the column, with only trace amountsof NIFA appearing in the wash fractions. Concentrations of MgADPbelow 1 mM were also effective, and an increase in the level ofcomplexes could be detected between 10 and 200 µM nucleotide concentration(Fig. 1c and data not shown). Complexes between NIFL and NIFAwere also observed with 1 mM MgATP $gamma$ S, the nonhydrolyzable analogueof ATP (Fig. 1b), but this was not as effective as ADP at lowerconcentrations. With MgGTP $gamma$ S, the nonhydrolyzable analogue ofGTP, only low levels of complexes were detected at 1 mM concentrationof the analogue (Fig. 1b).

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TABLE 1. Gel filtration of NIFL-NIFA complexes on Superose 12

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FIG. 1. NIFL-NIFA complex formed in the presence of nucleotides. Complexes were formed and chromatographed as described in Materials and Methods. Electrophoresis was carried out on SDS-polyacrylamide gels (10% polyacrylamide). Full-length NIFL_6his and NIFA were used at 2.5 µM, and nucleotides were used at 1 mM. (a) Complex formation with 1 mM MgADP. Lanes 1 to 3 and 9 to 11, wash fractions; lanes 4 to 6 and 12 to 14, fractions containing bound protein which eluted with 0.5 M imidazole. (b) Complex formation with 1 mM MgATP $gamma$ S or GTP $gamma$ S. Lanes 1 to 3 and 10 to 12, wash fractions; lanes 4 to 6 and 13 to 15, fractions containing protein obtained after elution. (C) Complex formation with 200 µM MgADP. Lanes 1 to 3 and 9 to 11, wash fractions; lanes 5 to 6 and 12 to 13, fractions containing protein obtained after elution. (D) Complex formation with 4 mM GTP in the presence and absence of 200 µM MgADP. Lanes 3 to 5 and 10 to 12, wash fractions; lanes 6 to 7 and 13 to 14, fractions containing protein obtained after elution. (E) Absorbance spectra of oxidized NIFL in the presence and absence of NIFA and 1 mM MgADP were measured in a Hewlett-Packard diode array spectrophotometer.

We have shown previously that inhibition of NIFA activity by NIFL in assays for open promoter complex formation is observedin the presence of 4 mM GTP and that the inhibition is enhancedby the addition of low concentrations of ADP (8, 23). Underthese conditions in our binding assay, the level of NIFL-NIFAcomplexes detected in the presence of 4 mM MgGTP was similar tothat observed with 1 mM MgGTP $gamma$ S. However, the presence of 200µM MgADP in addition to 4 mM MgGTP resulted in nearly all of theNIFA binding to the NIFL (Fig. 1d). Although these experimentsdo not permit accurate quantitation of the amount of complex formed,qualitatively it would appear that more complex is formed whenboth nucleotides are present and that a correlation exists betweenthe stimulation of the inhibitory effect of NIFL on NIFA activityby ADP and an increase in the level of NIFL-NIFA complexes. Thepresence of RNA polymerase and $sigma$ ^N in the initial incubation mix did not influence the amount ofNIFA bound to NIFL in the presence of ADP (data not shown). Thepresence of NIFA did not alter the spectral features of NIFL eitherin the presence or absence of MgADP, implying that NIFA bindingto NIFL does not change the environment of the bound flavin (Fig.1e). Under the conditions of the assays, NIFL still displays thecharacteristic absorption maximum at 445 nm and shoulders at 420and 470 nm indicative of protein-boundFAD.

The amino-terminal domain of NIFA influences the level of complex formation in the presence of ADP. The putative regulatory function of the amino-terminal domain of NIFA makes it a likely target for interaction with NIFL,which may, by analogy with other $sigma$ ^N-dependent activators, result in modulation of the ATPase activityof the central domain of the protein in response to NIFL. We examinedthe ability of an amino-terminally deleted NIFA protein, $Delta$ N-₁₉₁NIFA,(Fig. 2), to form a complex with NIFL in the presence of ADP. $Delta$ N-₁₉₁NIFA has transcriptional activity in vitro which is inhibitedby high concentrations of NIFL bound to ADP, although in contrastto full-length NIFA, the ATPase activity of the truncated NIFAprotein is unaffected under these conditions (unpublished results).Reactions were performed with C-terminally tagged forms of NIFA,either the full-length protein or $Delta$ N-₁₉₁NIFA, with nontagged full-lengthNIFL as the partner. In the absence of MgADP, no binding of NIFLto either form of NIFA was observed (Fig. 3). In the presenceof 1 mM MgADP, complexes were observed with the full-length NIFAand the proteins coeluted exactly as demonstrated in the previousexperiments with tagged NIFL and the native form of NIFA (Fig.3a). However, no binding to NIFL was detected with the truncatedform of NIFA in the presence of 1 mM MgADP, and NIFL eluted fromthe column in the wash fraction (Fig. 3b). The same result wasobtained when the experiment was repeated in the presence of 4mM MgGTP in addition to ADP (data not shown). Thus, the amino-terminaldomain of NIFA strongly influences complex formation between NIFLand NIFA in the presence of ADP.

