Protein HU binds specifically to kinked DNA

The ribosomal S16 protein of Escherichia coli displaying a DNA-nicking activity binds to cruciform DNA

We have recently shown that the ribosomal S16 protein of Escherichia coli is a magnesium-dependent DNase which introduces nicks into supercoiled DNA molecules [Oberto, J., Bonnefoy, E., Mouray, E., Pellegrini, O., Wikstrom, P. M. & Rouvière-Yaniv, J. (1996) Mol. Microbiol. 19, 1319-1330]. In this work we analysed the DNA-binding and DNA-nicking properties of S16 using two different approaches. Gel-retardation assays showed that S16 is a structure-specific DNA-binding protein displaying a preferential binding for cruciform DNA structures. This specific binding to cruciform DNA was further investigated using a supercoiled plasmid carrying the origin of replication of E. coli (oriC) which is an (A+T)-rich DNA region with abundant palindromic sequences susceptible of forming cruciform-like structures in vivo. We show that the nicks introduced by S16 in oriC are not randomly positioned but are precisely localised near such palindromic sequences. In addition, the nicking activity of S16 appeared to be sequence dependent since the cuts introduced by S16 occurred next to an adenine, in most cases an unpaired adenine, usually followed by a GTT sequence. Overall these experiments indicate that S16 requires a cruciform-like DNA structure to bind DNA and the presence of a particular sequence in order to introduce specific single-stranded cuts into a DNA molecule.

Recognition and manipulation of branched DNA structure by junction-resolving enzymes

The junction-resolving enzymes are a class of nucleases that introduce paired cleavages into four-way DNA junctions. They are important in DNA recombination and repair, and are found throughout nature, from eubacteria and their bacteriophages through to higher eukaryotes and their viruses. These enzymes exhibit structure-selective binding to DNA junctions; although cleavage may be more or less sequence-dependent, binding affinity is purely related to the branched structure of the DNA. Binding and cleavage events can be separated for a number of the enzymes by mutagenesis, and mutant proteins that are defective in cleavage while retaining normal junction-selective binding have been isolated. Critical acidic residues have been identified in several resolving enzymes, suggesting a role in the coordination of metal ions that probably deliver the hydrolytic water molecule. The resolving enzymes all bind to junctions in dimeric form, and the subunits introduce independent cleavages within the lifetime of the enzyme-junction complex to ensure resolution of the four-way junction. In addition to recognising the structure of the junction, recent data from four different junction-resolving enzymes indicate that they also manipulate the global structure. In some cases this results in severe distortion of the folded structure of the junction. Understanding the recognition and manipulation of DNA structure by these enzymes is a fascinating challenge in molecular recognition.

The cloning and overexpression of a cruciform binding protein from Ustilago maydis

The structural gene HMP1 encoding a cruciform DNA binding protein from Ustilago maydis has been cloned. Gene isolation was enabled by a polymerase chain reaction procedure using primers designed from amino acid sequence obtained from the purified protein. DNA sequence determination has revealed that the gene encodes a protein containing 98 amino acids with a calculated molecular weight of 10151. Comparison of the cDNA and genomic sequences indicated the presence of a single intron in the 5' coding region of the gene. The gene was over-expressed as a translational fusion with a hexahistidine leader sequence enabling affinity purification of the protein on an immobilized metal matrix. Protein isolated after over-expression exhibited cruciform binding activity, conforming earlier purified native protein results. Sequence analysis indicated that no HMG box was present and very little homology to other known cruciform binding proteins was found. It is plausible that HMP1 represents a novel class of proteins that recognize such secondary structures.

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.

