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 C⁵ 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.     

Subunit exchange and the role of dimer flexibility in DNA binding by the Fis protein

Fis is an abundant bacterial DNA binding protein that functions in many different reactions. We show here that Fis subunits rapidly exchange between dimers in solution by disulfide cross-linking mixtures of Fis mutants with different electrophoretic mobilities and by monitoring energy transfer between fluorescently labeled Fis subunits upon heterodimer formation. The effects of detergents and salt concentrations on subunit exchange imply that the dimer is predominantly stabilized by hydrophobic forces, consistent with the X-ray crystal structures. Specific and nonspecific DNA strongly inhibit Fis subunit exchange. In all crystal forms of Fis, the separation between the DNA recognition helices within the Fis dimer is too short to insert into adjacent major grooves on canonical B-DNA, implying that conformational changes within the Fis dimer and/or the DNA must occur upon binding. We therefore investigated the functional importance of dimer interface flexibility for Fis-DNA binding by studying the DNA binding properties of Fis mutants that were cross-linked at different positions in the dimer. Flexibility within the core dimer interface does not appear to be required for efficient DNA binding, Fis-DNA complex dissociation, or Fis-induced DNA bending. Moreover, FRET-based experiments provided no evidence for a change in the spatial relationship between the two helix-turn-helix motifs in the Fis dimer upon DNA binding. These results support a model in which the unusually short distance between DNA recognition helices on Fis is accommodated primarily through bending of the DNA.     

The recombinational enhancer for DNA inversion functions independent of its orientation as a consequence of dyad symmetry in the Fis-DNA complex.

The Escherichia coli Fis protein binds to specific DNA sequences whose base composition varies enormously. One known function of Fis is to stimulate site-specific DNA recombination. We used the Gin-mediated DNA inversion system of bacteriophage Mu to analyze Fis-DNA interaction. Efficient inversion requires an enhancer which consists of two Fis binding sites at a fixed distance from each other. Using mutant enhancers in which one of the Fis binding sites is replaced we show that Fis binds symmetrically to the DNA and we locate the center of symmetry. Furthermore, we show that one of the Fis binding sites can be replaced by a Fis binding site that normally functions in a process other than site-specific recombination.     

Control of DNA minor groove width and Fis protein binding by the purine 2-amino group

The width of the DNA minor groove varies with sequence and can be a major determinant of DNA shape recognition by proteins. For example, the minor groove within the center of the Fis–DNA complex narrows to about half the mean minor groove width of canonical B-form DNA to fit onto the protein surface. G/C base pairs within this segment, which is not contacted by the Fis protein, reduce binding affinities up to 2000-fold over A/T-rich sequences. We show here through multiple X-ray structures and binding properties of Fis–DNA complexes containing base analogs that the 2-amino group on guanine is the primary molecular determinant controlling minor groove widths. Molecular dynamics simulations of free-DNA targets with canonical and modified bases further demonstrate that sequence-dependent narrowing of minor groove widths is modulated almost entirely by the presence of purine 2-amino groups. We also provide evidence that protein-mediated phosphate neutralization facilitates minor groove compression and is particularly important for binding to non-optimally shaped DNA duplexes.     

Mechanism of chromosome compaction and looping by the Escherichia coli nucleoid protein Fis

Fis, the most abundant DNA-binding protein in Escherichia coli during rapid growth, has been suspected to play an important role in defining nucleoid structure. Using bulk-phase and single-DNA molecule experiments, we analyze the structural consequences of non-specific binding by Fis to DNA. Fis binds DNA in a largely sequence-neutral fashion at nanomolar concentrations, resulting in mild compaction under applied force due to DNA bending. With increasing concentration, Fis first coats DNA to form an ordered array with one Fis dimer bound per 21 bp and then abruptly shifts to forming a higher-order Fis-DNA filament, referred to as a low-mobility complex (LMC). The LMC initially contains two Fis dimers per 21 bp of DNA, but additional Fis dimers assemble into the LMC as the concentration is increased further. These complexes, formed at or above 1 microM Fis, are able to collapse large DNA molecules via stabilization of DNA loops. The opening and closing of loops on single DNA molecules can be followed in real time as abrupt jumps in DNA extension. Formation of loop-stabilizing complexes is sensitive to high ionic strength, even under conditions where DNA bending-compaction is unaltered. Analyses of mutants indicate that Fis-mediated DNA looping does not involve tertiary or quaternary changes in the Fis dimer structure but that a number of surface-exposed residues located both within and outside the helix-turn-helix DNA-binding region are critical. These results suggest that Fis may play a role in vivo as a domain barrier element by organizing DNA loops within the E. coli chromosome.     

