The role of the local environment of engineered Tyr to Trp substitutions for probing the denaturation mechanism of FIS.

Factor for inversion stimulation (FIS), a 98-residue homodimeric protein, does not contain tryptophan (Trp) residues but has four tyrosine (Tyr) residues located at positions 38, 51, 69, and 95. The equilibrium denaturation of a P61A mutant of FIS appears to occur via a three-state (N(2) ⇆ I(2) ⇆ 2U) process involving a dimeric intermediate (I(2)). Although it was suggested that this intermediate had a denatured C-terminus, direct evidence was lacking. Therefore, three FIS double mutants, P61A/Y38W, P61A/Y69W, and P61A/Y95W were made, and their denaturation was monitored by circular dichroism and Trp fluorescence. Surprisingly, the P61A/Y38W mutant best monitored the N(2) ⇆ I(2) transition, even though Trp38 is buried within the dimer removed from the C-terminus. In addition, although Trp69 is located on the protein surface, the P61A/Y69W FIS mutant exhibited clearly biphasic denaturation curves. In contrast, P61A/Y95W FIS was the least effective in decoupling the two transitions, exhibiting a monophasic fluorescence transition with modest concentration-dependence. When considering the local environment of the Trp residues and the effect of each mutation on protein stability, these results not only confirm that P61A FIS denatures via a dimeric intermediate involving a disrupted C-terminus but also suggest the occurrence of conformational changes near Tyr38. Thus, the P61A mutation appears to compromise the denaturation cooperativity of FIS by failing to propagate stability to those regions involved mostly in intramolecular interactions. Furthermore, our results highlight the challenge of anticipating the optimal location to engineer a Trp residue for investigating the denaturation mechanism of even small proteins.

Biochemical identification of base and phosphate contacts between Fis and a high-affinity DNA binding site.

Fis (factor for inversion stimulation) is a nucleoid-associated protein in Escherichia coli and other bacteria that stimulates certain site-specific DNA recombination events, alters DNA topology, and serves as a global gene regulator. DNA binding is central to the functions of Fis and involves a helix-turn-helix DNA binding motif located in the carboxy-terminal region. Specific DNA binding is observed at a number of sites exhibiting poorly related sequences. Such interactions require four critical base pairs positioned -7, -3, +3, and +7 nucleotides relative to the central nucleotide of a 15-bp core-binding site. To further understand how Fis interacts with DNA, we identified the positions of 14 DNA phosphates (based on ethylation interference assays) that are required for Fis binding. These are the 5' phosphates of the nucleotides at positions -8, -7, -6, +1, +2, +3, and +4 relative to the central nucleotide on both DNA strands. Another five phosphates located in the flanking regions from positions +10 through +14 can serve as additional contact sites. Using a combination of biochemical approaches and various mutant Fis proteins, we probed possible interactions between several key Fis residues and DNA bases or phosphates within a high-affinity binding site. We provide evidence in support of interactions between the R85 Fis residue and a highly conserved guanine at position -7 and between T87 and the critical base pairs at -3 and +3. In addition, we present evidence in support of interactions between N84 and the phosphate 5' to the base at +4, between R89 and the -7 phosphate, between T87 and the +3 and +4 phosphates, and between K90 and the +3 phosphate. This work provides functional evidence for some of the most critical interactions between Fis and DNA required for a high binding affinity and demonstrates the large contribution made by numerous phosphates to the stability of the Fis-DNA complex.

Functional characterization of the Escherichia coli Fis-DNA binding sequence.

