Structural analysis of the ParR/parC plasmid partition complex

Accurate DNA partition at cell division is vital to all living organisms. In bacteria, this process can involve partition loci, which are found on both chromosomes and plasmids. The initial step in Escherichia coli plasmid R1 partition involves the formation of a partition complex between the DNA-binding protein ParR and its cognate centromere site parC on the DNA. The partition complex is recognized by a second partition protein, the actin-like ATPase ParM, which forms filaments required for the active bidirectional movement of DNA replicates. Here, we present the 2.8 A crystal structure of ParR from E. coli plasmid pB171. ParR forms a tight dimer resembling a large family of dimeric ribbon-helix-helix (RHH)2 site-specific DNA-binding proteins. Crystallographic and electron microscopic data further indicate that ParR dimers assemble into a helix structure with DNA-binding sites facing outward. Genetic and biochemical experiments support a structural arrangement in which the centromere-like parC DNA is wrapped around a ParR protein scaffold. This structure holds implications for how ParM polymerization drives active DNA transport during plasmid partition.     

Involvement of transposable elements in the formation of hybrid phages between bacteriophage P1 and the R plasmid NR1

Homologous recombination between IS1 elements present on both replicons, P1 and NR1, resulted in P1-NR1 cointegrates and P1-RTF and P1-r-det phages. Cointegration between P1 and NR1-B, and NR1 derivative with multiple DNA rearrangements including insertion of the transposable element γδ, was also mediated by reciprocal recombination in IS1 sequences. However, all 4 hybrids studied carried deletions promoted by γδ residing on NR1-B. Further IS1-mediated deletions on the hybrid genomes resulted in plaque-forming P1Cm phages.     

Mechanisms involved in the formation of plaque-forming derivatives from over-sized hybrid phages between bacteriophage P1 and the R plasmid NR1

Three case histories document how subsequent events of genomic rearrangements and selection interplay in the evolution of infectious bacteriophage genomes carrying acquired genes. Two of the phages studied were plaque-forming P1CmTc recombinants derived from P1Cm1 and P1Tc1, both of which are hybrids between phage P1 and the R plasmid NR1. In the formation of the P1CmTc4 genome a postulated intermediate underwent IS1-mediated deletion formation. From the same intermediate P1CmTc1 must have evolved by IS1-mediated inversion followed by homologous recombination with a parental phage DNA. The third case documents formation of the P1Cm2 genome by “illegitimate” intramolecular recombination in the genome of P1-r-det, a hybrid between P1 and NR1.     

Probing the structure of complex macromolecular interactions by homolog specificity scanning: the P1 and P7 plasmid partition systems.

The P1 plasmid partition locus, P1 par, actively distributes plasmid copies to Escherichia coli daughter cells. It encodes two DNA sites and two proteins, ParA and ParB. Plasmid P7 uses a similar system, but the key macromolecular interactions are species specific. Homolog specificity scanning (HSS) exploits such specificities to map critical contact points between component macromolecules. The ParA protein contacts the par operon operator for operon autoregulation, and the ParB contacts the parS partition site during partition. Here, we refine the mapping of these contacts and extend the use of HSS to map protein-protein contacts. We found that ParB participates in autoregulation at the operator site by making a specific contact with ParA. Similarly, ParA acts in partition by making a specific contact with ParB bound at parS. Both these interactions involve contacts between a C-terminal region of ParA and the extreme N-terminus of ParB. As a single type of ParA-ParB complex appears to be involved in recognizing both DNA sites, the operator and the parS sites may both be occupied by a single protein complex during partition. The general HSS strategy may aid in solving the three-dimensional structures of large complexes of macromolecules.     

Bacterial actin: architecture of the ParMRC plasmid DNA partitioning complex

The R1 plasmid employs ATP-driven polymerisation of the actin-like protein ParM to move newly replicated DNA to opposite poles of a bacterial cell. This process is essential for ensuring accurate segregation of the low-copy number plasmid and is the best characterised example of DNA partitioning in prokaryotes. In vivo, ParM only forms long filaments when capped at both ends by attachment to a centromere-like region parC, through a small DNA-binding protein ParR. Here, we present biochemical and electron microscopy data leading to a model for the mechanism by which ParR-parC complexes bind and stabilise elongating ParM filaments. We propose that the open ring formed by oligomeric ParR dimers with parC DNA wrapped around acts as a rigid clamp, which holds the end of elongating ParM filaments while allowing entry of new ATP-bound monomers. We propose a processive mechanism by which cycles of ATP hydrolysis in polymerising ParM drives movement of ParR-bound parC DNA. Importantly, our model predicts that each pair of plasmids will be driven apart in the cell by just a single double helical ParM filament.     

