Nucleic Acids Research

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Nucleic Acids Research, 2002, Vol. 30, No. 18 3972-3980
© 2002 Oxford University Press

Secondary structure and DNA binding by the C-terminal domain of the transcriptional activator NifA from Klebsiella pneumoniae

Pampa Ray^1,2, K. John Smith¹, Rosemary A. Parslow¹, Ray Dixon² and Eva I. Hyde^*,1

¹ School of Biosciences, University of Birmingham, Birmingham B15 2TT, UK and ² Department of Molecular Microbiology, John Innes Centre, Norwich NR4 7UH, UK

*To whom correspondence should be addressed. Tel: +44 121 414 5393; Fax: +44 121 414 5982; Email: e.i.hyde{at}bham.ac.uk
Present address:
Pampa Ray, Department of Biological Sciences, Imperial College of Science, Technology and Medicine, London SW7 2AZ, UK

Received June 13, 2002; Revised and Accepted July 25, 2002

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 
The NifA protein of Klebsiella pneumoniae is required for transcriptional activation of all nitrogen fixation (nif) operons except the regulatory nifLA genes. At these operons, NifA binds to an upstream activator sequence (UAS), with the consensus TGT-N₁₀-ACA, via a C-terminal DNA-binding domain (CTD). Binding of the activator to this upstream enhancer-like sequence allows NifA to interact with RNA polymerase containing the alternative sigma factor, ⁵⁴. The isolated NifA CTD is monomeric and binds specifically to DNA in vitro as shown by DNase I footprinting. Heteronuclear 3D NMR experiments have been used to assign the signals from the protein backbone. Three -helices have been identified, based on secondary chemical shifts and medium range H_i-NH_{i + 1}, and NH_i-NH_{i + 1} NOEs. On addition of DNA containing a half-site UAS, several changes are observed in the NMR spectra, allowing the identification of residues that are most likely to interact with DNA. These occur in the final two helices of the protein, directly confirming that DNA binding is mediated by a helix–turn–helix motif.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 
The NifA protein, found in diazotrophic bacteria, is responsible for activating the transcription of genes required for nitrogen fixation. In Klebsiella pneumoniae, NifA activates transcription from all the operons involved in nitrogen fixation except for the nifLA operon, which is activated by the phosphorylated form of the transcriptional activator NtrC (1). Both NtrC and NifA work in conjunction with RNA polymerase containing the alternative ⁵⁴ (^N) factor (2). This form of RNA polymerase holoenzyme binds promoter DNA but requires an activator to initiate transcription. These ⁵⁴-dependent activators use hydrolysis of nucleoside triphosphates to catalyse the isomerisation of closed complexes between RNA polymerase and DNA to form open promoter complexes (3,4).

In the -subdivision of proteobacteria, for example in K.pneumoniae, the NifL protein regulates the activity of NifA in response to molecular oxygen and fixed nitrogen (5). In nitrogen-limiting conditions and in the absence of molecular oxygen, NifA binds to one or more upstream activator sequences (UAS) in the DNA (6). The UASs are positioned typically 100 bp upstream of the binding site of ⁵⁴ RNA polymerase (7); however, they can function up to 2 kb upstream of the transcription start site and also downstream of the start site, thus exhibiting behaviour similar to eukaryotic enhancer elements. Promoters often contain multiple UASs, which have weak homology to the consensus sequence, namely TGT-N₁₀-ACA. Mutational studies of nif UASs (8) show that the optimum binding sequence of K.pneumoniae NifA is 5'-TGT-G/A-G/A-G-3', as expected from the consensus for the wild-type UASs. In most cases, the intervening DNA between the UAS and the promoter bends with the aid of the integration host factor, facilitating contacts between the activator and RNA polymerase (9). The UAS enhancer-like sequence thus functions to position NifA at a location appropriate for interaction with the ⁵⁴ RNA polymerase.

