Regulation of gene expression by histone-like proteins in bacteria

Histone-like proteins in bacteria contribute to the control of gene expression, as well as participating in other DNA transactions such as recombination and DNA replication. They have also been described, somewhat vaguely, as contributors to the organization of the bacterial nucleoid. Our view of how these proteins act in the cell is becoming clearer, particularly in the cases of Fis, H-NS and HU, three of the most intensively studied members of the group. Especially helpful have been studies of the contributions of these proteins to the regulation of specific genes such as the gal operon, and genes coding for stable RNA species, topoisomerases, and the histone-like proteins themselves. Recent advances have also been assisted by insights into the effects the histone-like proteins exert on DNA structure not only at specific promoters but throughout the genome.     

Control of cell wall assembly by a histone-like protein in Mycobacteria

Bacteria coordinate assembly of the cell wall as well as synthesis of cellular components depending on the growth state. The mycobacterial cell wall is dominated by mycolic acids covalently linked to sugars, such as trehalose and arabinose, and is critical for pathogenesis of mycobacteria. Transfer of mycolic acids to sugars is necessary for cell wall biogenesis and is mediated by mycolyltransferases, which have been previously identified as three antigen 85 (Ag85) complex proteins. However, the regulation mechanism which links cell wall biogenesis and the growth state has not been elucidated. Here we found that a histone-like protein has a dual concentration-dependent regulatory effect on mycolyltransferase functions of the Ag85 complex through direct binding to both the Ag85 complex and the substrate, trehalose-6-monomycolate, in the cell wall. A histone-like protein-deficient Mycobacterium smegmatis strain has an unusual crenellated cell wall structure and exhibits impaired cessation of glycolipid biosynthesis in the growth-retarded phase. Furthermore, we found that artificial alteration of the amount of the extracellular histone-like protein and the Ag85 complex changes the growth rate of mycobacteria, perhaps due to impaired down-regulation of glycolipid biosynthesis. Our results demonstrate novel regulation of cell wall assembly which has an impact on bacterial growth.     

Specific and non-specific interactions of integration host factor with DNA: thermodynamic evidence for disruption of multiple IHF surface salt-bridges coupled to DNA binding.

Site-specific DNA binding of architectural protein integration host factor (IHF) is involved in formation of functional multiprotein-DNA assemblies in Escherichia coli, while non-specific binding of IHF and other histone-like proteins serves to structure the nucleoid. Here, we report an isothermal titration calorimetry study of the thermodynamics of binding IHF to a 34 bp fragment composed entirely of the specific H' site from lambda-phage DNA. At low to moderate [K(+)] (60-100 mM), strong competition is observed between specific and non-specific binding as a result of a low specificity ratio (approximately 10(2)) and a very small non-specific site size. In this [K(+)] range, both specific and non-specific binding are enthalpy-driven, with large negative enthalpy, entropy and heat capacity changes and binding constants that are insensitive to [K(+)]. Above 100 mM K(+), only specific binding is observed, and both the binding constant and the magnitudes of enthalpy, entropy and heat capacity changes all decrease strongly with increasing [K(+)]. When interpreted in the context of the structure of the specific complex, the thermodynamics provide compelling evidence for a previously unrecognized design principle by which proteins that form extensive binding interfaces with nucleic acids control binding constants, binding site sizes and effects of temperature and ion concentrations on stability and specificity. We propose that up to 22 of the 23 IHF cationic side-chains that are located within 6 A of DNA phosphate oxygen atoms in the complex, are masked in the absence of DNA by pairing with anionic carboxylate groups in intramolecular salt-bridges (dehydrated ion-pairs). These salt-bridges increase in stability with increasing temperature and decreasing [K(+)]. To explain the unusual thermodynamics of IHF-DNA interactions, we propose that both specific and non-specific binding at low [K(+)] require disruption of salt-bridges (as many as 18 for specific binding) whereupon many of the unmasked charged groups hydrate and the cationic groups interact with DNA. From structural or thermodynamic parallels with IHF, we propose that large-scale coupling of disruption of protein salt-bridges to DNA binding is significant for other large-interface DNA wrapping proteins including the nucleosome, lac repressor core tetramer, RNA polymerase core protein, HU and SSB.     

