High-affinity DNA binding of HU protein from the hyperthermophile Thermotoga maritima

Prokaryotic genomes are compacted by association with small basic proteins, generating what has been termed bacterial chromatin. The ubiquitous DNA-binding protein HU serves this function. DNA-binding properties of HU from the hyperthermophilic eubacterium Thermotoga maritima are shown here to differ significantly from those characteristic of previously described HU homologs. Electrophoretic mobility shift analyses show that T. maritima HU (TmHU) binds double-stranded DNA with high affinity (K(d)=5.6(+/-0.7) nM for 37 bp DNA). Equivalent affinity is observed between 4 degrees C and 45 degrees C. TmHU has higher affinity for DNA containing a set of 4 nt loops separated by 9 bp (K(d)=1.4(+/-0.3) nM), consistent with its introduction of two DNA kinks. Using DNA probes of varying length, the optimal binding site for TmHU is estimated at 37 bp, in sharp contrast to the 9-10 bp binding site reported for other HU homologs. Alignment of >60 HU sequences demonstrates significant sequence conservation: A DNA-intercalating proline residue is almost universally conserved, and it is preceded by arginine and asparagine in most sequences, generating a highly conserved RNP motif; V substitutes for R only in HU from Thermotoga, Thermus and Deinococcus. A fivefold increase in DNA-binding affinity is observed for TmHU in which V is replaced with R (TmHU-V61R; K(d)=1.1(+/-0.2) nM), but a change in the trajectory of DNA flanking the sites of DNA intercalation is inferred from analysis of TmHU-V61R binding to DNA modified with 4 nt loops or with substitutions of 5-hydroxymethyluracil for thymine. Survival in extreme environments places unique demands on protection of genomic DNA from thermal destabilization and on access of DNA to the cellular machinery, demands that may be fulfilled by the specific DNA-binding properties of HU and by the fine structure of the bacterial chromatin.     

The HU protein from Thermotoga maritima: recombinant expression, purification and physicochemical characterization of an extremely hyperthermophilic DNA-binding protein.

The histone-like protein TmHU from the hyperthermophilic eubacterium Thermotoga maritima was cloned, expressed to high levels in Escherichia coli, and purified to homogeneity by heat precipitation and cation exchange chromatography. CD spectroscopical studies with secondary structure analysis as well as comparative modeling demonstrate that the dimeric TmHU has a tertiary structure similar to other homologous HU proteins. The Tm of the protein was determined to be 96 degrees C, and thermal unfolding is nearly completely reversible. Surface plasmon resonance measurements for TmHU show that the protein binds to DNA in a highly cooperative manner, with a KD of 73 nM and a Hill coefficient of 7.6 for a 56 bp DNA fragment. It is demonstrated that TmHU is capable to increase the melting point of a synthetic, double-stranded DNA (poly[d(A-T)]) by 47 degrees C, thus suggesting that DNA stabilization may be a major function of this protein in hyperthermophiles. The significant in vitro protection of double-helical DNA may be useful for biotechnological applications.     

Binding of TmHU to single dsDNA as observed by optical tweezers

Optical tweezers are employed to study the action of the histone-like protein from Thermotoga maritima (TmHU) on DNA at a single molecule level. Binding and disruption of TmHU to and from DNA are found to take place in discrete steps of 4-5 nm length and a net binding enthalpy of about 16kBT. This is in reasonable agreement with a microscopic model that estimates the extension of the binding sites of the protein and evaluates the energetics mainly for bending of the DNA in the course of interaction.     

Single‐molecule tracking reveals that the nucleoid‐associated protein HU plays a dual role in maintaining proper nucleoid volume through differential interactions with chromosomal DNA

