Academic literature on the topic 'Histone-like protein H-NS'

The cyclic AMP receptor protein (CRP) is one of the best-known transcription factors, regulating about 400 genes. The histone-like nucleoid structuring protein (H-NS) is one of the nucleoid-forming proteins and is responsible for DNA packaging and gene repression in prokaryotes. In this study, the binding of ppGpp to CRP and H-NS was determined by fluorescence spectroscopy. CRP from Escherichia coli exhibited intrinsic fluorescence at 341 nm when excited at 280 nm. The fluorescence intensity decreased in the presence of ppGpp. The dissociation constant of 35 ± 3 µM suggests that ppGpp binds to CRP with a similar affinity to cAMP. H-NS also shows intrinsic fluorescence at 329 nm. The fluorescence intensity was decreased by various ligands and the calculated dissociation constant for ppGpp was 80 ± 11 µM, which suggests that the binding site was occupied fully by ppGpp under starvation conditions. This study suggests the modulatory effects of ppGpp in gene expression regulated by CRP and H-NS. The method described here may be applicable to many other proteins.

The histone-like nucleoid structuring (H-NS) protein is a major component of the folded chromosome in Escherichia coli and related bacteria. Functions attributed to H-NS include management of genome evolution, DNA condensation, and transcription. The wide-ranging influence of H-NS is remarkable given the simplicity of the protein, a small peptide, possessing rudimentary determinants for self-association, hetero-oligomerisation and DNA binding. In this review, I will discuss our understanding of H-NS with a focus on these structural elements. In particular, I will consider how these interaction surfaces allow H-NS to exert its different effects.

ABSTRACT The histone-like protein H-NS is a major component of the bacterial nucleoid and plays a crucial role in global gene regulation of enteric bacteria. It is known that the expression of a variety of genes is repressed by H-NS, and mutations in hns result in various phenotypes, but the role of H-NS in the drug resistance of Escherichia coli has not been known. Here we present data showing that H-NS contributes to multidrug resistance by regulating the expression of multidrug exporter genes. Deletion of the hns gene from the ΔacrAB mutant increased levels of resistance against antibiotics, antiseptics, dyes, and detergents. Decreased accumulation of ethidium bromide and rhodamine 6G in the hns mutant compared to that in the parental strain was observed, suggesting the increased expression of some drug exporter(s) in this mutant. The increased drug resistance and decreased drug accumulation caused by the hns deletion were completely suppressed by deletion of the multifunctional outer membrane channel gene tolC. At least eight drug exporter systems require TolC for their functions. Among these, increased expression of acrEF, mdtEF, and emrKY was observed in the Δhns strain by quantitative real-time reverse transcription-PCR analysis. The Δhns-mediated multidrug resistance pattern is quite similar to that caused by overproduction of the AcrEF exporter. Deletion of the acrEF gene greatly suppressed the level of Δhns-mediated multidrug resistance. However, this strain still retained resistance to some compounds. The remainder of the multidrug resistance pattern was similar to that conferred by overproduction of the MdtEF exporter. Double deletion of the mdtEF and acrEF genes completely suppressed Δhns-mediated multidrug resistance, indicating that Δhns-mediated multidrug resistance is due to derepression of the acrEF and mdtEF drug exporter genes.

ABSTRACT IS1, the smallest active transposable element in bacteria, encodes a transposase that promotes inter- and intramolecular transposition. Host-encoded factors, e.g., histone-like proteins HU and integration host factor (IHF), are involved in the transposition reactions of some bacterial transposable elements. Host factors involved in the IS1 transposition reaction, however, are not known. We show that a plasmid with an IS1 derivative that efficiently produces transposase did not generate miniplasmids, the products of intramolecular transposition, in mutants deficient in a nucleoid-associated DNA-binding protein, H-NS, but did generate them in mutants deficient in histone-like proteins HU, IHF, Fis, and StpA. Nor did IS1 transpose intermolecularly to the target plasmid in the H-NS-deficient mutant. The hns mutation did not affect transcription from the indigenous promoter of IS1 for the expression of the transposase gene. These findings show that transpositional recombination mediated by IS1 requires H-NS but does not require the HU, IHF, Fis, or StpA protein in vivo. Gel retardation assays of restriction fragments of IS1-carrying plasmid DNA showed that no sites were bound preferentially by H-NS within the IS1 sequence. The central domain of H-NS, which is involved in dimerization and/or oligomerization of the H-NS protein, was important for the intramolecular transposition of IS1, but the N- and C-terminal domains, which are involved in the repression of certain genes and DNA binding, respectively, were not. The SOS response induced by the IS1 transposase was absent in the H-NS-deficient mutant strain but was present in the wild-type strain. We discuss the possibility that H-NS promotes the formation of an active IS1 DNA-transposase complex in which the IS1 ends are cleaved to initiate transpositional recombination through interaction with IS1 transposase.