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FIG. 2. Comparison of the ability of truncated derivatives of NIFL and NIFA to form complexes in the presence of MgADP. N indicates the amino-terminal domain and C indicates the carboxy-terminal domain of each protein. $diamond$ indicates the histidine tag. +, able to form complex; $-$ , unable to form complex.

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FIG. 3. Complex formation between NIFL and full-length NIFA or $Delta$ N-₁₉₁NIFA. Complexes were formed, chromatographed, and electrophoresed as for Fig. 1. Histidine-tagged forms of NIFA and $Delta$ N-₁₉₁NIFA were used at 2.9 µM, and NIFL was used at 2.3 µM. MgADP was used at 1 mM where indicated. (a) Full-length NIFA and NIFL. (b) $Delta$ N-₁₉₁NIFA and NIFL. Lanes 2 to 4 and 9 to 11, wash fractions; lanes 5 to 7 and 12 to 14, fractions containing protein obtained after elution. Lane M contains molecular weight markers.

The C-terminal region of NIFL is involved in the ADP-dependent stimulation of NIFL-NIFA complex formation. We have previously characterized the properties of various domains and fragments of the NIFL protein with respect to inhibitionof NIFA activity and nucleotide binding (23). Two derivatives,NIFL(1-284), corresponding to the N-terminal domain, and the C-terminalsubdomain, NIFL(360-519) (Fig. 2) do not function as inhibitorsof the transcriptional activity of NIFA in vitro even in the presenceof ADP, although NIFL(360-519) is competent to bind nucleotides(23). A longer fragment, consisting of the whole C-terminalregion but lacking the first 147 amino acids of NIFL, includingthe flavin binding sites, NIFL(147-519), is competent to inhibitNIFA activity in the presence of ADP although it lacks the redoxresponse (23). We have examined the ability of these truncatedforms of NIFL to bind to NIFA in the presence of 1 mM MgADP. Experimentswere performed with C-terminal His-tagged versions of NIFL andfull-length NIFA as the nontagged partner. There was no ADP-dependentstimulation of complex formation between NIFA and NIFL(1-284)or NIFL(360-519) (data not shown). Presumably, these truncatedproteins lack either regions required for NIFA interaction or,in the case of NIFL(1-284), the nucleotide binding domain. TheNIFL(147-519) derivative was able to bind NIFA in the presenceof nucleotide. However, this protein did not seem to bind NIFAwith the same affinity as the wild-type NIFL. Assuming NIFL(147-519)is a dimer (23), a molar ratio of the truncated NIFL to NIFAof 3:1 was required before the majority of the NIFA was retainedon the column and coeluted with NIFL in the presence of MgADP(Fig. 4). At lower protein ratios, less complex was detected (datanot shown). Although the truncated NIFL must contain both theNIFA interaction and nucleotide binding sites, gel filtrationexperiments suggest that it is a dimer rather than a tetramerin solution, and it may not be able to bind to NIFA with the sameaffinity as the tetrameric form of the full-length protein.

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FIG. 4. Complex formation between NIFL(147-519)_6his and NIFA. Complexes were formed and chromatographed as described in Materials and Methods. Full-length NIFA was present in the assays at 2.5 µM, and NIFL(147-519) was present at 8.25 µM (1:3 NIFA/NIFL ratio). Lanes 1 to 3 and 6 to 8, wash fractions; lanes 4, 5, 9, and 10, fractions containing protein which eluted with 0.5 M imidazole. The presence (+) or absence ( $-$ ) of MgADP is indicated.

