Proteins from the prokaryotic nucleoid. Interaction of nucleic acids with the 15 kDa Escherichia coli histone-like protein H-NS

Modeling the compaction of bacterial chromosomes by biomolecular crowding and the cross-linking protein H-NS

Cells orchestrate the action of various molecules toward organizing their chromosomes. Using a coarse-grained computational model, we study the compaction of bacterial chromosomes by the cross-linking protein H-NS and cellular crowders. In this work, H-NS, modeled as a mobile "binder," can bind to a chromosome-like polymer with a characteristic binding energy. The simulation results reported here clarify the relative role of biomolecular crowding and H-NS in condensing a bacterial chromosome in a quantitative manner. In particular, they shed light on the nature and degree of crowder and H-NS synergetics: while the presence of crowders enhances H-NS binding to a chromosome-like polymer, the presence of H-NS makes crowding effects more efficient, suggesting two-way synergetics in chain compaction. Also, the results show how crowding effects promote clustering of bound H-NS. For a sufficiently large concentration of H-NS, the cluster size increases with the volume fraction of crowders.

Cooperative effects on the compaction of DNA fragments by the nucleoid protein H-NS and the crowding agent PEG probed by Magnetic Tweezers

BACKGROUND

DNA bridging promoted by the H-NS protein, combined with the compaction induced by cellular crowding, plays a major role in the structuring of the E. coli genome. However, only few studies consider the effects of the physical interplay of these two factors in a controlled environment.

METHODS

We apply a single molecule technique (Magnetic Tweezers) to study the nanomechanics of compaction and folding kinetics of a 6 kb DNA fragment, induced by H-NS bridging and/or PEG crowding.

RESULTS

In the presence of H-NS alone, the DNA shows a step-wise collapse driven by the formation of multiple bridges, and little variations in the H-NS concentration-dependent unfolding force. Conversely, the DNA collapse force observed with PEG was highly dependent on the volume fraction of the crowding agent. The two limit cases were interpreted considering the models of loop formation in a pulled chain and pulling of an equilibrium globule respectively.

CONCLUSIONS

We observed an evident cooperative effect between H-NS activity and the depletion of forces induced by PEG.

GENERAL SIGNIFICANCE

Our data suggest a double role for H-NS in enhancing compaction while forming specific loops, which could be crucial in vivo for defining specific mesoscale domains in chromosomal regions in response to environmental changes.

Bordetella pertussis Acetylome is Shaped by Lysine Deacetylase Bkd1

Post-translational modifications of proteins enable swift physiological adaptation of cells to altered growth conditions and stress. Aside from protein phosphorylation, acetylation on ε-amino groups of lysine residues (N-ε-lysine acetylation) represents another important post-translational modification of proteins. For many bacterial pathogens, including the whooping cough agent Bordetella pertussis, the role and extent of protein acetylation remain to be defined. We expressed in Escherichia coli the BP0960 and BP3063 genes encoding two putative deacetylases of B. pertussis and show that BP0960 encodes a lysine deacetylase enzyme, named Bkd1, that regulates acetylation of a range of B. pertussis proteins. Comparison of the proteome and acetylome of a Δbkd1 mutant with the proteome and acetylome of wild-type B. pertussis (PRIDE ID. PXD016384) revealed that acetylation on lysine residues may modulate activities or stabilities of proteins involved in bacterial metabolism and histone-like proteins. However, increased acetylation of the BvgA response regulator protein of the B. pertussis master virulence-regulating BvgAS two-component system affected neither the total levels of produced BvgA nor its phosphorylation status. Indeed, the Δbkd1 mutant was not impaired in the production of key virulence factors and its survival within human macrophages in vitro was not affected. The Δbkd1 mutant exhibited an increased growth rate under carbon source-limiting conditions and its virulence in the in vivo mouse lung infection model was somewhat affected. These results indicate that the lysine deacetylase Bkd1 and N-ε-lysine acetylation primarily modulate the general metabolism rather than the virulence of B. pertussis.

C-terminal intrinsically disordered region-dependent organization of the mycobacterial genome by a histone-like protein

The architecture of the genome influences the functions of DNA from bacteria to eukaryotes. Intrinsically disordered regions (IDR) of eukaryotic histones have pivotal roles in various processes of gene expression. IDR is rare in bacteria, but interestingly, mycobacteria produce a unique histone-like protein, MDP1 that contains a long C-terminal IDR. Here we analyzed the role of IDR in MDP1 function. By employing Mycobacterium smegmatis that inducibly expresses MDP1 or its IDR-deficient mutant, we observed that MDP1 induces IDR-dependent DNA compaction. MDP1-IDR is also responsible for the induction of growth arrest and tolerance to isoniazid, a front line tuberculosis drug that kills growing but not growth-retardated mycobacteria. We demonstrated that MDP1-deficiency and conditional knock out of MDP1 cause spreading of the M. smegmatis genome in the stationary phase. This study thus demonstrates for the first time a C-terminal region-dependent organization of the genome architecture by MDP1, implying the significance of IDR in the function of bacterial histone-like protein.