The Escherichia coli protein Fis is remarkable for its ability to interact specifically with DNA sites of highly variable sequences. The mechanism of this sequence-flexible DNA recognition is not well understood. In a previous study, we examined the contributions of Fis residues to high-affinity binding at different DNA sequences using alanine-scanning mutagenesis and identified several key residues for Fis-DNA recognition. In this work, we investigated the contributions of the 15-bp core Fis binding sequence and its flanking regions to Fis-DNA interactions. Systematic base-pair replacements made in both half sites of a palindromic Fis binding sequence were examined for their effects on the relative Fis binding affinity. Missing contact assays were also used to examine the effects of base removal within the core binding site and its flanking regions on the Fis-DNA binding affinity. The results revealed that: (1) the -7G and +3Y bases in both DNA strands (relative to the central position of the core binding site) are major determinants for high-affinity binding; (2) the C(5) methyl group of thymine, when present at the +4 position, strongly hinders Fis binding; and (3) AT-rich sequences in the central and flanking DNA regions facilitate Fis-DNA interactions by altering the DNA structure and by increasing the local DNA flexibility. We infer that the degeneracy of specific Fis binding sites results from the numerous base-pair combinations that are possible at noncritical DNA positions (from -6 to -4, from -2 to +2, and from +4 to +6), with only moderate penalties on the binding affinity, the roughly similar contributions of -3A or G and +3T or C to the binding affinity, and the minimal requirement of three of the four critical base pairs to achieve considerably high binding affinities.

Effects of Fis on Escherichia coli gene expression during different growth stages.

Fis is a nucleoid-associated protein in Escherichia coli that is abundant during early exponential growth in rich medium but is in short supply during stationary phase. Its role as a transcriptional regulator has been demonstrated for an increasing number of genes. In order to gain insight into the global effects of Fis on E. coli gene expression during different stages of growth in rich medium, DNA microarray analyses were conducted in fis and wild-type strains during early, mid-, late-exponential and stationary growth phases. The results uncovered 231 significantly regulated genes that were distributed over 15 functional categories. Regulatory effects were observed at all growth stages examined. Coordinate upregulation was observed for a number of genes involved in translation, flagellar biosynthesis and motility, nutrient transport, carbon compound metabolism, and energy metabolism at different growth stages. Coordinate down-regulation was also observed for genes involved in stress response, amino acid and nucleotide biosynthesis, energy and intermediary metabolism, and nutrient transport. As cells transitioned from the early to the late-exponential growth phase, different functional categories of genes were regulated, and a gradual shift occurred towards mostly down-regulation. The results demonstrate that the growth phase-dependent Fis expression triggers coordinate regulation of 15 categories of functionally related genes during specific stages of growth of an E. coli culture.

DksA is required for growth phase-dependent regulation, growth rate-dependent control, and stringent control of fis expression in Escherichia coli.

DksA is a critical transcription factor in Escherichia coli that binds to RNA polymerase and potentiates control of rRNA promoters and certain amino acid promoters. Given the kinetic similarities between rRNA promoters and the fis promoter (Pfis), we investigated the possibility that DksA might also control transcription from Pfis. We show that the absence of dksA extends transcription from Pfis well into the late logarithmic and stationary growth phases, demonstrating the importance of DksA for growth phase-dependent regulation of fis. We also show that transcription from Pfis increases with steady-state growth rate and that dksA is absolutely required for this regulation. In addition, both DksA and ppGpp are required for inhibition of Pfis promoter activity following amino acid starvation, and these factors act directly and synergistically to negatively control Pfis transcription in vitro. DksA decreases the half-life of the intrinsically short-lived fis promoter-RNA polymerase complex and increases its sensitivity to the concentration of CTP, the predominant initiating nucleotide triphosphate for this promoter. This work extends our understanding of the multiple factors controlling fis expression and demonstrates the generality of the DksA requirement for regulation of kinetically similar promoters.

The location of an engineered inter-subunit disulfide bond in factor for inversion stimulation (FIS) affects the denaturation pathway and cooperativity.