Structural Analysis of HMGD-DNA Complexes Reveals Influence of Intercalation on Sequence Selectivity and DNA Bending

The ubiquitous, eukaryotic, high-mobility group box (HMGB) chromosomal proteins promote many chromatin-mediated cellular activities through their non-sequence-specific binding and bending of DNA. Minor-groove DNA binding by the HMG box results in substantial DNA bending toward the major groove owing to electrostatic interactions, shape complementarity, and DNA intercalation that occurs at two sites. Here, the structures of the complexes formed with DNA by a partially DNA intercalation-deficient mutant of Drosophila melanogaster HMGD have been determined by X-ray crystallography at a resolution of 2.85 Å. The six proteins and 50 bp of DNA in the crystal structure revealed a variety of bound conformations. All of the proteins bound in the minor groove, bridging DNA molecules, presumably because these DNA regions are easily deformed. The loss of the primary site of DNA intercalation decreased overall DNA bending and shape complementarity. However, DNA bending at the secondary site of intercalation was retained and most protein-DNA contacts were preserved. The mode of binding resembles the HMGB1 box A-cisplatin-DNA complex, which also lacks a primary intercalating residue. This study provides new insights into the binding mechanisms used by HMG boxes to recognize varied DNA structures and sequences as well as modulate DNA structure and DNA bending.     

Large,sequence-dependent effects on DNA conformation by minor groove binding compounds

To determine what topological changes antiparasitic heterocyclic dications can have on kinetoplast DNA, we have constructed ligation ladders, with phased A5 and ATATA sequences in the same flanking sequence context, as models. Bending by the A5 tract is observed, as expected, while the ATATA sequence bends DNA very little. Complexes of these DNAs with three diamidines containing either furan, thiophene or selenophene groups flanked by phenylamidines were investigated along with netropsin. With the bent A5 ladder the compounds caused either a slight increase or decrease in the bending angle. Surprisingly, however, with ATATA all of the compounds caused significant bending, to values close to or even greater than the A5 bend angle. Results with a mixed cis sequence, which has one A5 and one ATATA, show that the compounds bend ATATA in the same direction as a reference A5 tract, that is, into the minor groove. These results are interpreted in terms of a groove structure for A5 which is largely pre-organized for a fit to the heterocyclic amidines. With ATATA the groove is intrinsically wider and must close to bind the compounds tightly. The conformational change at the binding site then leads to significant bending of the alternating DNA sequence.     

Attenuation of DNA-protein interactions associated with intrinsic, sequence-dependent DNA curvature.

Inherently curved DNA segments, associated with short runs of adenines, have been identified in many gene regulatory regions, yet their physiological significance remains unknown. The observations reported in this study indicate that intrinsically bent nucleic acid fragments are characterized by substantially attenuated affinities toward DNA-binding proteins involved in structural functions, such as H1 histone and protamine, as well as toward various DNA-modifying enzymes including ligases and exo- and endonucleases. Two mechanisms might be responsible for the altered binding properties. According to the first mechanism, the attenuated binding affinities and the bending represent two independent consequences of the unique structural parameters exhibited by A-tracts. Indeed, analysis of the degradation products obtained upon exposure of the curved sequences to various chemical nucleases points toward the narrowing of the DNA minor groove, a conformational modulation known to characterize A-tracts and to run along the axially-bent motifs, as a potential determinant of the observed binding attenuation. Alternatively, the conformational constraints which result from the stable bending might act to modulate the strength of DNA-protein interactions. Although the factor directly responsible for the altered binding affinities revealed by the bent sequences cannot as yet be conclusively resolved, it is proposed that a reiteration of this specific factor, being either an A-tract or a bend, in phase with the DNA helical repeat acts to amplify the modulation of the binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Minor groove to major groove, an unusual DNA sequence-dependent change in bend directionality by a distamycin dimer