TrmBL2 from Pyrococcus furiosus Interacts Both with Double-Stranded and Single-Stranded DNA

In many hyperthermophilic archaea the DNA binding protein TrmBL2 or one of its homologues is abundantly expressed. TrmBL2 is thought to play a significant role in modulating the chromatin architecture in combination with the archaeal histone proteins and Alba. However, its precise physiological role is poorly understood. It has been previously shown that upon binding TrmBL2 covers double-stranded DNA, which leads to the formation of a thick and fibrous filament. Here we investigated the filament formation process as well as the stabilization of DNA by TrmBL2 from Pyroccocus furiosus in detail. We used magnetic tweezers that allow to monitor changes of the DNA mechanical properties upon TrmBL2 binding on the single-molecule level. Extended filaments formed in a cooperative manner and were considerably stiffer than bare double-stranded DNA. Unlike Alba, TrmBL2 did not form DNA cross-bridges. The protein was found to bind double- and single-stranded DNA with similar affinities. In mechanical disruption experiments of DNA hairpins this led to stabilization of both, the double- (before disruption) and the single-stranded (after disruption) DNA forms. Combined, these findings suggest that the biological function of TrmBL2 is not limited to modulating genome architecture and acting as a global repressor but that the protein acts additionally as a stabilizer of DNA secondary structure.

Compaction of isolated Escherichia coli nucleoids: Polymer and H-NS protein synergetics

Escherichia coli nucleoids were compacted by the inert polymer polyethylene glycol (PEG) in the presence of the H-NS protein. The protein by itself appears to have little impact on the size of the nucleoids as determined by fluorescent microscopy. However, it has a significant impact on the nucleoidal collapse by PEG. This is quantitatively explained by assuming the H-NS protein enhances the effective diameter of the DNA helix leading to an increase in the depletion forces induced by the PEG. Ultimately, however, the free energy of the nucleoid itself turns out to be independent of the H-NS concentration. This is because the enhancement of the supercoil excluded volume is negligible. The experiments on the nucleoids are corroborated by dynamic light scattering and EMSA analyses performed on DNA plasmids in the presence of PEG and H-NS.

What matters for lac repressor search in vivo--sliding, hopping, intersegment transfer, crowding on DNA or recognition?

We have investigated which aspects of transcription factor DNA interactions are most important to account for the recent in vivo search time measurements for the dimeric lac repressor. We find the best agreement for a sliding model where non-specific binding to DNA is improbable at first contact and the sliding LacI protein binds at high probability when reaching the specific O_sym operator. We also find that the contribution of hopping to the overall search speed is negligible although physically unavoidable. The parameters that give the best fit reveal sliding distances, including hopping, close to what has been proposed in the past, i.e. ∼40 bp, but with an unexpectedly high 1D diffusion constant on non-specific DNA sequences. Including a mechanism of inter-segment transfer between distant DNA segments does not bring down the 1D diffusion to the expected fraction of the in vitro value. This suggests a mechanism where transcription factors can slide less hindered in vivo than what is given by a simple viscosity scaling argument or that a modification of the model is needed. For example, the estimated diffusion rate constant would be consistent with the expectation if parts of the chromosome, away from the operator site, were inaccessible for searching.

Substitutional analysis of the C-terminal domain of AbrB revealed its essential role in DNA-binding activity

The global transition state regulator AbrB controls more than 100 genes of the Bacillus relatives and is known to interact with varying DNA-sequences. The DNA-binding domain of the AbrB-like proteins was proposed to be located exclusively within the amino-terminal ends. However, the recognition of DNA, and specificity of the binding mechanism, remains elusive still in view of highly differing recognition sites. Here we present a substitutional analysis to examine the role of the carboxy-terminal domain of AbrB from Bacillus subtilis and Bacillus amyloliquefaciens. Our results demonstrate that the carboxy-terminal domains of AbrB affect the DNA-binding properties of the tetrameric AbrB. Most likely, the C-termini are responsible for the cooperative character observed for AbrB interaction with some DNA targets like tycA and phyC.

Gene 5.5 protein of bacteriophage T7 in complex with Escherichia coli nucleoid protein H-NS and transfer RNA masks transfer RNA priming in T7 DNA replication

DNA primases provide oligoribonucleotides for DNA polymerase to initiate lagging strand synthesis. A deficiency in the primase of bacteriophage T7 to synthesize primers can be overcome by genetic alterations that decrease the expression of T7 gene 5.5, suggesting an alternative mechanism to prime DNA synthesis. The product of gene 5.5 (gp5.5) forms a stable complex with the Escherichia coli histone-like protein H-NS and transfer RNAs (tRNAs). The 3'-terminal sequence (5'-ACCA-3') of tRNAs is identical to that of a functional primer synthesized by T7 primase. Mutations in T7 that suppress the inability of primase reduce the amount of gp5.5 and thus increase the pool of tRNA to serve as primers. Alterations in T7 gene 3 facilitate tRNA priming by reducing its endonuclease activity that cleaves at the tRNA-DNA junction. The tRNA bound to gp5.5 recruits H-NS. H-NS alone inhibits reactions involved in DNA replication, but the binding to gp5.5-tRNA complex abolishes this inhibition.