The NifA protein has a modular domain structure typical of other ⁵⁴-dependent transcriptional activators (5). The N-terminal domain may regulate the inhibition of NifA by NifL and contains a GAF domain that is common to several cyclic GMP receptors (10). It is attached to the remainder of the protein by a protease sensitive, glutamine rich, linker (11). This N-terminal domain is not conserved amongst ⁵⁴-dependent transcriptional activators. The central domain of NifA shows extensive homology to equivalent domains of other ⁵⁴ activators such as DctD, XylR and NtrC (12). These proteins are members of the AAA⁺ superfamily of ATPases, which use nucleotide hydrolysis to restructure their substrates (13). In ⁵⁴-dependent activators this conserved domain is sufficient for the nucleotide-dependent interactions which drive formation of the open promoter complex (14–16). The C-terminal domain (CTD) of NifA is required for enhancer-dependent transcriptional activation. It contains a putative helix–turn–helix (HTH) motif, which is presumed to recognise the UASs (17). For the ⁵⁴-dependent activators there is also a conserved Ala–Leu–X₉–Ala–Ala–X₂–Leu–Gly sequence in this domain, the terminal glycine being part of the HTH motif (12). The structure of a mutant CTD of another ⁵⁴-dependent activator, NtrC from Salmonella typhimurium, has been determined using NMR spectroscopy (18). It is structurally homologous to Fis, the factor in Escherichia coli responsible for site-specific inversion when bound to recombinational enhancers (19). Both Fis and NtrC are dimeric and primarily -helical in solution. Each monomer contains four helices, including a HTH motif. The dimerisation interface consists of parts of the first and second helices, forming an anti-parallel four-helix bundle. The mutant NtrC domain does not bind DNA (20), therefore it is not possible to examine the protein–DNA interactions. Although sequence homology studies have identified the DNA-binding regions of the ⁵⁴-dependent activators, no direct information is currently available about the interactions of the individual amino acids with DNA. The CTD of NifA is monomeric in solution (21) and binds specifically to DNA containing UASs in vivo and in vitro (22). In a previous study, we probed the conformation of the purified C-terminal, DNA-binding domain of K.pneumoniae NifA by a variety of spectroscopic techniques and compared the results with the secondary structure predicted from its primary sequence (21). These studies suggest that the domain is largely -helical in solution, with three helices, including the HTH motif. In this study, we examine the secondary structure of the protein in more detail by heteronuclear NMR spectroscopy, and examine changes in the spectrum of the protein on binding to DNA containing a half UAS. We present the first physical evidence for the interaction of protein residues within the HTH motif with its target DNA-binding site. We demonstrate that, for this particular ⁵⁴-dependent activator, the majority of amino acid residues which interact with the cognate DNA sequence lie on one surface of the recognition helix.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 
Protein preparation
The CTD of NifA from K.pneumoniae was expressed in E.coli BL21 (DE3) pLysS, from the pT7-7 vector derivative, pJES470 (22). This encodes a fusion peptide of the first nine amino acids of the pT7-7 vector (MARIRARGS) to the last 67 amino acids of NifA. The residues in this paper are labelled such that D1 corresponds to D457 of the full-length protein, with the residues from the linker as –9 to –1. ¹⁵N-labelled and doubly ¹⁵N/¹³C-labelled protein was prepared by growing the cells in M9 medium (23) with ¹⁵N-ammonium chloride and unenriched glucose or ¹³C₆-glucose as the sole nitrogen and carbon sources, respectively. The protein was prepared as in our previous study, using a phosphocellulose P10 column and a Trisacryl-blue column (21). To remove traces of nucleases, the protein was further purified using a Vydac C₁₈ reverse-phase column. The protein was loaded onto the column in buffer containing 25 mM ammonium acetate, 50 mM LiBr, pH 6.4, and eluted with a gradient of buffer in 0–50% acetonitrile. The protein eluted at 40% acetonitrile. Samples for NMR experiments were lyophilised, taken up in H₂O or D₂O as required, and dialysed into buffer containing 10 mM sodium phosphate, 0.5 M LiBr, 0.1 mM EDTA, 1 mM 4-(2-aminoethyl)-benzene sulphonyl fluoride (AEBSF), pH 6.4.

Protein concentrations were determined using Bradford assays calibrated with bovine serum albumin (BSA) as standard (24). All concentrations are reported for the domain as a monomer, as shown in our previous study (21).