Twin hydroxymethyluracil-A base pair steps define the binding site for the DNA-binding protein TF1

The DNA-bending protein TF1 is the Bacillus subtilis bacteriophage SPO1-encoded homolog of the bacterial HU proteins and the Escherichia coli integration host factor. We recently proposed that TF1, which binds with high affinity (Kd was approximately 3 nM) to preferred sites within the hydroxymethyluracil (hmU)-containing phage genome, identifies its binding sites based on sequence-dependent DNA flexibility. Here, we show that two hmU-A base pair steps coinciding with two previously proposed sites of DNA distortion are critical for complex formation. The affinity of TF1 is reduced 10-fold when both of these hmU-A base pair steps are replaced with A-hmU, G-C, or C-G steps; only modest changes in affinity result when substitutions are made at other base pairs of the TF1 binding site. Replacement of all hmU residues with thymine decreases the affinity of TF1 greatly; remarkably, the high affinity is restored when the two hmU-A base pair steps corresponding to previously suggested sites of distortion are reintroduced into otherwise T-containing DNA. T-DNA constructs with 3-base bulges spaced apart by 9 base pairs of duplex also generate nM affinity of TF1. We suggest that twin hmU-A base pair steps located at the proposed sites of distortion are key to target site selection by TF1 and that recognition is based largely, if not entirely, on sequence-dependent DNA flexibility.

Cruciform structures and functions

In this paper, a structure-function analysis of B-DNA self-fitting is reviewed in the light of recent oligonucleotide crystal structures. Their crystal packings provided a high-resolution view of B-DNA helices closely and specifically fitted by groove-backbone interaction, a natural and biologically relevant manner to assemble B-DNA helices. In revealing that new properties of the DNA molecule emerge during condensation, these crystallographic studies have pointed to the biological importance of DNA—DNA interactions.

Cascade regulation of the toluene-3-monooxygenase operon (tbuA1UBVA2C) of Burkholderia pickettii PKO1: role of the tbuA1 promoter (PtbuA1) in the expression of its cognate activator, TbuT

Burkholderia pickettii PKO1 metabolizes toluene and benzene via a chromosomally encoded toluene-3-monooxygenase pathway. Expression of the toluene-3-monooxygenase operon (tbuA1UBVA2C) is activated by the regulator, TbuT, in the presence of toluene. We have identified the TbuT coding region downstream of the toluene-3-monooxygenase structural genes by nucleotide sequence analysis and have shown that although TbuT is similar to XylR and DmpR, two members of the NtrC family of transcriptional activators which control toluene-xylene and (methyl)phenol catabolism, respectively, it is significantly different in the domain associated with effector specificity. Using a tbuA1-lacZ fusion reporter system, we determined that TbuT is activated not only by aromatic effectors but also the chlorinated aliphatic hydrocarbon trichloroethylene. Expression of tbuT and that of the tbuA1UBVA2C operon were found to be linked by readthrough transcription of tbuT from the toluene-3-monooxygenase promoter. As a result, transcription of tbuT is low when the toluene-3-monooxygenase operon is uninduced and high when expression of tbuA1UBVA2C is induced by toluene. Thus, the toluene-3-monooxygenase promoter drives the cascade expression of both the toluene-3-monooxygenase operon and tbuT, resulting in a positive feedback circuit. Examination of the nucleotide sequence upstream of the toluene-3-monooxygenase operon for promoter-like sequences revealed a -24 TGGC, -12 TTGC sequence, characteristic of sigma54 (rpoN)-dependent promoters. Primer extension and tbuA1-lacZ fusion analyses demonstrated that this -24, -12 promoter sequence, referred to as PtbuA1, was the toluene-3-monooxygenase promoter. Upstream of PtbuA1, a DNA region with dyad symmetry exhibited homology with the XylR-binding site present upstream of the Pu promoter. Deletions within this DNA sequence resulted in complete loss of expression from PtbuA1, suggesting that this region may serve as the TbuT-binding site.

Site-specific recombination by the beta protein from the streptococcal plasmid pSM19035: minimal recombination sequences and crossing over site

The beta recombinase from the broad host range Grampositive plasmid pSM19035 catalyzes intramolecular site-specific recombination between two directly or inversely oriented recombination sites in the presence of a chromatin-associated protein (Hbsu). The recombination site had been localized to a 447 bp DNA segment from pSM19035. This segment includes a 90 bp region that contains two adjacent binding sites (I and II) for beta protein dimers. Using in vitro recombination assays, we show that this 90 bp region is necessary and sufficient for beta protein-mediated recombination; this defines the six site as the region required for beta protein binding. The point of crossing over has been localized to the center of site I. Hbsu has a strong binding affinity for an unknown site located within the 447 bp segment containing the six site. We discuss the possibility that Hbsu recognizes an altered DNA structure, rather than a specific sequence, generated in the synaptic complex.