Roles of the DNA binding proteins H-NS and StpA in homologous recombination and repair of bleomycin-induced damage in Escherichia coli

The DNA binding protein H-NS promotes homologous recombination in Escherichia coli, but the role of its paralog StpA in this process remains unclear. Here we show that an hns mutant, but not an stpA mutant, are marginally defective in conjugational recombination and is sensitive to the double-strand-break-inducing agent bleomycin. Interestingly, the hns stpA double mutant is severely defective in homologous recombination and more bleomycin-sensitive than is the hns or stpA single mutant, indicating that the stpA mutation synergistically enhances the defects of homologous recombination and the increased bleomycin-sensitivity in the hns mutant. In addition, the transduction analysis in the hns stpA double mutant indicated that the stpA mutation also enhances the defect of recombination in the hns mutant. These results suggest that H-NS plays an important role in both homologous recombination and repair of bleomycin-induced damage, while StpA can substitute the H-NS function. The recombination analysis of hns single, stpA single, and hns stpA double mutants in the recBC sbcA and recBC sbcBC backgrounds suggested that the reduction of the hns single or hns stpA double mutants may not be due to the defect in a particular recombination pathway, but may be due to the defect in a common process of the pathways. The model for the functions of H-NS and StpA in homologous recombination and double-strand break repair is discussed.

The RovA regulons of Yersinia enterocolitica and Yersinia pestis are distinct: evidence that many RovA-regulated genes were acquired more recently than the core genome

RovA is a transcriptional activator of Yersinia invasin, an outer membrane protein involved in bacterial attachment and invasion across the intestinal epithelium. In Y. enterocolitica, a rovA mutant is attenuated for virulence compared with either wild-type or inv mutant strains, indicating that RovA may regulate additional virulence factors. Here, we used microarray analysis to define the RovA regulon. Curiously, there was little overlap between the RovA regulons of Y. enterocolitica and Y. pestis despite the fact that RovA itself is highly conserved between the two species. Some of these differences are explained by the observation that a number of RovA-regulated loci in Y. enterocolitica do not have orthologues in Y. pestis and vice versa, suggesting that RovA established regulatory control over genetic material acquired after the divergence of the species. Electromobility shift assays demonstrated that 15 of these RovA-regulated loci directly interact with RovA, and 11 of these promoters had similar affinity as observed for the inv promoter. H-NS and YmoA are believed to form a transcriptional repression complex on the inv promoter, and several studies indicate that RovA and H-NS have overlapping DNA binding sites. H-NS and YmoA regulated a subset of the RovA-regulated loci. Furthermore, H-NS directly bound to 14 of the 15 promoters bound by RovA. From these data, we hypothesize that RovA generally behaves as an anti-H-NS factor to alleviate transcriptional repression in Y. enterocolitica. A number of recent studies have presented data and a model suggesting that H-NS functions as a transcriptional silencer of horizontally acquired genes. This repression can be selectively relieved by regulators such as RovA, and the observation that nearly all RovA-activated genes are repressed by H-NS is consistent with this model.

Expression of the gene encoding the major bacterial nucleoid protein H-NS is subject to transcriptional auto-repression

Expression of a promoterless cat gene fused to a DNA fragment of approximately 400 bp, beginning at -313 of Escherichia coli hns, was significantly repressed in E. coli and Salmonella typhimurium strains with wild-type hns but not in mutants carrying hns alleles. CAT expression from fusions containing a shorter (110 bp) segment of hns was essentially unaffected in the same genetic backgrounds. The stage of growth was found to influence the extent of repression which was maximum (approximately 75%) in mid-log cultures and negligible in cells entering the stationary phase. The level of repression in early-log phase was lower than in mid-log phase cultures, probably because of the presence of high levels of Fis protein, which counteracts the H-NS inhibition by stimulating hns transcription. The effects observed in vivo were mirrored by similar results obtained in vitro upon addition of purified H-NS and Fis protein to transcriptional systems programmed with the same hns caf fusions. Electrophoretic gel shift assays, DNase I footprinting and cyclic permutation get analyses revealed that H-NS binds preferentially to the upstream region of its own gene recognizing two rather extended segments of DNA on both sides of a bend centred around -150. When these sites are filled by H-NS, an additional site between approximately -20 and -65, which partly overlaps the promoter, is also occupied. Binding of H-NS to this site is probably the ultimate cause of transcriptional auto-repression.

