Crystal structure of the holliday junction DNA in complex with a single RuvA tetramer

DnaB drives DNA branch migration and dislodges proteins while encircling two DNA strands

DnaB is a ring-shaped, hexameric helicase that unwinds the E. coli DNA replication fork while encircling one DNA strand. This report demonstrates that DnaB can also encircle both DNA strands and then actively translocate along the duplex. With two strands positioned inside its central channel, DnaB translocates with sufficient force to displace proteins tightly bound to DNA with no resultant DNA unwinding. Thus, DnaB may clear proteins from chromosomal DNA. Furthermore, while encircling two DNA strands, DnaB can drive branch migration of a synthetic Holliday junction with heterologous duplex arms, suggesting that DnaB may be directly involved in DNA recombination in vivo. DnaB binds to just one DNA strand during branch migration. T7 phage gp4 protein also drives DNA branch migration, suggesting this activity generalizes to other ring-shaped helicases.

Crystal structure of the RuvA-RuvB complex: a structural basis for the Holliday junction migrating motor machinery

We present the X-ray structure of the RuvA-RuvB complex, which plays a crucial role in ATP-dependent branch migration. Two RuvA tetramers form the symmetric and closed octameric shell, where four RuvA domain IIIs spring out in the two opposite directions to be individually caught by a single RuvB. The binding of domain III deforms the protruding beta hairpin in the N-terminal domain of RuvB and thereby appears to induce a functional and less symmetric RuvB hexameric ring. The model of the RuvA-RuvB junction DNA ternary complex, constructed by fitting the X-ray structure into the averaged electron microscopic images of the RuvA-RuvB junction, appears to be more compatible with the branch migration mode of a fixed RuvA-RuvB interaction than with a rotational interaction mode.

The C-terminal region of Escherichia coli UvrC contributes to the flexibility of the UvrABC nucleotide excision repair system

Nucleotide excision repair in Escherichia coli involves formation of the UvrB-DNA complex and subsequent DNA incisions on either site of the damage by UvrC. In this paper, we studied the incision of substrates with different damages in varying sequence contexts. We show that there is not always a correlation between the incision efficiency and the stability of the UvrB-DNA complex. Both stable and unstable UvrB-DNA complexes can be efficiently incised. However some lesions that give rise to stable UvrB-DNA complexes do result in a very low incision. We present evidence that this poor incision is due to sterical hindrance of the damage itself. In its C-terminal region UvrC contains two helix-hairpin-helix (HhH) motifs. Mutational analysis shows that these motifs constitute one functional unit, probably folded as one structural unit; the (HhH)2 domain. This (HhH)2 domain was previously shown to be important for the 5' incision on a substrate containing a (cis-Pt).GG adduct, but not for 3' incision. Here we show that, mainly depending on the sequence context of the lesion, the (HhH)2 domain can be important for 3' and/or 5' incision. We propose that the (HhH)2 domain stabilises specific DNA structures required for the two incisions, thereby contributing to the flexibility of the UvrABC repair system.

Holliday junction binding and processing by the RuvA protein of Mycoplasma pneumoniae

The RuvA, RuvB and RuvC proteins of Escherichia coli act together to process Holliday junctions formed during recombination and DNA repair. RuvA has a well-defined DNA binding surface that is sculptured specifically to accommodate a Holliday junction and allow subsequent loading of RuvB and RuvC. A negatively charged pin projecting from the centre limits binding of linear duplex DNA. The amino-acid sequences forming the pin are highly conserved. However, in certain Mycoplasma and Ureaplasma species the structure is extended by four amino acids and two acidic residues forming a crucial charge barrier are missing. We investigated the significance of these differences by analysing RuvA from Mycoplasma pneumoniae. Gel retardation and surface plasmon resonance assays revealed that this protein binds Holliday junctions and other branched DNA structures in a manner similar to E. coli RuvA. Significantly, it binds duplex DNA more readily. However it does not support branch migration mediated by E. coli RuvB and when bound to junction DNA is unable to provide a platform for stable binding of E. coli RuvC. It also fails to restore radiation resistance to an E. coli ruvA mutant. The data presented suggest that the modified pin region retains the ability to promote junction-specific DNA binding, but acts as a physical obstacle to linear duplex DNA rather than as a charge barrier. They also indicate that such an obstacle may interfere with the binding of a resolvase. Mycoplasma species may therefore process Holliday junctions via uncoupled branch migration and resolution reactions.

