The interaction of E. coli IHF protein with its specific binding sites

Wrapping of flanking non-operator DNA in lac repressor-operator complexes: implications for DNA looping

In our studies of lac repressor tetramer (T)-lac operator (O) interactions, we observed that the presence of extended regions of non-operator DNA flanking a single lac operator sequence embedded in plasmid DNA produced large and unusual cooperative and anticooperative effects on binding constants (Kobs) and their salt concentration dependences for the formation of 1:1 (TO) and especially 1:2 (TO2) complexes. To explore the origin of this striking behavior we report and analyze binding data on 1:1 (TO) and 1:2 (TO2) complexes between repressor and a single O(sym) operator embedded in 40 bp, 101 bp, and 2514 bp DNA, over very wide ranges of [salt]. We find large interrelated effects of flanking DNA length and [salt] on binding constants (K(TO)obs, K(TO2)obs) and on their [salt]-derivatives, and quantify these effects in terms of the free energy contributions of two wrapping modes, designated local and global. Both local and global wrapping of flanking DNA occur to an increasing extent as [salt] decreases. Global wrapping of plasmid-length DNA is extraordinarily dependent on [salt]. We propose that global wrapping is driven at low salt concentration by the polyelectrolyte effect, and involves a very large number (>/similar 20) of coulombic interactions between DNA phosphates and positively charged groups on lac repressor. Coulombic interactions in the global wrap must involve both the core and the second DNA-binding domain of lac repressor, and result in a complex which is looped by DNA wrapping. The non-coulombic contribution to the free energy of global wrapping is highly unfavorable ( approximately +30-50 kcal mol(-1)), which presumably results from a significant extent of DNA distortion and/or entropic constraints. We propose a structural model for global wrapping, and consider its implications for looping of intervening non-operator DNA in forming a complex between a tetrameric repressor (LacI) and one multi-operator DNA molecule in vivo and in vitro. The existence of DNA wrapping in LacI-DNA interactions motivates the proposal that most if not all DNA binding proteins may have evolved the capability to wrap and thereby organize flanking regions of DNA.

Unusual transcriptional and translational regulation of the bacteriophage Mu mom operon

The bacteriophage Mu mom gene encodes a novel DNA modification that protects the viral genome against a wide variety of restriction endonucleases. Expression of mom is subject to a series of unusual regulatory controls. Transcription requires the action of a phage-encoded protein, C, which binds (probably as a dimer) the mom promoter from -33 to -52 (with respect to the transcription start site) in two adjacent DNA major grooves on one face of the helix. No apparent direct interaction between C and the host RNA polymerase (RNAP) is evident; however, C binding alters mom DNA conformation. In the absence of C, RNAP binds the mom promoter at a site that results in transcription in a direction away from the mom gene. The function of this transcription is unknown. An additional layer of transcriptional regulation complexity is due to the fact that the host Dam DNA-(N6-adenine)methyltransferase is required. Dam methylation of three closely spaced upstream GATC sequences is necessary to prevent binding by the host protein, OxyR, which acts as a repressor. Repression is not mediated by inhibition of C binding, but rather through interference with C-mediated recruitment of RNAP to the correct site. Translation of mom is regulated by the phage Com protein. Com is only 62 amino acids long and contains a zinc finger-like structure (coordinated by four cysteine residues) in the amino terminal domain. Com binds mom mRNA 5' to the mom open reading frame, whose translation start signals are contained in a stem-loop translation-inhibition-structure. Com binding to its target site (5' to and adjacent to the translation-inhibition-structure) results in a stable change in RNA secondary structure that exposes the translation start signals.

Mutational analysis of the PapB transcriptional regulator in Escherichia coli. Regions important for DNA binding and oligomerization

PapB is a transcriptional regulator in the control of pap operon expression in Escherichia coli. There are PapB homologous proteins encoded by many fimbrial gene systems that are involved in the regulation of fimbriae-adhesin production, and previous studies suggested that PapB binds DNA through minor groove contact. Both deletion and alanine-scanning mutagenesis were used to identify functionally important regions of the PapB protein. Mutations altering Arg61 or Cys65 caused deficiency in DNA binding, indicating that these residues are critical for PapB binding to DNA. Alanine substitutions at positions 35-36, 53-56, and 74-76 resulted in mutants that were impaired in oligomerization. All these amino acid residues are conserved among the PapB homologous proteins, suggesting their importance in the whole family of regulatory proteins. The transcriptional efficiency of all the mutants was clearly reduced as compared with that of wild-type PapB. Taken together, we have localized regions in the PapB protein that are involved in DNA binding and oligomerization, and our results show that both functions are required for its activity as a transcriptional regulator.

Decreased imino proton exchange and base-pair opening in the IHF-DNA complex measured by NMR

Integration Host Factor, IHF, is an E. coli DNA binding protein that imposes a substantial bend on DNA. Previous footprinting studies and bending assays have characterized several recognition sequences in the bacterial and lambda phage genome as unique in the way they are bound by IHF. We have chosen one of the lambda phage sites, H1, for study because it presents a small yet sequence-specific substrate for NMR analysis of the complex. A 19 base-pair duplex, H19, corresponding to the recognition sequence at the H1 site was constructed by isotopically labeling one of the strands with 15N. (1H, 15N) heteronuclear NMR experiments aided in assigning the imino proton resonances of the DNA alone and in complex with IHF. The NMR results are consistent with a mode of binding observed in the recent crystal structure of IHF bound to another of its sites from the lambda phage genome. Additionally, the dramatic change that IHF imposes on the imino proton chemical shifts is indicative of a severe deviation from canonical B-DNA structure. In order to understand the dynamic properties of the DNA in the complex with IHF, the exchange rates of the imino protons with the solvent have been measured for H19 with and without IHF bound. A drastic reduction in exchange is observed for the imino protons in the IHF bound DNA. In the DNA-protein complex, groups of adjacent base-pair exchange at the same rate, and appear to close more slowly than the rate of imino proton exchange with bulk water, since their exchange rate is independent of catalyst concentration. We infer that segments of the double helix as large as 6 bp open in a cooperative process, and remain open much longer than is typical for opening fluctuations in naked duplex DNA. We discuss these results in terms of the specific protein-DNA contacts observed in the crystal structure.

