Purification and characterization of the AAA+ domain of Sinorhizobium meliloti DctD, a sigma54-dependent transcriptional activator

Combined In Silico and In Vitro Study to Reveal the Structural Insights and Nucleotide-Binding Ability of the Transcriptional Regulator PehR from the Phytopathogen Ralstonia solanacearum

The transcriptional regulator PehR regulates the synthesis of the extracellular plant cell wall-degrading enzyme polygalacturonase, which is essential in the bacterial wilt of plants caused by one of the most devastating plant phytopathogens, Ralstonia solanacearum. The bacterium has a wide global distribution infecting many different plant species, resulting in massive agricultural and economic losses. Because the PehR molecular structure has not yet been determined and the structural consequences of PehR on ligand binding have not been thoroughly investigated, we have used an in silico approach combined with in vitro experiments for the first time to characterize the PehR regulator from a local isolate (Tezpur, Assam, India) of the phytopathogenic bacterium R. solanacearum F1C1. In this study, an in silico approach was employed to model the 3D structure of the PehR regulator, followed by the binding analysis of different ligands against this regulatory protein. Molecular docking studies suggest that ATP has the highest binding affinity for the PehR regulator. By using molecular dynamics (MD) simulation analysis, involving root-mean-square deviation, root-mean-square fluctuations, hydrogen bonding, radius of gyration, solvent-accessible surface area, and principal component analysis, it was possible to confirm the sudden conformational changes of the PehR regulator caused by the presence of ATP. We used an in vitro approach to further validate the formation of the PehR-ATP complex. In this approach, recombinant DNA technology was used to clone, express, and purify the gene encoding the PehR regulator from R. solanacearum F1C1. Purified PehR was used in ATP-binding experiments using fluorescence spectroscopy and Fourier transform infrared spectroscopy, the outcomes of which showed a potent binding to ATP. The putative PehR-ATP-binding analysis revealed the importance of the amino acids Lys190, Glu191, Arg192, Arg375, and Asp378 for the ATP-binding process, but further study is required to confirm this. It will be simpler to comprehend the catalytic mechanisms of a crucial PehR regulator process in R. solanacearum with the aid of the ATP-binding process hints provided by these structural biology applications.

Engineering Transcription Factor BmoR Mutants for Constructing Multifunctional Alcohol Biosensors

Native transcription factor-based biosensors (TFBs) have the potential for the in situ detection of value-added chemicals or byproducts. However, their industrial application is limited by their ligand promiscuity, low sensitivity, and narrow detection range. Alcohols exhibit similar structures, and no reported TFB can distinguish a specific alcohol from its analogues. Here, we engineered an alcohol-regulated transcription factor, BmoR, and obtained various mutants with remarkable properties. For example, the generated signal-molecule-specific BmoRs could distinguish the constitutional isomers n-butanol and isobutanol, with insensitivity up to an ethanol concentration of 800 mM (36.9 g/L). Linear detection of 0-60 mM of a specific higher alcohol could be achieved in the presence of up to 500 mM (23.0 g/L) ethanol as background noise. Furthermore, we obtained two mutants with raised outputs and over 10⁷-fold higher sensitivity and one mutant with an increased upper detection limit (14.8 g/L n-butanol or isobutanol). Using BmoR as an example, this study systematically explored the ultimate detection limit of a TFB toward its small-molecule ligands, paving the way for in situ detection in biofuel and wine industries.

Sigma 54-Regulated Transcription Is Associated with Membrane Reorganization and Type III Secretion Effectors during Conversion to Infectious Forms of Chlamydia trachomatis

The factors that control the growth and infectious processes for Chlamydia are still poorly understood. This study used recently developed genetic tools to determine the regulon for one of the key transcription factors encoded by Chlamydia, sigma 54. Surrogate and computational analyses provide additional support for the hypothesis that sigma 54 plays a key role in controlling the expression of many components critical to converting and enabling the infectious capability of Chlamydia. These components include those that remodel the membrane for the extracellular environment and incorporation of an arsenal of type III secretion effectors in preparation for infecting new cells.