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.

The effect of nucleic acid geometry on counterion association

The very high axial charge density of nucleic acids is a physical characteristic that substantially influences the thermodynamics of virtually all processes in which they are involved. This arises from long range electrostatic interacts between nucleic acids and the counter- and co-ions in solution so that salt concentration dramatically effects the activities of both reactants and products. A significant contributor to the resulting salt dependence for processes involving nucleic acids (e.g. ligand binding to a choice of nucleic acid substrates or a structural change), is the difference in arrangement of the sugar-phosphate backbone of competing structures. This article reviews the results of a set of Grand Canonical Monte Carlo (GCMC) simulations that explores the effect of nucleic acid geometry, varied as a function of oligomer length and four-way junction branch length, on counterion association and therefore many nucleic acid processes. These GCMC simulations, which utilize a "primitive" model description of the nucleic acid, are complemented by a number of simulations which numerically solve the non-linear Poisson-Boltzmann equation utilizing detailed models for nucleic acids and proteins. Simulations of this kind are particularly useful for the study of systems that have been well characterized structurally, as well as thermodynamically. What is sought in the current article is insight into how an extremely general feature of DNA, namely the geometric arrangement of its phosphate charges surrounded by an exclusion surface, might play a role in determining nucleic acid processes.

Serratia marcescens contains a heterodimeric HU protein like Escherichia coli and Salmonella typhimurium

Homologs of the dimeric HU protein of Escherichia coli can be found in every prokaryotic organism that has been analyzed. In this work, we demonstrate that Serratia marcescens synthesizes two distinct HU subunits, like E. coli and Salmonella typhimurium, suggesting that the heterodimeric HU protein could be a common feature of enteric bacteria. A phylogenetic analysis of the HU-type proteins (HU and IHF) is presented, and a scheme for the origin of the hup genes and the onset of HU heterodimericity is suggested.

Characterization of the binding of HU and IHF, homologous histone-like proteins of Escherichia coli, to curved and uncurved DNA

The binding of E. coli histone-like protein HU to curved and uncurved DNA fragments containing adenine tracts was characterized by relative binding affinity assay, and compared with that of other homologous histone-like protein integration host factor (IHF). Both HU and IHF have about 3- to 5-fold higher affinity for overall curved DNA fragments such as (A6N4)11 and (A3T3N4)12 compared to a standard duplex fragment with mixed sequence. The binding manner of HU to the curved fragments was highly cooperative. However, loss of overall curvature for shorter fragments (< approximately 100 bp) reduced the preference of HU binding to curved (A3T3N4)n over uncurved (T3A3N4)n, indicating that the binding specificity of HU to curved DNA is length-dependent. Thus, the curved DNA configuration of the whole molecule facilitates the binding of several HU molecules to form the hierarchy of HU-DNA complex. Furthermore, it was shown that HU and IHF bind less well to (A6N9)n, which has a zig-zag straight structure, whereas they preferentially bind to uncurved (T3A3N4)14. These results suggested that not only intrinsically overall curvature but also the preferred orientations for DNA bending in the protein-DNA complex are important factors for affinities of HU and IHF.

Role of HU proteins in forming and constraining supercoils of chromosomal DNA in Escherichia coli

Induction of supercoiling in plasmid DNA by HU heterotypic and homotypic dimers, a mutant HU-2 (HupAN12), HBs and HB1 proteins with different DNA-binding affinities was investigated in vitro. The abilities of these proteins to induce supercoiling in DNA correlated with their affinities for DNA. Stoichiometrical analysis of HU heterodimers bound to DNA in the complex restraining the negative torsional tension of DNA showed that 12-13 dimers account for a single superhelical turn. The number of supercoils in the plasmid in vivo decreased on inhibition of DNA gyrase with coumermycin, reaching a steady-state level that indicated the existence of a compartment of restrained supercoils. The size of the restrained compartment was reduced in the absence of HU, indicating the participation of HU in constituting this fraction, and was larger on overproduction of HU-2 in the cells. An increased level of DNA gyrase, expressed from a plasmid carrying both gyr genes, in the cells did not compensate for the deficit of the restrained supercoils caused by HU deficiency, indicating seeming distinct and unrelated action of HU and DNA gyrase in introducing and constraining supercoiling of intracellular DNA.