Understanding apparent DNA flexibility enhancement by HU and HMGB architectural proteins

Understanding and predicting the mechanical properties of protein/DNA complexes are challenging problems in biophysics. Certain architectural proteins bind DNA without sequence specificity and strongly distort the double helix. These proteins rapidly bind and unbind, seemingly enhancing the flexibility of DNA as measured by cyclization kinetics. The ability of architectural proteins to overcome DNA stiffness has important biological consequences, but the detailed mechanism of apparent DNA flexibility enhancement by these proteins has not been clear. Here, we apply a novel Monte Carlo approach that incorporates the precise effects of protein on DNA structure to interpret new experimental data for the bacterial histone-like HU protein and two eukaryotic high-mobility group class B (HMGB) proteins binding to ∼ 200-bp DNA molecules. These data (experimental measurement of protein-induced increase in DNA cyclization) are compared with simulated cyclization propensities to deduce the global structure and binding characteristics of the closed protein/DNA assemblies. The simulations account for all observed (chain length and concentration dependent) effects of protein on DNA behavior, including how the experimental cyclization maxima, observed at DNA lengths that are not an integral helical repeat, reflect the deformation of DNA by the architectural proteins and how random DNA binding by different proteins enhances DNA cyclization to different levels. This combination of experiment and simulation provides a powerful new approach to resolve a long-standing problem in the biophysics of protein/DNA interactions.     

Archaebacterial histone-like proteins. Purification and characterization of helix stabilizing DNA binding proteins from the acidothermophile Sulfolobus acidocaldarius

Four DNA binding histone-like proteins have been purified from the nucleoid of the acidothermophilic archaebacterium Sulfolobus acidocaldarius to homogeneity employing DNA-cellulose chromatography and carboxymethylcellulose chromatography. The molecular weights of these proteins are in the range 8,000-12,500. Immunoblotting results suggest that a few antigenic determinants are common among these proteins which could not be detected by immunodiffusion. Spectroscopic properties of the proteins have been studied. The amino acid compositions of these proteins show both similarities and differences with histones and prokaryotic histone-like proteins. All of the four proteins bind native and denatured DNAs and single stranded RNA with differing affinities. Three of the proteins, denoted by HSNP (helix stabilizing nucleoid protein)-A, HSNP-C, and HSNP-C', show physiologically significant, strong, and synergistic effects in stabilizing duplex DNA against thermal denaturation with Tm increases in the range of 15-30 +/- degrees C.     

The human SWI-SNF complex protein p270 is an ARID family member with non-sequence-specific DNA binding activity

p270 is an integral member of human SWI-SNF complexes, first identified through its shared antigenic specificity with p300 and CREB binding protein. The deduced amino acid sequence of p270 reported here indicates that it is a member of an evolutionarily conserved family of proteins distinguished by the presence of a DNA binding motif termed ARID (AT-rich interactive domain). The ARID consensus and other structural features are common to both p270 and yeast SWI1, suggesting that p270 is a human counterpart of SWI1. The approximately 100-residue ARID sequence is present in a series of proteins strongly implicated in the regulation of cell growth, development, and tissue-specific gene expression. Although about a dozen ARID proteins can be identified from database searches, to date, only Bright (a regulator of B-cell-specific gene expression), dead ringer (a Drosophila melanogaster gene product required for normal development), and MRF-2 (which represses expression from the cytomegalovirus enhancer) have been analyzed directly in regard to their DNA binding properties. Each binds preferentially to AT-rich sites. In contrast, p270 shows no sequence preference in its DNA binding activity, thereby demonstrating that AT-rich binding is not an intrinsic property of ARID domains and that ARID family proteins may be involved in a wider range of DNA interactions.     