Chlamydia bacteria are obligate intracellular organisms with a phylum-defining biphasic developmental cycle that is intrinsically linked to its ability to cause disease. The progression of the chlamydial developmental cycle is regulated by the temporal expression of genes predominantly controlled by RNA polymerase sigma (σ) factors. Sigma 54 (σ⁵⁴) is one of three sigma factors encoded by Chlamydia for which the role and regulon are unknown. CtcC is part of a two-component signal transduction system that is requisite for σ⁵⁴ transcriptional activation. CtcC activation of σ⁵⁴ requires phosphorylation, which relieves inhibition by the CtcC regulatory domain and enables ATP hydrolysis by the ATPase domain. Prior studies with CtcC homologs in other organisms have shown that expression of the ATPase domain alone can activate σ⁵⁴ transcription. Biochemical analysis of CtcC ATPase domain supported the idea of ATP hydrolysis occurring in the absence of the regulatory domain, as well as the presence of an active-site residue essential for ATPase activity (E242). Using recently developed genetic approaches in Chlamydia to induce expression of the CtcC ATPase domain, a transcriptional profile was determined that is expected to reflect the σ⁵⁴ regulon. Computational evaluation revealed that the majority of the differentially expressed genes were preceded by highly conserved σ⁵⁴ promoter elements. Reporter gene analyses using these putative σ⁵⁴ promoters reinforced the accuracy of the model of the proposed regulon. Investigation of the gene products included in this regulon supports the idea that σ⁵⁴ controls expression of genes that are critical for conversion of Chlamydia from replicative reticulate bodies into infectious elementary bodies.

Engineering transcription factor BmoR for screening butanol overproducers

The wild-type transcription factors are sensitive to their corresponding signal molecules. Using wild-type transcription factors as biosensors to screen industrial overproducers are generally impractical because of their narrow detection ranges. This study took transcription factor BmoR as an example and aimed to expand the detection range of BmoR for screening alcohols overproducers. Firstly, a BmoR mutation library was established, and the mutations distributed randomly in all predicted functional domains of BmoR. Structure of BmoR-isobutanol complex were modelled, and isobutanol binding sites were confirmed by site-directed mutagenesis. Subsequently, the effects of the mutations on the detection range or output were confirmed in the BmoR mutants. Four combinatorial mutants containing one increased-detection-range mutation and one enhanced-output mutation were constructed. Compared with wild-type BmoR, F276A/E627N BmoR and D333N/E627N BmoR have wider detection ranges (0-100 mM) and relatively high outputs to the isobutanol added quantitatively or produced intracellularly, demonstrating they have potential for screening isobutanol overproduction strains. This work presented an example of engineering the wild-type transcription factors with physiological significance for industrial utilization.

Nucleotide Dependence of Subunit Rearrangements in Short-Form Rubisco Activase from Spinach

Higher-plant Rubisco activase (Rca) plays a critical role in regulating the activity of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco). In vitro, Rca is known to undergo dynamic assembly-disassembly processes, with several oligomer stoichiometries coexisting over a broad concentration range. Although the hexamer appears to be the active form, changes in quaternary structure could play a role in Rubisco regulation. Therefore, fluorescent labels were attached to the C-termini of spinach β-Rca, and the rate of subunit mixing was monitored by measuring energy transfer as a function of nucleotide and divalent cation. Only dimeric units appeared to exchange. Poorly hydrolyzable substrate analogues provided locked complexes with high thermal stabilities (apparent T_m = 60 °C) and an estimated t_1/2 of at least 7 h, whereas ATP-Mg provided tight assemblies with t_1/2 values of 30-40 min and ADP-Mg loose assemblies with t_1/2 values of <15 min. Accumulation of ADP to 20% of the total level of adenine nucleotide substantially accelerated equilibration. An initial lag period was observed with ATP·Mg, indicating inhibition of subunit exchange at low ADP concentrations. The ADP K_i value was estimated to exceed the K_m for ATP (0.772 ± 96 mM), suggesting that the equilibration rate is a function of the relative contributions of high- and low-affinity states. C-Terminal cross-linking generated covalent dimers, required the N-terminal extension to the AAA+ domain, and provided evidence of different classes of sites. We propose that oligomer reorganization may be stalled during periods of high Rubisco reactivation activity, whereas changes in quaternary structure are stimulated by the accumulation of ADP at low light levels.

