Atomic Force Microscopy Analysis of the Role of Major DNA-Binding Proteins in Organization of the Nucleoid in Escherichia coli

Bacterial genomic DNA is packed within the nucleoid of the cell along with various proteins and RNAs. We previously showed that the nucleoid in log phase cells consist of fibrous structures with diameters ranging from 30 to 80 nm, and that these structures, upon RNase A treatment, are converted into homogeneous thinner fibers with diameter of 10 nm. In this study, we investigated the role of major DNA-binding proteins in nucleoid organization by analyzing the nucleoid of mutant Escherichia coli strains lacking HU, IHF, H–NS, StpA, Fis, or Hfq using atomic force microscopy. Deletion of particular DNA-binding protein genes altered the nucleoid structure in different ways, but did not release the naked DNA even after the treatment with RNase A. This suggests that major DNA-binding proteins are involved in the formation of higher order structure once 10-nm fiber structure is built up from naked DNA.     

Dimerization and DNA‐dependent aggregation of the Escherichia coli nucleoid protein and chaperone CbpA

The Escherichia coli curved DNA‐binding protein A (CbpA) is a nucleoid‐associated DNA‐binding factor and chaperone that is expressed at high levels as cells enter stationary phase. Using a combination of genetics, biochemistry, structural modelling and single‐molecule atomic force microscopy we have examined dimerization of, and DNA binding by, CbpA. Our data show that CbpA dimerization is driven by a hydrophobic surface comprising amino acid side chains W287 and L290 located on the same side of an α helix close to the C‐terminus of CbpA. Derivatives of CbpA that are unable to dimerize are also unable to bind DNA. Free in solution, CbpA can exist as either a monomer or dimer. However, when bound to DNA, CbpA forms large aggregates that can protect DNA from degradation by nucleases. These CbpA–DNA aggregates are similar in morphology to protein–DNA complexes formed by the DNA‐binding protein from starved cells (Dps), the only other stationary phase‐specific nucleoid protein. Conversely, protein–DNA complexes formed by Fis, the major growth phase nucleoid protein, have a markedly different appearance.     

E. coli Fis Protein Insulates the cbpA Gene from Uncontrolled Transcription

The Escherichia coli curved DNA binding protein A (CbpA) is a poorly characterised nucleoid associated factor and co-chaperone. It is expressed at high levels as cells enter stationary phase. Using genetics, biochemistry, and genomics, we have examined regulation of, and DNA binding by, CbpA. We show that Fis, the dominant growth-phase nucleoid protein, prevents CbpA expression in growing cells. Regulation by Fis involves an unusual “insulation” mechanism. Thus, Fis protects cbpA from the effects of a distal promoter, located in an adjacent gene. In stationary phase, when Fis levels are low, CbpA binds the E. coli chromosome with a preference for the intrinsically curved Ter macrodomain. Disruption of the cbpA gene prompts dramatic changes in DNA topology. Thus, our work identifies a novel role for Fis and incorporates CbpA into the growing network of factors that mediate bacterial chromosome structure.     

An Escherichia coli protein that preferentially binds to sharply curved DNA

We attempted to find Escherichia coli proteins which preferentially bind to a curved DNA sequence even in the presence of an excess amount of a non-curved DNA sequence as a competitor, mainly by means of a DNA-binding gel retardation assay. Since the two sequences used had nearly the same nucleotide compositions, including consecutive dA5 stretches, we reasoned that this strategy would allow us to identify proteins which preferentially recognize an overall DNA curvature. We purified such a protein from E. coli. Its preferential binding to the curved DNA was found to be inhibited by distamycin, which removes the curvature from appropriate DNA sequences. The purified protein was identified as the E. coli nucleoid protein, H-NS.     

Gene silencing H-NS paralogue StpA forms a rigid protein filament along DNA that blocks DNA accessibility

Nucleoid-associated proteins are bacterial proteins that are responsible for chromosomal DNA compaction and global gene regulation. One such protein is Escherichia coli Histone-like nucleoid structuring protein (H-NS) which functions as a global gene silencer. Whereas the DNA-binding mechanism of H-NS is well-characterized, its paralogue, StpA which is also able to silence genes is less understood. Here we show that StpA is similar to H-NS in that it is able to form a rigid filament along DNA. In contrast to H-NS, the StpA filament interacts with a naked DNA segment to cause DNA bridging which results in simultaneous stiffening and bridging of DNA. DNA accessibility is effectively blocked after the formation of StpA filament on DNA, suggesting rigid filament formation is the important step in promoting gene silencing. We also show that >1 mM magnesium promotes higher order DNA condensation, suggesting StpA may also play a role in chromosomal DNA packaging.     