Isolation of the NIFL-NIFA complex from cell extracts in the presence of MgADP. We purified coexpressed NIFL and NIFA proteins from an E. coli BL21(DE3)(pLysS) strain carrying plasmid pPR38 in which theA. vinelandii nifLA operon was expressed from the T7 promoterusing the natural nifL ribosome binding site (23). In this constructthe NIFL protein was expressed with a C-terminal histidine tagand NIFA was nontagged. Induction with IPTG gave rise to approximatelystoichiometric amounts of NIFL and NIFA. Metal chelate affinitychromatography of the cell extract lysed and chromatographed inthe presence or absence of 1 mM MgADP resulted in isolation ofthe NIFL-NIFA complex only in the presence of the magnesium-boundnucleotide (Fig. 5a). The presence of either magnesium or ADPalone was not able to stabilize the complex and resulted in chromatographyof only NIFL_6his, with NIFA eluting in the column wash fractions.The NIFL-NIFA complex could be dissociated on the column by removalof MgADP. Figure 5b shows the NIFL-NIFA-containing fractions elutedfrom the nickel column in the presence of 1 mM MgADP comparedto those where NIFA had been dissociated from the bound complexby removal of nucleotide from the chromatography buffers. In thiscase, NIFA eluted from the column with 20 mM imidazole. Afterdialysis, this NIFA was essentially free of NIFL, as judged byinspection of Coomassie blue-stained gels (data not shown). Theactivity of this protein was compared to that of a control NIFApreparation which had been purified routinely in the absence ofNIFL. Both NIFA preparations were active in transcriptional activationfrom the nifH promoter and displayed identical behavior in a single-roundtranscription assay in the presence and absence of IHF (Fig. 6).

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FIG. 5. Isolation of the NIFL-NIFA complex directly from lysed cells. BL21(DE3)(pLysS) cells carrying plasmid pPR38 were grown as described in Materials and Methods. (a) The cell paste was resuspended in lysis buffer and divided into four aliquots. These were lysed and chromatographed as described in Materials and Methods with the following additions: lane 1, no nucleotide; lane 2, with 1 mM magnesium acetate; lane 3, with 1 mM ADP; lane 4, with 1 mM MgADP. Lanes 1 to 4, fractions containing protein which eluted with 0.5 M imidazole. Lane M contains molecular weight markers. (b) Cell paste was resuspended in lysis buffer containing 1 mM MgADP and was divided into two aliquots. These were applied to the nickel chelating column and washed with equilibration buffer containing 1 mM MgADP as described in Materials and Methods. Lane 1, cell supernatant; lane 2, nonbound protein from cell supernatant; lanes 3 to 7, NIFL-NIFA-containing fractions eluted with 0.5 M imidazole in the presence of 1 mM MgADP; lanes 8 to 13, fractions eluted with 0.5 M imidazole after washing the column in equilibration buffer without nucleotide to dissociate NIFA. (c and d) Absorbance spectra of oxidized NIFL and isolated NIFL-NIFA complex in the presence of 500 µM MgADP. The spectra were recorded with a Shimadzu MP2000 spectrophotometer with a 1-cm light path and 1-nm slit width.

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FIG. 6. Transcriptional activity of NIFA dissociated from the NIFL-NIFA complex. A single-round transcription assay from the nifH promoter was carried out as described in Materials and Methods. NIFA was dissociated from the NIFL-NIFA complex as described in the legend to Fig. 5. +, present; $-$ , absent.

The NIFL-NIFA complex could also be separated by heparin agarose chromatography performed in the absence of nucleotide wherethe NIFA bound normally and the NIFL eluted in the nonbound columnfractions (data not shown). The spectral features of the oxidizedNIFL-NIFA complex were similar to those of NIFL alone both inthe presence and absence of MgADP, with a characteristic absorptionmaximum at 445 nm and shoulders at 420 and 470 nm, indicativeof protein-bound FAD (Fig. 5c and d). The FAD moiety in NIFL complexedto NIFA in the presence of MgADP was reduced by sodium dithionite,as observed for the NIFL protein in isolation (data notshown).

Molecular mass estimation of the NIFL-NIFA complex. The apparent molecular masses of the NIFL-NIFA complexes and isolated proteins were estimated by gel filtration on Superose12 in the presence and absence of 500 µM MgADP (see Materialsand Methods) (Table 1). In the absence of nucleotide, purifiedNIFL sieved as a tetramer and NIFL sieved as a species, whichprobably represents an equilibrium between the dimer and tetramerforms. The presence of nucleotide did not appear to change theassociation state of the NIFL protein significantly, whereas theapparent increase in molecular mass of NIFA with MgADP may representa shift of the equilibrium to the tetramer form. The behaviorof purified NIFA preparations on gel filtration was found to besomewhat variable among preparations, with a range of molecularmasses being obtained (unpublished observation). However, thisdid not appear to influence the ability of the protein to bindto NIFL in the presence of MgADP, as all the NIFA preparationstested displayed similar behaviors in the binding assay. In thepresence of MgADP, NIFL-NIFA complexes, which were either isolatedfrom cell extracts or formed in vitro, sieved with an apparentmolecular mass of approximately 500 kDa, which would be consistentwith stoichiometry of a tetramer of NIFL bound to a tetramer ofNIFA. In the absence of MgADP, the NIFL-NIFA complex isolatedfrom cell extracts chromatographed with a lower apparent molecularmass, indicating dissociation of the complex upon removal of thenucleotide. The NIFL and NIFA proteins mixed in vitro withoutMgADP sieved as a single peak but with a molecular mass no greaterthan that of NIFL alone. The Superose 12 absorbance traces ofthe NIFL-NIFA complex isolated from cell extracts compared toeach protein chromatographed alone are shown in Fig. 7.