DNase I footprinting
The 341 bp EcoRI–BamHI fragment of pMB1 (25,26) containing three UASs from the nifH–nifJ intergenic region, was 5'-end labelled using [-³²P]dATP and T4 polynucleotide kinase. Reactions for the binding assays contained 5 nM DNA, 8.1 ng/µl poly(dI–dC) (Boehringer Mannheim), 25 mM Tris acetate pH 8, 50 mM potassium acetate, 13.5 mM ammonium acetate, 0.5 µM acetylated BSA (NEB) and 2.5–7.5 µM NifA C-terminal DNA-binding domain in a final volume of 15 µl. The reaction mixes were incubated at 30°C for 20 min. DNase I (1.1 x 10^–4 U; Boehringer Mannheim) was added in 3 µl of buffer containing 10 mM Tris–HCl, 10 mM CaCl₂, 40 mM MgCl₂ and 10% glycerol. Digestion was allowed to proceed for 30 s at 30°C and was terminated by adding 180 µl of 0.3 M sodium acetate, 10 mM EDTA. After ethanol precipitation and resuspension, the DNA fragments were separated on a 6% denaturing polyacrylamide gel, and analysed on a PhosphorImager (Molecular Dynamics).

Preparation of oligonucleotides for NMR experiments
5'-AATGTGGGAAAC-3' and 5'-GTTTCCCACATT-3' were purchased from MWG Biotech. The freeze-dried oligonucleotide samples were each dissolved in H₂O and passed through a Sephadex G-10 spin column to separate them from low molecular weight contaminants. The oligonucleotides were lyophilised and dissolved in buffer containing 10 mM sodium phosphate, 100 mM LiBr, 1 mM EDTA, pH 6.4, to a final concentration of 20 mM. Equivalent amounts of each oligonucleotide (based on their A₂₆₀) were mixed, heated to 70°C for 15 min and allowed to anneal by cooling slowly.

NMR spectroscopy of free protein
NMR samples of free protein contained 0.6 ml of 0.5 mM protein in 50 mM sodium phosphate buffer pH 6.4, 500 mM LiBr, 0.1 mM EDTA. Triple resonance and three-dimensional NMR experiments were performed on a four-channel Varian Unityplus 600 spectrometer, operating at 599.98 MHz at 27°C. Main-chain ¹HN, ¹⁵N, ¹³C and side-chain ¹³Cß resonances were assigned using HNCACB and CBCA(CO)NNH (27) and Cß-decoupled-HNCA (28) experiments. Main-chain ¹H and ¹³CO assignments were made using CBCACO(CA)HA (29), HBHA(CBCA)(CO)NNH (30), HNCO (27) and HNHA (31) spectra. Selective ¹³C decoupling was achieved using WURST-2 adiabatic decoupling schemes (28). ¹⁵N dimensions were generally collected with Kay-type sensitivity enhanced gradient coherence selection for quadrature detection and water suppression (27), and other dimensions were collected by using the standard time-proportional phase incrementation method. A 1–1.5 s recycle delay after acquisition and before the first pulse of the program was used. Typical sweep widths were 9 (direct) and 8 kHz (indirect) for ¹H, 1.5 kHz for ¹⁵N, 9.4 kHz for ¹³C/¹³Cß, 4.2 kHz for ¹³C, and 2.2 kHz for ¹³CO. 1024 points were collected in the direct ¹H dimension, with 32* complex points in ¹⁵N, between 48*–64* complex points in ¹³C/¹³Cß, 128* complex points in ¹³C, and 48* complex points in ¹³CO. The minimum number of scans to complete the phase cycle was collected in each case. A 3D NOESY-¹⁵N-sensitivity enhanced HSQC (32) was also collected in which four transients were acquired for each of 128* and 32* complex points in indirect ¹H and ¹⁵N dimensions, respectively.

¹H chemical shifts were referenced to the H₂O resonance, which was calibrated independently at 4.789 p.p.m. (at 27°C) relative to sodium 2,2-dimethylsilapentane-5-sulphonic acid. ¹⁵N and ¹³C chemical shifts were referenced indirectly (33). The NMR data were processed on a Silicon Graphics workstation using VNMR (Varian UK). Generally, sinebell squared apodisation shifted by 90° was used in each dimension. The intensities of cross-peaks in the 3D NOESY-¹⁵N filtered HSQC were measured in NMRCompass (Molecular Simulations). The chemical shifts of the C, H, CO and Cß resonances were used to determine the secondary structure of the protein using the program CSI (34).