Partitioning of the F plasmid: Overproduction of an essential protein for partition inhibits plasmid maintenance

Summary Multicopy plasmids carrying the sopB gene of the F plasmid inhibit stable inheritance of a coexisting mini-F plasmid. This incompatibility, termed IncG, is found to be caused by excess amounts of the SopB protein, which is essential for accuratepartitioning of plasmid DNA molecules into daughter cells. A sopB-carrying multicopy plasmid that shows the IncG⁺ phenotype was mutagenized in vitro and IncG negative mutant plasmids were isolated. Among these amber and missense mutants of sopB, mutants with a low plasmid copy number and a mutant in the Shine-Dalgarno sequence for translation of the SopB protein were obtained. These results demonstrate that the IncG phenotype is caused by the SopB protein, and that the incompatibility is expressed only when the protein is overproduced. This suggests that the protein must be kept at appropriate concentrations to ensure stable maintenance of the plasmid.     

Molecular Analysis of pSK1 par: A Novel Plasmid Partitioning System Encoded by Staphylococcal Multiresistance Plasmids

The segregation of prokaryotic plasmids typically requires a centromere-like site and two proteins, a centromere-binding protein (CBP) and an NTPase. By contrast, a single 245 residue Par protein mediates partition of the prototypical staphylococcal multiresistance plasmid pSK1 in the absence of an identifiable NTPase component. To gain insight into centromere binding by pSK1 Par and its segregation function we performed structural, biochemical and in vivo studies. Here we show that pSK1 Par binds a centromere consisting of seven repeat elements. We demonstrate this Par-centromere interaction also mediates Par autoregulation. To elucidate the Par centromere binding mechanism, we obtained a structure of the Par N-terminal DNA-binding domain bound to centromere DNA to 2.25 Å. The pSK1 Par structure, which harbors a winged-helix-turn-helix (wHTH), is distinct from other plasmid CBP structures but shows homology to the B. subtilis chromosome segregation protein, RacA. Biochemical studies suggest the region C-terminal to the Par wHTH forms coiled coils and mediates oligomerization. Fluorescence microscopy analyses show that pSK1 Par enhances the separation of plasmids from clusters, driving effective segregation upon cell division. Combined the data provide insight into the molecular properties of a single protein partition system.     

Mapping of functional domains in F plasmid partition proteins reveals a bipartite SopB-recognition domain in SopA

Active partition of the F plasmid to dividing daughter cells is assured by interactions between proteins SopA and SopB, and a centromere, sopC. A close homologue of the sop operon is present in the linear prophage N15 and, together with sopC-like sequences, it ensures stability of this replicon. We have exploited this sequence similarity to construct hybrid sop operons with the aim of locating specific interaction determinants within the SopA and SopB proteins that are needed for partition function and for autoregulation of sopAB expression. Centromere binding was found to be specified entirely by a central 25 residue region of SopB strongly predicted to form a helix-turn-helix structure. SopB protein also carries a species-specific SopA-interaction determinant within its N-terminal 45 amino acids, and, as shown by Escherichia coli two-hybrid analysis, a dimerization domain within its C-terminal 75 (F) or 97 (N15) residues. Promoter-operator binding specificity was located within an N-terminal 66 residue region of SopA, which is predicted to contain a helix-turn-helix motif. Two other regions of SopA protein, one next to the ATPase Walker A-box, the other C-terminal, specify interaction with SopB. Yeast two-hybrid analysis indicated that these regions contact SopB directly. Evidence for the involvement of the SopA N terminus in autoinhibition of SopA function was obtained, revealing a possible new aspect of the role of SopB in SopA activation.     

Studies with RP1 deletion plasmids: Incompatibility properties,plasmid curing and the spontaneous loss of resistance

Four deletion plasmids, pHH301, pHH302, pHH303 and pHH401, obtained from RP1 DNA-transformed bacterial clones, were shown to be incompatible with three P plasmids inEscherichia coli K12 strains. Kinetic experiments and colony tests were used to verify the position of these R plasmids.Pseudomonas aeruginosa andE. coli strains, harbouring deletion plasmids, could be cured by using two mutagens, acriflavine and mitomycin C, which affect a percentage of the cell population. The deletion plasmid-positive strains could also be induced at an elevated temperature to spontaneously loose their plasmids.     