Novel DNA Binding and Regulatory Activities for σ54 (RpoN) in Salmonella enterica Serovar Typhimurium 14028s

The variable sigma (σ) subunit of the bacterial RNA polymerase (RNAP) holoenzyme, which is responsible for promoter specificity and open complex formation, plays a strategic role in the response to environmental changes. Salmonella enterica serovar Typhimurium utilizes the housekeeping σ⁷⁰ and five alternative sigma factors, including σ⁵⁴ The σ⁵⁴-RNAP differs from other σ-RNAP holoenzymes in that it forms a stable closed complex with the promoter and requires ATP hydrolysis by an activated cognate bacterial enhancer binding protein (bEBP) to transition to an open complex and initiate transcription. In S. Typhimurium, σ⁵⁴-dependent promoters normally respond to one of 13 different bEBPs, each of which is activated under a specific growth condition. Here, we utilized a constitutively active, promiscuous bEBP to perform a genome-wide identification of σ⁵⁴-RNAP DNA binding sites and the transcriptome of the σ⁵⁴ regulon of S. Typhimurium. The position and context of many of the identified σ⁵⁴ RNAP DNA binding sites suggest regulatory roles for σ⁵⁴-RNAP that connect the σ⁵⁴ regulon to regulons of other σ factors to provide a dynamic response to rapidly changing environmental conditions.IMPORTANCE The alternative sigma factor σ⁵⁴ (RpoN) is required for expression of genes involved in processes with significance in agriculture, bioenergy production, bioremediation, and host-microbe interactions. The characterization of the σ⁵⁴ regulon of the versatile pathogen S. Typhimurium has expanded our understanding of the scope of the σ⁵⁴ regulon and how it links to other σ regulons within the complex regulatory network for gene expression in bacteria.

Subunit dynamics and nucleotide-dependent asymmetry of an AAA(+) transcription complex

Bacterial enhancer binding proteins (bEBPs) are transcription activators that belong to the AAA(+) protein family. They form higher-order self-assemblies to regulate transcription initiation at stress response and pathogenic promoters. The precise mechanism by which these ATPases utilize ATP binding and hydrolysis energy to remodel their substrates remains unclear. Here we employed mass spectrometry of intact complexes to investigate subunit dynamics and nucleotide occupancy of the AAA(+) domain of one well-studied bEBP in complex with its substrate, the σ(54) subunit of RNA polymerase. Our results demonstrate that the free AAA(+) domain undergoes significant changes in oligomeric states and nucleotide occupancy upon σ(54) binding. Such changes likely correlate with one transition state of ATP and are associated with an open spiral ring formation that is vital for asymmetric subunit function and interface communication. We confirmed that the asymmetric subunit functionality persists for open promoter complex formation using single-chain forms of bEBP lacking the full complement of intact ATP hydrolysis sites. Outcomes reconcile low- and high-resolution structures and yield a partial sequential ATP hydrolysis model for bEBPs.