Two crossed-linked variants of the homodimeric DNA binding protein factor for inversion stimulation (FIS) were created via engineering of single intermolecular disulfide bonds. The conservative S30C and the nonconservative V58C FIS independent mutations resulted in FIS crossed-linked at the A helix (C30-C30) and at the middle of the B helix (C58-C58). This study sought to investigate how the location of an intermolecular disulfide bond may determine the effect on stability and its propagation through the structure to preserve or alter the denaturation cooperativity of FIS. The oxidized and reduced S30C and V58C FIS exhibited a far-UV CD spectrum and DNA binding affinities that were similar to WT FIS, indicating no significant changes in secondary and tertiary structure. However, the reduced and oxidized forms of the mutants revealed significant differences in the stability and equilibrium denaturation mechanism between the two mutants. In the reduced state, S30C FIS had very little effect on FIS stability, whereas V58C FIS was 2-3 kcal/mol less stable than WT FIS. Interestingly, while both disulfide bonds significantly increased the resistance to urea- and guanidine hydrochloride (GuHCl)-induced denaturation, oxidized V58C FIS exhibited a three-state GuHCl-induced transition. In contrast, oxidized S30C FIS displayed a highly cooperative WT-like transition with both denaturants. The three-state denaturation mechanism of oxidized V58C FIS induced by the GuHCl salt was reproduced by urea denaturation at pH 4, suggesting that disruption of a C-terminus salt-bridge network is responsible for the loss of denaturation cooperativity of V58C FIS in GuHCl or urea, pH 4. A second mutation on V58C FIS created to place a single tryptophan probe (Y95W) at the C-terminus further implies that the denaturation intermediate observed in disulfide crossed-linked V58C FIS results from a decoupling of the stabilities of the C-terminus and the rest of the protein. These results show that, unlike the C30-C30 intermolecular disulfide bond, the C58-C58 disulfide bond did not evenly stabilize the FIS structure, thereby highlighting the importance of the location of an engineered disulfide bond on the propagation of stability and the denaturation cooperativity of a protein.

Common and variable contributions of Fis residues to high-affinity binding at different DNA sequences.

Fis is a nucleoid-associated protein that interacts with poorly related DNA sequences with a high degree of specificity. A difference of more than 3 orders of magnitude in apparent Kd values was observed between specific (Kd, approximately 1 to 4 nM) and nonspecific (Kd, approximately 4 microM) DNA binding. To examine the contributions of Fis residues to the high-affinity binding at different DNA sequences, 13 alanine substitutions were generated in or near the Fis helix-turn-helix DNA binding motif, and the resulting proteins were purified. In vitro binding assays at three different Fis sites (fis P II, hin distal, and lambda attR) revealed that R85, T87, R89, K90, and K91 played major roles in high-affinity DNA binding and that R85, T87, and K90 were consistently vital for binding to all three sites. Other residues made variable contributions to binding, depending on the binding site. N84 was required only for binding to the lambda attR Fis site, and the role of R89 was dramatically altered by the lambda attR DNA flanking sequence. The effects of Fis mutations on fis P II or hin distal site binding in vitro generally correlated with their abilities to mediate fis P repression or DNA inversion in vivo, demonstrating that the in vitro DNA-binding effects are relevant in vivo. The results suggest that while Fis is able to recognize a minimal common set of DNA sequence determinants at different binding sites, it is also equipped with a number of residues that contribute to the binding strength, some of which play variable roles.

The Escherichia coli Fis promoter is regulated by changes in the levels of its transcription initiation nucleotide CTP.

Expression of the Escherichia coli nucleoid-associated protein Fis (factor for inversion stimulation) is controlled at the transcriptional level in accordance with the nutritional availability. It is highly expressed during early logarithmic growth phase in cells growing in rich medium but poorly expressed in late logarithmic and stationary phase. However, fis mRNA expression is prolonged at high levels throughout the logarithmic and early stationary phase when the preferred transcription initiation site (+1C) is replaced with A or G, indicating that initiation with CTP is a required component of the regulation pattern. We show that RNA polymerase-fis promoter complexes are short lived and that transcription is stimulated over 20-fold from linear or supercoiled DNA if CTP is present during formation of initiation complexes, which serves to stabilize these complexes. Use of fis promoter fusions to lacZ indicated that fis promoter transcription is sensitive to the intracellular pool of the predominant initiating NTP. Growth conditions resulting in increases in CTP pools also result in corresponding increases in fis mRNA levels. Measurements of NTP pools performed throughout the growth of the bacterial culture in rich medium revealed a dramatic increase in all four NTP levels during the transition from stationary to logarithmic growth phase, followed by reproducible oscillations in their levels during logarithmic growth, which later decrease during the transition from logarithmic to stationary phase. In particular, CTP pools fluctuate in a manner consistent with a role in regulating fis expression. These observations support a model whereby fis expression is subject to regulation by the availability of its initiating NTP.

Variable contributions of tyrosine residues to the structural and spectroscopic properties of the factor for inversion stimulation.