Mode of DNA-protein interaction between the C-terminal domain of Escherichia coli RNA polymerase alpha subunit and T7D promoter UP element

The C-terminal domain (CTD) downstream from residue 235 of Escherichia coli RNA polymerase alpha subunit is involved in recognition of the promoter UP element. Here we have demonstrated, by DNase I and hydroxyl radical mapping, the presence of two UP element subsites on the promoter D of phage T7, each located half and one-and-a-half helix turns, respectively, upstream from the promoter -35 element. This non-typical UP element retained its alphaCTD-binding capability when transferred into the genetic environment of the rrnBP1 basic promoter, leading to transcription stimulation as high as the typical rrnBP1 UP element. Chemical protease FeBABE conjugated to alphaCTD S309C efficiently attacked the T7D UP element but not the rrnBP1 UP element. After alanine scanning, most of the amino acid residues that were involved in rrnBP1 interaction were also found to be involved in T7D UP element recognition, but alanine substitution at three residues had the opposite effect on the transcription activation between rrnBP1 and T7D promoters. Mutation E286A stimulated T7D transcription but inhibited rrnBP1 RNA synthesis, while L290A and K304A stimulated transcription from rrnBP1 but not the T7D promoter. Taken together, we conclude that although the overall sets of amino acid residues responsible for interaction with the two UP elements overlap, the mode of alphaCTD interaction with T7D UP element is different from that with rrnBP1 UP element, involving different residues on helices III and IV.

Crystal structure of the fission yeast mitochondrial Holliday junction resolvase Ydc2

Resolution of Holliday junctions into separate DNA duplexes requires enzymatic cleavage of an equivalent strand from each contributing duplex at or close to the point of strand exchange. Diverse Holliday junction-resolving enzymes have been identified in bacteria, bacteriophages, archaea and pox viruses, but the only eukaryotic examples identified so far are those from fungal mitochondria. We have now determined the crystal structure of Ydc2 (also known as SpCce1), a Holliday junction resolvase from the fission yeast Schizosaccharomyces pombe that is involved in the maintenance of mitochondrial DNA. This first structure of a eukaryotic Holliday junction resolvase confirms a distant evolutionary relationship to the bacterial RuvC family, but reveals structural features which are unique to the eukaryotic enzymes. Detailed analysis of the dimeric structure suggests mechanisms for junction isomerization and communication between the two active sites, and together with site-directed mutagenesis identifies residues involved in catalysis.

UP element-dependent transcription at the Escherichia coli rrnB P1 promoter: positional requirements and role of the RNA polymerase alpha subunit linker

The UP element stimulates transcription from the rrnB P1 promoter through a direct interaction with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). We investigated the effect on transcription from rrnB P1 of varying both the location of the UP element and the length of the alpha subunit interdomain linker, separately and in combination. Displacement of the UP element by a single turn of the DNA helix resulted in a large decrease in transcription from rrnB P1, while displacement by half a turn or two turns totally abolished UP element-dependent transcription. Deletions of six or more amino acids from within the alpha subunit linker resulted in a decrease in UP element-dependent stimulation, which correlated with decreased binding of alphaCTD to the UP element. Increasing the alpha linker length was less deleterious to RNA polymerase function at rrnB P1 but did not compensate for the decrease in activation that resulted from displacing the UP element. Our results suggest that the location of the UP element at rrnB P1 is crucial to its function and that the natural length of the alpha subunit linker is optimal for utilisation of the UP element at this promoter.