Use of a promiscuous, constitutively-active bacterial enhancer-binding protein to define the σ⁵⁴ (RpoN) regulon of Salmonella Typhimurium LT2

Background

Sigma54, or RpoN, is an alternative σ factor found widely in eubacteria. A significant complication in analysis of the global σ⁵⁴ regulon in a bacterium is that the σ⁵⁴ RNA polymerase holoenzyme requires interaction with an active bacterial enhancer-binding protein (bEBP) to initiate transcription at a σ⁵⁴-dependent promoter. Many bacteria possess multiple bEBPs, which are activated by diverse environmental stimuli. In this work, we assess the ability of a promiscuous, constitutively-active bEBP—the AAA+ ATPase domain of DctD from Sinorhizobium meliloti—to activate transcription from all σ⁵⁴-dependent promoters for the characterization of the σ⁵⁴ regulon of Salmonella Typhimurium LT2.

Results

The AAA+ ATPase domain of DctD was able to drive transcription from nearly all previously characterized or predicted σ⁵⁴-dependent promoters in Salmonella under a single condition. These promoters are controlled by a variety of native activators and, under the condition tested, are not transcribed in the absence of the DctD AAA+ ATPase domain. We also identified a novel σ⁵⁴-dependent promoter upstream of STM2939, a homolog of the cas1 component of a CRISPR system. ChIP-chip analysis revealed at least 70 σ⁵⁴ binding sites in the chromosome, of which 58% are located within coding sequences. Promoter-lacZ fusions with selected intragenic σ⁵⁴ binding sites suggest that many of these sites are capable of functioning as σ⁵⁴-dependent promoters.

Conclusion

Since the DctD AAA+ ATPase domain proved effective in activating transcription from the diverse σ⁵⁴-dependent promoters of the S. Typhimurium LT2 σ⁵⁴ regulon under a single growth condition, this approach is likely to be valuable for examining σ⁵⁴ regulons in other bacterial species. The S. Typhimurium σ⁵⁴ regulon included a high number of intragenic σ⁵⁴ binding sites/promoters, suggesting that σ⁵⁴ may have multiple regulatory roles beyond the initiation of transcription at the start of an operon.

The role of bacterial enhancer binding proteins as specialized activators of σ54-dependent transcription

Bacterial enhancer binding proteins (bEBPs) are transcriptional activators that assemble as hexameric rings in their active forms and utilize ATP hydrolysis to remodel the conformation of RNA polymerase containing the alternative sigma factor σ(54). We present a comprehensive and detailed summary of recent advances in our understanding of how these specialized molecular machines function. The review is structured by introducing each of the three domains in turn: the central catalytic domain, the N-terminal regulatory domain, and the C-terminal DNA binding domain. The role of the central catalytic domain is presented with particular reference to (i) oligomerization, (ii) ATP hydrolysis, and (iii) the key GAFTGA motif that contacts σ(54) for remodeling. Each of these functions forms a potential target of the signal-sensing N-terminal regulatory domain, which can act either positively or negatively to control the activation of σ(54)-dependent transcription. Finally, we focus on the DNA binding function of the C-terminal domain and the enhancer sites to which it binds. Particular attention is paid to the importance of σ(54) to the bacterial cell and its unique role in regulating transcription.

Engagement of arginine finger to ATP triggers large conformational changes in NtrC1 AAA+ ATPase for remodeling bacterial RNA polymerase

The NtrC-like AAA+ ATPases control virulence and other important bacterial activities through delivering mechanical work to σ54-RNA polymerase to activate transcription from σ54-dependent genes. We report the first crystal structure for such an ATPase, NtrC1 of Aquifex aeolicus, in which the catalytic arginine engages the γ-phosphate of ATP. Comparing the new structure with those previously known for apo and ADP-bound states supports a rigid-body displacement model that is consistent with large-scale conformational changes observed by low-resolution methods. First, the arginine finger induces rigid-body roll, extending surface loops above the plane of the ATPase ring to bind σ54. Second, ATP hydrolysis permits Pi release and retraction of the arginine with a reversed roll, remodeling σ54-RNAP. This model provides a fresh perspective on how ATPase subunits interact within the ring-ensemble to promote transcription, directing attention to structural changes on the arginine-finger side of an ATP-bound interface.