DNA looping-mediated repression by histone-like protein H-NS: specific requirement of Esigma70 as a cofactor for looping

Transcription initiation by RNA polymerase (RNP) carrying the house-keeping sigma subunit, sigma70 (Esigma70), is repressed by H-NS at a number of promoters including hdeABp in Escherichia coli, while initiation with RNP carrying the stationary phase sigma, sigma38 (Esigma38), is not. We investigated the molecular mechanism of selective repression by H-NS to identify the differences in transcription initiation by the two forms of RNPs, which show indistinguishable promoter selectivities in vitro. Using hdeABp as a model promoter, we observed with purified components that H-NS, acting at a sequence centered at -118, selectively repressed transcription by Esigma70. This selective repression is attributed to the differences in the interactions between hdeABp and the two forms of RNPs, since no other factor is required for the repression. We observed that the two forms of RNPs could form an open initiation complex (RP(O)) at hdeABp, but that Esigma70 failed to initiate transcription in the presence of H-NS. Interestingly, KMnO4 assays and high-resolution atomic force microscopy (AFM) revealed that hdeABp DNA wrapped around Esigma70 more tightly than around Esigma38, resulting in the potential crossing over of the DNA arms that project out of Esigma70 . RP(O) but not out of Esigma38 . RP(O). Based on these observations, we postulated that H-NS bound at -118 laterally extends by the cooperative recruitment of H-NS molecules to the promoter-downstream sequence joined by wrapping of the DNA around Esigma70 . RP(O), resulting in effective sealing of the DNA loop and trapping of Esigma70. Such a ternary complex of H-NS . Esigma70 hdeABp was demonstrated by AFM. In this case, therefore, Esigma70 acts as a cofactor for DNA looping. Expression of this class of genes by Esigma38 in the stationary phase is not due to its promoter specificity but to the architecture of the promoter . Esigma38 complex.

SspA is required for acid resistance in stationary phase by downregulation of H-NS inEscherichia coli

The stringent starvation protein A (SspA) is a RNA polymerase-associated protein and is required for transcriptional activation of bacteriophage P1 late promoters. However, the role of SspA in gene expression in Escherichia coli is essentially unknown. In this work, we show that SspA is essential for cell survival during acid-induced stress. Apparently, SspA inhibits stationary-phase accumulation of H-NS, a global regulator which functions mostly as a repressor, thereby derepressing multiple stress defence systems including those for acid stress and nutrient starvation. Consequently, the gene expression pattern of the H-NS regulon is altered in the sspA mutant, leading to acid-sensitive and hypermotile phenotypes. Thus, our study indicates that SspA is a global regulator, which acts upstream of H-NS, and thereby plays an important role in the stress response of E. coli during stationary phase. In addition, our results indicate that the expression of the H-NS regulon is sensitive to small changes in the cellular level of H-NS, enabling the cell to response rapidly to environment cues. As SspA and H-NS are highly conserved among Gram-negative bacteria, of which many are pathogenic, the global role of SspA in the stress response and pathogenesis is discussed.

The DNA binding protein H-NS binds to and alters the stability of RNA in vitro and in vivo

H-NS is an abundant prokaryotic transcription factor that preferentially binds to intrinsically bent DNA. Although H-NS has been shown to reduce the transcription of over 100 genes, evidence suggests that H-NS can also affect the translation of some genes. One such gene, rpoS, specifies a sigma factor, RpoS. The ability of H-NS to bind to the rpoS mRNA and the non-coding RNA regulator, DsrA, was tested. Electrophoretic mobility-shift assays yielded an apparent binding affinity of H-NS binding to curved DNA of approximately 1 microM, whereas binding to rpoS mRNA or DsrA RNA was approximately 3 microM. This RNA binding was not prevented by an excess of competitor yeast RNA, suggesting that H-NS specifically bound these RNAs. Footprint analysis with a single strand-specific ribonuclease was used to identify the H-NS binding site(s) on DsrA and rpoS mRNA. Surprisingly, H-NS appeared to enhance the cleavage of DsrA and rpoS mRNA. The enhanced cleavage was at sites that were predicted to be single-stranded and did not result from contaminating nucleases in the H-NS protein preparation or non-specific effects of the nuclease. Quantitative RT-PCR of RNA isolated from wild-type and hns- strains revealed that H-NS also affects the stability of DsrA in vivo. Thus H-NS appears to modulate RNA stability in vivo and in vitro.