In vitro selection of integration host factor binding sites

Integration host factor (IHF) is a bacterial protein that binds and severely bends a specific DNA target. IHF binding sites are approximately 30 to 35 bp long and are apparently divided into two domains. While the 3' domain is conserved, the 5' domain is degenerate but is typically AT rich. As a result of physical constraints that IHF must impose on DNA in order to bind, it is believed that this 5' domain must possess structural characteristics conducive for both binding and bending with little regard for specific contacts between the protein and the DNA. We have examined the sequence requirements of the 5' binding domain of the IHF binding target. Using a SELEX procedure, we randomized and selected variants of a natural IHF site. We then analyzed these variants to determine how the 5' binding domain affects the structure, affinity, and function of an IHF-DNA complex in a native system. Despite finding individual sequences that varied over 100-fold in affinity for IHF, we found no apparent correlation between affinity and function.

A quantitative UV laser footprinting analysis of the interaction of IHF with specific binding sites: re-evaluation of the effective concentration of IHF in the cell

The integration host factor (IHF) of Escherichia coli is a major nucleoid-associated protein that binds to specific sites on DNA. Using gel retardation and competition experiments we have estimated that in vitro IHF binds specific sites 1000-10,000 times more tightly than non-specific, chromosomal DNA. We have analyzed the in vitro and in vivo interaction of IHF with three specific binding sites using UV laser footprinting. Because there is a strict correspondence between the intensity of the footprinting signal and the occupancy of a site, we can correlate in vitro association constants with in vivo site occupancy. From the fractional occupancy of various ihf sites in vivo, we then estimate the amount of free IHF in the cell. Exponentially growing cells contain only about 0.7 nM of free IHF, a value 20-fold smaller than the one previously deduced from DMS footprinting. As a consequence low affinity sites are only partially occupied and strong binding sites reach semi-saturation. In stationary phase the concentration of free IHF in the cell increases about sevenfold. These results show that only a very small fraction of total IHF is free in solution. Given the affinity of IHF for non-specific DNA our data imply that a large part of chromosomal DNA is accessible to IHF, and that IHF is a major contributor to chromosomal DNA condensation. The in vivo UV-laser footprinting method is of general interest, because it allows the measurement and the comparison of DNA-protein interactions in vitro and in vivo.

Oligomeric interaction of the PapB transcriptional regulator with the upstream activating region of pili adhesin gene promoters in Escherichia coli

Transcriptional regulation of the pap genes, which encode fimbrial adhesins in uropathogenic Escherichia coli, depends on an upstream activating region. This region contains binding sites for a transcription factor, PapB, which is a member of a growing family of putative regulatory proteins found in several virulence-associated fimbrial gene systems. To assess the nature of the PapB binding sites, we studied different naturally occurring variants and a number of in vitro constructed mutant binding sites. DNase I footprinting analysis and visualization of the PapB-DNA complex by atomic force microscopy showed that the protein occupied a DNA region of more than 50 bp. Purified PapB protein was shown to recognize a motif including a 9 bp repeat sequence containing T/A triplets at a conserved position. PapB binding was affected by distamycin, and the results were consistent with the possibility that the binding to DNA occurred through minor groove interaction. From these analyses and estimation of the relative number of PapB proteins per binding site, we suggest that PapB binds the DNA in an oligomeric fashion and may function as an architectural factor in the transcriptional control of adhesin expression.

In vitro interaction of the IHF-like proteins Acinetobacter junii and Proteus vulgaris with ihf sites

The ability of the IHF-like proteins of Acinetobacter junii and Proteus vulgaris to interact with the H' attP and pR' ihf sites of lambda DNA was investigated. IHF from A. junii and P. vulgaris was found to bind the examined ihf sites in a way similar to IHF from Escherichia coli as shown by gel mobility shift DNA binding assays and footprinting analysis. The three IHF proteins bound to the pR' ihf site that overlaps the-35 region of that promoter and in vitro repression of transcription by each IHF was observed. These results confirm that IHF-like proteins from Gram-negative bacteria can recognize the same specific DNA sequences and appear to be important in regulation of transcription.

Nuclear magnetic resonance-based model of a TF1/HmU-DNA complex

Transcription factor 1 (TF1), a type II DNA-binding protein encoded by the Bacillus subtilis bacteriophage SPO1, has the capacity for sequence-selective DNA binding and a preference for 5-hydroxymethyl-2'-deoxyuridine (HmU)-containing DNA. In NMR studies of the TF1/HmU-DNA complex, intermolecular NOEs indicate that the flexible beta-ribbon and C-terminal alpha-helix are involved in the DNA-binding site of TF1, placing it in the beta-sheet category of DNA-binding proteins proposed to bind by wrapping two beta-ribbon "arms" around the DNA. Intermolecular and intramolecular NOEs were used to generate an energy-minimized model of the protein-DNA complex in which both DNA bending and protein structure changes are evident.

Interaction of the bacteriophage Mu transcriptional activator protein, C, with its target site in the mom promoter

The bacteriophage Mu C gene encodes a 16.5 kDa site-specific DNA binding protein that is a transcriptional activator of the four "late" promoters, Pmom, Plys, PI and PP. A symmetrical consensus C recognition sequence, TTAT[N5-6]ATAA, containing an inverted tetrad repeat separated by a spacer of five to six G+C-rich nucleotides, has been proposed. To investigate this, we used oligonucleotide mutagenesis to introduce random substitutions within and flanking the proposed C-target region; each variant site was tested for C recognition by an in vivo functional transactivation assay. We observed that all single mutations, in either tetrad, reduced C activation. Although two out of ten substitutions within the spacer reduced activation, the spacer region does not appear to make specific contact with C. We also used in vitro chemical-protection and -interference to study C contacts with Pmom. The results indicate that C contacts Pmom DNA on only one face of the helix through interactions within two adjacent major grooves; this conclusion was supported by gel shift analyses using synthetic oligonucleotide duplexes containing I.C or other base-pair substitutions. Evidence is also presented that C-Pmom contacts are asymmetrical, and that they extend two nucleotides 3' to the promoter-proximal tetrad. We also show that C binding induces a deformation, possibly a bend, in Pmom DNA.