Signal sensory systems that impact σ⁵⁴ -dependent transcription

Alternative σ-factors of bacteria bind core RNA polymerase to program the specific promoter selectivity of the holoenzyme. Signal-responsive changes in the availability of different σ-factors redistribute the RNA polymerase among the distinct promoter classes in the genome for appropriate adaptive, developmental and survival responses. The σ(54) -factor is structurally and functionally distinct from all other σ-factors. Consequently, binding of σ(54) to RNA polymerase confers unique features on the cognate holoenzyme, which requires activation by an unusual class of mechano-transcriptional activators, whose activities are highly regulated in response to environmental cues. This review summarizes the current understanding of the mechanisms of transcriptional activation by σ(54) -RNA polymerase and highlights the impact of global regulatory factors on transcriptional efficiency from σ(54) -dependent promoters. These global factors include the DNA-bending proteins IHF and CRP, the nucleotide alarmone ppGpp, and the RNA polymerase-targeting protein DksA.

Activation and repression of a sigmaN-dependent promoter naturally lacking upstream activation sequences

The Pseudomonas sp. strain ADP protein AtzR is a LysR-type transcriptional regulator required for activation of the atzDEF operon in response to nitrogen limitation and cyanuric acid. Transcription of atzR is directed by the sigma(N)-dependent promoter PatzR, activated by NtrC and repressed by AtzR. Here we use in vivo and in vitro approaches to address the mechanisms of PatzR activation and repression. Activation by NtrC did not require any promoter sequences other than the sigma(N) recognition motif both in vivo and in vitro, suggesting that NtrC activates PatzR in an upstream activation sequences-independent fashion. Regarding AtzR-dependent autorepression, our in vitro transcription experiments show that the concentration of AtzR required for repression of the PatzR promoter in vitro correlates with AtzR affinity for its binding site. In addition, AtzR prevents transcription from PatzR when added to a preformed E-sigma(N)-PatzR closed complex, but isomerization to an open complex prevents repression. Gel mobility shift and DNase I footprint assays indicate that DNA-bound AtzR and E-sigma(N) are mutually exclusive. Taken together, these results strongly support the notion that AtzR represses transcription from PatzR by competing with E-sigma(N) for their overlapping binding sites. There are no previous reports of a similar mechanism for repression of sigma(N)-dependent transcription.

Identification of the binding site of the σ 54 hetero-oligomeric FleQ/FleT activator in the flagellar promoters of Rhodobacter sphaeroides

Expression of the flagellar genes in Rhodobacter sphaeroides is dependent on one of the four sigma-54 factors present in this bacterium and on the enhancer binding proteins (EBPs) FleQ and FleT. These proteins, in contrast to other well-characterized EBPs, carry out activation as a hetero-oligomeric complex. To further characterize the molecular properties of this complex we mapped the binding sites or upstream activation sequences (UASs) of six different flagellar promoters. In most cases the UASs were identified at approximately 100 bp upstream from the promoter. However, the activity of the divergent promoters flhAp-flgAp, which are separated by only 53 bp, is mainly dependent on a UAS located approximately 200 bp downstream from each promoter. Interestingly, a significant amount of activation mediated by the upstream or contralateral UAS was also detected, suggesting that the architecture of this region is important for the correct regulation of these promoters. Sequence analysis of the regions carrying the potential FleQ/FleT binding sites revealed a conserved motif. In vivo footprinting experiments with the motAp promoter allowed us to identify a protected region that overlaps with this motif. These results allow us to propose a consensus sequence that represents the binding site of the FleQ/FleT activating complex.

