Crystal structure of the hexameric replicative helicase RepA of plasmid RSF1010

Unwinding of double-stranded DNA into single-stranded intermediates required for various fundamental life processes is catalyzed by helicases, a family of mono-, di- or hexameric motor proteins fueled by nucleoside triphosphate hydrolysis. The three-dimensional crystal structure of the hexameric helicase RepA encoded by plasmid RSF1010 has been determined by X-ray diffraction at 2.4 A resolution. The hexamer shows an annular structure with 6-fold rotational symmetry and a approximately 17 A wide central hole, suggesting that single-stranded DNA may be threaded during unwinding. Homologs of all five conserved sequence motifs of the DnaB-like helicase family are found in RepA, and the topography of the monomer resembles RecA and the helicase domain of the bacteriophage T7 gp4 protein. In a modeled complex, ATP molecules are located at the subunit interfaces and clearly define adenine-binding and ATPase catalytic sites formed by amino acid residues located on adjacent monomers; most remarkable is the "arginine finger" Arg207 contributing to the active site in the adjacent monomer. This arrangement of active-site residues suggests cooperativity between monomers in ATP hydrolysis and helicase activity of RepA. The mechanism of DNA unwinding remains elusive, as RepA is 6-fold symmetric, contrasting the recently published asymmetric structure of the bacteriophage T7 gp4 helicase domain.     

Binding of six nucleotide cofactors to the hexameric helicase RepA protein of plasmid RSF1010. 2. Base specificity, nucleotide structure, magnesium, and salt effect on the cooperative binding of the cofactors

Interactions of the RepA hexameric helicase with nucleotide cofactors have been examined using nucleotide analogues, TNP-ADP and TNP-ATP, and unmodified nucleotides. Thermodynamic parameters for the interactions of modified and unmodified nucleotides have been obtained using quantitative fluorescence titration and competition titration methods. The intrinsic binding constant of ATP is by a factor of approximately 10 and approximately 1000 higher than the value observed for ADP and PO(4)(-). The data suggest that helicase acquires free-energy transducing capabilities when associated with the ssDNA, thus, forming a "holoenzyme". ATP binding is characterized by significantly stronger negative cooperativity than ADP. The cooperative interactions are predominantly induced through the specific interactions of the gamma phosphate and the ribose with the protein. The salt effect on cofactor binding indicates a very different nature of the intrinsic and cooperative interactions. Surprisingly, binding of Mg(2+), to both the cofactor and helicase, predominantly controls the ADP-RepA interactions. Mg(2+) cations seem to play a role in affecting the distribution of high and low ssDNA-affinity states, through the strong effect on the diphosphate versus triphosphate binding. The data indicate that Mg(2+) has a dual function in nucleotide-helicase interactions. At low [Mg(2+)], NTP binds stronger than NDP and the enzyme is predominantly in the high ssDNA-affinity state. At higher [Mg(2+)], NTP binds weaker than NDP and the helicase subunits can exist in alternating low- and high-affinity states that facilitate the efficient dsDNA unwinding. The RepA helicase shows a preference toward purine nucleotides. The cooperative interactions are independent of the type of the base.     

Interactions of the RepA helicase hexamer of plasmid RSF1010 with the ssDNA. Quantitative analysis of stoichiometries, intrinsic affinities, cooperativities, and heterogeneity of the total ssDNA-binding site

Interactions between the replicative RepA helicase hexamer of plasmid RSF1010 with the single-stranded DNA (ssDNA) have been studied, using the quantitative fluorescence titration, analytical sedimentation velocity, and sedimentation equilibrium techniques. Experiments were performed with fluorescein-labeled ssDNA oligomers. Studies with unmodified ssDNA oligomers were accomplished using the macromolecular competition titration method. Analyses of RepA helicase interactions with a series of the ssDNA provide direct evidence that the total site-size of the RepA hexamer-ssDNA complex is 19 +/- 1 nucleotide residues. The total ssDNA-binding site of the hexamer has a heterogeneous structure. Part of the total binding site constitutes the proper ssDNA-binding site of the enzyme, an area that possesses strong ssDNA-binding capability and encompasses only 8 +/- 1 residues of the ssDNA. The statistical effect on the macroscopic binding constant for the proper ssDNA-binding site indicates that it is structurally separated from the remaining part of the total ssDNA-binding site. Engagement in interactions with the ssDNA is accompanied by net ion release. Moreover, the proper ssDNA-binding site shows little base specificity. On the other hand, with long ssDNA oligomers, the entire total ssDNA-binding site of the RepA hexamer engages in interactions with the ssDNA resulting in a dramatic change in the nature of interactions with the nucleic acid. The association includes an uptake of ions by the protein. Moreover, unlike the proper-ssDNA-binding site, the total binding site shows a significant preference for pyrimidine oligomers. In this aspect, the RepA helicase is different from the Escherichia coli DnaB hexamer that shows large preference for purine homo-oligomers. In similar solution conditions, the ssDNA intrinsic affinity of the RepA hexamer is similar to the intrinsic affinity of the DnaB helicase. The RepA helicase binds to ssDNA oligomers that can accept more than one RepA hexamer with significant positive cooperative interactions.     