Expression and purification of a putative H-NS nucleoid-associated protein from the phytopathogen Xylella fastidiosa

The H-NS protein is one of the major constituents of the nucleoid structure that has been implicated in the DNA packaging and in the global regulation of gene expression. The study of this transcriptional regulator is an effort to fight Xylella fastidiosa, a citrus pathogen responsible for a range of economically important plant diseases, including the citrus variegated chlorosis (CVC). The putative H-NS ORF was cloned into a pET32-Xa/LIC vector in order to overexpress it coupled with fusion tags in Escherichia coli BL21(DE3). The expressed recombinant protein was purified by immobilized metal affinity chromatography (Ni-NTA resin) and its identity verified by mass spectrometry (MALDI-TOF). Final purification was performed by cation-exchange chromatography (SP Sepharose Fast Flow) and the purified protein was found as a single band on SDS-PAGE. The folding and its DNA binding activity were verified by circular dichroism and fluorescence spectroscopy, respectively.

The bacterial regulatory protein H-NS--a versatile modulator of nucleic acid structures

The small DNA binding protein H-NS is attracting broad interest for its profound involvement in the regulation of bacterial physiology. It is involved in the regulation of many genes in response to a changing environment and functions in the adaptation to many different kinds of stress. Many H-NS-controlled genes, including the hns gene itself, are further linked to global regulatory networks. H-NS thus plays a key role in maintaining bacterial homeostasis under conditions of a rapidly changing environment. In this review we summarize recent results from combined biochemical and biophysical efforts which have yielded new insights into the three-dimensional structure and function of H-NS. The protein consists of two distinct domains separated by an unstructured linker region, and the structural details available today have helped to understand how these domains may interact with each other or with ligand molecules. Functional studies have, in addition, revealed mechanistic clues for the various H-NS activities, like temperature- or growth phase-dependent regulation. Important elements for the specific regulatory activities of H-NS comprise different modes of DNA binding, protein oligomerization, the competition with other regulators and the fact that the topology of the target DNA is modulated during complex formation. The distinctive ability to recognize nucleic acid structures in combination with other proteins also explains H-NS-dependent post-transcriptional activities where the interaction with defined RNA structures and the interference with RNA/protein complexes during mRNA translation are crucial for regulation. Thus, protein/protein interactions, in combination with the recognition and modulation of nucleic acid structures, are key elements of the different mechanisms which make H-NS such a versatile regulator.

Intrinsic DNA bends: an organizer of local chromatin structure for transcription

DNA with a curved trajectory of its helix axis is called bent DNA, or curved DNA. Interestingly, biologically important DNA regions often contain this structure, irrespective of the origin of DNA. In the last decade, considerable progress has been made in clarifying one role of bent DNA in prokaryotic transcription and its mechanism of action. However, the role of bent DNA in eukaryotic transcription remains unclear. Our recent study raises the possibility that bent DNA is implicated in the "functional packaging" of transcriptional regulatory regions into chromatin. In this article, I review recent progress in bent DNA research in eukaryotic transcription, and summarize the history of bent DNA research and several subjects relevant to this theme. Finally, I propose a hypothesis that bent DNA structures that mimic a negative supercoil, or have a right-handed superhelical writhe, organize local chromatin infrastructure to help the very first interaction between cis-acting DNA elements and activators that trigger transcription.

Phenotypic analysis of random hns mutations differentiate DNA-binding activity from properties of fimA promoter inversion modulation and bacterial motility

H-NS is a major Escherichia coli nucleoid-associated protein involved in bacterial DNA condensation and global modulation of gene expression. This protein exists in cells as at least two different isoforms separable by isoelectric focusing. Among other phenotypes, mutations in hns result in constitutive expression of the proU and fimB genes, increased fimA promoter inversion rates, and repression of the flhCD master operon required for flagellum biosynthesis. To understand the relationship between H-NS structure and function, we transformed a cloned hns gene into a mutator strain and collected a series of mutant alleles that failed to repress proU expression. Each of these isolated hns mutant alleles also failed to repress fimB expression, suggesting that H-NS-specific repression of proU and fimB occurs by similar mechanisms. Conversely, alleles encoding single amino acid substitutions in the C-terminal DNA-binding domain of H-NS resulted in significantly reduced affinity for DNA yet conferred a wild-type fimA promoter inversion frequency, indicating that the mechanism of H-NS activity in modulating promoter inversion is independent of DNA binding. Furthermore, two specific H-NS amino acid substitutions resulted in hypermotile bacteria, while C-terminal H-NS truncations exhibited reduced motility. We also analyzed H-NS isoform composition expressed by various hns mutations and found that the N-terminal 67 amino acids were sufficient to support posttranslational modification and that substitutions at positions 18 and 26 resulted in the expression of a single H-NS isoform. These results are discussed in terms of H-NS domain organization and implications for biological activity.