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FIG. 7. Absorbance traces of NIFL-NIFA complexes and individual proteins chromatographed on Superose 12. The column was calibrated with the following standards: thyroglobulin (669 kDa); $beta$ -amylase (200 kDa); alcohol dehydrogenase (150 kDa); bovine serum albumin (66 kDa); carbonic anhydrase (29 kDa); cytochrome c (12.4 kDa). The absorbance traces at 280 nm are shown for the NIFL-NIFA complex isolated from cell extract and chromatographed as described in Table 1 in the absence (A) or the presence (B) of 500 µM MgADP. The individual NIFL and NIFA proteins are those which had been dissociated from each other on the nickel column by removal of nucleotide and then chromatographed under the same conditions as the NIFL-NIFA complex in the presence and absence of 500 µM MgADP.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In earlier work we have demonstrated that the inhibitory activity of NIFL on NIFA activity is stimulated by the presence ofadenosine nucleotides, particularly ADP, in vitro (8). Thepresence of ADP overrides redox sensing by NIFL, since the ADP-boundform of the protein is inhibitory to NIFA activity even when theflavin moiety is in the reduced state (13). In the absence ofADP, the oxidized form of NIFL inhibits both the ATPase and GTPaseactivities of full-length NIFA, resulting in inhibition of opencomplex formation. We have now examined complex formation betweenoxidized NIFL and NIFA and found little interaction between thetwo proteins in the absence of nucleotide under the conditionsof the binding assay. The complex may not form in the absenceof nucleotides or may be too weak or transient to be detectedby cochromatography. The inhibitory effect of NIFL on NIFA activityand, by definition, the formation of the inhibitory complex canbe determined in vitro by measuring various functions of NIFA,including transcriptional activation and ATPase activity. Nucleotidesare always present in these assays, and the situation is complicatedby the potential interaction of the nucleotides with both NIFAand NIFL. Transcriptional activation by NIFA requires ATP or GTPhydrolysis to drive open complex formation (2, 3, 14).However, ATP hydrolysis by NIFA will result in the productionof ADP, which increases the inhibitory effect of NIFL. Inhibitionof NIFA activity by NIFL is also observed when GTP is used tomake open complexes, but the inhibition is increased when lowconcentrations of ADP are added in addition to GTP (23). Thepresence of GTP in our binding assay results in a low level ofNIFL-NIFA complexes, which is apparently sufficient for NIFL toinhibit the transcriptional activity of NIFA. The addition ofADP increases the amount of NIFL-NIFA complex detected when equimolarconcentrations of the two proteins are used. This is consistentwith the stimulation of the inhibitory effect of NIFL observedin the open-complex assays. Higher concentrations of NIFL maybe required to shift the equilibrium towards complex formationin the absence ofADP.