Quasi-equivalence in site-specific recombinase structure and function: crystal structure and activity of trimeric Cre recombinase bound to a three-way Lox DNA junction

The crystal structure of a novel Cre-Lox synapse was solved using phases from multiple isomorphous replacement and anomalous scattering, and refined to 2.05 A resolution. In this complex, a symmetric protein trimer is bound to a Y-shaped three-way DNA junction, a marked departure from the pseudo-4-fold symmetrical tetramer associated with Cre-mediated LoxP recombination. The three-way DNA junction was accommodated by a simple kink without significant distortion of the adjoining DNA duplexes. Although the mean angle between DNA arms in the Y and X structures was similar, adjacent Cre trimer subunits rotated 29 degrees relative to those in the tetramers. This rotation was accommodated at the protein-protein and DNA-DNA interfaces by interactions that are "quasi-equivalent" to those in the tetramer, analogous to packing differences of chemically identical viral subunits at non-equivalent positions in icosahedral capsids. This structural quasi-equivalence extends to function as Cre can bind to, cleave and perform strand transfer with a three-way Lox substrate. The structure explains the dual recognition of three and four-way junctions by site-specific recombinases as being due to shared structural features between the differently branched substrates and plasticity of the protein-protein interfaces. To our knowledge, this is the first direct demonstration of quasi-equivalence in both the assembly and function of an oligomeric enzyme.

Structural analysis of DNA replication fork reversal by RecG

The stalling of DNA replication forks that occurs as a consequence of encountering DNA damage is a critical problem for cells. RecG protein is involved in the processing of stalled replication forks, and acts by reversing the fork past the damage to create a four-way junction that allows template switching and lesion bypass. We have determined the crystal structure of RecG bound to a DNA substrate that mimics a stalled replication fork. The structure not only reveals the elegant mechanism used by the protein to recognize junctions but has also trapped the protein in the initial stage of fork reversal. We propose a mechanism for how forks are processed by RecG to facilitate replication fork restart. In addition, this structure suggests that the mechanism and function of the two largest helicase superfamilies are distinct.

Dissection of the regional roles of the archaeal Holliday junction resolvase Hjc by structural and mutational analyses

Hjc is an archaeal DNA endonuclease, which resolves the Holliday junction in the presence of divalent metals. Combined with mutational analyses, the x-ray structure of the Pyrococcus furiosus Hjc crystal grown in the presence of ammonium sulfate revealed a positively charged interface, rich in conserved basic residues, and the catalytic center (Nishino, T., Komori, K., Tsuchiya, D., Ishino, Y., and Morikawa, K. (2001) Structure 9, 197-T204). This structural study also suggested that the N-terminal segment and some loops of Hjc play crucial roles in the cleavage of DNA. However, a structural view of the interaction between these regions and DNA remains elusive. To clarify the regional roles of Hjc in the recognition of the Holliday junction, further structural and biochemical analyses were carried out. A new crystal form of Hjc was obtained from a polyethylene glycol solution in the absence of ammonium sulfate, and its structure has been determined at 2.16-A resolution. A comparison of the two crystal structures has revealed that the N-terminal segment undergoes a serious conformational change. The site-directed mutagenesis of the sulfate-binding site within the segment caused a dramatic decrease in the junction binding, but the mutant was still capable of cleaving DNA with a 20-fold lower efficiency. The kinetic analysis of Hjc-Holliday junction interaction indicated that mutations in the N-terminal segment greatly increased the dissociation rate constants of the Hjc-Holliday junction complex, explaining the decreased stability of the complex. This segment is also responsible for the disruption of base pairs near the junction center, through specific interactions with them. Taken together, these results imply that, in addition to the secondary effects of two basic loops, the flexible N-terminal segment plays predominant roles in the recognition of DNA conformation near the crossover and in correct positioning of the cleavage site to the catalytic center of the Hjc resolvase.