DNA sequence-dependent conformational changes induced by the minor groove binder, distamycin, have been evaluated by polyacrylamide gel electrophoresis. The distamycin binding affinity, cooperativity, and stoichiometry with three target DNA sequences that have different sizes of alternating AT sites, ATAT, ATATA, and ATATAT, have been determined by mass spectrometry and surface plasmon resonance to help explain the conformational changes. The results show that distamycin binds strongly to and bends five or six AT base pair minor groove sites as a dimer with positive cooperativity, while it binds to ATAT as a weak, slightly anticooperative dimer. The bending direction was evaluated with an in phase A-tract reference sequence. Unlike other similar monomer minor groove binding compounds, such as netropsin, the distamycin dimer changes the directionality of the overall curvature away from the minor groove to the major groove. This distinct structural effect may allow designed distamycin derivatives to have selective therapeutic effects.     

Examining the contribution of a dA+dT element to the conformation of Escherichia coli integration host factor-DNA complexes.

DNA binding proteins that induce structural changes in DNA are common in both prokaryotes and eukaryotes. Integration host factor (IHF) is a multi-functional DNA binding and bending protein of Escherichia coli that can mediate protein-protein and protein-DNA interactions by bending DNA. Previously we have shown that the presence of a dA+dT element 5'-proximal to an IHF consensus sequence can affect the binding of IHF to a particular site. In this study the contribution of various sequence elements to the formation of IHF-DNA complexes was examined. We show that IHF bends DNA more when it binds to a site containing a dA+dT element upstream of its core consensus element than to a site lacking a dA+dT element. We demonstrate that IHF can be specifically crosslinked to DNA with binding sites either containing or lacking this dA+dT element. These results indicate the importance of flanking DNA and a dA+dT element in the binding and bending of a site by IHF.     

The SKN-1 amino-terminal arm is a DNA specificity segment

The Caenorhabditis elegans SKN-1 protein binds DNA through a basic region like those of bZIP proteins and through a flexible amino-terminal arm segment similar to those with which numerous helix-turn-helix proteins bind to bases in the minor groove. A recent X-ray crystallographic structure suggests that the SKN-1 amino-terminal arm provides only nonspecific DNA binding. In this study, however, we demonstrate that this segment mediates recognition of an AT-rich element that is part of the preferred SKN-1 binding site and thereby significantly increases the sequence specificity with which SKN-1 binds DNA. Mutagenesis experiments show that multiple amino acid residues within the arm are involved in binding. These residues provide binding affinity through distinct but partially redundant interactions and enhance specificity by discriminating against alternate sites. The AT-rich element minor groove is important for binding of the arm, which appears to affect DNA conformation in this region. This conformational effect does not seem to involve DNA bending, however, because the arm does not appear to affect a modest DNA bend that is induced by SKN-1. The data illustrate an example of how a small, flexible protein segment can make an important contribution to DNA binding specificity through multiple interactions and mechanisms.     

Role of architectural elements in combinatorial regulation of initiation of DNA replication in Escherichia coli

Bending of DNA is a prerequisite of site-specific recombination and gene expression in many regulatory systems involving the assembly of specific nucleoprotein complexes. We have investigated how the uniquely clustered Dam methylase sites, GATCs, in the origin of Escherichia coli replication ( oriC  ) and their methylation status modulate the geometry of oriC and its interaction with architectural proteins, such as integration host factor (IHF), factor for inversion stimulation (Fis) and DnaA initiator protein. We note that 3 of the 11 GATC sites at oriC are strategically positioned within the IHF protected region. Methylation of the GATCs enhances IHF binding and alters the IHF-induced bend at oriC . GATC motifs also contribute to intrinsic DNA curvature at oriC and the degree of bending is modulated by methylation. The IHF-induced bend at oriC is further modified by Fis protein and IHF affinity for its binding site may be impaired by protein(s) binding to GATCs within the IHF site. Thus, GATC sites at oriC affect the DNA conformation and GATCs, in conjunction with the protein-induced bends, are critical cis -acting elements in specifying proper juxtapositioning of initiation factors in the early steps of DNA replication.     