Repressor induced site-specific binding of HU for transcriptional regulation

Transcription from two overlapping gal promoters is repressed by Gal repressor binding to bipartite gal operators, O(E) and O(I), which flank the promoters. Concurrent repression of the gal promoters also requires the bacterial histone-like protein HU which acts as a co-factor. Footprinting experiments using iron-EDTA-coupled HU show that HU binding to gal DNA is orientation specific and is specifically dependent upon binding of GalR to both O(E) and O(I). We propose that HU, in concert with GalR, forms a specific nucleoprotein higher order complex containing a DNA loop. This way, HU deforms the promoter to make the latter inactive for transcription initiation while remaining sensitive to inducer. The example of gal repression provides a model for studying how a 'condensed' DNA becomes available for transcription.

Interaction of MutS protein with the major and minor grooves of a heteroduplex DNA

Thermus aquaticus MutS protein is a DNA mismatch repair protein that recognizes and binds to heteroduplex DNAs containing mispaired or unpaired bases. Using enzymatic and chemical probe methods, we have examined the binding of Taq MutS protein to a heteroduplex DNA having a single unpaired thymidine residue. DNase I footprinting identifies a symmetrical region of protection 24-28 nucleotides long centered on the unpaired base. Methylation protection and interference studies establish that Taq MutS protein makes contacts with the major groove of the heteroduplex in the immediate vicinity of the unpaired base. Hydroxyl radical and 1, 10-phenanthroline-copper footprinting experiments indicate that MutS also interacts with the minor groove near the unpaired base. Together with the identification of key phosphate groups detected by ethylation interference, these data reveal critical contact points residing in the major and minor grooves of the heteroduplex DNA.

The integration host factor-DNA complex upstream of the early promoter of bacteriophage Mu is functionally symmetric

Inversion of the ihf site in the promoter region of the early promoter of bacteriophage Mu did not influence the integration host factor (IHF)-mediated functions. IHF bound to this inverted site could counteract H-NS-mediated repression, directly activate transcription, and support lytic growth of bacteriophage Mu. This implies that the IHF heterodimer and its asymmetrical binding site form a functionally symmetrical complex.

Coactivation in vitro of the sigma54-dependent promoter Pu of the TOL plasmid of Pseudomonas putida by HU and the mammalian HMG-1 protein

The mechanism by which the prokaryotic histone-like protein HU replaces the integration host factor (IHF) in the coactivation of the sigma54-dependent promoter Pu of Pseudomonas putida has been investigated. By using a preactivated form of the cognate activator protein XylR, we show that the functional replacement of IHF with HU previously suggested in vivo can be faithfully reproduced in vitro with purified components. Furthermore, the coactivation effect of IHF on Pu could be mimicked not only by HU but also by the mammalian nonhistone chromatin protein HMG-1 and could be bypassed by intrinsically curved DNA. These results suggest that either of two different mechanisms (generation of a site-specific static DNA bend or a general flexibilization of the promoter region) gives rise to the same structural effect of stimulating transcription from Pu through changes in promoter architecture.

A good turn for DNA: the structure of integration host factor bound to DNA

The crystal structure of integration host factor (IHF) complexed with DNA shows how a small heterodimeric protein can induce a big bend in DNA. IHF exerts leverage in the minor groove and wraps DNA around the body of the protein, providing another example of sequence-specific recognition of the minor groove.

Making DNA do a U-turn: IHF and related proteins

IHF and HU belong to a family of proteins that introduce sharp bends into DNA and act as accessory factors in a variety of cellular processes in prokaryotes. In addition to the crystal structure of IHF bound to DNA, the past year has seen a number of advances in the understanding of the interactions of these proteins with DNA in solution.

Function of the C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase in basal expression and integration host factor-mediated activation of the early promoter of bacteriophage Mu

Integration host factor (IHF) can activate transcription from the early promoter (Pe) of bacteriophage Mu both directly and indirectly. Indirect activation occurs through alleviation of H-NS-mediated repression of the Pe promoter (P. Van Ulsen, M. Hillebrand, L. Zulianello, P. Van de Putte, and N. Goosen, Mol. Microbiol. 21:567-578, 1996). The direct activation involves the C-terminal domain of the alpha subunit (alphaCTD) of RNA polymerase. We investigated which residues in the alphaCTD are important for IHF-mediated activation of the Pe promoter. Initial in vivo screening, using a set of substitution mutants derived from an alanine scan (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996; H. Tang, K. Severinov, A. Goldfarb, D. Fenyo, B. Chait, and R. H. Ebright, Genes Dev. 8:3058-3067, 1994), indicated that the residues, which are required for transcription activation by the UP element of the rrnB P1 promoter (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996), are also important for Pe expression in the presence of IHF. Two of the RNA polymerase mutants, alphaR265A and alphaG296A, that affected Pe expression most in vivo were subsequently tested in in vitro transcription experiments. Mutant RNA polymerase with alphaR265A showed no IHF-mediated activation and a severely reduced basal level of transcription from the Pe promoter. Mutant RNA polymerase with alphaG296A resulted in a slightly reduced transcription from the Pe promoter in the absence of IHF but could still be activated by IHF. These results indicate that interaction of the alphaCTD with DNA is involved not only in the IHF-mediated activation of Pe transcription but also in maintaining the basal level of transcription from this promoter. Mutational analysis of the upstream region of the Pe promoter identified a sequence, positioned from -39 to -51 with respect to the transcription start site, that is important for basal Pe expression, presumably through binding of the alphaCTD. The role of the alphaCTD in IHF-mediated stimulation of transcription from the Pe promoter is discussed.

DNA bending is induced by binding of the glucocorticoid receptor DNA binding domain and progesterone receptors to their response element

Circular permutation analysis was used to determine the degree of DNA bending induced by binding of the glucocorticoid receptor (GR) DNA binding domain (DBD), the human progesterone receptor (PR) DBD, PR-A:A and PR-B:B homodimers, and PR-A:B heterodimers to the glucocorticoid response element/progesterone response element (GRE/PRE). The bending angles induced by the GR DBD and the PR DBD were approximately 28 degrees and 25 degrees, respectively. The PR-B:B and PR-A:A homodimers and the PR-A:B heterodimers all induced similar DNA bending angles of 72-77 degrees. The substantially greater DNA bend induced by full-length PR compared to the PR DBD indicates that sequences outside the classic zinc finger DNA binding domain may play an important role in the interaction of PR with the GRE/PRE. Because PR-A:A and PR-B:B homodimers and the PR-A:B heterodimers induce similar DNA bends, the different abilities of the PR-A and PR-B isoforms to activate transcription are not due to differences in their abilities to distort DNA structure.