A unique beta-hairpin protruding from AAA+ ATPase domain of RuvB motor protein is involved in the interaction with RuvA DNA recognition protein for branch migration of Holliday junctions

The Escherichia coli RuvB protein is a motor protein that forms a complex with RuvA and promotes branch migration of Holliday junctions during homologous recombination. This study describes the characteristics of two RuvB mutants, I148T and I150T, that do not promote branch migration in the presence of RuvA. These RuvB mutants hydrolyzed ATP and bound duplex DNA with the same efficiency as wild-type RuvB, but the mutants did not form a complex with RuvA and were defective in loading onto junction DNA in a RuvA-assisted manner. A recent crystallographic study revealed that Ile(148) and Ile(150) are in a unique beta-hairpin that protrudes from the AAA(+) ATPase domain of RuvB. We propose that this beta-hairpin interacts with hydrophobic residues in the mobile third domain of RuvA and that this interaction is vital for the RuvA-assisted loading of RuvB onto Holliday junction DNA.

The crystal structures of DNA Holliday junctions

Nearly 40 years ago, Holliday proposed a four-stranded complex or junction as the central intermediate in the general mechanism of genetic recombination. During the past two years, six single-crystal structures of such DNA junctions have been determined by three different research groups. These structures all essentially adopt the antiparallel stacked-X conformation, but can be classified into three distinct categories: RNA-DNA junctions; ACC trinucleotide junctions; and drug-induced junctions. Together, these structures provide insight into how local and distant interactions help to define the detailed and general physical features of Holliday junctions at the atomic level.

Crystal structure of the archaeal holliday junction resolvase Hjc and implications for DNA recognition

BACKGROUND

Homologous recombination is a crucial mechanism in determining genetic diversity and repairing damaged chromosomes. Holliday junction is the universal DNA intermediate whose interaction with proteins is one of the major events in the recombinational process. Hjc is an archaeal endonuclease, which specifically resolves the junction DNA to produce two separate recombinant DNA duplexes. The atomic structure of Hjc should clarify the mechanisms of the specific recognition with Holliday junction and the catalytic reaction.

RESULTS

The crystal structure of Hjc from the hyperthermophilic archaeon Pyrococcus furiosus has been determined at 2.0 A resolution. The active Hjc molecule forms a homodimer, where an extensive hydrophobic interface tightly assembles two subunits of a single compact domain. The folding of the Hjc subunit is clearly different from any other Holliday junction resolvases thus far known. Instead, it resembles those of type II restriction endonucleases, including the configurations of the active site residues, which constitute the canonical catalytic motifs. The dimeric Hjc molecule displays an extensive basic surface on one side, which contains many conserved amino acids, including those in the active site.

CONCLUSIONS

The architectural similarity of Hjc to restriction endonucleases allowed us to construct a putative model of the complex with Holliday junction. This model accounts for how Hjc recognizes and resolves the junction DNA in a specific manner. Mutational and biochemical analyses highlight the importance of some loops and the amino terminal region in interaction with DNA.

Fine structure of E. coli RNA polymerase-promoter interactions: alpha subunit binding to the UP element minor groove

The alpha subunit of E. coli RNAP plays an important role in the recognition of many promoters by binding to the A+T-rich UP element, a DNA sequence located upstream of the recognition elements for the sigma subunit, the -35 and -10 hexamers. We examined DNA-RNAP interactions using high resolution interference and protection footprinting methods and using the minor groove-binding drug distamycin. Our results suggest that alpha interacts with bases in the DNA minor groove and with the DNA backbone along the minor groove, but that UP element major groove surfaces do not make a significant contribution to alpha binding. On the basis of these and previous results, we propose a model in which alpha contacts UP element DNA through amino acid residues located in a pair of helix-hairpin-helix motifs. Furthermore, our experiments extend existing information about recognition of the core promoter by sigma(70) by identifying functional groups in the major grooves of the -35 and -10 hexamers in which modifications interfere with RNAP binding. These studies greatly improve the resolution of our picture of the promoter-RNAP interaction.