Molecular aspects of the E. coli nucleoid protein, H-NS: a central controller of gene regulatory networks

The nucleoid-associated protein H-NS has a central role in the structuring and control of the enteric bacterial chromosome. This protein has been demonstrated to contribute to the regulation of expression for approximately thirty genes. In this article, the molecular aspects of H-NS structure and function are briefly reviewed. H-NS contains at least two independent structural domains: a C-terminal domain, involved in the DNA-protein interactions, and a N-terminal domain, likely involved in protein-protein interactions. Recent reports have revealed that H-NS is a key factor in a multi-component gene regulatory system. Factors have now been discovered which can backup or antagonise H-NS action at certain promoters. These recent findings are summarised and discussed in relationship to the role of H-NS in DNA packaging and nucleoid structure.

DNA binding is not sufficient for H-NS-mediated repression of proU expression

H-NS is a major component of bacterial chromatin and influences the expression of many genes. H-NS has been shown to exhibit a binding preference for certain AT-rich curved DNA elements in vitro. In this study we have addressed the factors that determine the specificity of H-NS action in vitro and in vivo. In bandshift studies, H-NS showed a slight binding preference for all curved sequences tested whether GC-based or AT-based; the specific architecture of the curve also influenced H-NS binding. In filter retention assays little difference in affinity could be detected for any sequence tested, including the downstream regulatory element (DRE) a downstream curved DNA element required for H-NS to repress transcription of the Salmonella typhimurium proU operon in vivo. A Kd of 1-2 microM was estimated for binding of H-NS to each of these sequences. In vivo, the distance between the proU promoter and the DRE, their relative orientations on the face of the DNA helix, and translation of the DRE had no major effect on proU regulation. None of the synthetic curved sequences tested could functionally replace the DRE in vivo. These data show that differential binding to curved DNA cannot account for the specificity of H-NS action in vivo. Furthermore, binding of H-NS to DNA per se is insufficient to repress the proU promoter. Thus, the DRE does not simply act as an H-NS binding site but must have a more specific role in mediating H-NS regulation of proU transcription.

The oligomeric structure of nucleoid protein H-NS is necessary for recognition of intrinsically curved DNA and for DNA bending

Escherichia coli hns, encoding the abundant nucleoid protein H-NS, was subjected to site-directed mutagenesis either to delete Pro115 or to replace it with alanine. Unlike the wild-type protein, hyperproduction of the mutant proteins did not inhibit macromolecular syntheses, was not toxic to cells and caused a less drastic compaction of the nucleoid. Gel shift and ligase-mediated circularization tests demonstrated that the mutant proteins retained almost normal affinity for non-curved DNA, but lost the wild-type capacity to recognize preferentially curved DNA and to actively bend non-curved DNA, a property of wild-type H-NS demonstrated here for the first time. DNase I foot-printing and in vitro transcription experiments showed that the mutant proteins also failed to recognize the intrinsically bent site of the hns promoter required for H-NS transcription autorepression and to inhibit transcription from the same promoter. The failure of the Pro115 mutant proteins to recognize curved DNA and to bend DNA despite their near normal affinity for non-curved DNA can be attributed to a defect in protein-protein interaction resulting in a reduced capacity to form oligomers observed in vitro and by a new in vivo test based on functional replacement by H-NS of the oligomerization domain (C-domain) of bacteriophage lambda cI repressor.

The nucleoid protein H-NS facilitates chromosome DNA replication in Escherichia coli dnaA mutants

Growth inhibition of the dnaA(Cs) mutant, which overinitiates chromosome replication, was shown to be dependent upon the nucleoid protein H-NS. [3H]thymine incorporation experiments indicated that the absence of H-NS inhibited overreplication by the dnaA(Cs) mutant. In addition, the temperature-sensitive phenotype of a dnaA46 mutant was enhanced by disruption of H-NS. These observations suggest that H-NS directly or indirectly facilitates the initiation of chromosome replication.

Fluorescence analysis of the Escherichia coli transcription regulator H-NS reveals two distinguishable complexes dependent on binding to specific or nonspecific DNA sites

Here we report a structural investigation of the transcription factor H-NS and its DNA interaction. H-NS has a general effect on transcription by compacting DNA; but for a number of specific genes, it is known to act directly as repressor or activator. The homodimeric protein binds to the major groove of DNA in a sequence-nonspecific manner, recognizing a curved conformation of the target DNA. H-NS consists of 136 amino acids with a single tryptophanyl residue at position 108. To overcome the apparent lack of any other structural details, we took advantage of the intrinsic fluorescence of Trp-108. Static and dynamic quenching constants obtained with the neutral quencher molecule acrylamide are consistent with a hydrophilic environment and high degree of solvent exposure for Trp-108. In addition, quenching studies in the presence of the anionic quencher iodide indicate a positively charged microenvironment for the same amino acid residue. Specific and nonspecific H-NS.DNA complexes were studied by gel retardation and fluorescence analysis. While specific H-NS.DNA complex formation is accompanied by a clear enhancement of the tryptophanyl fluorescence intensity, interaction in the presence of the nonspecific competitor DNA poly(dI-dC) decreases the fluorescence quantum yield.