The C-terminal domain of A. vinelandii NIFL shows strong similarity to the histidine protein kinase transmitter domains oftwo-component systems (5), including the region containingthe highly conserved histidine residue, which is autophosphorylatedin bona fide members of the family (19). However, there is noevidence that any phosphotransfer mechanism between NIFL and NIFAexists (2, 15, 20), and it seems likely that this pairof proteins has evolved from the classical sensor kinase responseregulator system to one where protein-protein interaction replacesphosphotransfer as a mechanism for signal transduction. AlthoughA. vinelandii NIFL possesses the conserved histidine residue,His³⁰⁵, no autophosphorylation of this residue has been detected (2).Our experiments with the truncated NIFL derivatives support thehypothesis that this region of the protein might be a candidatefor interaction with NIFA (22, 25), as in orthodox systemsthe modified histidine is likely to approach the receiver domainof the response regulator to effect phosphotransfer (18). Thelack of in vitro activity of the N-terminal and C-terminal subdomainsof NIFL in the presence of MgADP can be attributed to lack ofinteraction with NIFA. The C-terminal subdomain, although competentto bind nucleotide, presumably does not possess the binding sitesfor NIFA. This is in contrast to the NIFL protein from K. pneumoniae,where a similar truncation of the C-terminal domain is capableof inhibiting NIFA activity both in vivo and in vitro and thuspresumably contains the determinants for interaction with theactivator (17). The longer NIFL derivative, NIFL(147-519), whichdoes contain the region around the conserved histidine, can bindNIFA in the presence of ADP, implying that the site(s) of NIFAinteraction is likely to be located between residues 147 and 360.The removal of the PAS domain in this NIFL derivative does notprevent the ADP-dependent stimulation of NIFL binding to NIFA(23). Experiments with a truncated form of NIFA, lacking theN-terminal domain, have indicated that there may be at least twomechanisms by which NIFL inhibits NIFA activity. Inhibition ofthe ATPase activity of NIFA by NIFL requires the presence of anintact NIFA N-terminal domain, while a second mechanism of inhibitionstill occurs with the truncated protein (unpublished observations).An amino-terminally deleted form of the NIFA protein from K. pneumoniaeexpressed as a maltose-binding fusion also has transcriptionalactivity in vitro which is inhibited by NIFL (4), consistentwith our observations with the truncated A. vinelandii NIFA. Wehave now shown that the amino-terminal domain of NIFA also hasa strong influence on the affinity of the NIFL-NIFA interactionobserved in our binding assays. Interaction with the amino-terminaldomain may provide a mechanism by which the ATPase activity ofNIFA is inhibited byNIFL.

In aerobically grown cells under nitrogen-rich conditions, the constitutive activity of NIFA is repressed by NIFL, presumablyby the formation of the inhibitory complex, to prevent synthesisof nitrogenase in physiologically unfavorable conditions. Whenwe overexpressed NIFL and NIFA together under these conditions,we could isolate the NIFL-NIFA complex from the cell extract,but only when MgADP was present in the lysis and chromatographysteps. Thus, in these experiments it is not possible to distinguishcomplexes which had been present in the cells from those whichformed on cell lysis in the presence of MgADP. The NIFA whichdissociated from NIFL when nucleotide was removed from the complexretained transcriptional activity, indicating that it is not irreversiblymodified by NIFL binding. Whether NIFL-NIFA would normally beADP bound under repressing conditions in vivo may depend on theratio of ATP to ADP present in the cells. Changes in oxygen concentrationand nitrogen status are likely to influence this ratio, and thephysiological role of the nucleotide response may be to sensethe energy status of the cells so that nitrogenase is not synthesizedwhen the high energy demands of nitrogen fixation cannot be met.In an analogous system, the sporulation protein SpoIIAB from Bacillussubtilis is a serine protein kinase which has homology to thenucleotide binding pocket of the histidine protein kinase family.This protein interacts stoichiometrically with its partner, SpoIIAA,in response to adenosine nucleotide levels, with the ATP/ADP ratioinfluencing with which partner SpoIIAB interacts (1, 16).In the presence of ADP, SpoIIAB forms a complex with SpoIIAA,while with ATP it acts as an antisigma factor and forms a complexwith $sigma$ ^F to inhibit its activity. In this system, however, phosphorylationis also involved, as SpoIIAB phosphorylates SpoIIAA in the presenceof ATP, preventing its binding to SpoIIAB or reacting with SpoIIAB- $sigma$ ^F complexes. Although there is no evidence for any phosphotransferoccurring between NIFA and NIFL, it is possible that adenosinenucleotides influence NIFL and NIFA interactions similarly tothe SpoIIAA-SpoIIAB system, with ADP promoting NIFL-NIFA complexformation while ATP stimulates NIFA and $sigma$ ^N RNA polymeraseassociation.

	ACKNOWLEDGMENTS

We are extremely grateful to Susan Hill for discussions and observations on the properties of the NIFL-NIFA complex. We alsothank Andre Sobczyk for providing the plasmid construction usedto obtain purification of the amino-terminally deleted form ofA. vinelandii NIFA. We are grateful to Mike Merrick and Gary Sawersfor comments on themanuscript.

This work was supported by a Grant-in-Aid from the BBSRC to the John InnesCentre.

	FOOTNOTES

^* Corresponding author. Mailing address: Nitrogen Fixation Laboratory, John Innes Centre, Norwich Research Park, Colney, NorwichNR4 7UH, Norfolk, United Kingdom. Phone: 44 (0)1603 456900. Fax:44 (0)1603 454970. E-mail: austins{at}bbsrc.ac.uk.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Alper, S., L. Duncan, and R. Losick. 1994. An adenosine nucleotide switch controlling the activity of a cell type-specific transcription factor in Bacillus subtilis. Cell 77:195-205[Medline].

