Human endogenous retroviral element K10 (HERV-K10) encodes a full-length gag homologous 73-kDa protein and a functional protease

The gag-homologous region of the human endogenous retrovirus K10 (HERV-K10) was amplified by PCR from human genomic DNA and was analyzed by DNA cloning, sequencing, and expression of open reading frames in the prokaryotic pATH expression system. The analysis of genomic DNA of three donors provided evidence that HERV-K10 genes contain an open reading frame of 1966 bp spanning the entire gag-homologous region. In the prokaryotic system the entire reading frame of the HERV-K10 gag gene could be expressed as a fusion protein exhibiting a molecular weight of about 110,000. In addition, when the gag-homologous region and the adjacent HERV-K10 protease gene were prokaryotically expressed, we observed a Gag-protease fusion protein that exhibited specific autoproteolytic activities and processing of HERV-K10 Gag protein. By introducing deletions on the right end of the putative protease gene an autocatalytic site could be localized within 300 bp of the putative HERV-K10 protease gene. For the first time, these results provide evidence that the HERV-K10 encodes a full-length Gag protein and a functional protease.

Core RNA polymerase assists binding of the transcription factor sigma 54 to promoter DNA

The sigma subunit of bacterial RNA polymerase is necessary for the specific binding of RNA polymerase holoenzyme to promoter DNA. Promoter complexes which form with holoenzyme containing sigma 54 remain as closed complexes unless they are activated by one class of enhancer binding protein. The sigma 54 transcription factor can bind specifically to certain promoter sites in the absence of the core RNA polymerase subunits. This property has allowed demonstration of a new role for core polymerase in transcription, namely that it assists the binding of sigma 54 to promoter DNA. An altered form of sigma 54 with a deletion within the amino-terminal region showed increased affinity for specific DNA-binding sites. Although able to complex with core RNA polymerase the mutant sigma 54 failed to respond to core polymerase in the manner characteristic of the wild-type sigma 54 by altering its footprint. This result indicates that sigma 54 has a latent DNA-binding activity which is revealed by core RNA polymerase, and possibly involves a change in sigma 54 conformation. Promoter complexes which formed with sigma 54-holoenzyme appeared to be qualitatively different, depending upon the target promoter sequence, suggesting that different activatable complexes form at different promoter sequences.

The Klebsiella pneumoniae nifJ promoter: analysis of promoter elements regulating activation by the NifA promoter

The nifJ and nifH promoters of Klebsiella pneumoniae are divergently transcribed sigma 54-dependent promoters that are positively activated by the NifA protein. NifA binds to upstream activator sequences (UASs), usually located 60-200 bp upstream of the start of transcription. Bound NifA is presented to the RNA polymerase-sigma 54 complex (E sigma 54) via DNA loop formation, mediated by the binding of integration host factor protein (IHF) between E sigma 54 and NifA. The nifJ promoter sequence contains three potential NifA binding sites (UAS1, 2 and 3) and two potential RNA polymerase-sigma 54-binding sites (downstream promoter elements, DPEs 1 and 2). DPE2 is located 420 bp into the coding region and DPE1 overlaps UAS1 by 5 bp. Mutational and footprinting analyses have shown efficient activation of the nifJ promoter requires that NifA is bound at UAS 2 and 3. Transcription is initiated at DPE1. Only a weak interaction of NifA with the UAS overlapping DPE1 was detected. Footprints demonstrated that E sigma 54 forms a closed complex at DPE1 but not DPE2 and that bound E sigma 54 closely approaches the -15 region of DPE1. Stimulation of nifJ promoter activity by IHF was not as great as that observed for other nif promoters. In the absence of IHF nifH promoter sequences stimulated activation of the nifJ promoter. This appeared to require NifA bound at the nifH UAS. Thus, one additional role of IHF may be to partition NifA between the two promoters by constraining the topology of the DNA.