The heat-stable nucleoid structuring (H-NS, also referred to as histone-like nucleoid structuring) protein silences transcription of foreign genes in a variety of Gram-negative bacterial species. To take advantage of the products encoded in foreign genes, bacteria must overcome the silencing effects of H-NS. Because H-NS amounts are believed to remain constant, overcoming gene silencing has largely been ascribed to proteins that outcompete H-NS for binding to AT-rich foreign DNA. However, we report here that the facultative intracellular pathogenSalmonella entericaserovar Typhimurium decreases H-NS amounts 16-fold when inside macrophages. This decrease requires both the protease Lon and the DNA-binding virulence regulator PhoP. The decrease in H-NS abundance reduces H-NS binding to foreign DNA, allowing transcription of foreign genes, including those required for intramacrophage survival. The purified Lon protease degraded free H-NS but not DNA-bound H-NS. By displacing H-NS from DNA, the PhoP protein promoted H-NS proteolysis, thereby de-repressing foreign genes—even those whose regulatory sequences are not bound by PhoP. The uncovered mechanism enables a pathogen to express foreign virulence genes during infection without the need to evolve binding sites for antisilencing proteins at each foreign gene.

ABSTRACT Screening of Salmonella mutants for the ability to increase β-lactam resistance has led to the identification of a mutation in hns, which codes for the histone-like nucleoid structuring protein (H-NS). In this study, we report that H-NS modulates multidrug resistance through repression of the genes that encode the AcrEF multidrug efflux pump in Salmonella enterica serovar Typhimurium.

In prokaryotic cells, the nucleoid contains almost all the genetic materials as well as a number of nucleoid structuring factors. The nucleoid-associated proteins (NAPs) are known to have low molecular weight and the ability to form dimer or oligomer, and most of them can bind to DNA for regulation of gene expression. The Histone-like nucleoid structuring protein H-NS, well studied as one of the NAPs, acts as a global transcriptional repressor. It has independent functional N-terminal domain for oligomerization and C-terminal domain for DNA binding, joined by a flexible linker. H-NS contributes to horizontal genes transfer and responses to environmental factors like temperature or pH, which would influence the oligomerization ability of H-NS and DNA binding. The α-hemolysin expression-modulating protein Hha is a member of the Hha-YmoA family, expressed only in Gram-negative Enterobacteriaceae as a modulator of virulence factors expression. In E. coli, the binding of Hha to H-NS can modulate the expression of α-hemolysin operon, which is essential for the H-NS-regulated gene expression. In this study, both Hha and the oligomerization domain of H-NS (H-NS64) were expressed in E. coli and the purified proteins were crystallized. The Hha crystals diffracted to 2.2 Å; and the HhA/H-NS complex crystals diffracted to 1.8 Å. Both structures were successfully determined by molecular replacement method. Comparisons were carried out between the published apo Hha and H-NS structures and our complex structures. The structures showed the binding details between H-NS and Hha and also conformational changes of each protein, which may indicate how Hha regulates gene expressions through H-NS.
published_or_final_version
Physiology
Master
Master of Philosophy