The nucleoid-associated protein StpA binds curved DNA, has a greater DNA-binding affinity than H-NS and is present in significant levels in hns mutants

The StpA protein is closely related to H-NS, the well-characterised global regulator of gene expression which is a major component of eubacterial chromatin. Despite sharing a very high degree of sequence identify and having biochemical properties in common with H-NS, the physiological function of StpA remains unknown. We show that StpA exhibits similar DNA-binding activities to H-NS. Although both display a strong preference for binding to curved DNA, StpA binds DNA with a four-fold higher affinity than H-NS, with K(d)s of 0.7 microM and 2.8 microM, respectively. It has previously been reported that expression of stpA is derepressed in an hns mutant. We have quantified the amount of StpA protein produced under this condition and find it to be only one-tenth the level of H-NS protein in wild-type cells. Our findings explain why the presence of StpA does not compensate for the lack of H-NS in an hns mutant, and why the characteristic pleiotropic hns mutant phenotype is observed.     

Investigation of the self-association and hetero-association interactions of H-NS and StpA from Enterobacteria

The nucleoid-associated protein H-NS and its paralogue StpA are global regulators of gene expression and form an integral part of the protein scaffold responsible for DNA condensation in Escherichia coli and Salmonella typhimurium . Although protein oligomerization is a requirement for this function, it is not entirely understood how this is accomplished. We address this by reporting on the self-association of H-NS and its hetero-association with StpA. We identify residues 1–77 of H-NS as being necessary and sufficient for high-order association. A multi-technique-based approach was used to measure the effects of salt concentration on the size distribution of H-NS and the thermal stability of H-NS and StpA dimers. The thermal stability of the StpA homodimer is significantly greater than that of H-NS₁₋₇₄. Investigation of the hetero-association of H-NS and StpA proteins suggested that the association of H-NS with StpA is more stable than the self-association of either H-NS or StpA with themselves. This provides a clear understanding of the method of oligomerization of these important proteins in effecting DNA condensation and reveals that the different associative properties of H-NS and StpA allow them to perform distinct, yet complementary roles in the bacterial nucleoid.     

Effects of nucleoid proteins on DNA repression loop formation in Escherichia coli

The intrinsic stiffness of DNA limits its ability to be bent and twisted over short lengths, but such deformations are required for gene regulation. One classic paradigm is DNA looping in the regulation of the Escherichia coli lac operon. Lac repressor protein binds simultaneously to two operator sequences flanking the lac promoter. Analysis of the length dependence of looping-dependent repression of the lac operon provides insight into DNA deformation energetics within cells. The apparent flexibility of DNA is greater in vivo than in vitro, possibly because of host proteins that bind DNA and induce sites of flexure. Here we test DNA looping in bacterial strains lacking the nucleoid proteins HU, IHF or H-NS. We confirm that deletion of HU inhibits looping and that quantitative modeling suggests residual looping in the induced operon. Deletion of IHF has little effect. Remarkably, DNA looping is strongly enhanced in the absence of H-NS, and an explanatory model is proposed. Chloroquine titration, psoralen crosslinking and supercoiling-sensitive reporter assays show that the effects of nucleoid proteins on looping are not correlated with their effects on either total or unrestrained supercoiling. These results suggest that host nucleoid proteins can directly facilitate or inhibit DNA looping in bacteria.     

Association of nucleoid proteins with coding and non-coding segments of the Escherichia coli genome

The Escherichia coli chromosome is condensed into an ill-defined structure known as the nucleoid. Nucleoid-associated DNA-binding proteins are involved in maintaining this structure and in mediating chromosome compaction. We have exploited chromatin immunoprecipitation and high-density microarrays to study the binding of three such proteins, FIS, H-NS and IHF, across the E.coli genome in vivo. Our results show that the distribution of these proteins is biased to intergenic parts of the genome, and that the binding profiles overlap. Hence some targets are associated with combinations of bound FIS, H-NS and IHF. In addition, many regions associated with FIS and H-NS are also associated with RNA polymerase.     

