[Assays on comparing the local concentration of HU protein in the different regions of Escherichia coli genomic DNA].

HU, a nonspecific histone-like DNA binding protein is a major component of the bacterial nucleoid. HU is referred to as an accessory factor for complex protein-DNA assembly and as a protein involved in DNA compaction. In this study we investigated in vivo HU binding along the different regions of E. coli genome. For this purpose we used ChIP--in vivo formaldehyde crosslinking and immunoprecipitation of protein-DNA complexes with antiHU-antibodies. This technique allows to compare the local concentration of HU protein in the different regions of E. coli genomic DNA. In this study we analysed the HU-DNA crosslinking both in exponentially growing and stationary phase of bacteria in the following regions of E. coli genome: oriC region, promoter and structural regions of hupA and hupB genes coding two different subunits of HU, and structural parts of dps and glgS genes which are active only in stationary phase. Our results indicate that in exponentially growing E. coli cells the local concentration of HU protein is uniform for all analysed regions of genome and does not depend on their transcriptional status. The twofold increase of local concentration of HU protein was also shown for all analysed genome regions in the stationary phase cells.

Massive parallel analysis of the binding specificity of histone-like protein HU to single- and double-stranded DNA with generic oligodeoxyribonucleotide microchips.

A generic hexadeoxyribonucleotide microchip has been applied to test the DNA-binding properties of HU histone-like bacterial protein, which is known to have a low sequence specificity. All 4096 hexamers flanked within 8mers by degenerate bases at both the 3'- and 5'-ends were immobilized within the 100 x 100 x 20 mm polyacrylamide gel pads of the microchip. Single-stranded immobilized oligonucleotides were converted in some experiments to the double-stranded form by hybridization with a specified mixture of 8mers. The DNA interaction with HU was characterized by three type of measurements: (i) binding of FITC-labeled HU to microchip oligonucleotides; (ii) melting curves of complexes of labeled HU with single-stranded microchip oligonucleotides; (iii) the effect of HU binding on melting curves of microchip double-stranded DNA labeled with another fluorescent dye, Texas Red. Large numbers of measurements of these parameters were carried out in parallel for all or many generic microchip elements in real time with a multi-wavelength fluorescence microscope. Statistical analysis of these data suggests some preference for HU binding to G/C-rich single-stranded oligonucleotides. HU complexes with double-stranded microchip 8mers can be divided into two groups in which HU binding either increased the melting temperature (T(m)) of duplexes or decreased it. The stabilized duplexes showed some preference for presence of the sequence motifs AAG, AGA and AAGA. In the second type of complex, enriched with A/T base pairs, the destabilization effect was higher for longer stretches of A/T duplexes. Binding of HU to labeled duplexes in the second type of complex caused some decrease in fluorescence. This decrease also correlates with the higher A/T content and lower T(m). The results demonstrate that generic microchips could be an efficient approach in analysis of sequence specificity of proteins.

The Escherichia coli histone-like protein HU regulates rpoS translation.

Escherichia coli HU protein is a major component of the bacterial nucleoid. HU stabilizes higher order nucleoprotein complexes and belongs to a family of DNA architectural proteins. Here, we report that HU is required for efficient expression of the sigma S subunit of RNA polymerase. This rpoS-encoded alternative sigmaS factor induces a number of genes implicated in cell survival in stationary phase and in multiple stress resistance. By analysis of rpoS-lacZ fusions and by pulse-chase experiments, we show that the efficiency of rpoS translation is reduced in cells lacking HU, whereas neither rpoS transcription nor protein stability is affected by HU. Gel mobility shift assays show that HU is able to bind specifically an RNA fragment containing the translational initiation region of rpoS mRNA 1000-fold more strongly than double-stranded DNA. Together with the in vivo data, this finding strongly suggests that, by binding to rpoS mRNA, HU directly stimulates rpoS translation. We demonstrate here that HU, an abundant DNA-binding, histone-like protein, is able specifically to recognize an RNA molecule and therefore play a role in post-transcriptional regulation.

Does the parallel evolution pattern between the replication-segregation proteins and HU have a biological significance?

The bacterial chromosome is a highly compacted nucleoproteic structure. Its apparent disordered morphology is difficult to conciliate with newly discovered mechanisms governing the propagation of genetic information between mother and daughter cells. Recent experiments in bacterial genetics, biochemistry and cytology from a number of laboratories are beginning to unravel how at each cell division, DNA replication and segregation proteins interact spatially with specific DNA motifs to orchestrate replication and movement of replication forks and chromosomes. We propose here a method to confirm and perhaps extend these experiments by in silico protein sequence comparisons and phylogeny. This analysis showed a parallel evolution between the histone-like protein HU and key protein factors involved in DNA replication and chromosome segregation.