NMR spectroscopy of protein–DNA complexes
Titrations were performed by adding microlitre aliquots of DNA into a 40 µM protein solution in buffer containing 10 mM sodium phosphate, 100 mM LiBr, 5 mM EDTA, pH 6.4, with 10% D₂O. HSQC spectra (35) were collected on a Bruker AMX-500 spectrometer, operating at 500.13 MHz. The spectra were collected with 1024 data points with a sweep width of 14.7 p.p.m. in the direct dimension, and 256 experiments, with a sweep width of 32 p.p.m., in the indirect dimension and 128 scans per experiment. The water peak was reduced by using a modified WATERGATE pulse sequence. Phase cycling was performed in phase sensitive mode using the time-proportional phase incrementation method for quadrature detection in the indirect dimension. The spectra were processed using UXNMR software.

To estimate the apparent dissociation constant of the DNA–protein complex, the chemical shifts of the protein resonances were measured at different concentrations of DNA. For several peaks, these data were fitted simultaneously to the equations below (reviewed in 36), using non-linear regression in Sigmaplot (SPSS Inc):

_obs = _E + ([EL] / E_T)(_EL – _E)

[EL] = 1/2[E_T + L_T + K_d – {(E_T + L_T + K_d)² – 4E_TL_T}^1/2]

where _obs is the observed shift of the resonance; _E is its shift in the free protein; _EL is its shift in the protein–DNA complex; [EL] is the concentration of the protein–DNA complex; E_T is the total protein concentration; L_T is the total DNA concentration; K_d is the dissociation constant of the protein–DNA complex. Individual values for _E, _EL were obtained for each peak, with a global fit for K_d.

For peaks in intermediate exchange:

2(_E – _EL) (1 / _E + 1 / _EL) = k_off / (1 + P_EL / P_E)

where _E is the lifetime of the resonance in the free protein; _EL is the lifetime in the DNA complex = 1 / k_off; P_EL and P_E are the fractions of protein in the bound and free state, respectively.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 
Assignment of the NMR spectrum of NifA CTD and secondary structure elements within the domain
The C-terminal domain of NifA was overexpressed in E.coli as a fusion protein from a vector encoding nine amino acids from the vector pT7-7 fused to 67 amino acids at the C-terminus of NifA (22). To test that the purification method yielded active protein, DNase I protection assays were performed using DNA containing the K.pneumoniae nifH promoter and the nifH–nifJ intergenic region (Fig. 1). Protection from DNase I cleavage of the region –138 to –117 bp upstream of the nifH transcription start site is observed at 2.3 µM NifA. This shows that the protein is active and binds specifically to the nifH UAS, as in previous studies (23). Little protection of the nifJ UAS sequences is seen with the CTD of NifA at these concentrations. However, at protein concentrations >8.3 µM, some protection of bands at the nifJ UAS2 and UAS3 is observed (data not shown). This indicates that the CTD of NifA from K.pneumoniae binds more weakly to the nifJ UASs than to the nifH UAS. The same concentrations of protein were needed to obtain footprints after ion-exchange chromatography, reverse-phase HPLC and after dialysis in 0.5 M LiBr for the preparation of NMR samples, showing that the purification method did not affect the activity of the protein (data not shown).

View larger version (112K): [in this window] [in a new window]   Figure 1. (A) Representation of the DNA fragment used in DNase I footprinting experiments, showing the intergenic region between the divergent nifH and nifJ promoters. The promoter elements and protein-binding sites are boxed and direction of transcription shown with arrows. DPE, downstream promoter element; IHF, binding site for integration host factor protein; UAS, upstream activator sequence. The position and sequences of the UASs are shown under the appropriate box. The numbering used is relative to the closest transcription start site. There are 30 bp between the nifH UAS and nifJ UAS3. (B) DNase I footprint of NifA CTD from K.pneumoniae on the EcoRI–BamHI fragment of pMB1. Lanes 1–5, fragment 5'-end labelled at the EcoRI end. Lane 1, DNA template (no DNase I); lane 2, G+A sequencing ladder; lanes 3–6, DNA template plus DNase I; lane 3, no protein; lane 4, 2.3 µM NifA CTD; lane 5, 4 µM NifA CTD; lanes 6–11, fragment 5'-end labelled at the BamHI end; lane 6, DNA template (no DNase I); lane 7, G+A sequencing ladder; lanes 8–11, DNase I plus DNA; lane 8, no protein; lane 9, 1 µM NifA CTD; lane 10, 2.3 µM NifA CTD; lane 11, 4 µM NifA CTD.