The StpA Protein Functions as a Molecular Adapter To Mediate Repression of the bgl Operon by Truncated H-NS in Escherichia coli

The mechanism of repression of the β-glucoside utilization (bgl) operon of Escherichia coli by a carboxy-terminally truncated derivative of the nucleoid-associated protein H-NS which is defective in DNA binding was investigated. The DNA-binding function of the H-NS-like protein StpA was found to be necessary for repression, which is consistent with a role for StpA as a DNA-binding adapter for mutant derivatives of H-NS.     

Testing mechanisms of DNA sliding by architectural DNA-binding proteins: dynamics of single wild-type and mutant protein molecules in vitro and in vivo

Architectural DNA-binding proteins (ADBPs) are abundant constituents of eukaryotic or bacterial chromosomes that bind DNA promiscuously and function in diverse DNA reactions. They generate large conformational changes in DNA upon binding yet can slide along DNA when searching for functional binding sites. Here we investigate the mechanism by which ADBPs diffuse on DNA by single-molecule analyses of mutant proteins rationally chosen to distinguish between rotation-coupled diffusion and DNA surface sliding after transient unbinding from the groove(s). The properties of yeast Nhp6A mutant proteins, combined with molecular dynamics simulations, suggest Nhp6A switches between two binding modes: a static state, in which the HMGB domain is bound within the minor groove with the DNA highly bent, and a mobile state, where the protein is traveling along the DNA surface by means of its flexible N-terminal basic arm. The behaviors of Fis mutants, a bacterial nucleoid-associated helix-turn-helix dimer, are best explained by mobile proteins unbinding from the major groove and diffusing along the DNA surface. Nhp6A, Fis, and bacterial HU are all near exclusively associated with the chromosome, as packaged within the bacterial nucleoid, and can be modeled by three diffusion modes where HU exhibits the fastest and Fis the slowest diffusion.     

Cooperative transitions of isolated Escherichia coli nucleoids: implications for the nucleoid as a cellular phase

The genomic DNA of Escherichia coli occurs in compact bodies known as nucleoids. Organization and structure of nucleoids are poorly understood. Compact, characteristically shaped, nucleoids isolated by the polylysine-spermidine procedure were visualized by DNA fluorescence microscopy. Treatment with urea or trypsin converted compact nucleoids to partially expanded forms. The transition in urea solutions was accompanied by release of most DNA-associated proteins; the transition point between compact and partially expanded forms was not changed by the loss of the proteins nor was it changed in nucleoids isolated from cells after exposure to chloramphenicol or from cells in which Dps, Fis, or H-NS and StpA had been deleted. Partially expanded forms became dispersed upon RNase exposure, indicating a role of RNA in maintaining the partial expansion. Partially expanded forms that had been stripped of most DNA-associated proteins were recompacted by polyethylene glycol 8,000, a macromolecular crowding agent, in a cooperative transition. DNA-associated proteins are suggested to have relatively little effect on the phase-like behavior of the cellular nucleoid. Changes in the urea transition indicate that a previously described procedure for compaction of polylysine-spermidine nucleoids may have an artifactual basis, and raise questions about reports of repetitive local structures involving the DNA of lysed cells.     

Chimeric HU-IHF proteins that alter DNA-binding ability.

Chimeric proteins between Escherichia coli histone-like HU and IHF were constructed by genetic engineering, in which part of the arm region was replaced by the corresponding region of IHF alpha (designated as HupANhimA) or IHF beta (HupANhimD); alternatively, an alpha-helix 2-beta 1 region was replaced by the corresponding region of IHF alpha (HupAXhimA) or IHF beta (HupAXhimD) (symbols N and X indicate NotI and XhoI junctions). These proteins were synthesized in a hupA-hupB double-deletion mutant. HupANhimA exhibited marked reduction in nonspecific DNA binding in vitro, and a drastic loss of HU activity in replicative transposition of Mu phage in vivo. HupANhimD also showed a significant reduction in the ability for DNA binding, though this protein supported Mu phage development. In contrast, the other two chimeric HU proteins showed only slight changes in nonspecific DNA-binding ability: they retained activities for transposition of Mu phage in vivo. These observations confirm that the flexible arm of HU-2, a domain proposed for DNA binding [Tanaka et al., Nature 310 (1984) 376-381; Goshima et al., Gene 96 (1990) 141-145], plays an important role in the physiological function of this protein. The results indicate that a unique conformation of the arm structure of HU protein, particularly the N-terminal half of a two-strand antiparallel beta-ribbon of the structure, is important for the DNA-binding ability of this protein.