2. Austin, S., M. Buck, W. Cannon, T. Eydmann, and R. Dixon. 1994. Purification and in vitro activities of the native nitrogen fixation control proteins NIFA and NIFL. J. Bacteriol. 176:3460-3465[Abstract/Free Full Text].

3. Berger, D. K., F. Narberhaus, and S. Kustu. 1994. The isolated catalytic domain of NIFA, a bacterial enhancer-binding protein, activates transcription in-vitro. Activation is inhibited by NIFL. Proc. Natl. Acad. Sci. USA 91:103-107[Abstract/Free Full Text].

4. Berger, D. K., F. Narberhaus, H. S. Lee, and S. Kustu. 1995. In vitro studies of the domains of the nitrogen-fixation regulatory protein NIFA. J. Bacteriol. 177:191-199[Abstract/Free Full Text].

5. Blanco, G., M. Drummond, P. Woodley, and C. Kennedy. 1993. Sequence and molecular analysis of the nifL gene of Azotobacter vinelandii. Mol. Microbiol. 9:869-880[Medline].

6. Dixon, R. 1998. The oxygen-responsive NIFL-NIFA complex: a novel two-component regulatory system controlling nitrogenase synthesis in $gamma$ -Proteobacteria. Arch. Microbiol. 169:371-380[Medline].

7. Drummond, M. H., and J. C. Wootton. 1987. Sequence of nifL from Klebsiella pneumoniae: mode of action and relationship to two families of regulatory proteins. Mol. Microbiol. 1:37-44[Medline].

8. Eydmann, T., E. Söderbäck, T. Jones, S. Hill, S. Austin, and R. Dixon. 1995. Transcriptional activation of the nitrogenase promoter in vitro: adenosine nucleosides are required for inhibition of NIFA activity by NIFL. J. Bacteriol. 177:1186-1195[Abstract/Free Full Text].

9. Govantes, F., E. Andujar, and E. Santero. 1998. Mechanism of translational coupling in the nifLA operon of Klebsiella pneumoniae. Embo. J. 17:2368-2377[Medline].

10. Govantes, F., J. A. Molina-Lopez, and E. Santero. 1996. Mechanism of coordinated synthesis of the antogonistic regulatory proteins NifL and NifA of Klebsiella pneumoniae. J. Bacteriol. 178:6817-6823[Abstract/Free Full Text].

11. Govantes, F., and E. Santero. 1996. Transcription termination within the regulatory nifLA operon of Klebsiella pneumoniae. Mol. Gen. Genet. 250:447-454[Medline].

12. Henderson, N., S. A. Austin, and R. A. Dixon. 1989. Role of metal ions in negative regulation of nitrogen fixation by the nifL gene product from Klebsiella pneumoniae. Mol. Gen. Genet. 216:484-491.

13. Hill, S., S. Austin, T. Eydmann, T. Jones, and R. Dixon. 1996. Azotobacter vinelandii NIFL is a flavoprotein that modulates transcriptional activation of nitrogen-fixation genes via a redox-sensitive switch. Proc. Natl. Acad. Sci. USA 93:2143-2148[Abstract/Free Full Text].

14. Lee, H.-S., D. K. Berger, and S. Kustu. 1993. Activity of purified NIFA, a transcriptional activator of nitrogen fixation genes. Proc. Natl. Acad. Sci. USA 90:2266-2270[Abstract/Free Full Text].

15. Lee, H.-S., F. Narberhaus, and S. Kustu. 1993. In vitro activity of NifL, a signal transduction protein for biological nitrogen fixation. J. Bacteriol. 175:7683-7688[Abstract/Free Full Text].

16. Min, K. T., C. M. Hilditch, B. Diederich, J. Errington, and M. D. Yudkin. 1993. Sigma F, the first compartment-specific transcription factor of B. subtilis, is regulated by an anti-sigma factor that is also a protein kinase. Cell 74:735-742[Medline].

17. Narberhaus, F., H.-S. Lee, R. A. Schmitz, L. He, and S. Kustu. 1995. The C-terminal domain of NIFL is sufficient to inhibit NIFA activity. J. Bacteriol. 177:5078-5087[Abstract/Free Full Text].

18. Park, H., S. K. Saha, and M. Inouye. 1998. Two-domain reconstitution of a functional protein histidine kinase. Proc. Natl. Acad. Sci. USA 95:6728-6732[Abstract/Free Full Text].