HU (Histone‐like protein from Escherichia coli strain U93) is the most conserved nucleoid‐associated protein in eubacteria, but how it impacts global chromosome organization is poorly understood. Using single‐molecule tracking, we demonstrate that HU exhibits nonspecific, weak, and transitory interactions with the chromosomal DNA. These interactions are largely mediated by three conserved, surface‐exposed lysine residues (triK), which were previously shown to be responsible for nonspecific binding to DNA. The loss of these weak, transitory interactions in a HUα(triKA) mutant results in an over‐condensed and mis‐segregated nucleoid. Mutating a conserved proline residue (P63A) in the HUα subunit, deleting the HUβ subunit, or deleting nucleoid‐associated naRNAs, each previously implicated in HU’s high‐affinity binding to kinked or cruciform DNA, leads to less dramatically altered interacting dynamics of HU compared to the HUα(triKA) mutant, but highly expanded nucleoids. Our results suggest HU plays a dual role in maintaining proper nucleoid volume through its differential interactions with chromosomal DNA. On the one hand, HU compacts the nucleoid through specific DNA structure‐binding interactions. On the other hand, it decondenses the nucleoid through many nonspecific, weak, and transitory interactions with the bulk chromosome. Such dynamic interactions may contribute to the viscoelastic properties and fluidity of the bacterial nucleoid to facilitate proper chromosome functions.     

The essential histone-like protein HU plays a major role in Deinococcus radiodurans nucleoid compaction

The nucleoid of radioresistant bacteria, including D .  radiodurans , adopts a highly condensed structure that remains unaltered after exposure to high doses of irradiation. This structure may contribute to radioresistance by preventing the dispersion of DNA fragments generated by irradiation. In this report, we focused our study on the role of HU protein, a nucleoid-associated protein referred to as a histone-like protein, in the nucleoid compaction of D. radiodurans. We demonstrate, using a new system allowing conditional gene expression, that HU is essential for viability in D. radiodurans . Using a tagged HU protein and immunofluorescence microscopy, we show that HU protein localizes all over the nucleoid and that when HU is expressed from a thermosensitive plasmid, its progressive depletion at the non-permissive temperature generates decondensation of DNA before fractionation of the nucleoid into several entities and subsequent cell lysis. We also tested the effect of the absence of Dps, a protein also involved in nucleoid structure. In contrast to the drastic effect of HU depletion, no change in nucleoid morphology and cell viability was observed in dps mutants compared with the wild-type, reinforcing the major role of HU in nucleoid organization and DNA compaction in D. radiodurans .     

HU binds and folds single-stranded DNA

The nucleoid-associated protein HU plays an important role in bacterial nucleoid organization and is involved in numerous processes including transposition, recombination and DNA repair. We show here that HU binds specifically DNA containing mismatched region longer than 3 bp as well as DNA bulges. HU binds single-stranded DNA (ssDNA) in a binding mode that is reminiscent but different from earlier reported specific HU interactions with double-helical DNA lesions. An HU dimer requires 24 nt of ssDNA for initial binding, and 12 nt of ssDNA for each additional dimer binding. In the presence of equimolar amounts of HU dimer and DNA, the ssDNA molecule forms an U-loop (hairpin-like) around the protein, providing contacts with both sides of the HU body. This mode differs from the binding of the single-strand-binding protein (SSB) to ssDNA: in sharp contrast to SSB, HU binds ssDNA non-cooperatively and does not destabilize double-helical DNA. Furthermore HU has a strong preference for poly(dG), while binding to poly(dA) is the weakest. HU binding to ssDNA is probably important for its capacity to cover and protect bacterial DNA both intact and carrying lesions.     

A hyperthermostable bacterial histone-like protein as an efficient mediator for transfection of eukaryotic cells

Gene delivery has shown potential in a variety of applications, including basic research, therapies for inborn genetic defects, cancer, AIDS, tissue engineering, and vaccination. Most available systems have serious drawbacks, such as safety hazards, inefficiency under in vivo-like conditions, and expensive production. When using naked DNA, for instance, a large amount of ultrapure DNA has to be applied as a result of degradation by nucleases. Similarly, the use of eukaryotic histones, synthetic peptides, or peptide nucleic acids may be limited by high production costs. We have demonstrated a biotechnologically feasible and economical approach for gene delivery using the histone-like protein from the hyperthermostable eubacterium Thermotoga maritima, TmHU as an efficient gene transfer reagent. HU can be easily isolated from recombinant Escherichia coli, is extraordinarily stable, and protects dsDNA from thermal denaturation. This study demonstrates its use as an inexpensive tool for gene delivery.     