Conformation of short DNA fragments by modulated fluorescence polarization anisotropy

The technique of fluorescence polarization anisotropy (FPA) decay of intercalated ethidium has been used to study DNA conformation and dynamics, which are being recognized as primary determinants in transcription control and other cellular processes. Frequency modulated FPA when applied to two DNA molecules, a "straight" 50 base-pairs duplex fragment, and a bent fragment of similar length, has yielded different rotational diffusion coefficients for the two fragments. The data have been processed with an analytical model and with Brownian dynamics simulations, obtaining a good fit and a quantitative agreement between the two models. Both analyses have confirmed that one fragment can be described as a straight cylinder, while the other fragment is bent, with an angle estimated to be 45 degrees +/- 3 degrees. FPA has proved to be very powerful in determining simple conformations of short DNA duplexes and also particularly apt to probe the dynamical features of DNA fragments where conventional methods are either too cumbersome or fail to give quantitative results. In addition, the ligand no longer behaves ideally due to its complex structure and charge distribution. Thus for the protein the slope is no longer related simply to the net ligand charge, and the PB model gives a much larger slope than the LL model.(ABSTRACT TRUNCATED AT 400 WORDS)

Theory of the mobility-shift assay of nonspecific protein-DNA complexes governed by conditional probabilities: the HU:DNA complex

Complexes of an 88 bp DNA and the HU protein were studied by both experimental and theoretical electrophoretic mobility-shift analyses. Experimental analysis defined the stoichiometry of binding and estimated an apparent intrinsic dissociation constant (Kd = 1 to 3 x 10(-7) M) for the HU:DNA complexes. The theory of conditional probabilities was applied to the binding of HU to DNA in order to fix the initial equilibrium composition of mixtures to be assayed theoretically by the mobility-shift procedure. Electrophoretic mobility-shift patterns were obtained by numerical solution of a set of simultaneous transport-reaction equations, in which the chemical kinetic term is formulated in terms of dissociation of the different DNA:HU complexes in gel cages. The computed patterns simulated the experimental patterns describing the titration of a fixed concentration of an 88 bp DNA fragment with dimeric HU. These insightful results provide guidelines for interpretation of the electrophoretic behavior of systems in which a ligand binds nonspecifically to DNA. In particular, the narrow unresolved zone observed both experimentally and theoretically beyond 50-60% saturation is a reaction zone characteristic of noncooperative ligand-binding governed by conditional probabilities. The discrepancy between the theoretically assigned and experimental values of the intrinsic binding constant is attributed to an HU-induced change in the conformation of DNA.

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.

HU protein of Escherichia coli binds specifically to DNA that contains single-strand breaks or gaps

In this study, we have identified a protein in Escherichia coli that specifically binds to double-stranded DNA containing a single-stranded gap of one nucleotide. The gap-DNA binding (GDB) protein was purified to apparent homogeneity. The analysis of the amino-terminal sequencing of the GDB protein shows two closely related sequences we identify as the alpha and beta subunits of the HU protein. Furthermore, the GDB protein is not detected in the crude extract of an E. coli double mutant strain hupA hupB that has no functional HU protein. These results led us to identify the GDB protein as the HU protein. HU binds strongly to double-stranded 30-mer oligonucleotides containing a nick or a single-stranded gap of one or two nucleotides. Apparent dissociation constants were measured for these various DNA duplexes using a gel retardation assay. The KD(app) values were 8 nM for the 30-mer duplex that contains a nick and 4 and 2 nM for those that contain a 1-or a 2-nucleotide gap, respectively. The affinity of HU for these ligands is at least 100-fold higher than for the same 30-mer DNA duplex without nick or gap. Other single-stranded breaks or gaps, which are intermediate products in the repair of abasic sites after incision by the Fpg, Nth, or Nfo proteins, are also preferentially bound by the HU protein. Due to specific binding to DNA strand breaks, HU may play a role in replication, recombination, and repair.