Histone-like protein HU from Deinococcus radiodurans binds preferentially to four-way DNA junctions

The histone-like protein HU from Escherichia coli is involved in DNA compaction and in processes such as DNA repair and recombination. Its participation in these events is reflected in its ability to bend DNA and in its preferred binding to DNA junctions and DNA with single-strand breaks. Deinococcus radiodurans is unique in its ability to reconstitute its genome from double strand breaks incurred after exposure to ionizing radiation. Using electrophoretic mobility shift assays (EMSA), we show that D.radiodurans HU (DrHU) binds preferentially only to DNA junctions, with half-maximal saturation of 18 nM. In distinct contrast to E.coli HU, DrHU does not exhibit a marked preference for DNA with nicks or gaps compared to perfect duplex DNA, nor is it able to mediate circularization of linear duplex DNA. These unexpected properties identify DrHU as the first member of the HU protein family not to serve an architectural role and point to its potential participation in DNA recombination events. Our data also point to a mechanism whereby differential target site selection by HU proteins is achieved and suggest that the substrate specificity of HU proteins should be expected to vary as a consequence of their individual capacity for inducing the required DNA bend.     

Regulation of the Chlamydia trachomatis histone H1-like protein Hc2 is IspE dependent and IhtA independent

The chlamydial histone-like proteins, Hc1 and Hc2, function as global regulators of chromatin structure and gene expression. Hc1 and Hc2 expression and activity are developmentally regulated. A small metabolite that disrupts Hc1 interaction with DNA also disrupts Hc2 interactions; however, the small regulatory RNA that inhibits Hc1 translation is specific to Hc1.     

Role of HU and DNA supercoiling in transcription repression: specialized nucleoprotein repression complex at gal promoters in Escherichia coli

Efficient repression of the two promoters P1 and P2 of the gal operon requires the formation of a DNA loop encompassing the promoters. In vitro, DNA looping-mediated repression involves binding of the Gal repressor (GalR) to two gal operators (OE and OI) and binding of the histone-like protein HU to a specific locus (hbs) about the midpoint between OE and OI, and supercoiled DNA. Without DNA looping, GalR binding to OE partially represses P1 and stimulates P2. We investigated the requirement for DNA supercoiling and HU in repression of the gal promoters in vivo in strains containing a fusion of a reporter gene, gusA or lacZ, to each promoter individually. While the P1 promoter was found to be repressible in the absence of DNA supercoiling and HU, the repression of P2 was entirely dependent upon DNA supercoiling in vivo. The P2 promoter was fully derepressed when supercoiling was inhibited by the addition of coumermycin in cells. P2, but not P1, was also totally derepressed by the absence of HU or the OI operator. From these results, we propose that the repression of the gal promoters in vivo is mediated by the formation of a higher order DNA-multiprotein complex containing GalR, HU and supercoiled DNA. In the absence of this complex, P1 but not P2 is still repressed by GalR binding to OE. The specific nucleoprotein complexes involving histone-like proteins, which repress promoter activity while remaining sensitive to inducing signals, as discussed, may occur more generally in bacterial nucleoids.     

Novel histone-like DNA-binding proteins in the nucleoid from the acidothermophillic archaebacterium Sulfolobus acidocaldarius that protect DNA against thermal denaturation

DNA of acidothermophilic archaebacterium Sulfolobus acidocaldarius has a base composition of about 40 mol% G + C content. A low intracellular salt concentration has been inferred for this organism. These features and the high optimal temperature of growth (75°C) would have a destabilising effect on the helical structure of the intracellular DNA. Hence, the nucleoid of this organism has been isolated in order to analyse its proteins composition and to identify any protein factors responsible for stabilisation of the organism's DNA at its growth temperature. The acid-soluble fraction of the nucleoid contains four low-molecular-weight basic proteins. The four proteins have been purified to homogeneity and antibodies to these proteins have been raised in rabbits. Immunodiffusion results suggest that the proteins are antigenically distinct. Three proteins (A, C and C′) stabilise different double-stranded DNA during thermal denaturation and increase T_m of DNA by about 25 C°. These proteins are referred to as helix-stabilising nucleoid proteins (HSNP). Protein B (referred to a DNA-binding nucleoid protein, DBNP-B) does not show helix-stabilising effect. None of the four proteins stabilises double-stranded RNA. The four proteins bind to native and denatured DNA to different extents as measured by DNA-cellulose chromatography and [³H]DNA binding by filtration. We suggest, based on the DNA binding, histone-like and helix-stabilising properties, that the intracellular function of these proteins is to prevent strand separation of DNA at the optimal temperature of growth (75°C).     