博士
國立臺灣大學
生化科學研究所
103
Organisms using DNA as their hereditary substance, the genetic information of these DNA sequence can be expressed and regulated by DNA-related functional proteins, such as transcriptional factors and DNA-binding proteins. Around a decade ago, a new category of control factors of DNA-related functional proteins called the DNA mimic protein had been identified. The DNA mimic protein can inhibit and/or regulate the function and activity of DNA-related functional proteins by its DNA-like shape and unique surface negative charge pattern. Thus, DNA mimic proteins are involved in certain important cellular processes and may be involved in many undiscovered regulation mechanisms. To identify the DNA mimic protein in T4 phage, we focused on the proteins which have the properties found in known DNA mimic proteins: small protein size and low isoelectric point (pI). After the sequence analysis, we found that anti restriction nuclease (Arn) protein may be a DNA mimic protein. By using structural approaches, the crystal structure of Arn was determined. Interestingly, the negative charge distribution of Arn dimer surface is similar to the phosphate group distribution on DNA, implying Arn dimer could act as a DNA mimic. Furthermore, the size and shape of Arn dimer is similar to the DNA mimic protein overcome classical restriction (Ocr). To identify the interaction partner of T4 phage Arn in Escherichia coli (E. coli), the His-pull-down was used and we further discovered that bacterial histone-like nucleoid structuring (H-NS) protein can interact with Arn specifically. Arn/H-NS interaction reveals a novel regulation mechanism. When infecting the E. coli, T4 phage encounters attacks from host’s defense systems. For example, bacteria express some small DNA-binding proteins to bind and entangle foreign or phage DNAs, inducing the gene silencing effect. H-NS is a member of these kind of protein. Thus, in order to infect and replicate in E. coli successfully, T4 phage has to evolve some strategies to overcome the gene silencing effect from H-NS. Therefore, using a DNA mimic protein to inhibit H-NS is a straightforward way for T4 phage. To confirm our hypothesis in this undiscovered function of Arn, electrophoresis mobility shift assay (EMSA) was used and demonstrated that Arn competes with bacteria as well as phage DNA fragments for binding to H-NS. Computer modeling analysis revealed that Arn dimer competes with DNA to interact with the H-NS DNA binding domain via its negatively-charged side. Additionally, in vitro gene expression and electron microscopy analyses further indicated that Arn antagonizes the gene-silencing effect of H-NS on the reporter gene. In summary, we discovered a novel mechanism for phage-bacteria battle from T4 phage, which employs the DNA mimic protein Arn to counteract the H-NS gene-silencing effect by its DNA-like surface.