Crystal structure of an IHF-DNA complex: a protein-induced DNA U-turn

Integration host factor (IHF) is a small heterodimeric protein that specifically binds to DNA and functions as an architectural factor in many cellular processes in prokaryotes. Here, we report the crystal structure of IHF complexed with 35 bp of DNA. The DNA is wrapped around the protein and bent by >160 degrees, thus reversing the direction of the helix axis within a very short distance. Much of the bending occurs at two large kinks where the base stacking is interrupted by intercalation of a proline residue. IHF contacts the DNA exclusively via the phosphodiester backbone and the minor groove and relies heavily on indirect readout to recognize its binding sequence. One such readout involves a six-base A tract, providing evidence for the importance of a narrow minor groove.

High resolution footprinting of a type I methyltransferase reveals a large structural distortion within the DNA recognition site

The type I DNA methyltransferase M.EcoR124I is a multi-subunit enzyme that binds to the sequence GAAN6RTCG, transferring a methyl group from S-adenosyl methionine to a specific adenine on each DNA strand. We have investigated the protein-DNA interactions in the complex by DNase I and hydroxyl radical footprinting. The DNase I footprint is unusually large: the protein protects the DNA on both strands for at least two complete turns of the helix, indicating that the enzyme completely encloses the DNA in the complex. The higher resolution hydroxyl radical probe shows a smaller, but still extensive, 18 bp footprint encompassing the recognition site. Within this region, however, there is a remarkably hyper-reactive site on each strand. The two sites of enhanced cleavage are co-incident with the two adenines that are the target bases for methylation, showing that the DNA is both accessible and highly distorted at these sites. The hydroxyl radical footprint is unaffected by the presence of the cofactor S-adenosyl methionine, showing that the distorted DNA structure induced by M.EcoR124I is formed during the initial DNA binding reaction and not as a transient intermediate in the reaction pathway.

In vitro transcriptional analysis of TyrR-mediated activation of the mtr and tyrP+3 promoters of Escherichia coli

In order to understand the mechanism by which the TyrR protein activates transcription from the mtr and tyrP+3 promoters, we have carried out in vitro transcription experiments with supercoiled DNA templates. We have shown that addition of the histone-like protein HU or integration host factor (IHF) greatly inhibited the transcription from the mtr and tyrP+3 promoters. In the presence of phenylalanine, the wild-type TyrR protein, but not a mutant TyrR protein (activation negative), was able to relieve the HU- or IHF-mediated inhibition of transcription. In contrast, the alleviation of the HU- or IHF-mediated transcription inhibition by the wild-type TyrR protein did not occur when a mutant RNA polymerase with a C-terminally truncated alpha subunit was used to carry out the transcription reaction.

Structure and function of the Pseudomonas putida integration host factor

Integration host factor (IHF) is a DNA-binding and -bending protein that has been found in a number of gram-negative bacteria. Here we describe the cloning, sequencing, and functional analysis of the genes coding for the two subunits of IHF from Pseudomonas putida. Both the ihfA and ihfB genes of P. putida code for 100-amino-acid-residue polypeptides that are 1 and 6 residues longer than the Escherichia coli IHF subunits, respectively. The P. putida ihfA and ihfB genes can effectively complement E. coli ihf mutants, suggesting that the P. putida IHF subunits can form functional heterodimers with the IHF subunits of E. coli. Analysis of the amino acid differences between the E. coli and P. putida protein sequences suggests that in the evolution of IHF, amino acid changes were mainly restricted to the N-terminal domains and to the extreme C termini. These changes do not interfere with dimer formation or with DNA recognition. We constructed a P. putida mutant strain carrying an ihfA gene knockout and demonstrated that IHF is essential for the expression of the P(U) promoter of the xyl operon of the upper pathway of toluene degradation. It was further shown that the ihfA P. putida mutant strain carrying the TOL plasmid was defective in the degradation of the aromatic model compound benzyl alcohol, proving the unique role of IHF in xyl operon promoter regulation.

Integration host factor alleviates the H-NS-mediated repression of the early promoter of bacteriophage Mu

Integration host factor (IHF), which is a histone-like protein, has been shown to positively regulate transcription in two different ways. It can either help the formation of a complex between a transcription factor and RNA polymerase or it can itself activate RNA polymerase without the involvement of other transcription factors. In this study, we present a third mechanism for IHF-stimulated gene expression, by counteracting the repression by another histone-like protein, H-NS. The early (Pe) promoter of bacteriophage Mu is specifically inhibited by H-NS, both in vivo and in vitro. For this inhibition, H-NS binds to a large DNA region overlapping the Pe promoter. Binding of IHF to a binding site just upstream of Pe alleviates the H-NS-mediated repression of transcription. This same ihf site is also involved in the direct activation of Pe by IHF. In contrast to the direct activation by IHF, however, the alleviating effect of IHF appears not to be dependent on the relevant position of the ihf site on the DNA helix, and it also does not require the presence of the C-terminal domain of the alpha subunit of RNA polymerase. Footprint analysis shows that binding of IHF to the ihf site destabilizes the interaction of H-NS with the DNA, not only in the IHF-binding region but also in the DNA regions flanking the ihf site. These results suggest that IHF disrupts a higher-order nucleoprotein complex that is formed by H-NS and the DNA.

Phage HK022 Roi protein inhibits phage lytic growth in Escherichia coli integration host factor mutants

Temperate coliphage HK022 requires integration host factor (IHF) for lytic growth. The determinant responsible for this requirement was identified as a new gene (roi) located between genes P and Q. This gene encodes a DNA-binding protein (Roi) containing a helix-turn-helix motif. We have shown that Roi binds a site within its own gene that is closely linked to an IHF binding site. By gel retardation experiments, we have found that IHF binding stabilizes the interaction of Roi with its gene. We have isolated three independent phage mutants that are able to grow on an IHF- host. They carry different mutations scattered in the roi gene and specifying single amino-acid changes. The interactions of all three Roi mutant proteins with the Roi binding site differed from that of the wild type. Roi displays strong similarities, in its C-terminal half, to two putative DNA-binding proteins of bacteriophage P1: Ant1 and KilA. The mode of action of the Roi protein and the possibility that IHF is modulating the expression and/or the action of Roi are discussed.