ADPase activity of recombinantly expressed thermotolerant ATPases may be caused by copurification of adenylate kinase of Escherichia coli

Except for apyrases, ATPases generally target only the gamma-phosphate of a nucleotide. Some non-apyrase ATPases from thermophilic microorganisms are reported to hydrolyze ADP as well as ATP, which has been described as a novel property of the ATPases from extreme thermophiles. Here, we describe an apparent ADP hydrolysis by highly purified preparations of the AAA+ ATPase NtrC1 from an extremely thermophilic bacterium, Aquifex aeolicus. This activity is actually a combination of the activities of the ATPase and contaminating adenylate kinase (AK) from Escherichia coli, which is present at 1/10,000 of the level of the ATPase. AK catalyzes conversion of two molecules of ADP into AMP and ATP, the latter being a substrate for the ATPase. We raise concern that the observed thermotolerance of E. coli AK and its copurification with thermostable proteins by commonly used methods may confound studies of enzymes that specifically catalyze hydrolysis of nucleoside diphosphates or triphosphates. For example, contamination with E. coli AK may be responsible for reported ADPase activities of the ATPase chaperonins from Pyrococcus furiosus, Pyrococcus horikoshii, Methanococcus jannaschii and Thermoplasma acidophilum; the ATP/ADP-dependent DNA ligases from Aeropyrum pernix K1 and Staphylothermus marinus; or the reported ATP-dependent activities of ADP-dependent phosphofructokinase of P. furiosus. Purification methods developed to separate NtrC1 ATPase from AK also revealed two distinct forms of the ATPase. One is tightly bound to ADP or GDP and able to bind to Q but not S ion exchange matrixes. The other is nucleotide-free and binds to both Q and S ion exchange matrixes.

Dissecting the ATP hydrolysis pathway of bacterial enhancer-binding proteins

bEBPs (bacterial enhancer-binding proteins) are AAA+ (ATPase associated with various cellular activities) transcription activators that activate gene transcription through a specific bacterial sigma factor, sigma(54). Sigma(54)-RNAP (RNA polymerase) binds to promoter DNA sites and forms a stable closed complex, unable to proceed to transcription. The closed complex must be remodelled using energy from ATP hydrolysis provided by bEBPs to melt DNA and initiate transcription. Recently, large amounts of structural and biochemical data have produced insights into how ATP hydrolysis within the active site of bEBPs is coupled to the re-modelling of the closed complex. In the present article, we review some of the key nucleotides, mutations and techniques used and how they have contributed towards our understanding of the function of bEBPs.

Look, no hands! Unconventional transcriptional activators in bacteria

Transcriptional activation in bacteria usually involves an activator protein that binds to sites near the target promoter. Some activators of sigma(54)-RNA polymerase holoenzyme, however, can stimulate transcription even when their DNA-binding domains are removed. Recent studies have revealed examples of sigma(54)-dependent activators that naturally lack DNA-binding domains and seem to activate transcription from solution rather than from specific DNA sites. In addition, some activators that function with other forms of RNA polymerase holoenzyme, including Bacillus subtilis Spx and the bacteriophage N4 single-stranded DNA-binding protein, also stimulate transcription without binding to DNA. Because binding to regulatory sites enables activators to stimulate transcription from specific promoters, alternative strategies for achieving specificity are required for activators that do not bind to DNA.

Coupling nucleotide hydrolysis to transcription activation performance in a bacterial enhancer binding protein

The bacterial enhancer binding proteins (bEBP) are members of the AAA+ protein family and have a highly conserved 'DE' Walker B motif thought to be involved in the catalytic function of the protein with an active role in nucleotide hydrolysis. Based on detailed structural data, we analysed the functionality of the conserved 'DE' Walker B motif of a bEBP model, phage shock protein F (PspF), to investigate the role of these residues in the sigma(54)-dependent transcription activation process. We established their role in the regulation of PspF self-association and in the relay of the ATPase activity to the remodelling of an RNA polymerase.promoter complex (Esigma(54).DNA). Specific substitutions of the conserved glutamate (E) allowed the identification of new functional ATP.bEBP.Esigma(54) complexes which are stable and transcriptionally competent, providing a new tool to study the initial events of the sigma(54)-dependent transcription activation process. In addition, we show the importance of this glutamate residue in sigma(54).DNA conformation sensing, permitting the identification of new intermediate stages within the transcription activation pathway.