Bacteria lack nucleus and any other membrane-bound organelles. Hence all the cellular components, including proteins, DNA, RNA and other components are located within the cytoplasm. The region of the cell which encompasses the bacterial genomic DNA is termed ‘Nucleoid’. The nucleoid is composed largely of DNA and small amounts of proteins and RNA. The genomic DNA is organized in ways that are compatible with all the major DNA-related processes like replication, transcription and chromosome segregation. Proteins that play important role(s) in the structuring of DNA and having the potential to influence gene expression have been explored in all kingdoms of life. The organization of bacterial chromosome is influenced by several important factors. These factors include molecular crowding, negative supercoiling of DNA and NAPs (nucleoid-associated proteins) and transcription. Nucleoid-associated proteins are abundant and relatively low-molecular mass proteins which can bind DNA and function as architectural constituents in the nucleoid. Additionally, NAPs are involved in all the major cellular processes like replication, repair and gene transcription. At least a dozen distinct NAPs are known to be present in E. coli. HU, IHF (integration host factor), H-NS (histone-like nucleoid-structuring), Fis (Factor for inversion stimulation), Dps (DNA protection from starvation) are some of the abundant NAPs in E. coli. Most of these proteins bind DNA and show either DNA bending, bridging or wrapping which are directly relevant to their physiological role(s). As most of these proteins are involved in the regulation of transcription of many genes, they act as factors unifying gene regulation with nucleoid architecture and environment. Pathogenic bacteria have the ability to grow and colonize different environments and thus need to adapt to constantly changing conditions within the host. H-NS and IHF, being able to link environmental cues to the regulation of gene expression, play an important role in the bacterial pathogenesis. H-NS is one of the well studied NAPs in enterobacteria, and is known as a global gene silencer. It is also an important DNA structuring protein, involved in chromosome packaging. H-NS protein is a small (~15 kDa) protein, which is present at approximately 20000 copies/ cell. The most striking feature of H-NS is that although it binds DNA in a relatively sequence-independent fashion but is known to preferentially recognize and bind intrinsically curved DNA. It also constrains DNA supercoils in vitro, thereby affects DNA topology. H-NS also influences replication, recombination and genomic stability. In addition, it functions as a global regulator by regulating the expression of various genes which are linked to environmental adaptation. Various studies have shown the association of H-NS to AT-rich regions of the genome. About 5% of E. coli genes are regulated by H-NS, bulk of which are (~80%) negatively regulated. H-NS is involved in the silencing of horizontally-acquired genes, many of which are involved in pathogenesis, in a process known as xenogeneic silencing. H-NS is known to regulate the expression of various virulence factors like cytotoxins, fimbriae and siderophores in several pathogenic bacteria. Several studies have revealed that hns mutants show increased frequency of illegitimate recombination and reduction in intra-chromosomal recombination, indicating the involvement of H-NS in DNA repair/recombination. H-NS is known to act in several transposition systems, which it does so due to its ability to interact with other proteins involved and due to its DNA structure-specific binding activity. The prototypical IHF (Integration Host Factor) was originally discovered in E. coli as an essential co-factor for the site-specific recombination of phage λ. E. coli IHF belongs to DNABII structural family, along with HU and other proteins and consists of two subunits, IHFα and IHFβ. Thesubunits are ~10 kDa each and are essential for full IHF activity. Apart from its role in bacteriophage integration/excision, IHF also has roles in various processes such as DNA replication, transcription and also in several site-specific recombination systems. In most of these processes, IHF acts as an architectural component by facilitating the formation of nucleoprotein complexes by bending DNA at specific sites. IHF acts as a transcriptional regulator, influencing the global gene expression in E. coli and S. Typhimurium. Gene regulation by IHF requires its DNA architectural role, facilitating interactions between RNA polymerase and regulatory protein. The high intracellular concentration of IHF indicates that it might associate with DNA in a non-specific manner and contribute to chromatin organization. The binding of E. coli IHF causes the DNA to adopt U-turn and brings the non-adjacent sequences into close juxtaposition. IHF is also involved in gene regulation in several pathogenic organisms and is shown to regulate expression of many virulence factors. Despite extensive literature on NAPs, very little is known about NAPs and nucleoid architecture in M. tuberculosis. In the light of significant physiological roles played by NAPs in adaptation to environmental changes and in growth and virulence of bacteria, elucidation of their roles in M. tuberculosis is of paramount importance for a better understanding of its pathogen city. M. tuberculosis Rv3852 (hns) gene is predicted to encode a 134 amino acid protein with a molecular mass of 13.8 kDa. The amino acid sequence alignment revealed that M. tuberculosis H-NS and E. coli H-NS showed very low degree of sequence identity (6%). To explore the biochemical properties of M. tuberculosis H-NS, the sequence corresponding to Rv3852 was amplified via PCR, cloned and plasmid expressing M. tuberculosis hns was constructed. M. tuberculosis H-NS was over expressed and purified to homogeneity. E. coli H-NS was also over expressed and purified. Comparison of experimentally determined secondary structure showed considerable differences between M. tuberculosis and E. coli H-NS proteins. Chemical cross linking suggested that M. tuberculosis H-NS protein exists in both monomeric and dimeric forms in solution, consistent with the diametric nature of E. coli H-NS protein. Our studies have revealed that M. tuberculosis H-NS binds in a more structure-specific manner to DNA replication and repair intermediates, but displays lower affinity for double stranded DNA with relatively higher GC content. It bound to the