Hexameric RSF1010 helicase RepA: the structural and functional importance of single amino acid residues

In the known monoclinic crystals the 3-dimensional structure of the hexameric, replicative helicase RepA encoded by plasmid RSF1010 shows 6-fold rotational symmetry. In contrast, in the cubic crystal form at 2.55 Å resolution described here RepA has 3-fold symmetry and consists of a trimer of dimers. To study structure–function relationships, a series of repA deletion mutants and mutations yielding single amino acid exchanges were constructed and the respective gene products were analyzed in vivo and in vitro. Hexamerization of RepA occurs via the N-terminus and is required for NTP hydrolysis. The C-terminus is essential both for the interaction with the replication machinery and for the helicase activity. Functional analyses of RepA variants with single amino acid exchanges confirmed most of the predictions that were based on the published 3-dimensional structure. Of the five motifs conserved in family 4 helicases, all residues conserved in RepA and T7 gp4 helicases participate in DNA unwinding. Residues K42, E76, D77, D139 and H178, proposed to play key roles in catalyzing the hydrolysis of NTPs, are essential for RepA activity. Residue H178 of motif H3 couples nucleotide consumption to DNA strand separation.     

Complete nucleotide sequence and gene organization of the broad-host-range plasmid RSF1010

We present the complete nucleotide sequence of RSF1010, a naturally occurring broad-host-range plasmid belonging to the Escherichia coli incompatibility group Q and encoding resistance to streptomycin and sulfonamides. A molecule of RSF1010 DNA consists of 8684 bp and has a G + C content of 61%. Analysis of the distribution of translation start and stop codons in the sequence has revealed the existence of more than 40 open reading frames potentially capable of encoding polypeptides of 60 or more amino acids. To date, products of eleven such potential RSF1010 genes have been identified through the application of controlled expression vector systems, and for eight of them, the reading frame has been confirmed by N- and/or C-terminal amino acid sequence determinations on the purified proteins. The sequencing results are discussed in relation to the systems of replication, host range, conjugal mobilization and antibiotic resistance determinants associated with the RSF1010 plasmid.     

Multiple global conformational states of the hexameric RepA helicase of plasmid RSF1010 with different ssDNA-binding capabilities are induced by different numbers of bound nucleotides. Analytical ultracentrifugation and dynamic light scattering studies

Global conformational transitions of the hexameric RepA helicase of plasmid RSF1010, induced by the nucleoside tri and di-phosphate binding, have been examined using analytical ultracentrifugation and dynamic light scattering techniques. The global structure of the RepA hexamer in solution, modeled as an oblate ellipsoid of revolution, is very different from its crystal structure, with the axial ratio of the ellipsoid being ∼4.5 as compared to only ∼2.4 in the crystal structure. The large axial ratio and the experimentally determined partial specific volume strongly suggest that, in solution, the diameter of the cross-channel of the hexamer is larger than ∼17 Å seen in the crystal. The global conformation of the helicase is modulated by a specific number of bound nucleotides. The enzyme exists in at least four conformational states, occurring sequentially as a function of the number of bound cofactors. These conformational states are different for ADP, as compared to β,γ-imidoadenosine 5′-triphosphate (AMP-PNP). Modulation of the global structure is separated into two phases, different for complexes with up to three bound nucleotides, from the effect observed at the saturating level of cofactors. This heterogeneity indicates different functional roles of the two modulation processes. Nucleotide control of helicase - single-stranded (ss)DNA interactions occurs through affecting the enzyme structure and the ssDNA affinity prior to DNA binding. Only one conformational state of the helicase, with two AMP-PNP molecules bound, has dramatically higher ssDNA-affinities than the complexes with ADP. Moreover the same state also has an increased site-size of the enzyme - ssDNA complexes. The implications of these findings for functional activities of a hexameric helicase are discussed.     

Plasmid RSF1010 DNA replication in vitro promoted by purified RSF1010 RepA, RepB and RepC proteins.