Increased sensitivity to gamma irradiation in bacteria lacking protein HU

The heterodimeric HU protein, isolated from Escherichia coli, is associated with the bacterial nucleoid and shares some properties with both histones and HMG proteins. It is the prototype of small bacterial DNA binding proteins with a pleiotropic role in the cell. HU participates in several biological processes like cell division, initiation of DNA replication, transposition, and other biochemical functions. We show here that bacteria lacking HU are extremely sensitive to gamma irradiation. Expression of either one of the subunits of HU in the hupAB double mutant nearly restores the normal survival rate. This shows that the sensitivity is due to the absence of HU rather than being the result of a secondary mutation occurring in the hupAB cells or a modification of the SOS repair system, since SOS genes are induced normally in the absence of HU. Finally, in vitro studies give an indication of its potential role: HU protects DNA against cleavage by gamma-rays.

DNA looping by Saccharomyces cerevisiae high mobility group proteins NHP6A/B. Consequences for nucleoprotein complex assembly and chromatin condensation

The formation of higher order protein.DNA structures often requires bending of DNA strands between specific sites, a process that can be facilitated by the action of nonspecific DNA-binding proteins which serve as assembly factors. A model for this activity is the formation of the invertasome, an intermediate structure created in the Hin-mediated site-specific DNA inversion reaction, which is stimulated by the prokaryotic nucleoid-associated protein HU. Previously, we have shown that the mammalian HMG1/2 proteins substitute for HU in this system and display efficient DNA wrapping activity in vitro. In the present work, we isolate the primary sources of assembly factor activity in Saccharomyces cerevisiae, as measured by the ability to stimulate invertasome formation, and show that these are the previously identified NHP6A/B proteins. NHP6A/B have comparable or greater activity in DNA binding, bending, and supercoiling with respect to HU and HMG1 and appear to form more stable protein.DNA complexes. In addition, expression of NHP6A in mutant Escherichia coli cells lacking HU and Fis restores normal morphological appearance to these cells, specifically in nucleoid condensation and segregation. From these data we predict diverse architectural roles for NHP6A/B in manipulating chromosome structure and promoting the assembly of multicomponent protein.DNA complexes.

Conformational changes of DNA minicircles upon the binding of the archaebacterial histone-like protein MC1

Binding of the archaebacterial histone-like protein MC1 to DNA minicircles has been examined by gel retardation and electron microscopy. MC1 preferentially binds to a 207-base pair relaxed DNA minicircle as compared with the linear fragment. Random binding is observed at very low ionic strength, and a slight increase in salt concentration highly favors the formation of a complex that corresponds to the binding of two MC1 molecules per DNA ring. Measurements of dissociation rates show that this complex is remarkably stable, and electron microscopy reveals that it is characterized by two diametrically opposed kinks. These results are discussed in regard to the mechanisms by which MC1 affects DNA structure.

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.

Structure of the four-way DNA junction and its interaction with proteins

The four-way DNA junction is an important intermediate in recombination processes; it is, the substrate for different enzyme activities. In solution, the junction adopts a right-handed, antiparallel-stacked X-structure formed by the pairwise coaxial-stacking of helical arms. The stereochemistry is determined by the juxtaposition of grooves and backbones, which is optimal when the smaller included angle is 60 degrees. The antiparallel structure has two distinct sides with major and minor groove-characteristics, respectively. The folding process requires the binding of metal cations, in the absence of which, the junction remains extended without helix-helix stacking. The geometry of the junction can be perturbed by the presence of certain base-base mispairs or phosphodiester discontinuities located at the point of strand exchange. The four-way DNA junction is selectively cleaved by a number of resolving enzymes. In a number of cases, these appear to recognize the minor groove face of the junction and are functionally divisible into activities that recognize and bind the junction, and a catalytic activity. Some possible mechanisms for the recognition of branched DNA structure are discussed.