Heterogeneous nucleotide occupancy stimulates functionality of phage shock protein F, an AAA+ transcriptional activator

The catalytic AAA+ domain (PspF1-275) of an enhancer-binding protein is necessary and sufficient to contact sigma54-RNA polymerase holoenzyme (Esigma54), remodel it, and in so doing catalyze open promoter complex formation. Whether ATP binding and hydrolysis is coordinated between subunits of PspF and the precise nature of the nucleotide(s) bound to the oligomeric forms responsible for substrate remodeling are unknown. We demonstrate that ADP stimulates the intrinsic ATPase activity of PspF1-275 and propose that this heterogeneous nucleotide occupancy in a PspF1-275 hexamer is functionally important for specific activity. Binding of ADP and ATP triggers the formation of functional PspF1-275 hexamers as shown by a gain of specific activity. Furthermore, ATP concentrations congruent with stoichiometric ATP binding to PspF1-275 inhibit ATP hydrolysis and Esigma54-promoter open complex formation. Demonstration of a heterogeneous nucleotide-bound state of a functional PspF1-275.Esigma54 complex provides clear biochemical evidence for heterogeneous nucleotide occupancy in this AAA+ protein. Based on our data, we propose a stochastic nucleotide binding and a coordinated hydrolysis mechanism in PspF1-275 hexamers.

Structures and organisation of AAA+ enhancer binding proteins in transcriptional activation

Initiation of transcription is a major point of transcriptional regulation and invariably involves the transition from a closed to an open RNA polymerase (RNAP) promoter complex. In the case of the sigma(54)-RNAP, this multi step process requires energy, provided by ATP hydrolysis occurring within the AAA+ domain of enhancer binding proteins (EBPs). Typically, EBPs have an N-terminal regulatory domain, a central AAA+ domain that directly contacts sigma(54) and a C-terminal DNA binding domain. The following AAA+ EBP crystal structures have recently become available: heptameric AAA+ domains of NtrC1 and dimeric NtrC1 with its regulatory domain, hexameric AAA+ domains of ZraR with DNA binding domains, apo and nucleotide bound forms of the AAA+ domain of PspF as well as a cryo-EM structure of the AAA+ domain of PspF complexed with sigma(54). These AAA+ domains reveal the structural conservation between EBPs and other AAA+ domains. EBP specific structural features involved in substrate remodelling are located proximal to the pore of the hexameric ring. Parallels with the substrate binding elements near the central pore of other AAA+ members are drawn. We propose a structural model of EBPs in complex with a sigma(54)-RNAP-promoter complex.

Negative Regulation of AAA+ ATPase Assembly by Two Component Receiver Domains: A Transcription Activation Mechanism that is Conserved in Mesophilic and Extremely Hyperthermophilic Bacteria

Only a few transcriptional regulatory proteins have been characterized in extremely hyperthermophilic organisms, and most function as repressors. Structural features of the NtrC1 protein from the hyperthermophilic bacterium Aquifex aeolicus suggested that this protein functions similarly to the sigma(54)-polymerase activator DctD of Sinorhizobium meliloti. Here, we demonstrate that NtrC1 is an enzyme that hydrolyzes ATP to activate initiation of transcription by sigma(54)-holoenzyme. New structural data, including small-angle solution scattering data and the crystal structure of the phosphorylated receiver domain, show that NtrC1 uses a signal transduction mechanism very similar to that of DctD to control assembly of its AAA+ ATPase domain. As for DctD, the off-state of NtrC1 depends upon a tight dimer of the receiver domain to repress oligomerization of an intrinsically competent ATPase domain. Activation of NtrC1 stabilizes an alternative dimer configuration of the receiver domain that is very similar to the on-state dimers of the DctD and FixJ receiver domains. This alternative dimer appears to relieve repression of the ATPase domain by disrupting the off-state dimerization interface along the helical linker region between receiver and ATPase domains. Bacterial enhancer binding proteins typically have two linker sequences, one between N-terminal regulatory and central ATPase domains, and one between the central ATPase and C-terminal DNA binding domains. Sequence analyses reveal an intriguing correlation between the negative regulation mechanism of NtrC1 and DctD, and a structured N-terminal linker and unstructured C-terminal one; conversely, the very different, positive mechanism present in NtrC protein occurs in the context of an unstructured N-terminal linker and a structured C-terminal one. In both cases, the structured linkers significantly contribute to the stability of the off-state dimer conformation. These analyses also raise the possibility that a structured linker between N-terminal regulatory and central output domains is used frequently in regulatory proteins from hyperthermophilic organisms.