Anatomy of a flexer-DNA complex inside a higher-order transposition intermediate

SUMMARY

Escherichia coli HU, a nonsequence-specific histone- and HMG-like DNA-binding protein, was chemically converted into a series of HU-nucleases with an iron-EDTA-based cleavage moiety positioned at 16 rationally selected sites. Specific DNA cleavage patterns from each of these HU-nucleases allowed us to determine the precise localization, stoichiometry, and orientation of HU binding in the Mu transpososome, a multiprotein structure that mediates the chemical reactions in DNA transposition. Correlation of the DNA cleavage data with the position of the cleavage moiety in the HU three-dimensional structure indicates the presence of a dramatic DNA bend, for which the bend center, direction, and magnitude were assessed. The data, which directly localize selected HU amino acids with respect to DNA in the transpososome, were used as constraints for computer-based molecular modeling to derive the first snapshot of an HU-DNA interaction.

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.

Interaction of CodY, a novel Bacillus subtilis DNA-binding protein, with the dpp promoter region

The product of the codY gene is required for nutritional repression of the Bacillus subtillis dipeptide permease operon (dpp), an operon expressed at early stationary phase in nutrient-rich medium. Though unrelated to any known DNA-binding protein, CodY was shown to bind specifically to the dpp promoter region. DNase I footprinting experiments revealed that the CodY-protected region encompasses the dpp transcription start site and overlaps with the region protected by another regulatory protein, AbrB. CodY and AbrB were found to compete, in vitro, for binding to the dpp promoter region. Binding of CodY was altered in mutants defective in nutritional regulation.

Transcriptional activator of phage phi 29 late promoter: mapping of residues involved in interaction with RNA polymerase and in DNA bending

Phage phi 29 regulatory protein p4 activates transcription from the late A3 promoter by stabilizing sigma A-RNA polymerase at the promoter as a closed complex. Activation requires interaction between both proteins. Protein p4 bends the DNA upon binding. We have performed a detailed mutagenesis study of the carboxyl end of the protein, which is involved in both transcription activation and DNA bending. The results indicate that Arg-120 is the most critical residue for activation, probably mediating the interaction with RNA polymerase. Several basic residues have been identified, including Arg-120, that contribute to maintenance of the DNA bending, probably via electrostatic interactions with the DNA backbone. The degree or stability of the induced bend apparently relies on the additive contribution of all basic residues of the carboxyl end of the protein. Therefore, the activation and DNA bending surfaces overlap, and Arg-120 should interact with both DNA and RNA polymerase. As we show that protein p4 is a dimer in solution, and is bound to DNA as a tetramer, the results suggest a model in which two of the p4 subunits interact with the DNA, bending it, while the other two subunits remain accessible to interact with RNA polymerase.

The leucine-responsive regulatory protein (Lrp) from Escherichia coli. Stoichiometry and minimal requirements for binding to DNA

Lrp (Leucine-responsive regulatory protein) regulates the expression of a number of operons in Escherichia coli. A recent study of DNA sequences recognized by Lrp established the consensus as a 15-bp sequence, YAGHAWATTWTDCTR (Y = C/T, H = "not G," W = A/T, D ="not C," R = A/G) (Cui, Y., Wang, Q., Stormo, G. D., and Calvo, J. M. (1995) J. Bacteriol. 177, 4872-4880). Here we report the stoichiometry of Lrp binding (an Lrp dimer binds to a single binding site) and studies that define the minimal length of DNA required for binding. A double-stranded 15 mer having a sequence that closely matches the consensus does not show measurable binding to Lrp. One or two base pairs of DNA flanking each end are not sufficient for binding, but constructs having 3-5 additional base pairs (21 mer) show relatively strong binding. Single-stranded flanking DNA also contributes to strong binding. The extent of the contribution to binding is dependent upon whether the single strand is on the left or right of the double-stranded region and whether the polarity of the single-stranded DNA is 5' to 3' or 3' to 5'.

Specific targeting of protein-DNA complexes by DNA-reactive drugs (+)-CC-1065 and pluramycins

To gain insight into the interactions between transcriptional factor proteins and DNA, the DNA-reactive drugs (+)-CC-1065 and pluramycin were used to target specific protein-DNA complexes. The structural features of the complex between the transcriptional activator Sp1 and the 21-base-pair repeat of the early promoter region of SV40 DNA were examined using hydroxyl-radical footprinting; (+)-CC-1065, a sequence-specific minor groove bending probe; and circularization experiments. The results show that the 21-base-pair repeat region has an intrinsically in-phase bent structure that is stabilized upon saturation Sp1 binding by protein-DNA and protein-protein interactions to produce a looping structure. The intercalating drug pluramycin was used to probe the structural details of the interaction between the TATA binding protein (TBP) and the TATA box DNA sequence. TBP, which directs initiation of RNA transcription, exhibits two-fold symmetry and apparently interacts with the TATA box in a symmetrical fashion. However, the interaction results in an asymmetric effect, in that transcription is initiated only in the downstream direction. Using pluramycin as a probe, it was determined that TBP binding to the human myoglobin TATA sequences enhances pluramycin reactivity at a site immediately downstream of the TATA box. The implications on transcriptional control of ternary complexes comprised of transcriptional factors, DNA, and DNA-reactive compounds will be presented.

Multiple nosZ promoters and anaerobic expression of nos genes necessary for Pseudomonas stutzeri nitrous oxide reductase and assembly of its copper centers

Respiration of N oxides (denitrification) by bacteria is expressed facultatively in response to environmental stimuli. We have studied the transcriptional organization of the nos gene cluster of Pseudomonas stutzeri. This cluster carries the information for a functional nitrous oxide reductase (NosZ) which catalyzes the last step of the denitrification process. The nos genes are transcribed in three units, nosR, nosZ, and nosDFY. Transcription of nosZ is initiated from six different promoters which extend over a region of about 200 bp. The activity of two promoters varies subject to different growth conditions. Promoter P3 is active preferentially under denitrifying conditions and presumably under the control of a homolog of the transcriptional regulator FNR. Promoter P2 is the most active start site under aerobiosis and likely to initiate the low constitutive expression of nosZ. Transcription of nosR, encoding a regulator for nosZ expression, and transcription of the nosDFY operon, required for the copper chromophore assembly of NosZ, are both initiated from a single promoter. Transcription of nosR and the nosDFY operon was shown by phoA and lacZ fusions to be activated under a lowered oxygen tension and the simultaneous presence of an N oxide. The enzymatic activities associated with the hybrid proteins suggest for NosR and NosF a location in the cytoplasmic membrane and the cytoplasm, respectively.