Prokaryotic HU and eukaryotic HMG1: a kinked relationship

HU and IHF proteins have long been considered the prokaryotic analogues of eukaryotic histones. Their ability to bend DNA, however, is distinctly similar to that of eukaryotic HMG-box proteins, a recently identified family of chromatin components and transcription factors. In some conditions, HU and HMG1-like proteins can even be swapped, both in vitro and in vivo. In spite of this, HU/IHF and HMG-box proteins are not evolutionarily related, and represent two independent solutions for the same biochemical problem.

Cloning and expression of the hup encoding a histone-like protein of Campylobacter jejuni

A Campylobacter jejuni gene, designated hup, that appears to encode a homolog of the histone-like DNA-binding protein, HU, has been cloned, sequenced and expressed in Escherichia coli. Immunoblotting and in vitro transcription/translation analyses revealed a 11-kDa protein that was produced by recombinant plasmids containing hup. The gene contains an open reading frame (ORF) sufficient to encode a protein of 98 amino acids (aa) with a calculated molecular mass of 10,267 Da and a predicted isoelectric point of 10.1. The deduced aa sequence of the protein, designated HCj, exhibits considerable sequence identity with members of the HU family of proteins from other eubacterial species. The transcription start point was identified by primer extension analysis and appropriately spaced promoter sequences were found which exhibit considerable similarity to E. coli and Bacillus promoters. Southern hybridization analyses indicate that C. jejuni has a single copy of hup.

The protein HU can displace the LexA repressor from its DNA-binding sites

The major bacterial histone-like protein HU is a small, basic, dimeric protein composed of two closely related subunits. HU is involved in several processes in the bacterial cell such as the initiation of replication, transposition, gene inversion and cell division. It has been suggested that HU could introduce structural changes to the DNA which would facilitate or inhibit the binding of regulatory proteins to their specific sites. In this study we investigated the effect of HU on the binding of LexA protein, the regulator of SOS functions, to three of its specific binding sites. We show that HU can displace LexA from its binding sites on the operators of the lexA, recA and sfiA genes. The lexA operator was the most sensitive while the higher affinity sfiA operator was the least sensitive. Since HU, like its homologue IHF, probably binds DNA in the minor groove we tested the effect of distamycin, a drug which binds to the minor groove, on LexA binding. Like HU, this drug disrupted LexA-operator complexes. These results suggest that distortion of the minor groove of the lexA operators excludes the binding of the repressor to the major groove.

Molecular recognition of DNA structure by proteins that mediate genetic recombination

The latter half of genetic recombination is mediated by proteins that recognise the structure of the four-way DNA junction, and manipulate this structure. In solution the four-way junction adopts a stacked X-structure in the presence of metal ions. The folding is brought about by the pairwise coaxial stacking of helices in a right-handed antiparallel X-shaped structure. The four-way junction is cleaved by structure-selective resolving enzymes that have been isolated from a wide variety of sources, from eubacteria and their phages through to mammals. In addition, another class of proteins accelerate the branch migration of the junction. These proteins all appear to be divisible into a component that recognises structure and another that carries out a reaction on the junction. Thus the ability of structure-selective binding to the four-way DNA junction is a key feature of enzymes important in genetic recombination.

IHF supresses the inhibitory effect of H-NS on HU function in the hin inversion system