Novel substitutions in the sigma54-dependent activator DctD that increase dependence on upstream activation sequences or uncouple ATP hydrolysis from transcriptional activation

Sinorhizobium meliloti DctD is an activator of sigma(54)-RNA polymerase holoenzyme and member of the AAA+ superfamily of ATPases. DctD uses energy released from ATP hydrolysis to stimulate the isomerization of a closed promoter complex to an open complex. DctD binds to upstream activation sequences (UAS) and contacts the closed complex through DNA looping to activate transcription, but the UAS is not essential for activation if DctD is expressed at higher than normal levels. Introduction of specific substitutions within or near the conserved ESELFG motif in the C3 region of a truncated, constitutively active form of DctD produced several mutant forms of the protein that had increased dependence on the UAS for activation. Removing the DNA-binding domain from one UAS-dependent mutant and from one activation-deficient mutant significantly increased transcriptional activation, indicating that the DNA-binding domain interfered with the activities of these mutant proteins. A UAS-dependent mutant with a P315L substitution in the C6 region was identified from a genetic screen. Alanine scanning mutagenesis of conserved amino acid residues around Pro-315 produced two additional UAS-dependent mutants as well as several mutants that failed to activate transcription but retained ATPase activity. In contrast to the two mutant proteins with substitutions in the C3 region, removal of the DNA-binding domain from the mutant proteins with substitutions in the C6 region did not stimulate their activity. The residues in the C6 region that were altered are in a probable hinge region between the alpha/beta and alpha-helical subdomains of the AAA+ domain. The alpha-helical subdomain contains the sensor II helix that has been implicated in other AAA+ proteins as sensing changes in the nucleotide during the hydrolysis cycle. Substitutions in the hinge region may have abolished nucleotide sensing by interfering with subdomain interactions, altering the relative orientation of the sensor II helix or interfering with oligomerization of the protein.

Reorganisation of an RNA polymerase-promoter DNA complex for DNA melting

Sigma factors, the key regulatory components of the bacterial RNA polymerase (RNAP), direct promoter DNA binding and DNA melting. The sigma(54)-RNAP forms promoter complexes in which DNA melting is only triggered by an activator and ATP hydrolysis-driven reorganisation of an initial sigma(54)-RNAP-promoter complex. We report that an initial bacterial RNAP-DNA complex can be reorganised by an activator to form an intermediate transcription initiation complex where full DNA melting has not yet occurred. Using sigma(54) as a chemical nuclease we now show that the reorganisation of the initial sigma(54)-RNAP-promoter complex occurs upon interaction with the activator at the transition point of ATP hydrolysis. We demonstrate that this reorganisation event is an early step in the transcription initiation pathway that occurs independently of RNAP parts normally associated with stable DNA melting and open complex formation. Using photoreactive DNA probes, we provide evidence that within this reorganised sigma(54)-RNAP-promoter complex, DNA contacts across the 'to be melted' sequences are made by the sigma(54) subunit. Strikingly, the activator protein, but not core RNAP subunits, is close to these DNA sequences.