A partially folded state of hen egg white lysozyme in trifluoroethanol: structural characterization and implications for protein folding

The effect of 2,2,2-trifluoroethanol (TFE) on the solution conformation of hen egg white lysozyme has been investigated using circular dichroism (CD) and 1H nuclear magnetic resonance (NMR) spectroscopy. Addition of TFE to lysozyme at pH 2.0, 27 degrees C, up to a concentration of 15% (v/v) induces only slight changes in the NMR spectrum. However, above this concentration a cooperative transition to a new but partially structured state of the protein is observed. This state shows no structural cooperativity against further denaturation and is characterized by an ellipticity in the far-UV CD greater than that of the native protein. Near-UV CD intensity is dramatically reduced compared with that of the native state, and 1H NMR studies indicate that side-chain interactions are substantially averaged in this denatured state. Solvent proton/deuterium exchange rates for 66 amide hydrogens were measured site-specifically by a combination of amide trapping experiments and 2D 1H NMR. Significant protection from exchange occurs for about 25 backbone amides, the majority of which are located in regions of the protein that are helical in the native enzyme. By contrast, amides located in a second region of the native protein which contains a beta-sheet and one 3(10)-helix as well as a long loop show little protection. This pattern of protection resembles that found in the stable molten globule state of alpha-lactalbumin and in an early kinetic intermediate detected in the refolding of hen lysozyme.

Expression of Epstein-Barr virus membrane antigen gp350/220 in E. coli and in insect cells

The Epstein-Barr virus open reading frame BLLF1 encodes the major envelope glycoproteins gp350 and gp220. Fragments of the gp350/220 gene were expressed in Escherichia coli in order to define regions of the polypeptide chain reacting with human sera. The C-terminal half of the protein was sufficient for recognition by all VCA-positive sera tested. A membrane anchor truncated version of gp350/220 was expressed in insect cells using the baculovirus system. Proteins of different sizes were specifically detected in the cells while a glycosylated 220-kDa protein was secreted. The insect cells were tested for their suitability as tools for performing monospecific immunofluorescence.

Hydrogen exchange in native and denatured states of hen egg-white lysozyme

The hydrogen exchange kinetics of 68 individual amide protons in the native state of hen lysozyme have been measured at pH 7.5 and 30 degrees C by 2D NMR methods. These constitute the most protected subset of amides, with exchange half lives some 10(5)-10(7) times longer than anticipated from studies of small model peptides. The observed distribution of rates under these conditions can be rationalized to a large extent in terms of the hydrogen bonding of individual amides and their burial from bulk solvent. Exchange rates have also been measured in a reversibly denatured state of lysozyme; this was made possible under very mild conditions, pH 2.0 35 degrees C, by lowering the stability of the native state through selective cleavage of the Cys-6-Cys-127 disulfide cross-link (CM6-127 lysozyme). In this state the exchange rates for the majority of amides approach, within a factor of 5, the values anticipated from small model peptides. For a few amides, however, there is evidence for significant retardation (up to nearly 20-fold) relative to the predicted rates. The pattern of protection observed under these conditions does not reflect the behavior of the protein under strongly native conditions, suggesting that regions of native-like structure do not persist significantly in the denatured state of CM6-127 lysozyme. The pattern of exchange rates from the native protein at high temperature, pH 3.8 69 degrees C, resembles that of the acid-denatured state, suggesting that under these conditions the exchange kinetics are dominated by transient global unfolding. The rates of folding and unfolding under these conditions were determined independently by magnetization transfer NMR methods, enabling the intrinsic exchange rates from the denatured state to be deduced on the basis of this model, under conditions where the predominant equilibrium species is the native state. Again, in the case of most amides these rates showed only limited deviation from those predicted by a simple random coil model. This reinforces the view that these denatured states of lysozyme have little persistent residual order and contrasts with the behavior found for compact partially folded states of proteins, including an intermediate detected transiently during the refolding of hen lysozyme.

Specific binding of the transcription factor sigma-54 to promoter DNA

A central event in transcription is the assembly on DNA of specific complexes near the initiation sites for RNA synthesis. Activation of transcription by one class of enhancer-binding proteins requires an RNA polymerase holoenzyme containing the specialized transcription factor, sigma-54 (sigma 54). We report here that sigma 54 alone specifically binds to promoter DNA and is responsible for many of the close contacts between RNA polymerase holoenzyme and promoter DNA, a property proposed for the major sigma 70 protein family. Binding of sigma 54 to promoter DNA is not equivalent to that of holoenzyme suggesting that there is a constraint on sigma 54 conformation when bound with core RNA polymerase. Footprints indicate sigma 54 is at the leading edge of DNA-bound holoenzyme. Like the holoenzyme, sigma 54-binding to promoter DNA does not result in DNA strand separation. Instead the specific DNA-binding activity of sigma 54 assists assembly of a closed promoter complex. This complex can be isomerized to the open (DNA melted) complex by activator protein, but promoter-bound sigma 54 alone cannot be induced to melt DNA. The pathway leading to productive transcription is similar to that proposed for eukaryotic RNA polymerase II systems.