In the hin-mediated DNA inversion system, HU facilitates formation of the synaptic complex composed of two recombination sites spaced 996 bp apart and of the enhancer situated between them, by looping the DNA as to promote interaction of Hin invertase with the Fis enhancer factor [Johnson et al., Nature 329 (1987) 462-465]. The HU requirement for the in vivo hin-mediated inversion was demonstrated previously [Wada et al., Gene 76 (1989) 345-352; Hillyard et al., J. Bacteriol. 172 (1990) 5402-5407; Haykinson and Johnson, EMBO J. 12 (1993) 2503-2512] and in the current experiments. This HU action, however, required IHF when H-NS was present in the cell; i.e., the inversion reaction of the hin-invertible DNA fragment carried by the pKK1202R plasmid proceeded efficiently in host cells either deficient in H-NS or in the presence of both H-NS and IHF, but not in the cells depleted for IHF alone. The level of hin mRNA in mutant cells lacking HU or IHF, in which hin inversion did not occur, was normal or slightly increased. When IHF was absent, the stimulating effect of HU on in vitro DNA circle formation of a 125-bp hin fragment between hixL and the enhancer where Fis binds was inhibited by H-NS. The present study provides an example of a multi-component interaction between HU, H-NS and IHF on the hin DNA region, which contains three characteristic sites, a d(A/T)4 stretch and bent DNA site, and two putative IHF-binding sites.

DNA looping by the HMG-box domains of HMG1 and modulation of DNA binding by the acidic C-terminal domain

We have compared HMG1 with the product of tryptic removal of its acidic C-terminal domain termed HMG3, which contains two 'HMG-box' DNA-binding domains. (i) HMG3 has a higher affinity for DNA than HMG1. (ii) Both HMG1 and HMG3 supercoil circular DNA in the presence of topoisomerase I. Supercoiling by HMG3 is the same at approximately 50 mM and approximately 150 mM ionic strength, as is its affinity for DNA, whereas supercoiling by HMG1 is less at 150 mM than at 50 mM ionic strength although its affinity for DNA is unchanged, showing that the acidic C-terminal tail represses supercoiling at the higher ionic strength. (iii) Electron microscopy shows that HMG3 at a low protein:DNA input ratio (1:1 w/w; r = 1), and HMG1 at a 6-fold higher ratio, cause looping of relaxed circular DNA at 150 mM ionic strength. Oligomeric protein 'beads' are apparent at the bases of the loops and at cross-overs of DNA duplexes. (iv) HMG3 at high input ratios (r = 6), but not HMG1, causes DNA compaction without distortion of the B-form. The two HMG-box domains of HMG1 are thus capable of manipulating DNA by looping, compaction and changes in topology. The acidic C-tail down-regulates these effects by modulation of the DNA-binding properties.

Mutational analysis of the DNA binding domain A of chromosomal protein HMG1

We have mutated several residues of the first of the two HMG-boxes of mammalian HMG1. Some mutants cannot be produced in Escherichia coli, suggesting that the peptide fold is grossly disrupted. A few others can be produced efficiently and have normal DNA binding affinity and specificity; however, they are more sensitive towards heating and chaotropic agents than the wild type polypeptide. Significantly, the mutation of the single most conserved residue in the rather diverged HMG-box family falls in this 'in vitro temperature-sensitive' category, rather than in the non-folded category. Finally, two other mutants have reduced DNA binding affinity but unchanged binding specificity. Overall, it appears that whenever the HMG-box can fold, it will interact specifically with kinked DNA.

Interaction of Fis protein with DNA: bending and specificity of binding

The Escherichia coli Fis protein is a dimeric DNA-binding protein whose specific binding sites share a weak consensus sequence. Use of the gel retardation technique indicates that binding of Fis on a linear DNA fragment leads to the formation of a ladder of defined retarded complexes, independently of the presence of a specific site. This non-specific binding of Fis is consistent with a model where equivalent low-affinity sites on a given fragment would be bound randomly and independently of each other by consecutive Fis dimers. Evidence is presented that non-specific binding of Fis can, however, induce an apparent site-specific conformational change in the DNA. This observation is discussed in terms of a model in which each Fis:DNA complex detected in gel retardation experiments actually represents a dynamic equilibrium of a fixed number of Fis dimers distributed on the fragment.

Histones, HMG, HU, IHF: Même combat

In this review article we present a compilation of the proteins homologous to Escherichia coli HU: the HU-like family. Two of these, HU and IHF from E coli have been extensively characterized genetically and biochemically. Due to their DNA binding activities, these proteins confer a condensed shape to the chromosome and regulate the transcription of selected sets of its genes. The parallel between the dual function of the HU-like proteins and the roles described for eukaryotic histone and HMG proteins is striking, especially in the view that they are evolutionary unrelated.