A Systematic In Vitro Study of Nucleoprotein Complexes Formed by Bacterial Nucleoid-Associated Proteins Revealing Novel Types of DNA Organization

Bacterial nucleoid is a dynamic entity that changes its three-dimensional shape and compaction depending on cellular physiology. While these changes are tightly associated with compositional alterations of abundant nucleoid-associated proteins implicated in reshaping the nucleoid, their cooperation in regular long-range DNA organization is poorly understood. In this study, we reconstitute a novel nucleoprotein structure in vitro, which is stabilized by cooperative effects of major bacterial DNA architectural proteins. While, individually, these proteins stabilize alternative DNA architectures consistent with either plectonemic or toroidal coiling of DNA, the combination of histone-like protein, histone-like nucleoid structuring protein, and integration host factor produces a conspicuous semiperiodic structure. By employing a bottom-up in vitro approach, we thus characterize a minimum set of bacterial proteins cooperating in organizing a regular DNA structure. Visualized structures suggest a mechanism for nucleation of topological transitions underlying the reshaping of DNA by bacterial nucleoid-associated proteins.     

Detection and localization of a chloroplast-encoded HU-like protein that organizes chloroplast nucleoids

Chloroplast DNA (cpDNA) is packed into discrete structures called chloroplast nucleoids (cp-nucleoids). The structure of cpDNA is thought to be important for its maintenance and regulation. In bacteria and mitochondria, histone-like proteins (such as HU and Abf2, respectively) are abundant and play important roles in DNA organization. However, a primary structural protein has yet to be found in cp-nucleoids. Here, we identified an abundant DNA binding protein from isolated cp-nucleoids of the primitive red alga Cyanidioschyzon merolae. The purified protein had sequence homology with the bacterial histone-like protein HU, and it complemented HU-lacking Escherichia coli mutants. The protein, called HC (histone-like protein of chloroplast), was encoded by a single gene (CmhupA) in the C. merolae chloroplast genome. Using immunofluorescence and immunoelectron microscopy, we demonstrated that HC was distributed uniformly throughout the entire cp-nucleoid. The protein was expressed constitutively throughout the cell and the chloroplast division cycle, and it was able to condense DNA. These results indicate that HC, a bacteria-derived histone-like protein, primarily organizes cpDNA into the nucleoid.     

Higher order oligomerization is required for H-NS family member MvaT to form gene-silencing nucleoprotein filament

MvaT from Pseudomonas aeruginosa is a member of the histone-like nucleoid structuring protein (H-NS) family of nucleoid-associated proteins widely spread among Gram-negative bacteria that functions to repress the expression of many genes. Recently, it was reported that H-NS from Escherichia coli can form rigid nucleoproteins filaments on DNA, which are important for their gene-silencing function. This raises a question whether the gene-silencing function of MvaT, which has only ∼18% sequence similarity to H-NS, is also based on the formation of nucleoprotein filaments. Here, using magnetic tweezers and atomic force microscopy imaging, we demonstrate that MvaT binds to DNA through cooperative polymerization to form a nucleoprotein filament that can further organize DNA into hairpins or higher-order compact structures. Furthermore, we studied DNA binding by MvaT mutants that fail to repress gene expression in P. aeruginosa because they are specifically defective for higher-order oligomer formation. We found that, although the mutants can organize DNA into compact structures, they fail to form rigid nucleoprotein filaments. Our findings suggest that higher-order oligomerization of MvaT is required for the formation of rigid nucleoprotein filaments that silence at least some target genes in P. aeruginosa. Further, our findings suggest that formation of nucleoprotein filaments provide a general structural basis for the gene-silencing H-NS family members.