In vitro integration of human immunodeficiency virus type 1 cDNA into targets containing protein-induced bends

Integration of human immunodeficiency virus type 1 cDNA into a target DNA can be strongly influenced by the conformation of the target. For example, integration in vitro is sometimes favored in target DNAs containing sequence-directed bends or DNA distortions caused by bound proteins. We have analyzed the effect of DNA bending by studying integration into two well-characterized protein-DNA complexes: Escherichia coli integration host factor (IHF) protein bound to a phage IHF site, and the DNA binding domain of human lymphoid enhancer factor (LEF) bound to a LEF site. Both of these proteins have previously been reported to bend DNA by approximately 140 degrees. Binding of IHF greatly increases the efficiency of in vitro integration at hotspots within the IHF site. We analyzed a series of mutants in which the IHF site was modified at the most prominent hotspot. We found that each variant still displayed enhanced integration upon IHF binding. Evidently the local sequence is not critical for formation of an IHF hotspot. LEF binding did not create preferred sites for integration. The different effects of IHF and LEF binding can be rationalized in terms of the different proposed conformations of the two protein-DNA complexes.

A role for a small stable RNA in modulating the activity of DNA-binding proteins

The 10Sa RNA, encoded by the E. coli ssrA gene, appears to modulate action of some DNA-binding proteins. When ssrA is inactivated, lacZ expression from the lac operon, as well as galK from a gal operon fused to a phage lambda promoter, is reduced from that observed in bacteria wild-type for ssrA. These differences are not observed if the relevant repressor is inactive, suggesting that in the absence of 10Sa RNA binding of LacI and lambda cI repressors is enhanced. Gel mobility shifts show that 10Sa RNA binds these repressors and that an excess of 10Sa RNA competes for binding of lambda cI with a DNA fragment containing the OR2 repressor-binding sequence. Similar observations were made in studies of the E. coli LexA repressor and phage P22 C1 transcription activator proteins. These results suggest that direct interaction with 10Sa RNA may explain this modulation of protein-DNA interactions.

Cooperative binding of Tn3 resolvase monomers to a functionally asymmetric binding site

BACKGROUND

The inverted repeat is a common feature of protein-binding sites in DNA. The two-fold symmetry of the inverted repeat corresponds to the two-fold symmetry of the protein that binds to it. In most natural inverted-repeat binding sites, however, the DNA sequence does not have perfect two-fold symmetry. Our study of how a site-specific recombinase recognizes an inverted-repeat binding site indicates that such sequence asymmetry can be functionally important.

RESULTS

Tn3 resolvase forms two complexes with the 34 base-pair binding site II of its recombination region, res. A resolvase monomer first binds at the left end of the site; a second monomer then binds cooperatively at the right end. In both complexes, the DNA is bent by resolvase. In contrast, the closely related gamma delta resolvase binds to site II mainly as a dimer. Insertion of 5 or 10 base pairs at the centre of the site does not prevent cooperative binding of two Tn3 resolvase subunits. The fully occupied site II has a very asymmetric structure. Reversal of the orientation of site II in res blocks recombination; thus, its asymmetric properties are functionally important. We propose a structure for the two-subunit complex formed with site II, based on our results and by analogy with the co-crystal structure of gamma delta resolvase bound to res site I.

CONCLUSIONS

Deviations from perfect inverted-repeat symmetry in a resolvase-binding site lead to ordered binding of subunits, structural asymmetry of resolvase-DNA complexes, and asymmetric function.

Participation of the flank regions of the integration host factor protein in the specificity and stability of DNA binding

The heterodimeric integration host factor (IHF) protein is a site-specific DNA-binding protein from Escherichia coli that strongly bends the DNA. It has been proposed (Yang, C., and Nash, H.A. (1989) Cell 57, 869-880; Granston, A. E., and Nash, H. A. (1993) J. Mol. Biol 234, 45-59; Lee, E. C., Hales, L. M., Gumport, R. I., and Gardner, J. F. (1992) EMBO J. 11, 305-313) that the wrapping of the DNA around the protein is stabilized through interactions between the flanks of the protein and the DNA. In order to elucidate which domains of the IHF protein are involved in these interactions, we have constructed mutant proteins in which the C-terminal part of one of the subunits has been deleted. We observed that the C-terminal alpha 3 helix of HimD is involved in the stability of DNA binding, but not in the specificity. In contrast the corresponding alpha 3 helix of HimA is essential for the sequence specificity, since an IHF mutant lacking this domain only binds to the DNA in a non-specific way. The possible role of the two C-terminal alpha-helical structures in complex formation will be discussed. We also examined the properties of an IHF mutant that has an amino acid substitution between beta sheets beta 1 and beta 2 of the HimD subunit (R46H). The occupancy of the ihf site by the mutant and wild type proteins differ in the 3' part of the ihf site and as a result the bend introduced in the DNA by the mutant protein is less pronounced. We propose that the arginine 46 in the HimD subunit is in vicinity of the TTR region of the consensus and that through contacts within the minor groove the DNA bend introduced by IHF is stabilized.

The sigma 54-dependent promoter Ps of the TOL plasmid of Pseudomonas putida requires HU for transcriptional activation in vivo by XylR

In the presence of toluene and xylenes, the sigma 54-dependent Ps promoter of the TOL (toluene biodegradation) plasmid pWW0 of Pseudomonas putida is activated at a distance by the XylR protein, of the NtrC family of transcriptional regulators. Since contacts between XylR bound to upstream activating sites and the RNA polymerase require the looping out of the intervening DNA segment, the intrinsic curvature, the bendability of the corresponding sequence, and the spatial effects of protein-induced DNA bending have an influence on promoter activity. Unlike other sigma 54-dependent promoters, Ps does not require the structural aid of the integration host factor to assemble a specific promoter geometry required for transcriptional initiation. In vivo analysis of transcriptional activity in various genetic backgrounds suggests, instead, that the looping out of intervening DNA sequences in Ps would result from the exacerbation of a preexisting static bend within the region, assisted by the histone-like protein HU.