19. Parkinson, J. S., and E. C. Kofoid. 1992. Communication modules in bacterial signalling proteins. Annu. Rev. Genet. 26:71-112[Medline].

20. Schmitz, R., L. He, and S. Kustu. 1996. Iron is required to relieve inhibitory effects of NifL on transcriptional activation by NifA in Klebsiella pneumoniae. J. Bacteriol. 178:4679-4687[Abstract/Free Full Text].

21. Schmitz, R. A. 1997. NifL of Klebsiella pneumoniae carries an N-terminally bound FAD cofactor, which is not directly required for the inhibitory function of NifL. FEMS Microbiol. Lett. 157:313-318[Medline].

22. Sidoti, C., G. Harwood, R. Ackerman, J. Coppard, and M. Merrick. 1993. Characterisation of mutations in the Klebsiella pneumoniae nitrogen fixation regulatory gene nifL which impair oxygen regulation. Arch. Microbiol. 159:276-281[Medline].

23. Söderbäck, E., F. Reyes-Ramirez, T. Eydmann, S. Austin, S. Hill, and R. Dixon. 1998. The redox- and fixed nitrogen-responsive regulatory protein NIFL from Azotobacter vinelandii comprises discrete flavin and nucleotide-binding domains. Mol. Microbiol. 28:179-192[Medline].

24. Taylor, B. L., and I. B. Zhulin. 1999. PAS domains: internal sensors of oxygen, redox and light. Microbiol. Mol. Biol. Rev. 63:479-506[Abstract/Free Full Text].

25. Woodley, P., and M. Drummond. 1994. Redundancy of the conserved His residue in Azotobacter vinelandii NifL, a histidine protein kinase homologue which regulates transcription of nitrogen fixation genes. Mol. Microbiol. 13:619-626[Medline].

26. Wootton, J. C., and M. Drummond. 1989. The Q-linker: a class of interdomain sequences found in bacterial multidomain regulatory proteins. Protein Eng. 2:535-543[Abstract/Free Full Text].

27. Zhulin, I. B., B. L. Taylor, and R. Dixon. 1997. PAS domain S-boxes in Archea, Bacteria and sensors for oxygen and redox. Trends Biochem. Sci. 22:331-333[Medline].