We have constructed and analyzed an in vitro system that will efficiently replicate plasmid RSF1010 and its derivatives. The system contains a partially purified extract from E.coli cells and three purified RSF1010-encoded proteins, the products of genes repA, repB (or mobA/repB), and repC. Replication in this system mimics the in vivo mechanism in that it (i) is initiated at oriV, the origin of vegetative DNA replication, (ii) proceeds in a population of plasmid molecules in both directions from this 396-base-pair origin region, and (iii) is absolutely dependent on the presence of each of the three rep gene products. In addition, we find that E.coli DNA gyrase, DnaZ protein (gamma subunit of poIIII holoenzyme) and SSB are required for in vitro plasmid synthesis. The bacterial RNA polymerase, the initiation protein DnaA, and the primosomal proteins DnaB, DnaC, DnaG and DnaT are not required. Furthermore, the replicative intermediates seen in the electron microscope suggest that replication in vitro begins with the simultaneous or non-simultaneous formation of two displacement loops that expand for a short stretch of DNA toward each other, and form a theta-type structure when the two displacing strands pass each other.     

Dynamics of the ssDNA Recognition by the RepA Hexameric Helicase of Plasmid RSF1010: Analyses Using Fluorescence Stopped-Flow Intensity and Anisotropy Methods

The kinetic mechanism of the single-stranded DNA (ssDNA) recognition by the RepA hexameric replicative helicase of the plasmid RSF1010 and the nature of formed intermediates, in the presence of the ATP nonhydrolyzable analog, β,γ-imidoadenosine-5′-triphosphate (AMP-PNP), have been examined, using the fluorescence intensity and anisotropy stopped-flow and analytical ultracentrifugation methods. Association of the RepA hexamer with the ssDNA oligomers that engage the total DNA-binding site and exclusively the strong DNA-binding subsite is a minimum four-step mechanism

     

质粒RSF1010寄主范围特性的遗传学分析

采用Tn5插入诱变、限制性核酸内切酶作图以及DNA转化等方法,对广泛寄主范围型质粒SF 1010的衍生体－pKT 2 40进行研究。证实质粒的寄主围决定于它在遗传背景不同的寄主中复制并保存自身的能力,而repA,rcpB和repC基因为该质拉复制所必需。     

A relative of the broad-host-range plasmid RSF1010 detected in Erwinia amylovora.

Streptomycin- and sulfonamide-resistant Erwinia amylovora CA3R from California contained an 8.7-kb plasmid, pEa8.7, with a sulII-strA-strB resistance region; furthermore, PCR, sequencing, hybridization, and restriction analyses showed that pEa8.7 was closely related or identical to broad-host-range plasmid RSF1010. Although RSF1010 has been found in a variety of bacteria, this is the first report of its presence in plant pathogenic bacteria.     

Replication of the nonconjugative plasmid RSF1010 in Escherichia coli K-12.

Replicating DNA molecules of the nonconjugative R plasmid RSF1010 (Smr Sur) were cleaved with the EcoRI restriction endonuclease and examined with the electron microscope. Results of this analysis indicated that replication is initiated from an origin located at about 19% of total genome size from one of the EcoRI ends. Replication proceeded either unidirectionally or bidirectionally with equal frequency. Results of the analysis of replicative intermediates of RSF1010 containing the Apr-transposable sequence (Tn) are also presented.     

Interactions of the Escherichia coli DnaB helicase hexamer with the replication factor the DnaC protein. Effect of nucleotide cofactors and the ssDNA on protein-protein interactions and the topology of the complex

Quantitative studies of interactions between the Escherichia coli replication factor DnaC protein and the DnaB helicase have been performed using sedimentation velocity and fluorescence energy transfer techniques. The applied novel analysis of the sedimentation data allows us to construct thermodynamic rigorous binding isotherms without any assumption as to the relationship between the observed molecular property of the complexes formed, the average sedimentation coefficient, or the degree of binding. Experiments have been performed with the fluorescein-modified DnaB helicase, which allows an exclusive monitoring of the DnaB-DnaC complex formation. The DnaC binding to the unmodified helicase has been characterized in competition experiments. The data establish that, in the presence of the ATP analog AMP-PNP, or ADP, a maximum of six DnaC monomers bind cooperatively to the DnaB hexamer. The positive cooperative interactions are limited to the two neighboring DnaC molecules. Analyses using a statistical thermodynamic hexagon model indicate that, under the solution conditions examined, the affinity is characterized by the intrinsic binding constant K=1.4(+/-0.5)x10(5)M(-1) and cooperativity parameter sigma=21+/-5. These data suggest strongly that the DnaC-DnaB complex exists in vivo as a mixture of complexes with a different number of bound DnaC molecules, although the complex with six DnaC molecules bound dominates the distribution. The DnaC nucleotide-binding site is not involved in the stabilization of the complex. Moreover, the hydrolysis of NTP bound to the helicase or the DnaC is not required for the release of the DnaC protein from the complex. The single-stranded DNA (ssDNA) bound to the helicase does not affect the DnaC protein binding. However, in the presence of the DNA, there is a significant difference in the energetics and structure of the ternary complex, DnaC-DnaB-ssDNA, formed in the presence of AMP-PNP as compared to ADP. The topology of the ternary complex DnaC-DnaB-ssDNA has been determined using the fluorescence energy transfer method. In solution, the DnaC protein-binding site is located on the large 33 kDa domain of the DnaB helicase. The significance of the results in the functioning of the DnaB helicase-DnaC protein complex is discussed.     