Holliday junction (HJ), the central recombination intermediate, with high affinity. Furthermore, similar to M. tuberculosis H-NS, E. coli H-NS was able to bind to replication and recombination intermediates, but at a lower affinity than M. tuberculosis H-NS. To gain insights into homologous recombination in the context of nucleoid, we investigated the ability of M. tuberculosis RecA to catalyze DNA strand exchange between single-strand DNA and linear duplex DNA in the presence of increasing amounts of H-NS. We found that M. tuberculosis H-NS inhibited strand exchange mediated by its cognate RecA in a concentration dependent manner. Similar effect was seen in the case of E. coli H-NS, where it was able to suppress DNA strand exchange promoted by E. coli RecA, but at relatively higher concentrations, suggesting that H-NS proteins act as ‘roadblocks’ to strand exchange promoted by their cognate RecA proteins. H-NS and members of H-NS-family of NAPs are known to form rigid nucleoprotein filament structures on binding to DNA, which results in gene-silencing and is also implicated in chromosomal organization. Studies have also shown that H-NS mutants defective in gene silencing also lack the ability to form rigid nucleoprotein filament structure and that nucleoprotein filament structure is responsive to environmental factors. Our studies employing ligase-mediated DNA circularization assays reveal that both E. coli and M. tuberculosis H-NS proteins abrogate the circularization of linear DNA substrate by rigidifying the DNA backbone. These results suggest that M. tuberculosis H-NS could form nucleoprotein filament-like structures upon binding to DNA and these structures might be involved in transcriptional repression, chromosomal organization and protection of genomic DNA. In summary, these findings provide insights into the role of M. tuberculosis H-NS in homologous and/or homeologous recombination as well as transcriptional regulation and nucleoid organization. The second part of the thesis concerns the characterization of M. tuberculosis integration host factor (mIHF). The annotation of whole-genome sequence of M. tuberculosis H37Rv showed the presence of Mtihf gene (Rv1388) which codes for a putative 20-kDa integration host factor (mIHF). Amino acid sequence alignment revealed very low degree of sequence identity between mIHF and E. coli IHFαβ subunits. Unlike E. coli IHF, mIHF is essential for the viability of M. tuberculosis. The three-dimensional molecular modeling of mIHF based upon co crystal structure of Streptomycin coelicolor IHF (sIHF) duplex DNA, showed the presence of conserved Arg170, Arg171, Arg173, which were predicted to be involved in DNA binding and a conserved Pro150, in the tight turn. The coding sequence corresponding to the M. tuberculosis H37Rv ihf gene (Rv1388) was amplified, cloned and plasmid over expressing M. tuberculosis ihf (pMtihf) was constructed. Using pMtihf as a template and using specific primers, mutant ihf encoding plasmids were constructed in which, the arginine at position 170, 171, or 173 was replaced with alanine or aspartate and proline at position 150 was substituted with alanine. To explore the role of mIHF in cell viability, we investigated the ability of M. tuberculosis ihf to complement E. coli ΔihfA or ΔihfB strains against genotoxic stress. Despite low sequence identity between Mtihf and E. coli ihfA and ihfB, wild type Mtihf was able to rescue the UV and MMS sensitive phenotypes of E. coli ΔihfAand ΔihfBstrains, whereas Mtihf alleles bearing mutations in the DNA-binding residues failed to confer resistance against DNA-damaging agents. To further characterize the functions of mIHF, wild type and mutant versions of mIHF proteins were over expressed and purified to near homogeneity. Circular dichroism spectroscopy of wild type mIHF and mIHF mutant proteins revealed that they have similar secondary structures. By employing size-exclusion chromatography and blue-native PAGE, we determined that mIHF exists as a dimmer in solution. To understand the mechanistic basis of mIHF functions, we carried out electrophoretic mobility shift assays. In these assays, we found that wild-type mIHF showed high affinity and stable binding to DNA containing attB and attP sites and also to curved DNA, but not those mIHF mutants bearing mutations in DNA-binding residues. Because wild type mIHF was able to rescue the UV and MMS sensitive phenotypes of E. coli ΔihfA and ΔihfB strains, we ascertained the effect of overexpression of mIHF proteins on the bacterial nucleoid. Our results revealed that wild type mIHF was also able to cause significant nucleoid compaction upon its overexpression, but mutant mIHF proteins were unable to cause compaction of E. coli nucleoid structure. M. smegmatis IHF is known to stimulate L5 phage integrase mediated site-specific recombination, we investigated the ability of mIHF to promote site-specific recombination. In vitro recombination assays showed that M. tuberculosis IHF effectively stimulated the L5 integrase mediated site-specific recombination. Since DNA-bending activity of E. coli IHF is necessary for its functions in various processes like initiation of replication, site-specific recombination, transcriptional regulation and chromosomal organization, we asked whether mIHF possesses DNA bending activity. We employed ligase mediated DNA circularization assays, which revealed that like E. coli IHF, mIHF was able to bend DNA resulting in the covalent closure of DNA to yield circular DNA molecules. Interestingly mIHF also resulted in the formation of slower migrating linear DNA multimers, albeit to a lesser extent, which suggest that both E. coli IHF and mIHF show DNA-bending, but the mechanism is distinct. Further studies using atomic force microscopy showed that depending upon the placement of preferred binding site (curved-DNA sequence) mIHF promotes DNA compaction into nucleoid-like or higher order filamentous structures. Together, these findings provide insights into functions of mIHF in the organization of bacterial nucleoid and formation of higher-order nucleoprotein structures. Importantly, our studies revealed that the DNA-binding residues, the DNA bending mechanism and mechanism of action of mIHF during site-specific recombination were different from E. coli IHF protein. Together with extensive biochemical and in vitro data of bacterial growth, the findings presented in this thesis provide novel insights into the biological roles of H-NS and mIHF in M. tuberculosis.