 
In order to determine the secondary structure of the CTD by NMR spectroscopy, the protein was labelled with ¹⁵N and ¹³C. The ¹H-¹⁵N HSQC spectrum of the protein in 0.5 M LiBr is shown in Figure 2. This spectrum is very similar to that observed previously in 0.5 M NaCl (21). Normally, for a protein containing only 75 amino acid residues, the resonances can be completely assigned using ¹⁵N-labelled protein alone. Due to the considerable overlap of both the ¹H and ¹⁵N resonances, heteronuclear 3D triple resonance NMR experiments with ¹³C/¹⁵N double-labelled protein were used to determine the assignments of the backbone resonances. Main-chain ¹HN, ¹⁵N, ¹³C and side-chain ¹³Cß resonances were assigned sequentially using a combination of HNCACB and CBCA(CO)NNH (27) spectra. A high-resolution Cß-decoupled-HNCA (28) experiment, showing connectivities only to ¹³C, was used to resolve sequential C resonances that were close in chemical shift. Strips from the 3D spectra illustrating the sequential assignments for residues 51–60 are shown in the Supplementary Material (Fig. S1). Main-chain ¹H, ¹Hß and ¹³CO assignments were made using HBHA(CBCA)(CO)NNH (30) experiments and HNCO (27) experiments. The assignments were confirmed using CBCACO(CA)HA (29) and HNHA (31) spectra. For Thr49 and Met64, which are adjacent to proline residues (that do not contain amides protons), the Cß resonances could not be assigned by this combination of methods. Also, no assignments were made for Pro3, which is adjacent to Pro4. (The remaining chemical shift assignments are listed in the Supplementary Material, Table S1.)

View larger version (54K): [in this window] [in a new window]   Figure 2. 15N-1H heteronuclear single quantum coherence spectrum of NifA CTD from K.pneumoniae in 10 mM sodium phosphate buffer, pH 6.6, containing 500 mM LiBr, and 0.1 mM EDTA at 27°C. The peaks from the peptide amide groups are labelled with their assignments, numbered with D458 as residue 1. Unlabelled peaks arise from Asn and Gln side chains and the eight N-terminal amino acids of the protein that come from the expression vector. (A) Full amide spectrum. (B) An expansion of the dotted region of the spectrum shown in (A).

 
The C and H chemical shifts are strongly influenced by the orientation of the groups relative to the carbonyl of the amide bond. The chemical shift index uses the difference in observed shift from that expected for a random coil to predict secondary structure (34). For NifA the consensus secondary structure from the C, H, Cß and CO shifts indicates the presence of -helices between residues 23–34, 39–45 and 51–59 (Fig. 3). The ¹⁵N-HSQC edited NOESY (32), which shows which protons are close in space, was also analysed for indications of secondary structure. Cross-peaks between adjacent NH residues were observed for residues 27–33, 36–48 and 51–61, while cross-peaks between H resonances and NH groups three residues apart (_i-NH_{i + 3}) were observed for residues 27–33, 40–44 and 51–56. These NOEs also suggest the presence of -helices within these regions of the domain. The corresponding NOEs at residues 23–26, at the beginning of the first helix, cannot be assigned unambiguously due to overlap between NH resonances and between H resonances. The results from the NOEs and chemical shift indices are in agreement with predictions from the PredictProtein program, which indicated helices between residues 25–34, 39–46 and 51–59 (22). There is no evidence for any ß-strands, or for any regular secondary structure in the N-terminal part of the domain before residue 23.

View larger version (21K): [in this window] [in a new window]   Figure 3. Histogram showing the intensities of NOEs in the 15N-HSQC edited NOESY and consensus chemical shift index of the C-terminal domain of NifA from K.pneumoniae. (A–C) Intensities of NOEs: (A) NHi-NHi + 1 NOEs, (B) Hi-NHi + 1 NOEs, (C) Hi-NHi + 3 NOEs. The maximum NOE intensity observed was 1.6 units. X shows positions at which the overlap of resonances prevented unambiguous assignment of NOEs. (D) The consensus chemical shift index based on the 1H, 13C, 13Cß and 13CO chemical shifts (34). (E) Sequence of the protein used. Residue 1 corresponds to D458 of the full-length protein, residues –8 to –1 come from the expression vector.