Activator-independent formation of a closed complex between sigma 54-holoenzyme and nifH and nifU promoters of Klebsiella pneumoniae

The alternative sigma factor sigma 54 is required for transcription of nitrogen fixation genes in Klebsiella pneumoniae and other diazotrophs. The nif genes, and other E sigma 54-dependent genes whose products are necessary for a wide range of processes, are postively regulated. A unifying model that is well supported by studies on nif and other nitrogen-regulated (ntr) genes includes the central tenet that sigma 54 confers upon core RNA polymerase the ability to recognize and bind specific promoter sequences, but not the ability to isomerize to the open complex without assistance from the appropriate activator protein. Direct physical evidence for formation of an activator-independent complex between E sigma 54 and the NifA-dependent K. pneumoniae nifH and nifU promoters has, to date, been lacking. Using purified components we have now demonstrated formation of the closed complex at these promoters, indicating that it is an intermediate along the pathway to open complex formation. The closed complex was not detected when conserved features of the promoter were altered by mutation, nor was its stability increased when integration host factor protein was bound adjacent to the E sigma 54 recognition sequence.

Central domain of the positive control protein NifA and its role in transcriptional activation

The positive control protein NifA of Klebsiella pneumoniae activates transcription by RNA polymerase containing sigma 54 by catalysing open promoter complex formation. We show that the integrity of the putative ATP-binding pocket in the central domain of NifA is necessary for the positive control function of NifA, but is not required for DNA-binding or recognition of NifA by NifL. The inactive mutant NifA proteins are trans dominant to wild-type NifA and are unable to catalyse formation of open promoter complexes irrespective of whether a closed promoter complex at the nifH promoter has preformed. Formation of the closed complex results in a DNA structural distortion adjacent to the DNA region melted in the open promoter complex. This distortion lies at the leading edge of the E sigma 54 footprint. Although unable to catalyse open complex formation, some mutant NifAs altered the chemical reactivity of the distorted base-pair indicating that they retain the ability to recognize the closed promoter complex. The activation phenotype of partially active NifA molecules was sensitive to promoter sequences known to influence closed complex formation, indicating differences in (1) the susceptibility of the closed complexes towards activation and (2) their requirements for NifA during activation.

Expression of the HIV-1 Nef protein in the baculovirus system: investigation of anti-Nef antibodies response in human sera and subcellular localization of Nef

The nef gene of HIV-1 was expressed in insect cells using the eucaryotic baculovirus system. The recombinant Nef protein frequently reacted with seropositive sera of HIV-1 and HIV-2 infected patients. Anti-Nef antibodies in HIV-1 seronegative high risk groups individuals were only occasionally seen. Confocal laser scanning microscopy demonstrated that Nef is present both in the cytoplasm and in the nucleus, indicating that Nef might directly function on gene expression.

Preparation and properties of des-Tyr98 and des-Arg97-Tyr98 acylphosphatase (muscular isoenzyme)

Previous NMR reports indicated that Tyr98, the C-terminal residue of the muscular form of acylphosphatase, is likely to be part of the enzyme's active site. In addition, there is evidence that an arginine residue participates to the catalyzed reaction, possibly as phosphate binding site. Among all Arg residues present in the muscular forms of acylphosphatase, four, i.e. Arg23, Arg74, Arg77, and Arg97, appear to be conserved in all species checked thus far. We prepared the des-Tyr98 and des-Arg97-Tyr98 derivatives of the native acylphosphatase to investigate the properties of both modified enzymes. The enzyme lacking Tyr98 was found to be catalytically less effective than the native one, whereas the des-Arg97-Tyr98 acylphosphatase was completely inactive. This evidence suggests that Arg97 participates directly to the active site catalytic mechanism. Fluorescence and CD spectra revealed that the latter enzyme could have been undergone some conformational change that could account for the loss of activity; on the other hand, the one-dimensional NMR spectra of either native and des-Arg97-Tyr98 enzymes were strictly similar, thus demonstrating that the removal of the two C-terminal residues does not markedly affect the fold of the enzyme. The results reported are proof of a critical contribution of Arg97 to the acylphosphatase active site; however, we cannot exclude that the function of this residue is merely to stabilize the active site conformation and dynamics.