The diverse roles of tyrosine residues in proteins may be attributed to their dual hydrophobic and polar nature, which can result in hydrophobic and ring stacking interactions, as well as hydrogen bonding. The small homodimeric DNA binding protein, factor for inversion stimulation (FIS), contains four tyrosine residues located at positions 38, 51, 69, and 95, each involved in specific intra- or intermolecular interactions. To investigate their contributions to the stability, flexibility, and spectroscopic properties of FIS, each one was independently mutated to phenylalanine. Equilibrium denaturation experiments show that Tyr95 and Tyr51 stabilize FIS by about 2 and 1 kcal/mol, respectively, as a result of their involvement in a hydrogen bond-salt bridge network. In contrast, Tyr38 destabilizes FIS by about 1 kcal/mol due to the placement of a hydroxyl group in a hydrophobic environment. The stability of FIS was not altered when the solvent-exposed Tyr69 was mutated. Limited proteolysis with trypsin and V8 proteases was used to monitor the flexibility of the C-terminus (residues 71-98) and the dimer core (residues 26-70), respectively. The results for Y95F and Y51F FIS revealed a different proteolytic susceptibility of the dimer core compared to the C-terminus, suggesting an increased flexibility of the latter. DNA binding affinity of the various FIS mutants was only modestly affected and correlated inversely with the C-terminal flexibility probed by trypsin proteolysis. Deconvolution of the fluorescence contribution of each mutant revealed that it varies in intensity and direction for each tyrosine in WT FIS, highlighting the role of specific interactions and the local environment in determining the fluorescence of tyrosine residues. The significant changes in stability, flexibility, and signals observed for the Y51F and Y95F mutations are attributed to their coupled participation in the hydrogen bond-salt bridge network. These results highlight the importance of tyrosine hydrogen-bonding and packing interactions for the stability of FIS and demonstrate the varying roles that tyrosine residues can play on the structural and spectroscopic properties of even small proteins.

Growth phase-dependent regulation and stringent control of fis are conserved processes in enteric bacteria and involve a single promoter (fis P) in Escherichia coli.

The intracellular concentration of the Escherichia coli factor for inversion stimulation (Fis), a global regulator of transcription and a facilitator of certain site-specific DNA recombination events, varies substantially in response to changes in the nutritional environment and growth phase. Under conditions of nutritional upshift, fis is transiently expressed at very high levels, whereas under induced starvation conditions, fis is repressed by stringent control. We show that both of these regulatory processes operate on the chromosomal fis genes of the enterobacteria Klebsiella pneumoniae, Serratia marcescens, Erwinia carotovora, and Proteus vulgaris, strongly suggesting that the physiological role of Fis is closely tied to its transcriptional regulation in response to the nutritional environment. These transcriptional regulatory processes were previously shown to involve a single promoter (fis P) preceding the fis operon in E. coli. Recent work challenged this notion by presenting evidence from primer extension assays which appeared to indicate that there are multiple promoters upstream of fis P that contribute significantly to the expression and regulation of fis in E. coli. Thus, a rigorous analysis of the fis promoter region was conducted to assess the contribution of such additional promoters. However, our data from primer extension analysis, S1 nuclease mapping, beta-galactosidase assays, and in vitro transcription analysis all indicate that fis P is the sole E. coli fis promoter in vivo and in vitro. We further show how certain conditions used in the primer extension reactions can generate artifacts resulting from secondary annealing events that are the likely source of incorrect assignment of additional fis promoters.

From two-state to three-state: the effect of the P61A mutation on the dynamics and stability of the factor for inversion stimulation results in an altered equilibrium denaturation mechanism.