DNA and its counterions: a molecular dynamics study

The behaviour of mobile counterions, Na⁺ and K⁺, was analysed around a B-DNA double helix with the sequence CCATGCGCTGAC in aqueous solution during two 50 ns long molecular dynamics trajectories. The movement of both monovalent ions remains diffusive in the presence of DNA. Ions sample the complete space available during the simulation time, although individual ions sample only about one-third of the simulation box. Ions preferentially sample electronegative sites around DNA, but direct binding to DNA bases remains a rather rare event, with highest site occupancy values of <13%. The location of direct binding sites depends greatly on the nature of the counterion. While Na⁺ binding in both grooves is strongly sequence-dependent with the preferred binding site in the minor groove, K⁺ mainly visits the major groove and binds close to the centre of the oligomer. The electrostatic potential of an average DNA structure therefore cannot account for the ability of a site to bind a given cation; other factors must also play a role. An extensive analysis of the influence of counterions on DNA conformation showed no evidence of minor groove narrowing upon ion binding. A significant difference between the conformations of the double helix in the different simulations can be attributed to extensive α/γ transitions in the phosphate backbone during the simulation with Na⁺. These transitions, with lifetimes over tens of nanoseconds, however, appear to be correlated with ion binding to phosphates. The ion-specific conformational properties of DNA, hitherto largely overlooked, may play an important role in DNA recognition and binding.     

Modeling helix-turn-helix protein-induced DNA bending with knowledge-based distance restraints.

A crucial element of many gene functions is protein-induced DNA bending. Computer-generated models of such bending have generally been derived by using a presumed bending angle for DNA. Here we describe a knowledge-based docking strategy for modeling the structure of bent DNA recognized by a major groove-inserting alpha-helix of proteins with a helix-turn-helix (HTH) motif. The method encompasses a series of molecular mechanics and dynamics simulations and incorporates two experimentally derived distance restraints: one between the recognition helix and DNA, the other between respective sites of protein and DNA involved in chemical modification-enabled nuclease scissions. During simulation, a DNA initially placed at a distance was "steered" by these restraints to dock with the binding protein and bends. Three prototype systems of dimerized HTH DNA binding were examined: the catabolite gene activator protein (CAP), the phage 434 repressor (Rep), and the factor for inversion stimulation (Fis). For CAP-DNA and Rep-DNA, the root mean square differences between model and x-ray structures in nonhydrogen atoms of the DNA core domain were 2.5 A and 1.6 A, respectively. An experimental structure of Fis-DNA is not yet available, but the predicted asymmetrical bending and the bending angle agree with results from a recent biochemical analysis.     

Mapping the transition state for DNA bending by IHF

How DNA-bending proteins recognize their specific sites on DNA remains elusive, particularly for proteins that use indirect readout, which relies on sequence-dependent variations in DNA flexibility/bendability. The question remains as to whether the protein bends the DNA (protein-induced bending) or, alternatively, "prebent" DNA conformations are thermally accessible, which the protein captures to form the specific complex (conformational capture). To distinguish between these mechanisms requires characterization of reaction intermediates and, in particular, snapshots of the transition state along the recognition pathway. We present such a snapshot, from measurements of DNA bending dynamics in complex with Escherichia coli integration host factor (IHF), an architectural protein that bends specific sites on λ-DNA in a U-turn by creating two sharp kinks in DNA. Fluorescence resonance energy transfer measurements in response to laser temperature-jump perturbation monitor DNA bending. We find that nicks or mismatches that enhance DNA flexibility at the site of the kinks show 3- to 4-fold increase in DNA bending rates that reflect a 4- to 11-fold increase in binding affinities, while sequence modifications away from the kink sites, as well as mutations in IHF designed to destabilize the complex, have negligible effect on DNA bending rates despite >250-fold decrease in binding affinities. These results support the scenario that the bottleneck in the recognition step for IHF is spontaneous kinking of cognate DNA to adopt a partially prebent conformation and point to conformational capture as the underlying mechanism of initial recognition, with additional protein-induced bending occurring after the transition state.