Mutual stabilisation of bacteriophage Mu repressor and histone-like proteins in a nucleoprotein structure

Integration host factor (IHF) binds in a sequence-specific manner to the bacteriophage Mu early operator. It participates with bound Mu repressor, c, in building stable, large molecular mass nucleoprotein complexes in vitro and enhances repression of early transcription in vivo. We demonstrate that, when the specific IHF binding site with the operator is mutated, the appearance of large molecular mass complexes still depends on IHF and c, but the efficiency of their formation is reduced. Moreover, the IHF-like HU protein, which binds DNA in a non-sequence-specific way, can substitute for IHF and participate in complex formation. Since the complexes require both c and a host factor (IHF or HU), the results imply that these proteins stabilise each other within the nucleoprotein structures. These results suggest that IHF and HU are directed to the repressor-operator complexes, even in the absence of detectable sequence-specific binding. This could be a consequence of their preferential recognition of DNA containing a distortion such as that introduced by repressor binding to the operator. The histone-like proteins could then stabilise the nucleoprotein complexes simply by their capacity to maintain a bend in DNA rather than by specific protein-protein interactions with c. This model is supported by the observation that the unrelated eukaryotic HMG-1 protein, which exhibits a similar marked preference for structurally deformed DNA, is also able to participate in the formation of higher-order complexes with c and the operator DNA.

Identification of related genes in phages phi 80 and P22 whose products are inhibitory for phage growth in Escherichia coli IHF mutants

Bacteriophage lambda grows in both IHF+ and IHF- host strains, but the lambdoid phage phi 80 and hybrid phage lambda (QSRrha+)80 fail to grow in IHF- host strains. We have identified a gene, rha, in the phi80 region of the lambda(QSRrha+)80 genome whose product, Rha, inhibits phage growth in an IHF- host. A search of the GenBank database identified a homolog of rha, ORF201, a previously identified gene in phage P22, which similarly inhibits phage growth in IHF- hosts. Both rha and ORF201 contain two possible translation start sites and two IHF binding site consensus sequences flanking the translation start sites. Mutations allowing lambda (QSRrha+)80 and P22 to grow in IHF- hosts map in rha and ORF201, respectively. We present evidence suggesting that, in an IHF+ host, lambda(QSRrha+)80 expresses Rha only late in infection but in an IHF- host the phage expresses Rha at low levels early in infection and at levels higher than those in an IHF+ host late in infection. We suspect that the deregulation of rha expression and, by analogy, ORF201 expression, is responsible for the failure of phi80, lambda(QSRrha+)80, and P22 to grow in IHF mutants.

Negative and positive regulation of Tn10/IS10-promoted recombination by IHF: two distinguishable processes inhibit transposition off of multicopy plasmid replicons and activate chromosomal events that favor evolution of new transposons

Tn10 is a composite transposon; inverted repeats of insertion sequence IS10 flank a tetracycline-resistance determinant. Previous work has identified several regulatory processes that modulate the interaction between Tn10 and its host. Among these, host-specified DNA adenine methylation, an IS10-encoded antisense RNA and preferential cis action of transposase are particularly important. We now find that the accessory host protein IHF and the sequences that encode the IHF-binding site in IS10 are also important regulators of the Tn10 transposition reaction in vivo and that these determinants are involved in two distinguishable regulatory processes. First, IHF and the IHF-binding site of IS10, together with other host components (e.g., HU), negatively regulate the normal intermolecular transposition process. Such negative regulation is prominent only for elements present on multicopy plasmid replicons. This multicopy plasmid-specific regulation involves effects both on the transposition reaction per se and on transposase gene expression. Second, specific interaction of IHF with its binding site stimulates transposon-promoted chromosome rearrangements but not transposition of a short Tn10-length chromosomal element. However, additional considerations predict that IHF action should favor chromosomal transposition for very long composite elements. On the basis of these and other observations we propose that, for chromosomal events, the major role of IHF is to promote the evolution of new IS10-based composite transposons.

Assembly and function of a TCR alpha enhancer complex is dependent on LEF-1-induced DNA bending and multiple protein-protein interactions

In this study we examine the molecular basis for the synergistic regulation of the minimal TCR alpha enhancer by multiple proteins. We find that reconstitution of TCR alpha enhancer function in nonlymphoid cells requires expression of the lymphoid-specific proteins LEF-1, Ets-1 and PEBP2 alpha (CBF alpha), and a specific arrangement of their binding sites in the enhancer. We show that Ets-1 cooperates with PEBP2 alpha to bind adjacent sites at one end of the enhancer, forming a ternary complex that is unstable by itself. Stable occupancy of the Ets-1- and PEBP2 alpha-binding sites in a DNase I protection assay was found to depend on both a specific helical phasing relationship with a nonadjacent ATF/CREB-binding site at the other end of the enhancer and on LEF-1. The HMG domain of LEF-1 was found previously to bend the DNA helix in the center of the TCR alpha enhancer. We now show that the HMG domain of the distantly related SRY protein, which also bends DNA, can partially replace LEF-1 in stimulating enhancer function in transfection assays. Taken together with the observation that Ets-1 and members of the ATF/CREB family have the potential to associate in vitro, these data suggest that LEF-1 can coordinate the assembly of a specific higher-order enhancer complex by facilitating interactions between proteins bound at nonadjacent sites.

Activation of a temporally regulated Caulobacter promoter by upstream and downstream sequence elements

The flagellar genes of Caulobacter crescentus are expressed under cell-cycle control. Expression is regulated by both flagellar assembly cues and cell-cycle events. In this paper we define the sequences required for the expression of the flgF operon, a new class of sigma 54 flagellar promoter. This promoter type is expressed in the middle portion of the cell cycle and regulates the expression of basal-body genes. DNase I footprinting and mutagenesis demonstrates that an integration host factor (IHF)-binding site is required for maximal levels of transcription of the flgF promoter. In addition to containing a conventional upstream enhancer element (RE-1), this promoter is unusual in that it also requires sequences (element RE-2) immediately downstream of the transcriptional start site for maximal levels of gene expression. Cell-cycle experiments indicate that RE-1 and RE-2 contribute equally to the regulation of temporal transcription. The presence of two intact elements in the promoter results in a fourfold increase in promoter activity compared with a promoter containing only one intact element, suggesting that these two elements may function synergistically to activate transcription.