Macromolecular crowding effects on the interaction of DNA with Escherichia coli DNA-binding proteins: a model for bacterial nucleoid stabilization

DNA-binding protein fractions from exponential and stationary phase cell extracts of E. coli were isolated by affinity chromatography on native DNA-cellulose. The ability of these fractions to convert DNA into a readily-sedimented form was compared in the absence or presence of added polymers. In the absence of polymers, large amounts of the proteins were required. In the presence of polyethylene glycol or polyvinylpyrrolidone, much smaller amounts of the DNA-binding proteins were required, indicating a macromolecular crowding effect from these polymers. The enhanced binding under crowded conditions appears to resolve a paradox between the cellular abundance of the DNA-binding proteins and the amounts required in earlier in vitro studies. The 'histone-like' protein HU from the DNA-binding protein fraction was preferentially incorporated into the pelleted DNA in the presence of polymers. Purified HU at roughly similar amounts caused a similar conversion of DNA to a readily-sedimentable ('condensed') form. Crowding-enhancement of DNA condensation by promoting the binding of proteins to the DNA provides a model for the stabilization of systems such as the bacterial nucleoid or kinetoplast DNA.

The chromatin-associated protein H-NS

H-NS is a major component of chromatin in enteric bacteria. H-NS plays a structural role in organising the chromosome, and influences DNA rearrangements as well as the expression of many genes. The biochemical and functional characteristics of H-NS are distinct from those of 'typical' DNA-binding proteins and much remains to be learned about the mechanism(s) by which H-NS acts. In this article we review our current understanding of the role of H-NS, and describe possible models by which H-NS might influence DNA structure and gene expression.

Gene 5.5 protein of bacteriophage T7 inhibits the nucleoid protein H-NS of Escherichia coli

Gene 5.5 of coliphage T7 is one of the most highly expressed genes during T7 infection. Gene 5.5 protein, purified from cells overexpressing the cloned gene, purifies with the nucleoid protein H-NS of Escherichia coli during three chromatographic steps. A fusion protein of gene 5.5 protein and maltose binding protein also purifies with H-NS. The fusion protein binds to the DNA-H-NS complex and abolishes H-NS-mediated inhibition of transcription by Escherichia coli and T7 RNA polymerases in vitro. Expression of gene 5.5 also relieves the repression of the Escherichia coli proU promoter by H-NS in vivo. The change of leucine to proline at residue 30 of gene 5.5 protein abolishes the interaction between gene 5.5 protein and H-NS.

Function of the Escherichia coli nucleoid protein, H-NS: molecular analysis of a subset of proteins whose expression is enhanced in a hns deletion mutant

The expression of numerous Escherichia coli cellular proteins was previously demonstrated to be greatly enhanced in a hns deletion background, relative to the levels in wild-type cells. In this study, a subset of such proteins, expression of which is affected by H-NS, was partially purified, and the genes coding for some of the proteins were identified and characterized. Two of the proteins thus characterized, 19K and 17K, were found to be encoded by previously predicted genes that are located adjacent to, and downstream of, the trpABCDE operon (27.6 min on the E. coli genetic map). The genes coding for the other two proteins, 10K-L and 10K-S, are located at 77.5 min on the genetic map. Their nucleotide sequences were determined and revealed that they may constitute an operon. To characterize the putative promoters for these genes, a set of promoter-lacZ transcriptional fusion genes was constructed on the E. coli chromosome. The results of such promoter-probe analyses indicated that H-NS represses the expression of these genes at the transcriptional level. Furthermore, H-NS appeared to exhibit relatively strong affinity for the putative promoter sequences in vitro. These results are compatible with the hypothesis that H-NS functions as a transcriptional repressor.

Autoregulatory expression of the Escherichia coli hns gene encoding a nucleoid protein: H-NS functions as a repressor of its own transcription

The Escherichia coli nucleoid protein, H-NS (or H1a), appears to influence the regulation of a variety of unrelated E. coli genes and operons. To gain an insight into the regulation of the hns gene itself, we constructed in this study a hns-lacZ transcriptional fusion gene and inserted a single copy at the att lambda locus on the E. coli chromosome. Expression of hns transcription appeared to be moderately regulated in a growth phase-dependent manner. It also emerged that hns transcription is under negative autoregulation, at least in the logarithmic growth phase. The results of in vitro transcription experiments confirmed that H-NS functions as a repressor for its own transcription. Thus, H-NS was shown to exhibit relatively high affinity for the DNA sequence encompassing the hns promoter region, as compared with a non-specific sequence. These results support the view that the nucleoid protein, H-NS, can function as a transcriptional regulator.