 
Titration of NifA CTD with a DNA oligonucleotide containing a half-site UAS
Full-length NifA, like other prokaryotic HTH proteins, is oligomeric and binds to a palindromic UAS with the consensus sequence TGT-N₁₀-ACA. To study the interactions between the NifA CTD and DNA, the protein was titrated with a synthetic oligodeoxynucleotide and the effects on the HSQC spectra examined. To simplify the spectral analysis, we used an oligodeoxynucleotide containing the UAS half-site 5'-TGTGGG-3', to ensure binding of protein monomers rather than dimers. This sequence is contained in the natural nifH UAS that binds more tightly to the NifA CTD than the other two UASs in the nifH–nifJ intergenic region (Fig. 1). It also corresponds to the optimum binding sequence of the full-length NifA protein from K.pneumoniae (8). The oligodeoxynucleotide used in this study consisted of a dodecamer containing this sequence with additional flanking bases from the nifH UAS to enhance the binding of the protein and the stability of the DNA duplex.

Figure 4 shows the effect of addition of DNA on the HSQC spectrum of the protein. Most cross-peak positions remain unchanged or move very slightly on addition of DNA; for example, Val38, Gly47 and Leu46. Some peaks, such as those from Gln39, Lys41, Arg56, Tyr55 and Met60, shift considerably but remain sharp and can be followed throughout the titration. A few peaks such as those from Ala40 and Thr49 broaden out and disappear completely. Interestingly, the peak due to residue Gln39, at 130.5 and 9.3 p.p.m., broadens on the addition of 5 equivalents of DNA but reappears at 15 equivalents of DNA, suggesting that this is now almost completely in the bound form. The chemical shift differences for the amide hydrogen and nitrogen between free protein and protein in the presence of 15 equivalents of DNA are shown in Figure 5.

View larger version (68K): [in this window] [in a new window]   Figure 4. 15N-1H HSQC spectra of the CTD of NifA from K.pneumoniae at 27°C in the presence of oligodeoxynucleotide containing a half-site UAS. The concentration of the protein was 40 µM in buffer containing 10 mM sodium phosphate, 100 mM LiBr and 5 mM EDTA pH 6.4. (A) Spectrum in the presence of 15 equivalents of oligodeoxynucleotide. Peak numbers are shown at the positions corresponding to the spectrum in the absence of DNA (as in Fig. 2A). (B) Overlay of the central part of five HSQC spectra at increasing concentrations of oligodeoxynucleotide. The expansion is of the dotted region in (A). Contour colours: black, no DNA; red, 0.75 equivalents DNA; brown, 1.5 equivalents DNA; blue, 5 equivalents DNA; and green, 15 equivalents DNA. Selected cross-peaks are labelled with their assignment and arrows indicating the changes in shift.

 

View larger version (23K): [in this window] [in a new window]   Figure 5. Histogram showing the differences in chemical shift between the NifA CTD and the domain in the presence of 15 equivalents of an oligodeoxynucleotide containing a half-site UAS. P marks the position of proline. Chemical shift difference values have not been determined for residues G-2, S-1, D1, A8, S9, S10 and D24 (marked X), due to overlap in the spectrum of the free protein. Residues A40, T49 and A54 are missing due to broadening and are marked by double-ended arrows. (A) Differences in 1HN shift. The error estimate is ±0.03 p.p.m. (B) Differences in 15N shift. The error estimate is ±0.13 p.p.m.

 
The effects observed are due to different changes in chemical shifts between the resonances in the free protein and in the protein–DNA complex. The free and bound states of the protein are in dynamic equilibrium. If the chemical shift difference (in Hz) between the two states of a resonance is smaller than the rate of exchange, one sharp peak is observed. The chemical shift value of this peak is a weighted average of the chemical shifts of the resonance in the free and bound state, and so the peak moves towards the bound position as the DNA concentration increases. This is seen with most resonances. However, if the chemical shift difference between the free and bound states (in Hz) is similar in size to the exchange rate, then the resonances are in intermediate exchange. The peak broadens, and may not be visible above the noise level.

The chemical exchange behaviour observed in the NMR spectra shows that the binding is weak, consistent with the DNase I footprinting on the longer DNA fragment. Figure 6 shows the chemical shifts of several of the protein resonances plotted against the concentration of added DNA. The curves show the fit of the data to a model in which there is 1:1 protein:DNA binding with the free and bound resonances in fast exchange, with a K_d of 200 µM. The data for both amide ¹H and ¹⁵N peaks show good fit to this model, for various chemical shift differences. However, the K_d is poorly defined and if the peaks are not in full fast exchange, the estimate of K_d may be erroneous. Based on the largest chemical shift difference observed, the off-rate is of the order of 800 s^–1 (Fig. 6).