The regulation of transcription initiation by integration host factor

Integration host factor (IHF) of Escherichia coli is an asymmetric histone-like protein that binds and bends the DNA at specific sequences. IHF functions as an accessory factor in a wide variety of processes including replication, site-specific recombination and transcription. In many of these processes IHF was shown to act as an architectural element which helps the formation of nucleo-protein complexes by bending of the DNA at specific sites. This MicroReview shows how such a structural role of IHF can influence the initiation of transcription. In addition, it summarizes the evidence indicating that IHF can stimulate transcription via a direct interaction with RNA polymerase and explores the possibility that the asymmetry of the IHF protein might reflect such an interaction.

Substitutions in conserved dodecapeptide motifs that uncouple the DNA binding and DNA cleavage activities of PI-SceI endonuclease

The PI-SceI endonuclease from yeast belongs to a protein family whose members contain two conserved dodecapeptide motifs within their primary sequences. The function of two acidic residues within these motifs, Asp218 and Asp326, was examined by substituting alanine, asparagine, and glutamic acid residues at these positions. All of the purified mutant proteins bind to the PI-SceI recognition site with the same affinity and specificity as the wild-type enzyme. By contrast, substituting alanine or asparagine amino acids at the two positions completely eliminates strand cleavage of substrate DNA, whereas substitution with glutamic acid markedly reduces the cleavage activity. Experiments using nicked substrates demonstrate that the wild-type enzyme shows no strand preference during cleavage. These results are consistent with a model in which both acidic residues are part of a single catalytic center that cleaves both DNA strands. Furthermore, substrate binding by wild-type PI-SceI stimulates hydroxyl radical or hydroxide ion attack at the cleavage site while binding by the alanine-substituted proteins either stimulates this attack significantly less or protects the DNA at this position. These finding are discussed in terms of possible reaction mechanisms for PI-SceI-mediated endonucleolytic cleavage.

The c-myc promoter binding protein (MBP-1) and TBP bind simultaneously in the minor groove of the c-myc P2 promoter

The c-myc promoter binding protein (MBP-1) is a DNA binding protein which negatively regulates the expression of the human c-myc gene. MBP-1 binds to a sequence which overlaps the binding site for the general transcription factor TBP, within the c-myc P2 promoter region. Since TBP binds in the minor groove, MBP-1 might inhibit c-myc transcription by preventing the formation of a functional preinitiation complex. In support of this hypothesis, we have demonstrated that MPB-1 is a minor groove binding protein. In order to characterize MBP-1 binding, we substituted A-T base pairs in the MBP-1 binding site with I-C base pairs, which changes the major groove surface without altering the minor groove surface. This substitution did not inhibit the sequence-specific binding of MBP-1 and TBP. On the other hand, G-C to I-C substitution within the MBP-1 binding site alters the minor groove and prevents MBP-1 binding. Competitive electrophoretic mobility shift assays were used to show that berenil, distamycin, and mithramycin, all of which bind in the minor groove, compete with MBP-1 for binding to the MPB-1 binding site. These minor groove binding ligands also effectively inhibit the simultaneous DNA binding activity of both MBP-1 and TBP. We conclude that both MBP-1 and TBP can bind simultaneously in the minor groove of the TATA motif on the c-myc P2 promoter. This suggests that MBP-1 may negatively regulate c-myc gene expression by preventing efficient transcription initiation.

Cloning and sequence analyses of the genes coding for the integration host factor (IHF) and HU proteins of Pseudomonas aeruginosa

Histone-like proteins, such as HU and the integration host factor (IHF), are small, dimeric, DNA-bending proteins which play a role in maintaining constrained DNA structures and hence in regulating gene expression. Two different strategies were used to isolate the genes coding for Pseudomonas aeruginosa (Pa) HU and IHF, two proteins that we have previously isolated from a mucoid strain. By use of a PCR-based technique with oligodeoxyribonucleotides (oligos) designed from the N-terminal amino acid (aa) sequences of HU and the beta-subunit of IHF, and Southern blot analyses, hupB and himD, encoding HU and IHF beta, respectively, have been cloned. The himA gene of Pa, encoding the alpha-subunit of IHF, was isolated using himA of Escherichia coli (Ec) as a probe in Southern blot analyses. The deduced hupB product (90 aa, 9 kDa) is 79% identical to HU beta and 61% to HU alpha of Ec. The predicted products of himA (100 aa, 11.5 kDa) and of himD (94 aa, 10.6 kDa) share 77 and 70% identity with IHF alpha and IHF beta of Ec, respectively. The promoter region of himD contains an IHF consensus sequence, as is the case for Ec himD.

Crystal structure of the replication terminator protein from B. subtilis at 2.6 A

The crystal structure of the replication terminator protein (RTP) of B. subtilis has been determined at 2.6 A resolution. As previously suggested by both biochemical and biophysical studies, the molecule exists as a symmetric dimer and is in the alpha + beta protein-folding class. The protein has several uncommon features, including an antiparallel coiled-coil, which serves as the dimerization domain, and both an alpha-helix and a beta-ribbon suitably positioned to interact with the major and minor grooves of B-DNA. A site has been identified on the surface of RTP that is biochemically and positionally suitable for interaction with the replication-specific helicase. Other features of the structure are consistent with the polar contrahelicase mechanism of the protein. A model of the interaction between RTP and its cognate DNA is presented.

The Bacillus subtilis histone-like protein Hbsu is required for DNA resolution and DNA inversion mediated by the beta recombinase of plasmid pSM19035

The beta recombinase, encoded by the Gram-positive bacterial plasmid pSM19035, is unable to mediate DNA recombination in vitro unless a host factor is provided. The factor has now been identified as the Bacillus subtilis Hbsu protein. Hbsu is a nonspecific DNA-binding and DNA-bending protein. The beta recombinase, in the presence of highly purified Hbsu protein, is able to catalyze in vitro intramolecular recombination between two specific recombination sites on a supercoiled DNA molecule. DNA resolution was obtained when the two crossing over sites (six sites) were directly oriented, whereas DNA inversion was the product when the six sites were in inverse orientation. The ability of the Escherichia coli chromatin-associated proteins HU, IHF, Fis, and H-NS to substitute for Hbsu was investigated. HU efficiently stimulated beta-mediated recombination, while the effect of IHF was partial and that of Fis and H-NS was undetectable. In addition, the beta protein was able to mediate DNA recombination in both wild-type and IHF-deficient E. coli cells, but failed to do so in an HU-deficient strain. The data presented provide direct evidence that a chromatin-associated protein is strictly required for beta-mediated recombination.