Activation of the Pseudomonas TOL plasmid upper pathway operon. Identification of binding sites for the positive regulator XylR and for integration host factor protein

Expression of the Pseudomonas putida TOL plasmid upper pathway operon requires a promoter that belongs to the -12/-24 class. Stimulation of transcription from this promoter is positively controlled by the effector-activated XylR protein and requires a form of RNA-polymerase holoenzyme containing the RpoN-encoded sigma factor, sigma 54. XylR-dependent stimulation of transcription from the Pseudomonas TOL upper pathway promoter was examined using deletions, insertions, and in vivo dimethyl sulfate footprinting. Two upstream activator sequences were identified in the -160 (UAS1) and -130 (UAS2) regions. Deletion of these two regions abolished transcription activation, although conservation of the UAS2 element alone allowed limited transcription stimulation. Separation of UAS1 from UAS2 by half a turn or a full turn significantly reduced XylR stimulation of transcription from the upper pathway operon promoter. An inverted repeated ATTTGN2CAAAT (where N is any nucleoside), which most likely represented the XylR recognition sequence, was identified. Binding of XylR was observed in vivo in the absence of effector, but changes in the binding pattern were induced in the presence of m-methylbenzyl alcohol, a XylR effector. In vivo footprinting analysis revealed that changes in the methylation pattern of G and T also occurred in the -50 to -90 region, which is probably occupied by integration host factor (IHF) protein. IHF was required for maximal expression from the TOL upper pathway operon promoter in Escherichia coli. Separation of the IHF site from UAS2 by a full helix turn did not significantly affect stimulation of transcription, which is consistent with this region playing a conformational role, rather than a regulatory one, in promoter function.

Organization and function of binding sites for the transcriptional activator NifA in the Klebsiella pneumoniae nifE and nifU promoters

The interaction of the Klebsiella pneumoniae NifA protein, a sigma 54-dependent activator, with the nifE and nifU promoters was analysed. At these promoters NifA established contacts in addition to those predicted by the minimal formulation NifA binding site (5'-TGT-N10-ACA). The positions of the contacts indicate that bound NifA molecules could assemble to form an oligomer. At both promoters contacts with NifA are made predominantly on one face of the DNA helix, and all contacts appear necessary for full activation by NifA. The close contacts made by NifA appear to be made by the DNA-binding domain of NifA. This domain shows specific DNA-binding activity in vitro. The binding of NifA to one site in the nifU promoter depends upon occupancy of additional upstream sequences by NifA. At the nifE promoter NifA binds adjacent to an integration host factor (IHF) binding site, but in contrast to results obtained with the nifU promoter IHF does not diminish nifE promoter occupancy by NifA. The IHF requirement for efficient in vivo activation of the nifU promoter by NifA was greater than that of the nifE promoter. Accordingly, the affinity of IHF for the nifU promoter is higher than for the nifE promoter. Amongst promoters utilizing the sigma 54 holoenzyme, the nifE promoter appears somewhat atypical in having the activator bound at around position -74 rather than the usual 100 base-pairs or more upstream from the transcription start site.

Biochemical characterization of phosphorylation site mutants of simian virus 40 large T antigen: evidence for interaction between amino- and carboxy-terminal domains

The simian virus 40 large T antigen is phosphorylated at eight or more sites that are clustered in an amino-terminal region and a carboxy-terminal region of the protein. Mutants carrying exchanges at these phosphorylation sites have been generated in vitro by bisulfite or oligonucleotide-directed mutagenesis and analyzed for their phosphorylation patterns. Two-dimensional phosphopeptide analyses of the mutant large T antigens confirmed most of the previously identified phosphorylation sites, namely, serine residues 106, 112, 123, 639, 677, and 679 and threonine residues 124 and 701. In addition, serine residue 120 was identified as a new site, whereas serines residues 111 and 676 were excluded. Interestingly, several of the mutants exhibited secondary effects in that a mutation in the amino-terminal region affected phosphorylation at distant and even carboxy-terminal sites and vice versa. Thus, the amino- and carboxy-terminal domains appear to be in close proximity in the three-dimensional structure of large T antigen. The possible consequences of the above findings and the role of phosphorylation are discussed.

Immunological study of the nef protein from HIV-1 by polyclonal and monoclonal antibodies

We constructed and expressed different overlapping fusion proteins with the nef gene of HIV-1 and generated specific polyclonal rabbit and monoclonal mouse antibodies against these recombinant proteins. The rabbit antisera, one of the monoclonal antibodies as well as a serum from a HIV-1 infected patient recognized the nef protein with Mr 27 kDa in latently HIV-1 infected glioma cells in the immunoblot. In contrast, these antibodies could not detect nef in productively HIV-1 infected Molt-3 cells neither in immunoblot nor in indirect immunofluorescence assays. These results indicate the possible participation of nef in viral latency. The recombinant nef proteins were used as probes for anti-nef antibodies in human sera. We observed in 17 of 57 sera tested specific anti-nef antibodies. All of these anti-nef positive sera also contained antibodies directed against viral structural proteins. The NH2-terminal region of the recombinant nef was shown to be the major immunodominant antigenic site in the immunoblot assay.