Two single-strand DNA initiation signals located in the oriV region of plasmid RSF1010

Two single-strand initiation signals (ssi) are found in the oriV region of broad-host-range plasmid RSF1010, using a plaque assay system with a mutant M13 phage which lacks the greater part of the complementary DNA strand origin (oric). These two signals, designated ssiA and ssiB, have RSF1010-specific properties, because they require one or more RSF1010-specific factors provided in trans. The functional activity of ssiA is higher than that of ssiB. The two signals are located on separate DNA strands, so that the DNA chain elongations initiated from them in the opposite directions may pass each other. It is conceivable that these signals, ssiA and ssiB, direct DNA priming functions at the initiation stage in vegetative DNA replication of RSF1010.     

The interaction of RepC initiator with iterons in the replication of the broad host-range plasmid RSF1010.

The replication origin of the broad host-range plasmid RSF1010 contains 3.5 copies of a 20mer iteron sequence that bind specifically to the plasmid-encoded initiator, RepC. Here we demonstrated that even a single iteron was bent upon binding of RepC. Moreover, the bending angle seems to become larger along with the increment of the number of iterons. In a mutational analysis of the iteron sequence, we isolated seven kinds of base-substitution mutants of iterons, and estimated the replication activity of these mutants in vivo. We found that each of the subsections in the 20mer iteron sequence made a distinct contribution to the initiation of RSF1010 DNA replication. With the binding assay of RepC and mutated iterons in vitro, we found that the formation of a productive RepC-iteron complex was required for the initiation of plasmid DNA replication.     

Transfer of the broad-host-range IncQ plasmid RSF1010 and other plasmid vectors to the Gram-positive methylotroph Brevibacterium methylicum by electrotransformation

Gram-positive facultative methylotrophic coryneform bacterium Brevibacterium methylicum was efficiently transformed with various plasmids using electroporation of intact cells. In addition to the plasmid vectors pEC71 and pZ6-1 constructed on the basis of cryptic plasmids from coryneform bacteria, broad-host-range plasmids pLS5 (derivative of plasmid pMV158 from Streptococcus agalactiae) and RSF1010 belonging to the incompatibility group IncQ from Gram-negative bacteria were found to be present as autonomous structurally unchanged DNA molecules in B. methylicum transformants. With the exception of pZ6-1, all these plasmids were stably maintained in B. methylicum cells grown under non-selective conditions. When plasmid DNAs isolated from B. methylicum were used, the highest efficiency of transformation (10⁵ transformants/g DNA) was achieved. Correspondence to: J. Nevera     

Interactions of Escherichia coli primary replicative helicase DnaB protein with nucleotide cofactors.

Interactions between the Escherichia coli primary replicative helicase DnaB protein and nucleotide cofactors have been studied using several fluorescent nucleotide analogs and unmodified nucleotides. The thermodynamically rigorous fluorescent titration technique has been used to obtain true binding isotherms, independently of the assumptions of any relationships between the observed quenching of protein fluorescence and the degree of nucleotide binding. Fluorescence titrations using several MANT derivatives of nucleoside diphosphates (MANT-ADP, 3',2'-O-(N-methylantraniloyl)adenosine-5'-diphosphate; MANT-GDP, 3',2'-O(N-methylantraniloyl)guanosine-5'-diphosphate; MANT-CDP, 3',2'-O-(N-methylantraniloyl)cytidine-5'-diphosphate; MANT-UDP, 3',2'-O-(N-methylantraniloyl)uridine-5'-diphosphate) have shown that the DnaB helicase has a preference for purine nucleotides. Binding of all modified nucleotides is characterized by similar negative cooperativity, indicating that negative cooperative interactions are base-independent. Thermodynamic parameters for the interactions of the unmodified nucleotides (ADP, GDP, CDP, and UDP) and inorganic phosphate (P(i)) have been obtained by using the competition titration approach. To analyze multiple ligand binding to a finite circular lattice, for a general case in which each lattice binding site can exist in different multiple states, we developed a matrix method approach to derive analytical expressions for the partition function and the average degree of binding for such cases. Application of the theory to competition titrations has allowed us to extract the intrinsic binding constants and cooperativity parameters for all unmodified ligands. This is the first quantitative estimate of affinities and the mechanisms of binding of different unmodified nucleotides and inorganic phosphate for a hexameric helicase. The intrinsic affinities of all of the studied ATP analogs are lower than the intrinsic affinities of the corresponding ADP analogs. The implications of these results for the mechanism of helicase action are discussed.