Factor for inversion stimulation (FIS) is a 22 kDa homodimeric protein found in enteric bacteria that is involved in the stimulation of certain DNA recombination events and transcription regulation of many genes. FIS has a central helix with a 20 degrees kink, which is only reduced by 4 degrees after a proline 61 to alanine mutation (P61A). This mutation appears to have little effect on FIS function, yet it is striking that proline 61 is highly conserved among fis genes. Therefore, we studied the role of proline 61 on the stability and flexibility of FIS. The urea-induced equilibrium denaturation of P61A FIS was monitored by circular dichroism and fluorescence anisotropy. Despite the apparent two-state transition, the concentration dependence of the transition slope (m value) shows that a two-state model, as seen for wild-type (WT) FIS, did not adequately describe the denaturation of P61A FIS. Global fitting of the data indicates that the denaturation of P61A FIS occurs via a three-state process involving a dimeric intermediate and has an overall DeltaG(H2O) for unfolding of 18.6 kcal/mol, 4 kcal/mol higher than that for WT FIS. Limited trypsin proteolysis experiments show that the DNA binding C-terminus of P61A FIS is more labile to cleavage than that of WT FIS, suggesting an increased flexibility of this region in P61A FIS. In contrast, the resulting dimeric core (residues 6-71) of P61A FIS is more resistant to proteolysis, consistent with the presence of a dimeric intermediate not seen in WT FIS. Model transition curves generated using the parameters obtained by global fitting predicted a two-state-like transition at low P61A concentrations that becomes less cooperative with increasing protein concentration, as was experimentally observed. At concentrations of P61A FIS much higher than are experimentally feasible, a biphasic transition is predicted. Thus, this work demonstrates that a single mutation may be sufficient to alter a protein's denaturation mechanism and underscores the importance of analyzing the denaturation mechanism of oligomeric proteins over a wide concentration range. These results suggest that proline 61 in FIS may be conserved in order to optimize the global stability and the dynamics of the functionally important C-terminus.

Factors affecting start site selection at the Escherichia coli fis promoter.

Transcription initiation with CTP is an uncommon feature among Escherichia coli sigma(70) promoters. The fis promoter (fis P), which is subject to growth phase-dependent regulation, is among the few that predominantly initiate transcription with CTP. Mutations in this promoter that cause a switch from utilization of CTP to either ATP or GTP as the initiation nucleotide drastically alter its growth phase regulation pattern, suggesting that the choice of the primary initiating nucleotide can significantly affect its regulation. To better understand what factors influence this choice in fis P, we made use of a series of promoter mutations that altered the nucleotide or position used for initiation. Examination of these promoters indicates that start site selection is determined by a combination of factors that include preference for a nucleotide distance from the -10 region (8 > 7 > 9 >> 6 >> 10 > 11), initiation nucleotide preference (A = G >> CTP > or = UTP), the DNA sequence surrounding the initiation region, the position of the -35 region, and changes in the intracellular nucleoside triphosphate pools. We describe the effects that each of these factors has on start site selection in the fis P and discuss the interplay between position and nucleotide preference in this important process.

Equilibrium denaturation studies of the Escherichia coli factor for inversion stimulation: implications for in vivo function.

The Factor for Inversion Stimulation (FIS) is a dimeric DNA binding protein found in enteric bacteria that is involved in various cellular processes, including stimulation of certain specialized DNA recombination events and transcription regulation of a large number of genes. The intracellular FIS concentration, when cells are grown in rich media, varies dramatically during the early logarithmic growth phase. Its broad range of concentrations could potentially affect the nature of its quaternary structure, which in turn, could affect its ability to function in vivo. Thus, we examined the stability of FIS homodimers under a wide range of concentrations relevant to in vivo expression levels. Its urea-induced equilibrium denaturation was monitored by far- and near-UV circular dichroism (CD), tyrosine fluorescence, and tyrosine fluorescence anisotropy. The denaturation transitions obtained were concentration-dependent and showed similar midpoints (C(m)) and m values, suggesting a two-state denaturation process involving the native dimer and unfolded monomers (N(2) <--> 2U). The DeltaG(H(2)O) for the unfolding of FIS determined from global and individual curve fitting was 14.2 kcal/mole. At concentrations <9 microM, the FIS dimer began to dissociate, as noted by the change in CD signal and size-exclusion high-pressure liquid chromatography retention times and peak width. The estimated dimer dissociation constant based on the CD and size-exclusion chromatography data is in the micromolar range, resulting in a DeltaG(H(2)O) of at least 5 kcal/mole less than that calculated from the urea denaturation data. This discrepancy suggests a deviation from a two-state denaturation model, perhaps due to a marginally stable monomeric intermediate. These observations have implications for the stability and function of FIS in vivo.