The X philes: structure-specific endonucleases that resolve Holliday junctions

Genetic recombination is a critical cellular process that promotes evolutionary diversity, facilitates DNA repair and underpins genome duplication. It entails the reciprocal exchange of single strands between homologous DNA duplexes to form a four-way branched intermediate commonly referred to as the Holliday junction. DNA molecules interlinked in this way have to be separated in order to allow normal chromosome transmission at cell division. This resolution reaction is mediated by structure-specific endonucleases that catalyse dual-strand incision across the point of strand cross-over. Holliday junctions can also arise at stalled replication forks by reversing the direction of fork progression and annealing of nascent strands. Resolution of junctions in this instance generates a DNA break and thus serves to initiate rather than terminate recombination. Junction resolvases are generally small, homodimeric endonucleases with a high specificity for branched DNA. They use a metal-binding pocket to co-ordinate an activated water molecule for phosphodiester bond hydrolysis. In addition, most junction endonucleases modulate the structure of the junction upon binding, and some display a preference for cleavage at specific nucleotide target sequences. Holliday junction resolvases with distinct properties have been characterized from bacteriophages (T4 endo VII, T7 endo I, RusA and Rap), Bacteria (RuvC), Archaea (Hjc and Hje), yeast (CCE1) and poxviruses (A22R). Recent studies have brought about a reappraisal of the origins of junction-specific endonucleases with the discovery that RuvC, CCE1 and A22R share a common catalytic core.

The acidic pin of RuvA modulates Holliday junction binding and processing by the RuvABC resolvasome

Holliday junctions are four-way branched DNA structures formed during recombination, replication and repair. They are processed in Escherichia coli by the RuvA, RuvB and RuvC proteins. RuvA targets the junction and facilitates loading of RuvB helicase and RuvC endonuclease to form complexes that catalyse junction branch migration (RuvAB) and resolution (RuvABC). We investigated the role of RuvA in these reactions and in particular the part played by the acidic pin located on its DNA-binding surface. By making appropriate substitutions of two key amino acids (Glu55 and Asp56), we altered the charge on the pin and investigated how this affected junction binding and processing. We show that two negative charges on each subunit of the pin are crucial. They facilitate junction targeting by preventing binding to duplex DNA and also constrain branch migration by RuvAB in a manner critical for junction processing. These findings provide the first direct evidence that RuvA has a mechanistic role in branch migration. They also provide insight into the coupling of branch migration and resolution by the RuvABC resolvasome.

Identification and characterization of Thermus thermophilus HB8 RuvA protein, the subunit of the RuvAB protein complex that promotes branch migration of Holliday junctions

The Escherichia coli ruvA and ruvB genes constitute an SOS-regulated operon. The products of these genes form a protein complex that promotes branch migration of the Holliday junction, an intermediate of homologous recombination. RuvA protein binds specifically to the Holliday junction and recruits RuvB protein to the junction. RuvB is an ATP-driven motor protein involved in branch migration. We previously cloned the ruvB gene of the thermophilic bacterium Thermus thermophilus HB8 (Tth) and found that, in contrast to the operon structure in most mesothermic bacteria, the ruvA gene is absent from the vicinity of ruvB. In this work, we cloned the ruvA gene from T. thermophilus HB8 and analyzed its nucleotide sequence. Tth RuvA is a protein of 20,414 Da consisting of 191 amino acid residues, and is 37% identical in amino acid sequence to E. coli RuvA. Tth ruvA complemented the DNA repair defect of E. coli deltaruvA mutants. The purified Tth RuvA protein stimulated Tth RuvB activities, such as hydrolysis of ATP and promotion of branch migration of the Holliday junction, in a manner similar to the RuvA-RuvB interactions observed in E. coli. In addition, Tth RuvA stimulated the E. coli RuvB activities in vitro, which was well consistent with the results of in vivo hetero-complementation experiments.