Bacterial protein HU dictates the morphology of DNA condensates produced by crowding agents and polyamines

Controlling the size and shape of DNA condensates is important in vivo and for the improvement of nonviral gene delivery. Here, we demonstrate that the morphology of DNA condensates, formed under a variety of conditions, is shifted completely from toroids to rods if the bacterial protein HU is present during condensation. HU is a non-sequence-specific DNA binding protein that sharply bends DNA, but alone does not condense DNA into densely packed particles. Less than one HU dimer per 225 bp of DNA is sufficient to completely control condensate morphology when DNA is condensed by spermidine. We propose that rods are favored in the presence of HU because rods contain sharply bent DNA, whereas toroids contain only smoothly bent DNA. The results presented illustrate the utility of naturally derived proteins for controlling the shape of DNA condensates formed in vitro. HU is a highly conserved protein in bacteria that is implicated in the compaction and shaping of nucleoid structure. However, the exact role of HU in chromosome compaction is not well understood. Our demonstration that HU governs DNA condensation in vitro also suggests a mechanism by which HU could act as an architectural protein for bacterial chromosome compaction and organization in vivo.     

Structural organization of avian retrovirus integrase in assembled intasomes mediating full-site integration

Retrovirus preintegration complexes (PIC) purified from virus-infected cells are competent for efficient concerted integration of the linear viral DNA ends by integrase (IN) into target DNA (full-site integration). In this report, we have shown that the assembled complexes (intasomes) formed in vitro with linear 3.6-kbp DNA donors possessing 3'-OH-recessed attachment (att) site sequences and avian myeloblastosis virus IN (4 nm) were as competent for full-site integration as isolated retrovirus PIC. The att sites on DNA with 3'-OH-recessed ends were protected by IN in assembled intasomes from DNase I digestion up to approximately 20 bp from the terminus. Several DNA donors containing either normal blunt-ended att sites or different end mutations did not allow assembly of complexes that exhibit the approximately 20-bp DNase I footprint at 14 degrees C. At 50 and 100 mm NaCl, the approximately 20-bp DNase I footprints were produced with wild type (wt) U3 and gain-of-function att site donors for full-site integration as previously observed at 320 mm NaCl. Although the wt U5 att site donors were fully competent for full-site integration at 37 degrees C, the approximately 20-bp DNase I footprint was not observed under a variety of assembly conditions including low NaCl concentrations at 14 degrees C. Under suboptimal assembly conditions for intasomes using U3 att DNA, DNase I probing demonstrated an enhanced cleavage site 9 bp from the end of U3 suggesting that a transient structural intasome intermediate was identified. Using a single nucleotide change at position 7 from the end and a series of small size deletions of wt U3 att site sequences, we determined that sequences upstream of the 11th nucleotide position were not required by IN to produce the approximately 20-bp DNase I footprint and full-site integration. The results suggest the structural organization of IN at the att sites in reconstituted intasomes was similar to that observed in PIC.     

Topography of simian virus 40 A protein-DNA complexes: arrangement of protein bound to the origin of replication.

DNA binding regions I, II, and III at the origin of replication have different arrangements of A protein (T antigen) recognition pentanucleotides. The A protein also protects each region from DNase in distinctly different patterns. Footprint and fragment assays led to the following conclusions: (i) in some cases a single recognition pentanucleotide is sufficient to direct the binding and accurate alignment of A protein on DNA; (ii) the A protein binds within isolated region I or II in a sequential process leading to multiple overlapping areas of DNase protection within each region; and (iii) the 23-base pair span of recognition sequences in region II allows binding and protection of a longer length of DNA than the 23-base pair span in region I. We propose a model of protein binding that addresses the problem of variations in the arrangement of pentanucleotides in regions I and II and explains the observed DNase protection patterns. The central feature of the model requires each protomer of A protein to bind to a pentanucleotide in a unique direction. The resulting orientation of protein would protect more DNA at the 5' end of the 5'-GAGGC-3' recognition sequence than at the 3' end. The arrangement of multiple protomers at the origin of simian virus 40 replication is discussed.     