HU-GFP and DAPI co-localize on the Escherichia coli nucleoid.

The heterodimeric HU protein, one of the most abundant DNA binding proteins, plays a pleiotropic role in bacteria. Among others, HU was shown to contribute to the maintenance of DNA superhelical density in Escherichia coli. By its properties HU shares some traits with histones and HMG proteins. More recently, its specific binding to DNA recombination and repair intermediates suggests that HU should be considered as a DNA damage sensor. For all these reasons, it will be of interest to follow the localization of HU within the living bacterial cells. To this end, we constructed HU-GFP fusion proteins and compared by microscopy the GFP green fluorescence with images of the nucleoid after DAPI staining. We show that DAPI and HU-GFP colocalize on the E. coli nucleoid. HU, therefore, can be considered as a natural tracer of DNA in the living bacterial cell.

Roles of Escherichia coli histone-like protein HU in DNA replication: HU-beta suppresses the thermosensitivity of dnaA46ts.

The HU protein is a small, basic, heat-stable DNA-binding protein that is well-conserved in prokaryotes and is associated with the bacterial nucleoid. In enterobacteria, including Escherichia coli, HU is a heterotypic dimer, HUalphabeta, composed of two closely related sub-units encoded by the hupA and hupB genes, respectively. HU was shown to participate in vitro in the initiation of DNA replication as an accessory factor to assist the action of DnaA protein in the unwinding of oriC DNA. To further elucidate the role of HU in the regulation of the DNA replication initiation process, we tested the synchrony phenotype in the absence of either one or both HU sub-units. The hupAB mutant exhibits an asynchronous initiation, the hupA mutant shows a similar reduced synchrony, whereas the hupB mutant shows a normal phenotype. Using a thermosensitive dnaA46 strain (dnaA46ts), an initiation mutant, we reveal a special role of HUbeta. The presence of a plasmid overproducing HUbeta in a dnaA46ts lacking HU (hupAB background) compensates for the thermosensitivity of this initiation mutant. Moreover, the overproduction of HUbeta confers to dnaA46ts a pattern of asynchrony similar to that of a dnaAcos, the intragenic suppressor of dnaA46ts. We show that the relative ratio of HUalpha versus HUbeta is greatly perturbed in dnaA46ts which accumulates little, if any, HUbeta. Therefore, the suppression of thermosensitivity in dnaA46hupAB by HUbeta may be caused by an unexpected absence of HUbeta in the dnaA46ts mutant. Visibly the HU composition is sensitive to the different states of DnaA, and may play a role during the regulation of the initiation process of the DNA replication by affecting subsequent events along the cell cycle.

The histone-like protein HU binds specifically to DNA recombination and repair intermediates.

The heterodimeric HU protein associated with the Escherichia coli nucleoid shares some properties with histones and HMG proteins. HU binds DNA junctions and DNA containing a nick much more avidly than double-stranded (ds-) DNA. Cells lacking HU are extremely sensitive to gamma irradiation and we wondered how HU could play a role in maintaining the integrity of the bacterial chromosome. We show that HU binds with high affinity to DNA repair and recombination intermediates, including DNA invasions, DNA overhangs and DNA forks. The DNA structural motif that HU specifically recognizes in all these structures consists of a ds-DNA module joined to a second module containing either ds- or single-stranded (ss-) DNA. The two modules rotate freely relative to one another. Binding specificity results from the simultaneous interaction of HU with these two modules: HU arms bind the ds-DNA module whereas the HU body contacts the 'variable' module containing either ds- or ss-DNA. Both structural motifs are recognized by HU at least 1000-fold more avidly than duplex DNA.

Overproduction and improved strategies to purify the threenative forms of nuclease-free HU protein.