Lethal overproduction of the Escherichia coli nucleoid protein H-NS: ultramicroscopic and molecular autopsy

The Escherichia coli hns gene, which encodes the nucleoid protein H-NS, was deprived of its natural promoter and placed under the control of the inducible lambda PL promoter. An hns mutant yielding a protein (H-NS delta 12) with a deletion of four amino acids (Gly112-Arg-Thr-Pro115) was also obtained. Overproduction of wild-type (wt) H-NS, but not of H-NS delta 12, resulted in a drastic loss of cell viability. The molecular events and the morphological alterations eventually leading to cell death were investigated. A strong and nearly immediate inhibition of both RNA and protein synthesis were among the main effects of overproduction of wt H-NS, while synthesis of DNA and cell wall material was inhibited to a lesser extent and at a later time. Upon cryofixation of the cells, part of the overproduced protein was found in inclusion bodies, while the rest was localized by immunoelectron microscopy to the nucleoids. The nucleoids appeared condensed in cells expressing both forms of H-NS, but the morphological alterations were particularly dramatic in those overproducing wt H-NS; their nucleoids appeared very dense, compact and almost perfectly spherical. These results provide direct evidence for involvement of H-NS in control of the organization and compaction of the bacterial nucleoid in vivo and suggest that it may function, either directly or indirectly, as transcriptional repressor and translational inhibitor.

Molecular analysis of the Escherichia coli hns gene encoding a DNA-binding protein, which preferentially recognizes curved DNA sequences

We previously demonstrated that the E. coli protein, H-NS (or H1a), encoded by the gene hns (or osmZ or bglY) preferentially recognizes curved DNA sequences in vitro. In order to gain further insight into the complex function of H-NS and the significance of DNA curvature, we constructed a structurally defined hns deletion mutant on the E. coli chromosome. The hns deletion mutant thus obtained showed a variety of phenotypes previously for other lesions in hns. It was further demonstrated that, in this hns deletion background, numerous E. coli cellular proteins were either strongly expressed or remarkably repressed, as compared to their expression levels in wild-type cells.

Escherichia coli DNA-binding protein H-NS is localized in the nucleoid

Electron microscope localization of the 15.4-kDa DNA-binding protein H-NS was carried out in Escherichia coli cells subjected to cryosubstitution followed by immuno-labelling with the protein A/gold technique. Three types of E. coli cells were used: (1) "normal" cells growing exponentially at 37 degrees C; (2) "cold-shocked" cells two hours after the shift from 37 degrees C to 10 degrees C; and (3) cells in which an expression vector had been induced to overproduce H-NS. The results clearly indicate that in all 3 cases, the vast majority of the molecules reacting with anti-H-NS antibodies are localized within the nucleoid and at the border between the nucleoid and the ribosome-rich cytoplasm, which supports the premise that H-NS is implicated in the condensation of the nucleoid.

Protein H1: a role for chromatin structure in the regulation of bacterial gene expression and virulence?

There has been a recent revival of interest in one of the most abundant Escherichia coli proteins, H1 (also called H-NS). This protein was first identified many years ago as a major component of the bacterial nucleoid, and has been characterized biochemically by several groups. However, no clear function for the protein emerged from these studies. Our thinking has been transformed by recent findings which complement the biochemistry with genetic data. Several mutations, selected over many years by virtue of their diverse effects on gene expression, have turned out to be allelic and to fall within the structural gene for H1. Bringing together the genetics and the biochemistry has demonstrated that the whole is worth more than the sum of the parts! These findings have far-reaching implications for the mechanisms by which gene expression is regulated and also, perhaps, for the control of bacterial virulence.

Histone-like protein H1 (H-NS), DNA supercoiling, and gene expression in bacteria

Changes in DNA supercoiling in response to environmental signals such as osmolarity, temperature, or anaerobicity appear to play an underlying role in the regulation of gene expression in bacteria. Extensive genetic analyses have implicated the osmZ gene in this regulatory process: osmZ mutations are highly pleiotropic and alter the topology of cellular DNA. We have shown that the product of the osmZ gene is the "histone-like" protein H1 (H-NS). Protein H1 is one of the most abundant components of bacterial chromatin and binds to DNA in a relatively nonspecific fashion. These data imply a regulatory role for one of the major components of bacterial chromatin and provide support for the notion that changes in DNA topology and/or chromatin structure play a role in regulating gene expression.

Characterization of the structural genes for the DNA-binding protein H-NS in Enterobacteriaceae

The promoter region of Escherichia coli hns, the structural gene for the DNA-binding protein H-NS, has been identified by use of a promoter search vector and the in vivo transcriptional start point by primer extension analysis. The homologous hns genes of two other Enterobacteriaceae, Proteus vulgaris and Serratia marcescens, were identified by heterologous hybridization with a DNA probe derived from E. coli hns, cloned and sequenced. Taking into account only the invariant nucleotides and amino acids, the homology of H-NS among the three organisms was found to be greater than 70% at the DNA level and greater than 75% at the protein level. The three hns genes were also found to have nearly identical transcriptional and translational signals.