Increased bending rigidity of single DNA molecules by H-NS,a temperature and osmolarity sensor

Histonelike nucleoid structuring protein (H-NS) is an abundant prokaryotic protein participating in nucleoid structure, gene regulation, and silencing. It plays a key role in cell response to changes in temperature and osmolarity. Force-extension measurements of single, twist-relaxed lambda-DNA-H-NS complexes show that these adopt more extended configurations compared to the naked DNA substrates. Crosslinking indicates that H-NS can decorate DNA molecules at one H-NS dimer per 15-20 bp. These results suggest that H-NS polymerizes along DNA, forming a complex of higher bending rigidity. These effects are not observed above 32 degrees C or at high osmolarity, supporting the hypothesis that a direct H-NS-DNA interaction plays a key role in gene silencing. Thus, we propose that H-NS plays a unique structural role, different from that of HU and IHF, and functions as one of the environmental sensors of the cell.     

DNA Clasping by Mycobacterial HU: The C-Terminal Region of HupB Mediates Increased Specificity of DNA Binding

Background

HU a small, basic, histone like protein is a major component of the bacterial nucleoid. E. coli has two subunits of HU coded by hupA and hupB genes whereas Mycobacterium tuberculosis (Mtb) has only one subunit of HU coded by ORF Rv2986c (hupB gene). One noticeable feature regarding Mtb HupB, based on sequence alignment of HU orthologs from different bacteria, was that HupB_Mtb bears at its C-terminal end, a highly basic extension and this prompted an examination of its role in Mtb HupB function.

Methodology/Principal Findings

With this objective two clones of Mtb HupB were generated; one expressing full length HupB protein (HupB_Mtb) and another which expresses only the N terminal region (first 95 amino acid) of hupB (HupB_MtbN). Gel retardation assays revealed that HupB_MtbN is almost like E. coli HU (heat stable nucleoid protein) in terms of its DNA binding, with a binding constant (K_d) for linear dsDNA greater than 1000 nM, a value comparable to that obtained for the HUαα and HUαβ forms. However CTR (C-terminal Region) of HupB_Mtb imparts greater specificity in DNA binding. HupB_Mtb protein binds more strongly to supercoiled plasmid DNA than to linear DNA, also this binding is very stable as it provides DNase I protection even up to 5 minutes. Similar results were obtained when the abilities of both proteins to mediate protection against DNA strand cleavage by hydroxyl radicals generated by the Fenton''s reaction, were compared. It was also observed that both the proteins have DNA binding preference for A:T rich DNA which may occur at the regulatory regions of ORFs and the oriC region of Mtb.

Conclusions/Significance

These data thus point that HupB_Mtb may participate in chromosome organization in-vivo, it may also play a passive, possibly an architectural role.     

A comparative proteomic approach to better define Deinococcus nucleoid specificities

Compared to radiation-sensitive bacteria, the nucleoids of radiation-resistant Deinococcus species show a higher degree of compaction. Such a condensed nucleoid may contribute to the extreme radiation resistance of Deinococcus by limiting dispersion of radiation-induced DNA fragments. Architectural proteins may play a role in this high degree of nucleoid compaction, but comparative genomics revealed only a limited number of Deinococcus homologs of known nucleoid-associated proteins (NAPs) from other species such as Escherichia coli. A comparative proteomic approach was used to identify potentially novel proteins from isolated nucleoids of Deinococcus radiodurans and Deinococcus deserti. Proteins in nucleoid enriched fractions were identified and semi-quantified by shotgun proteomics. Based on normalized spectral counts, the histone-like DNA-binding protein HU appeared to be the most abundant among candidate NAPs from both micro-organisms. By immunofluorescence microscopy, D. radiodurans HU and both DNA gyrase subunits were shown to be distributed throughout the nucleoid structure and absent from the cytoplasm. Taken together, our results suggest that D. radiodurans and D. deserti bacteria contain a very low diversity of NAPs, with HU and DNA gyrase being the main proteins involved in the organization of the Deinococcus nucleoids.     