Analysis of site-directed mutations in the alpha- and beta-subunits of Klebsiella pneumoniae nitrogenase

Using directed mutagenesis, amino acid substitutions have been made in the alpha- and beta-subunits of the klebsiella pneumoniae nitrogenase component 1 at positions normally occupied by conserved cysteine or tyrosine residues. Nif+, Nif- and intermediate phenotypes have been obtained. To extend our earlier biochemical characterization (Kent et al., 1989) the electrophoretic mobility of component 1 of the mutant and wild-type nitrogenases has been analysed by non-denaturing gel electrophoresis. The major and minor forms of component 1 separated by this methodology have been probed for by using both polyclonal and monoclonal antibodies. All Nif+ mutants exhibited a distribution of electrophoretic forms of component 1 comparable to the wild type, and the abundance of the major form found in purified nitrogenase correlated approximately with the specific activity of the extract. In contrast, after electrophoresis, component 1 from Nif- mutants exhibited either a major low-mobility form or a fast-moving form. Analysis of nitrogenase polypeptides synthesized in the absence of co-factor (FeMoco) allowed us to conclude that changing cysteine 275 to alanine in the alpha-subunit produces component 1 defective in its interaction with FeMoco. Substitution of other conserved cysteine residues by alanine appears to prevent early steps in nitrogenase assembly or to promote degradation. Two single mutations (cysteine 89 to alanine in the alpha-subunit and cysteine 94 to alanine in the beta-subunit) which are tightly Nif- can be combined to produce a weakly active nitrogenase, indicating regions involved in the interaction between subunits.

The influence of the Klebsiella pneumoniae regulatory gene nifL upon the transcriptional activator protein NifA

The influence of the Klebsiella pneumoniae nifL gene product upon the interaction of the transcriptional activator protein NifA with the nifH promoter has been examined using in vivo dimethylsulphate 'footprinting'. Binding of NifA to the upstream activator sequence (UAS) of the nifH promoter in the presence of the NifL protein was observed under nitrogen-limiting growth conditions. Growth in the presence of NH4+ or addition of NH4+ to nitrogen-limited cells diminished the interaction of NifA with the UAS when NifL was present. Repression of nif transcription by NifL may therefore involve an interaction between NifL and NifA which reduces the affinity of NifA for the UAS.

Activation of the Klebsiella pneumoniae nifU promoter: identification of multiple and overlapping upstream NifA binding sites

The Klebsiella pneumoniae nifU promoter is positively controlled by the NifA protein and requires a form of RNA polymerase holoenzyme containing the rpoN encoded sigma factor, sigma 54. Occupancy of the K. pneumoniae nifU promoter by NifA was examined using in vivo dimethyl sulphate footprinting. Three binding sites for NifA (Upstream Activator Sequences, UASs 1, 2 and 3) located at -125, -116 and -72 were identified which conform to the UAS consensus sequence TGT-N10-ACA. An additional NifA binding site was identified at position -90. The UASs located at -125 (UAS1) and -116 (UAS2) overlap and do not appear to bind NifA as independent sites. They may represent a NifA binding site interacting with two NifA dimers. UAS3 is located at -72, and abuts a binding site for integration host factor (IHF) and is not normally highly occupied by NifA. In the absence of IHF UAS3 showed increased occupancy by NifA. Mutational and footprinting analysis of the three UASs indicates (1) IHF and NifA can compete for binding and that this competition influences the level of expression from the nifU promoter (2) that UAS2 is a principle sequence of the UAS 1,2 region required for activation and (3) that none of the NifA binding sites interacts with NifA independently. In vivo KMnO4 footprinting demonstrated that NifA catalyses open complex formation at the nifU promoter. IHF was required for maximal expression from the nifU and nifH promoters in Escherichia coli, and for the establishment of a Nif+ phenotype in E. coli from the nif plasmid pRD1.