The heterodimeric HU protein was isolated from Escherichia coli as one of the most abundant DNA binding proteins associated with the bacterial nucleoid. HUalphabeta is composed of two very homologous subunits, but HU can also be present in E. coli under its two homodimeric forms, HUalpha(2) and HUbeta(2). This protein is conserved either in its heterodimeric form or in one of its homodimeric forms in all bacteria, in plant chloroplasts and in some viruses. HU can participate, like the histones, in the maintenance of DNA supercoiling and in DNA condensation. This protein which does not recognize any specific sequence on double-stranded DNA, has been shown to bind specifically to cruciform DNA as does the eukaryotic HMG1 protein and to a series of structures which are found as intermediates of DNA repair, e.g., nick, gap, 3'overhang, etc. The strong binding of HU to these diverse DNA structures could explain, in part at least, its pleiotropic role in the bacterial cell. To understand all the facets of its interactions with nucleic acids, it was necessary to develop a procedure which allowed the purification of the three forms of HU under their native form and without the nuclease activity strongly associated with the protein. We describe here such a procedure as well as demonstrating that the three histidine-tagged HUs we have produced, have conserved the binding characteristics of native HUs. Interestingly, by two complementation tests, we show that the histidine-tagged HUs are fully active in vivo.

The binding motif recognized by HU on both nicked and cruciform DNA.

The heterodimeric HU protein, highly conserved in bacteria and involved in transposition, recombination, DNA repair, etc., shares similarity with histones and HMGs. HU, which binds DNA with low affinity and without sequence specificity, binds strongly and specifically to DNA junctions and DNA containing single-strand breaks. The fine structure of these specific complexes was studied by footprinting and HU chemically converted into nucleases. The positioning of HUalphabeta on nicked DNA is asymmetrical and specifically oriented: the beta-arm binds the area surrounding the break whereas the alpha-arm lies on the 3' DNA branch. This positioning necessitates a pronounced bend in the DNA at the discontinuous point, which was estimated by circular permutation assay to be 65 degrees. At junctions, HU is similarly asymmetrically positioned in an identical orientation: the junction point plays the role of the discontinuous point in the nicked DNA. The HU binding motif present in both structures is a pair of inclined DNA helices.

Differential binding of the Escherichia coli HU, homodimeric forms and heterodimeric form to linear, gapped and cruciform DNA.

We have shown recently that the relative abundance of the three dimeric forms (alpha2, alphabeta and beta2) of the HU protein from Escherichia coli varies during growth and in response to environmental changes. Using gel retardation assays we have compared the DNA binding properties of the three dimers with different DNA substrates. The determination of their DNA binding parameters shows that the relative affinities of HUalphabeta and HUalpha2 are comparable. Both recognize, with a high degree of affinity under stringent conditions, cruciform structures or DNA molecules with a nick or a gap, whereas they bind to linear DNA only at low salt. DNA containing a gap of two nucleotides is in fact the substrate recognized with the highest degree of affinity by these two forms under all conditions. Conversely, HUbeta2 binds very poorly to duplex DNA and shows a much lower affinity for nicked or gapped DNAs. However, HUbeta2 binds to cruciform DNA structures almost as well as HUalphabeta and HUalpha2. This almost exclusive binding of HUbeta2 to a unique substrate is surprising in regards of the quasi identity, in the three forms, of the flexible arms considered as the DNA-binding domains of the three forms of HU. Cruciform DNA may stabilize HUbeta2 structure which could be structurally defective.

Variation in HU composition during growth of Escherichia coli: the heterodimer is required for long term survival.

The histone-like dimeric HU protein of Escherichia coli is encoded by two closely related genes, hupA and hupB. We show here that expression from the single hupA promoter and from the three hupB promoters varies during growth phase. The weak hupB-P4 promoter is active immediately after dilution. Transcription of the hupA gene is activated early in logarithmic phase. A little later, at mid to late exponential phase, RNA originating at the hupB-P2 promoter is detected. The hupB-P3 promoter is activated last when the cells enter stationary phase. Although the hup mRNAs are unstable, the HU protein is very stable so that the variations in the mRNAs synthesis are reflected in the level of the two HU subunits and in the composition of HU dimers. Cells growing exponentially contain a mixture of homodimeric alpha 2 and heterodimeric alpha beta but no beta 2 is detected. In stationary cells, the predominant form is the heterodimer alpha beta. The presence of the heterodimeric form is required for optimal survival of E. coli after prolonged starvation. The three forms of HU are not equivalent, since beta 2 is incapable of promoting formation of DNA supercoiling like alpha beta and alpha 2 do. The putative roles of each form of HU are discussed.

Alterations of the outer membrane composition in Escherichia coli lacking the histone-like protein HU.