View larger version (20K): [in this window] [in a new window]   Figure 6. Chemical shifts of selected resonances at different oligodeoxynucleotide concentrations. The solid line shows the theoretical titration curves for 1:1 protein:DNA complex formation with a Kd of 200 µM in fast exchange. (A) 1H shifts of M60 (diamonds) and R56 (triangles). (B) 15N shifts of R51 (circles) and I59 (squares).

 

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 
In order to gain a better understanding of the mode of DNA binding in this family of transcription activators, we have examined the secondary structure of NifA and its interactions with DNA using ¹H NMR spectroscopy. The chemical shift indices and the patterns of NOEs show that the C-terminal domain contains three helices at residues 23–34, 39–45 and 51–59. There is no evidence for any regular secondary structure prior to residue 23.

The only other ⁵⁴-dependent transcription factor for which the structure of the DNA-binding domain has been examined is that of NtrC^3-ala from S.typhimurium (18). NtrC is dimeric and contains four helices. Alignment of the secondary structural elements of the two proteins shows that the three helices in the NifA CTD align well with those in NtrC CTD (Fig. 7). In NtrC, however, there is an additional N-terminal helix between residues 402 and 414 that is absent in NifA and helix B in NtrC is longer than that in NifA. In NtrC, helices A and B form an anti-parallel four-helix bundle with the corresponding helices from a second subunit in the dimer. There are several hydrophobic contacts between residues in these helices, involving Leu421, Leu422 and Leu429 at the N-terminus of helix B. Amino acids corresponding to these leucine residues are absent in NifA, hence it is unable to form the dimer interface.

View larger version (27K): [in this window] [in a new window]   Figure 7. Sequence alignment of the C-terminal domains of NifA from K.pneumoniae and NtrC from S.typhimurium. The residues in an -helical conformation are boxed. Helices in NtrC are labelled (A)–(D) according to Pelton et al. (18). The three residues mutated to Ala in the NtrC construct are indicated. Residues in NifA that show sizeable changes in chemical shift on the addition of DNA are coloured based on their weighted average change in 1H and 15N chemical shift, av = [0.5{(H)2 + 0.2(N)2]}1/2. Red, residues in intermediate exchange; yellow, residues with av = 0.3 p.p.m.; green, residues with av = 0.15 p.p.m.; blue, residues with av = 0.1 p.p.m.; violet, residues with av = 0.08 p.p.m. The sequences were aligned using the subprogram Pile-up in GCG (Wisconsin Package version 10.2, Genetics Computer Group, Madison, WI).

 
The second half of helix B of NtrC and the remaining two helices align well with the helices of NifA. Glu24 of NifA CTD is equivalent to Glu430 of helix B in NtrC and this helix contains the Ala–Leu of the conserved Ala–Leu–X₉– Ala–Ala–X₂–Leu–Gly sequence (12). The four C-terminal residues of helix C of NtrC contain the Ala–Ala–X₂ part of the sequence and are identical to those in NifA. The Leu–Gly sequence is thus in the turn between helices C and D. It has not been possible to determine the secondary structure of Pro50 in NifA as it does not contain an amide proton, but residues Arg51–Asp61 in NifA CTD align with helix D.

The structure of the DNA-binding domain of TyrR from Haemophilus influenzae has also been determined (37). TyrR belongs to the NtrC family of proteins, as it contains an AAA⁺-like central domain, but it is a ⁷⁰-dependent transcriptional activator. Like NtrC, it contains four helices but it is monomeric. The last three helices of TyrR align with those of NifA and NtrC. The first, so-called, hinge helix, is poorly formed and does not show any sequence homology to either NtrC or NifA. However, a hydrophobic patch on helix B that has been suggested to contact the central domain may be present in all three proteins. In NifA this would include residues Arg27, Ala30 and Leu33.