The role of surface-exposed lysines in wrapping DNA about the bacterial histone-like protein HU

Several basic proteins, including the ubiquitous HU proteins, serve histone-like functions in prokaryotes. Significant sequence conservation exists between HU homologues; yet binding sites varying from 9 to 37 bp have been reported. TF1, an HU homologue with a 37 bp binding site that is encoded by the Bacillus subtilis bacteriophage SPO1, binds with nM affinity to DNA that contains 5-hydroxymethyluracil (hmU) in place of thymine and to T-containing DNA with loops. We evaluated the contribution of three conserved lysines to specifying the length of the binding site and show that Lys3 is critical for maintaining a long binding site in T-containing DNA: A mutant protein in which Lys3 is replaced with Gln(TF1-K3Q) is completely deficient in forming a stable complex. The affinity for 37 bp hmU-containing DNA is also reduced, from approximately 3 nM for wild-type TF1 to approximately 90 nM for TF1-K3Q. The decrease in affinity of TF1-K3Q for hmU-containing DNA > or = 25 bp suggests that Lys3 contacts DNA 8-9 bp distal to the sites of kinking. We propose that Lys3 forms an internal saltbridge to Asp26 in HU homologues characterized by shorter binding sites and that its surface exposure, and hence a longer binding site, may correlate with absence of this aspartate.     

Modulation of DNA conformations through the formation of alternative high-order HU-DNA complexes

HU is an abundant, highly conserved protein associated with the bacterial chromosome. It belongs to a small class of proteins that includes the eukaryotic proteins TBP, SRY, HMG-I and LEF-I, which bind to DNA non-specifically at the minor groove. HU plays important roles as an accessory architectural factor in a variety of bacterial cellular processes such as DNA compaction, replication, transposition, recombination and gene regulation. In an attempt to unravel the role this protein plays in shaping nucleoid structure, we have carried out fluorescence resonance energy transfer measurements of HU-DNA oligonucleotide complexes, both at the ensemble and single-pair levels. Our results provide direct experimental evidence for concerted DNA bending by HU, and the abrogation of this effect at HU to DNA ratios above about one HU dimer per 10-12 bp. These findings support a model in which a number of HU molecules form an ordered helical scaffold with DNA lying in the periphery. The abrogation of these nucleosome-like structures for high HU to DNA ratios suggests a unique role for HU in the dynamic modulation of bacterial nucleoid structure.     

Hyperthermophilic topoisomerase I from Thermotoga maritima. A very efficient enzyme that functions independently of zinc binding

Topoisomerases, by controlling DNA supercoiling state, are key enzymes for adaptation to high temperatures in thermophilic organisms. We focus here on the topoisomerase I from the hyperthermophilic bacterium Thermotoga maritima (optimal growth temperature, 80 degrees C). To determine the properties of the enzyme compared with those of its mesophilic homologs, we overexpressed T. maritima topoisomerase I in Escherichia coli and purified it to near homogeneity. We show that T. maritima topoisomerase I exhibits a very high DNA relaxing activity. Mapping of the cleavage sites on a variety of single-stranded oligonucleotides indicates a strong preference for a cytosine at position -4 of the cleavage, a property shared by E. coli topoisomerase I and archaeal reverse gyrases. As expected, the mutation of the putative active site Tyr 288 to Phe led to a totally inactive protein. To investigate the role of the unique zinc motif (Cys-X-Cys-X(16)-Cys-X-Cys) present in T. maritima topoisomerase I, experiments have been performed with the protein mutated on the tetracysteine motif. Strikingly, the results show that zinc binding is not required for DNA relaxation activity, contrary to the E. coli enzyme. Furthermore, neither thermostability nor cleavage specificity is altered in this mutant. This finding opens the question of the role of the zinc-binding motif in T. maritima topoisomerase I and suggests that this hyperthermophilic topoisomerase possesses a different mechanism from its mesophilic homolog.     

DNase I hypersensitive regions correlate with a site-specific endogenous nuclease activity on the r-chromatin of Tetrahymena

A novel nuclease activity have been detected at three specific sites in the chromatin of the spacer region flanking the 5'-end of the ribosomal RNA gene from Tetrahymena. The endogenous nuclease does not function catalytically in vitro, but is in analogy with the DNA topoisomerases activated by strong denaturants to cleave DNA at specific sites. The endogenous cleavages have been mapped at positions +50, -650 and -1100 relative to the 5'-end of the pre-35S rRNA. The endogenous cleavage sites are associated with micrococcal nuclease hypersensitive sites and DNase I hypersensitive regions. Thus, a single well-defined micrococcal nuclease hypersensitive site is found approximately 130 bp upstream from each of the endogenous cleavages. Clusters of defined sites, the majority of which fall within the 130 bp regions defined by vicinal micrococcal nuclease and endogenous cleavages, constitute the DNase I hypersensitive regions.