Escherichia coli cells lacking the histone-like protein HU form filaments and have an abnormal number of anucleate cells. Furthermore, their phenotype resembles that of rfa mutants, the well-characterized deep-rough phenotype, as they show an enhanced permeability that renders them hypersensitive to chloramphenicol, novobiocin, and detergents. We show that, unlike rfa mutants, hupAB mutants do not have a truncated lipopolysaccharide but do have an abnormal abundance of OmpF porin in their outer membrane. While the complete absence of HU does not abolish the osmoregulation of OmpF protein synthesis, the steady-state level of micF RNA, the negative regulator of OmpF, decreases in bacteria lacking HU, increasing the basal level of this membrane protein. These findings demonstrate a novel link between a bacterial chromosomal protein and the outer membrane composition.

Regulation of HU alpha and HU beta by CRP and FIS in Escherichia coli.

The dimeric histone-like protein HU, one of the most abundant DNA binding proteins of Escherichia coli, is encoded by two closely related but unlinked genes, hupA and hupB. Overproduction of one or the other of the subunits has been shown to induce the SOS response and mucoidy. To understand how the synthesis of this protein is coordinated, we studied the transcription control of the two hup genes. We show here that CRP stimulated the transcription of both genes. In contrast, the FIS protein, one of the major positive regulators of the stable RNA operons, stimulated the transcription of the hupA gene, whereas it repressed that of the hupB gene. Moreover, stringent control, which like FIS also regulates the transcription of the stable RNA operons, affected the hupB transcription while it had no effect on hupA. This opposite regulation of the transcription of the two HU genes is reflected at the protein level signifying that changes in the composition of HU occur upon changes in the environment. It is rather unexpected that such divergent transcriptional regulation controls the two genes encoding a dimeric protein.

The Escherichia coli ribosomal protein S16 is an endonuclease.

The histone-like protein HU isolated from Escherichia coli exhibited, after several purification steps, a Mg(2+)-dependent nuclease activity. We show here that this activity can be dissociated from HU by a denaturation-renaturation step, and is due to a small fraction of ribosomal protein S16 co-purifying with HU. S16 is an essential component of the 30S ribosomal particles. We have cloned, overproduced, and purified a histidine-tagged S16 and shown that this protein is a DNA-binding protein carrying a Mg(2+)-Mn(2+)-dependent endonuclease activity. This is an unexpected property for a ribosomal protein.

Cross-talk between topoisomerase I and HU in Escherichia coli.

In Escherichia coli about one half of the negative supercoiling of DNA is constrained by proteins, in contrast to the situation in eukaryotic cells where most of the DNA is constrained by histones. The level of supercoiling in the unrestrained portion is controlled by a balance between the supercoiling activity of gyrase and the relaxing activity of DNA topoisomerase I. In the present work we show, by disrupting one or both genes encoding the heterodimeric protein HU, that an interplay exists in bacteria between HU and topoisomerase I activity: a decrease in the intracellular concentration of HU was accompanied by an increase in relaxing activity as measured in cell extracts. Conversely, a topA10 mutant of topoisomerase I, which has low levels of relaxing activity, was unable to accept an HU deficiency introduced by transduction. Thus it appears that the ability to increase relaxing activity, or to decrease an excess of supercoiling, is important for cells to survive in the absence of HU. These data can be explained in terms of HU constraining supercoiling in vivo as it does in vitro: the absence of HU would generate more unconstrained supercoiling, which in turn would require an increase in relaxing activity to maintain physiological levels.

Histone-like protein HU and bacterial DNA topology: suppression of an HU deficiency by gyrase mutations.

The abundant bacterial protein called HU has the ability to wrap and bend DNA in vitro, and thus it has long been thought to play a role in DNA supercoiling. In the absence of HU, Escherichia coli formed tiny colonies on agar, rapidly accumulated suppressor mutations, and was hypersensitive to novobiocin. Three types of evidence implicated gyrase in the suppression of an HU deficiency. First, spontaneous suppressors that restored normal growth and reduced sensitivity to novobiocin mapped in gyrB, one of the genes encoding DNA gyrase. Second, a pair of known gyrB mutations (gyrB-203 Ts gyrB-221 NovR) allowed normal growth at permissive (30 degrees C) but not at intermediate (37 degrees C) conditions. Third, introduction of a gyrB-expressing plasmid restored normal colony size. DNA supercoiling comparisons showed that chromosomal supercoiling decreased in the absence of HU and increased toward wild-type levels in the presence of a spontaneous gyrB suppressor. Taken together, these data establish that HU has a physiological role in chromosomal DNA topology, probably by facilitating the action of gyrase.

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.