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	ALL ASM JOURNALS

1.	Alper, S., L. Duncan, and R. Losick. 1994. An adenosine nucleotide switch controlling the activity of a cell type-specific transcription factor in Bacillus subtilis. Cell 77:195-205[Medline].
2.	Austin, S., M. Buck, W. Cannon, T. Eydmann, and R. Dixon. 1994. Purification and in vitro activities of the native nitrogen fixation control proteins NIFA and NIFL. J. Bacteriol. 176:3460-3465[Abstract/Free Full Text].
3.	Berger, D. K., F. Narberhaus, and S. Kustu. 1994. The isolated catalytic domain of NIFA, a bacterial enhancer-binding protein, activates transcription in-vitro. Activation is inhibited by NIFL. Proc. Natl. Acad. Sci. USA 91:103-107[Abstract/Free Full Text].
4.	Berger, D. K., F. Narberhaus, H. S. Lee, and S. Kustu. 1995. In vitro studies of the domains of the nitrogen-fixation regulatory protein NIFA. J. Bacteriol. 177:191-199[Abstract/Free Full Text].
5.	Blanco, G., M. Drummond, P. Woodley, and C. Kennedy. 1993. Sequence and molecular analysis of the nifL gene of Azotobacter vinelandii. Mol. Microbiol. 9:869-880[Medline].
6.	Dixon, R. 1998. The oxygen-responsive NIFL-NIFA complex: a novel two-component regulatory system controlling nitrogenase synthesis in $gamma$ -Proteobacteria. Arch. Microbiol. 169:371-380[Medline].
7.	Drummond, M. H., and J. C. Wootton. 1987. Sequence of nifL from Klebsiella pneumoniae: mode of action and relationship to two families of regulatory proteins. Mol. Microbiol. 1:37-44[Medline].
8.	Eydmann, T., E. Söderbäck, T. Jones, S. Hill, S. Austin, and R. Dixon. 1995. Transcriptional activation of the nitrogenase promoter in vitro: adenosine nucleosides are required for inhibition of NIFA activity by NIFL. J. Bacteriol. 177:1186-1195[Abstract/Free Full Text].
9.	Govantes, F., E. Andujar, and E. Santero. 1998. Mechanism of translational coupling in the nifLA operon of Klebsiella pneumoniae. Embo. J. 17:2368-2377[Medline].
10.	Govantes, F., J. A. Molina-Lopez, and E. Santero. 1996. Mechanism of coordinated synthesis of the antogonistic regulatory proteins NifL and NifA of Klebsiella pneumoniae. J. Bacteriol. 178:6817-6823[Abstract/Free Full Text].
11.	Govantes, F., and E. Santero. 1996. Transcription termination within the regulatory nifLA operon of Klebsiella pneumoniae. Mol. Gen. Genet. 250:447-454[Medline].
12.	Henderson, N., S. A. Austin, and R. A. Dixon. 1989. Role of metal ions in negative regulation of nitrogen fixation by the nifL gene product from Klebsiella pneumoniae. Mol. Gen. Genet. 216:484-491.
13.	Hill, S., S. Austin, T. Eydmann, T. Jones, and R. Dixon. 1996. Azotobacter vinelandii NIFL is a flavoprotein that modulates transcriptional activation of nitrogen-fixation genes via a redox-sensitive switch. Proc. Natl. Acad. Sci. USA 93:2143-2148[Abstract/Free Full Text].
14.	Lee, H.-S., D. K. Berger, and S. Kustu. 1993. Activity of purified NIFA, a transcriptional activator of nitrogen fixation genes. Proc. Natl. Acad. Sci. USA 90:2266-2270[Abstract/Free Full Text].
15.	Lee, H.-S., F. Narberhaus, and S. Kustu. 1993. In vitro activity of NifL, a signal transduction protein for biological nitrogen fixation. J. Bacteriol. 175:7683-7688[Abstract/Free Full Text].
16.	Min, K. T., C. M. Hilditch, B. Diederich, J. Errington, and M. D. Yudkin. 1993. Sigma F, the first compartment-specific transcription factor of B. subtilis, is regulated by an anti-sigma factor that is also a protein kinase. Cell 74:735-742[Medline].
17.	Narberhaus, F., H.-S. Lee, R. A. Schmitz, L. He, and S. Kustu. 1995. The C-terminal domain of NIFL is sufficient to inhibit NIFA activity. J. Bacteriol. 177:5078-5087[Abstract/Free Full Text].
18.	Park, H., S. K. Saha, and M. Inouye. 1998. Two-domain reconstitution of a functional protein histidine kinase. Proc. Natl. Acad. Sci. USA 95:6728-6732[Abstract/Free Full Text].
19.	Parkinson, J. S., and E. C. Kofoid. 1992. Communication modules in bacterial signalling proteins. Annu. Rev. Genet. 26:71-112[Medline].
20.	Schmitz, R., L. He, and S. Kustu. 1996. Iron is required to relieve inhibitory effects of NifL on transcriptional activation by NifA in Klebsiella pneumoniae. J. Bacteriol. 178:4679-4687[Abstract/Free Full Text].
21.	Schmitz, R. A. 1997. NifL of Klebsiella pneumoniae carries an N-terminally bound FAD cofactor, which is not directly required for the inhibitory function of NifL. FEMS Microbiol. Lett. 157:313-318[Medline].
22.	Sidoti, C., G. Harwood, R. Ackerman, J. Coppard, and M. Merrick. 1993. Characterisation of mutations in the Klebsiella pneumoniae nitrogen fixation regulatory gene nifL which impair oxygen regulation. Arch. Microbiol. 159:276-281[Medline].
23.	Söderbäck, E., F. Reyes-Ramirez, T. Eydmann, S. Austin, S. Hill, and R. Dixon. 1998. The redox- and fixed nitrogen-responsive regulatory protein NIFL from Azotobacter vinelandii comprises discrete flavin and nucleotide-binding domains. Mol. Microbiol. 28:179-192[Medline].
24.	Taylor, B. L., and I. B. Zhulin. 1999. PAS domains: internal sensors of oxygen, redox and light. Microbiol. Mol. Biol. Rev. 63:479-506[Abstract/Free Full Text].
25.	Woodley, P., and M. Drummond. 1994. Redundancy of the conserved His residue in Azotobacter vinelandii NifL, a histidine protein kinase homologue which regulates transcription of nitrogen fixation genes. Mol. Microbiol. 13:619-626[Medline].
26.	Wootton, J. C., and M. Drummond. 1989. The Q-linker: a class of interdomain sequences found in bacterial multidomain regulatory proteins. Protein Eng. 2:535-543[Abstract/Free Full Text].
27.	Zhulin, I. B., B. L. Taylor, and R. Dixon. 1997. PAS domain S-boxes in Archea, Bacteria and sensors for oxygen and redox. Trends Biochem. Sci. 22:331-333[Medline].