The IHF proteins of Rhodobacter capsulatus and Pseudomonas aeruginosa

The binding properties of the two IHF consensus sequences present in the promoter region of the hydrogenase structural operon, hupSL, of Rhodobacter capsulatus were studied by gel retardation assays using the heterodimeric IHF-like proteins isolated from R capsulatus, from Pseudomonas aeruginosa and from Escherichia coli. The three IHF proteins bound preferentially to the IHF consensus proximal to hupS. The three-dimensional structure of R capsulatus IHF was modeled using a computer-based amino acid replacement strategy and the known coordinates of crystallized HU protein (HBS) from Bacillus stearothermophilus. Double-stranded DNA and the interaction of IHF and DNA were then modeled using the molecular modeling package Quanta 3.3, and taking into account foot-printing data obtained with IHF-DNA complexes and the fact that the replacement of Arg8 by Cys8 in the alpha subunit, the product of himA, renders R capsulatus IHF ineffective in the activation of hydrogenase synthesis. In this model, IHF is shown to interact with DNA bent by 140 degrees, and Arg8 of HimA capable of interacting with the phosphate-ribose backbone of DNA in the flanking region of the IHF binding site.

Chromosome partition in Escherichia coli

The past year has seen important genetic and biochemical advances in our understanding of the mechanisms that are involved in chromosome partition into two daughter cells in Escherichia coli. Topoisomerase IV and XerCD recombinase have been shown to be required for the unlinking of replicated chromosomes. MukB, an alpha-helical coiled-coil protein, has been shown to be involved in chromosome partition, and this is the first candidate for a bacterial motor protein. Another protein, FtsZ, has been shown to form a constriction ring in cell division and may also relate to chromosome partition.

Integration host factor binds to a unique class of complex repetitive extragenic DNA sequences in Escherichia coli

Interspersed repeated DNA sequences are characteristic features of both prokaryotic and eukaryotic genomes. REP sequences are defined as conserved repetitive extragenic palindromic sequences and are found in Escherichia coli, Salmonella typhimurium and other closely related enteric bacteria. These REP sequences may participate in the folding of the bacterial chromosome. In this work we describe a unique class of 28 conserved complex REP clusters, about 100bp long, in which two inverted REPs are separated by a singular integration host factor (IHF) recognition sequence. We term these sequences RIP (for repetitive IHF-binding palindromic) elements and demonstrate that IHF binds to them specifically. It is estimated that there are about 70 RIP elements in E. coli. Our analysis shows that the RIP elements are evenly distributed around the bacterial chromosome. The possible function of the RIP element is discussed.

The nonspecific DNA-binding and -bending proteins HMG1 and HMG2 promote the assembly of complex nucleoprotein structures

The mammalian high mobility group proteins HMG1 and HMG2 are abundant, chromatin-associated proteins whose cellular function is not known. In this study we show that these proteins can substitute for the prokaryotic DNA-bending protein HU in promoting the assembly of the Hin invertasome, an intermediate structure in Hin-mediated site-specific DNA inversion. Formation of this complex requires the assembly of the Hin recombinase, the Fis protein, and three cis-acting DNA sites, necessitating the looping of intervening DNA segments. Invertasome assembly is strongly stimulated by HU or HMG proteins when one of these segments is shorter than 104 bp. By use of ligase-mediated circularization assays, we demonstrate that HMG1 and HMG2 can bend DNA extremely efficiently, forming circles as small as 66 bp, and even 59-bp circles at high HMG protein concentrations. In both invertasome assembly and circularization assays, substrates active in the presence of HMG1 contain one less helical turn of DNA compared with substrates active in the presence of HU protein. Analysis of different domains of HMG1 generated by partial proteolytic digestion indicate that DNA-binding domain B is sufficient for both bending and invertasome assembly. We suggest that an important biological function of HMG1 and HMG2 is to facilitate cooperative interactions between cis-acting proteins by promoting DNA flexibility. A general role for HMG1 and HMG2 in chromatin structure is also suggested by their ability to wrap DNA duplexes into highly compact forms.