Figure 8 shows a schematic model of the terminal three helices of NifA, based on the orientation of the corresponding helices in NtrC (18). The side chains of the residues that give the largest change in chemical shift on addition of DNA are shown and coloured. The largest chemical shift differences on binding DNA are clustered, occurring at Gln39 and Ala40 at the N-terminus of the second helix, at Thr49 in the turn, at Arg51 at the N-terminus of the final helix and at Ala54 in the centre of the final helix. We also see significant changes at Arg56 in the centre of this helix and at Ile59 and Met60 at the end of helix D. These chemical shift changes indicate changes in the chemical environment of the amide group. This can be due either to direct interactions between the residue and DNA or because the residue is undergoing a change in conformation as a result of DNA binding elsewhere. The positions in the NifA CTD affected on DNA binding are similar to those expected from direct interactions of other HTH proteins and their operator sequences. For example, interactions of bacteriophage 434 repressor with the phosphate backbone of DNA occur at the N-terminus of the first helix; base-specific DNA protein contacts occur at the N-terminus of the second helix and one turn further away; while further contacts with the DNA phosphate backbone occur at residues two turns further away (38). The binding of the protein to the DNA thus is similar to that of other HTH proteins, directly verifying the theoretical predictions of Drummond et al. (17). Because of the absence of the amide hydrogen at Pro50, we cannot define its secondary structure or the effects of DNA on this residue from the HSQC spectra. However, large effects of DNA binding occur at Arg51, Ala54 and Tyr55, suggesting that Pro50 (one turn from Ala54) is at the beginning of the recognition helix and so would also interact with the DNA. This would agree with sequence alignment with NtrC. The three alanine mutations in the mutant NtrC^3-ala CTD that replace Arg456, Asn457 and Arg461 align with Pro50, Arg51 and Tyr55, respectively, of NifA CTD, explaining why this protein does not bind DNA.

View larger version (57K): [in this window] [in a new window]   Figure 8. Schematic model of the terminal three helices of NifA, based on the orientation of the corresponding helices in NtrC (18). The helices are shown as blue cylinders with grey ribbon for the turns. The side chains of the residues that give the largest change in chemical shift on addition of DNA are shown, coloured according to their weighted average 1H and 15N chemical shift, av as in Figure 7. The sequences of NifA and NtrC were aligned as in Figure 7 and NifA was modelled on the structure of NtrC using the program Modeller 4 (40).

 
In studies by Morett et al. (8) on the full-length NifA protein, mutations corresponding to R51Q, R51L, Y55F and R56Q showed poor activation from the nifH promoter. This suggests that these residues may bind DNA. R51K and R56K showed activity equivalent to wild-type, suggesting that lysine, but not other residues, can substitute for these arginines, and that Arg51 and Arg56 may form contacts with DNA at the nifH UAS that are essential for transcriptional activation in vivo. Surprisingly, A54G also was active, although Ala54 is strongly affected by DNA binding in this study. It is possible that the backbone amide group contacts DNA and is important rather than the side chain. Q52G showed poor activity, although in our study, Gln52 is not affected by DNA binding. However, this mutant protein may be affected in folding as it did not activate the glnAp2 promoter, which can be activated in vivo in the absence of the DNA-binding domain. Gly47, the conserved glycine in the turn of the motif, is unaffected by the presence of DNA, as expected, although it is structurally important for DNA binding, as shown in mutational studies of NifA from other species (39). Thus, our NMR studies support the previous biological findings.

In conclusion, our studies show that that the C-terminal domain of NifA from K.pneumoniae contains three -helices and provide strong evidence that the final two helices comprise a classical HTH motif required for DNA recognition. Based on the changes observed in the chemical shifts, we have demonstrated that the N-terminus of the second helix and residues on one face of the third helix interact with the cognate DNA sequence. This is the first direct evidence of the mode of DNA recognition in the ⁵⁴-dependent class of enhancer-binding proteins.

	SUPPLEMENTARY MATERIAL

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 
Supplementary Material is available at NAR Online.

	ACKNOWLEDGEMENTS

 
We thank S. Kustu for the kind gift of plasmid pJES470, Y. Gao and A. J. Pemberton for maintenance of the NMR instrumentation at the University of Birmingham and A. L. Lovering for modelling NifA. This study was supported in part by a BBSRC-CASE studentship (to P.R.). The NMR instrumentation at the University of Birmingham was supported in part by grant 056432 from the Wellcome Trust (to E.I.H.), while the computing facilities were purchased by grant G460017 from the MRC. K.J.S. was supported by grant G9815098 from the MRC.

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TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION SUPPLEMENTARY MATERIAL REFERENCES

 

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