Tumor necrosis factor-alpha inhibits albumin gene expression in a murine model of cachexia

The mechanisms responsible for decreased serum albumin levels in patients with cachexia-associated infection, inflammation, and cancer are unknown. Since tumor necrosis factor-alpha (TNF alpha) is elevated in cachexia-associated diseases, and chronic administration of TNF alpha induces cachexia in animal models, we assessed the regulation of albumin gene expression by TNF alpha in vivo. In this animal model of cachexia, Chinese hamster ovary cells transfected with the functional gene for human TNF alpha were inoculated into nude mice (TNF alpha mice). TNF alpha mice became cachectic and manifested decreased serum albumin levels, albumin synthesis, and albumin mRNA levels. However, even before the TNF alpha mice lost weight, their albumin mRNA steady-state levels were decreased approximately 90%, and in situ hybridization revealed a low level of albumin gene expression throughout the hepatic lobule. The mRNA levels of several other genes were unchanged. Hepatic nuclei from TNF alpha mice before the onset of weight loss were markedly less active in transcribing the albumin gene than hepatic nuclei from control mice. Therefore, TNF alpha selectively inhibits the genetic expression of albumin in this model before weight loss.

Site-directed mutagenesis of the Klebsiella pneumoniae nitrogenase. Effects of modifying conserved cysteine residues in the alpha- and beta-subunits

The five conserved cysteine residues present in the alpha-subunit and the three conserved cysteine residues present in the beta-subunit of nitrogenase component 1 were individually changed to alanine. Mutations in the alpha-subunit at positions 63, 89, 155 and 275 and in the beta-subunit at positions 69, 94 and 152 all resulted in a loss of diazotrophic growth and component 1 activity and loss of the normal e.p.r. signal of the component 1 protein. Component 2 activity was retained. Replacement of cysteine-184 in the alpha-subunit with alanine greatly diminished, but did not eliminate, diazotrophic growth and component 1 activity. Substitution of serine for cysteine at position 152 in the beta-subunit, in contrast with the substitution of alanine at this position, resulted in the formation of active component 1. Replacement of the non-conserved cysteine-112 in the beta-subunit with alanine did not greatly perturb diazotrophic growth or the activity of component 1. Extracts prepared from a mutant, with cysteine-275 of the alpha-subunit replaced by alanine, complemented extracts of a mutant unable to synthesize the iron-molybdenum cofactor of nitrogenase, indicating that the alanine-275 substitution increases the availability of cofactor. Furthermore extracts of this mutant exhibited an e.p.r. signal similar to that of extracted iron-molybdenum cofactor. These data suggest a role for cysteine-275 as a ligand to the cofactor.

In vivo studies on the interaction of RNA polymerase-sigma 54 with the Klebsiella pneumoniae and Rhizobium meliloti nifH promoters. The role of NifA in the formation of an open promoter complex

Transcription from the Klebsiella pneumoniae and Rhizobium meliloti nifH promoters requires the positive control protein NifA and the alternative sigma factor sigma 54, encoded by the rpoN gene. Transcription from the K. pneumoniae nifH promoter is fully dependent upon NifA bound at the upstream activator sequence (UAS) whereas the R. meliloti nifH promoter can be efficiently activated in the absence of this sequence and can also be activated by a mutant form of NifA unable to bind the UAS. The in vivo interaction of RNA polymerase-sigma 54 with these promoters was examined using dimethyl sulphate footprinting. The R. meliloti nifH promoter but not the K. pneumoniae nifH promoter showed sigma 54-dependent methylation protection of guanine residues at -14, -25 and -26, the most conserved nucleotides characteristic of sigma 54-dependent promoters. A mutant derivative of the K. pneumoniae nifH promoter bearing transitions at positions from -15 to -17 showed sigma 54-dependent methylation protection of guanines -13, -24 and -25. The enhanced interaction of the RNA polymerase-sigma 54 with this mutant promoter correlates with its increased level of activation by a form of NifA unable to bind the UAS. Use of in vivo KMnO4 footprinting to detect single-stranded pyrimidine residues and in vivo methylation protection demonstrated that the sigma 54-dependent protection observed in the R. meliloti and mutant K. pneumoniae nifH promoter results from the formation of a closed promoter complex. The isomerization of the pre-existing closed complex to an open promoter form, as judged by the local denaturation of promoter DNA which rendered sequences from +5 to -10 reactive towards KMnO4, was shown to be fully dependent on NifA. We propose a model in which the fidelity of activation of sigma 54-dependent promoters relies on a weak activator-independent interaction of RNA polymerase-sigma 54 with the promoter. A specific interaction of the appropriate activator with its respective UAS is then required for the positive control protein to facilitate open complex formation.