The DNA binding domains of P1 ParB and the architecture of the P1 plasmid partition complex

Stable maintenance of P1 plasmids in Escherichia coli is mediated by a high affinity nucleoprotein complex called the partition complex, which consists of ParB and the E. coli integration host factor (IHF) bound specifically to the P1 parS site. IHF strongly stimulates ParB binding to parS, and the minimal partition complex contains a single dimer of ParB. To examine the architecture of the partition complex, we have investigated the DNA binding activity of various ParB fragments. Gel mobility shift and DNase I protection assays showed that the first 141 residues of ParB are dispensable for the formation of the minimal, high affinity partition complex. A fragment missing only the last 16 amino acids of ParB bound specifically to parS, but binding was weak and was no longer stimulated by IHF. The ability of IHF to stimulate ParB binding to parS correlated with the ability of ParB to dimerize via its C terminus. Using full and partial parS sites, we show that two regions of ParB, one in the center and the other near the C terminus of the protein, interact with distinct sequences within parS. Based on these data, we have proposed a model of how the ParB dimer binds parS to form the minimal partition complex.     

Adenosine monophosphate-induced amplification of ColE1 plasmid DNA in Escherichia coli

ColE1 plasmid copy number was analyzed in relaxed (relA) and stringent (relA(+)) Escherichia coli cells after supplementation of culture media with adenosine monophosphate (AMP). When a relaxed E. coli strain bearing ColE1 plasmid was cultured in LB medium for 18 h and induced with AMP for 4h, the plasmid DNA yield was significantly increased, from 2.6 to 16.4 mgl(-1). However no AMP-induced amplification of ColE1 plasmid DNA was observed in the stringent host. Some plasmid amplification was observed in relA mutant cultures in the presence of adenosine, while adenine, ADP, ATP, ribose, potassium pyrophosphate and sodium phosphate caused a minor, if any, increase in ColE1 copy number. A mechanism for amplification of ColE1 plasmid DNA with AMP in relA mutant bacteria is suggested, in which AMP interferes with the aminoacylation of tRNAs, increases the abundance of uncharged tRNAs, and uncharged tRNAs promote plasmid DNA replication. According to this proposal, in relA(+) cells, the AMP induction could not increase ColE1 plasmid copy number because of lower abundance of uncharged tRNAs. Our results suggest that the induction with AMP can be used as an effective method of amplification of ColE1 plasmid DNA in relaxed strains of E. coli.     

Sphingosine 1-Phosphate (S1P) Receptors 1 and 2 Coordinately Induce Mesenchymal Cell Migration through S1P Activation of Complementary Kinase Pathways

Normal bone turnover requires tight coupling of bone resorption and bone formation to preserve bone quantity and structure. With aging and during several pathological conditions, this coupling breaks down, leading to either net bone loss or excess bone formation. To preserve or restore normal bone metabolism, it is crucial to determine the mechanisms by which osteoclasts and osteoblast precursors interact and contribute to coupling. We showed that osteoclasts produce the chemokine sphingosine 1-phosphate (S1P), which stimulates osteoblast migration. Thus, osteoclast-derived S1P may recruit osteoblasts to sites of bone resorption as an initial step in replacing lost bone. In this study we investigated the mechanisms by which S1P stimulates mesenchymal (skeletal) cell chemotaxis. S1P treatment of mesenchymal (skeletal) cells activated RhoA GTPase, but this small G protein did not contribute to migration. Rather, two S1P receptors, S1PR1 and S1PR2, coordinately promoted migration through activation of the JAK/STAT3 and FAK/PI3K/AKT signaling pathways, respectively. These data demonstrate that the chemokine S1P couples bone formation to bone resorption through activation of kinase signaling pathways.     

Function of the loop residue Thr792 in human DNA topoisomerase II alpha

We studied the mutation effect of one of the putative loop residues Thr792 in human DNA topoisomerase II alpha (TOP2 alpha). Thr792 mutants were expressed from high or low copy plasmids in a temperature sensitive yeast strain deficient in TOP2 (top2-1). When expressed from a high copy plasmid, mutants with small side chains complemented the yeast defect; however, from a low copy plasmid, only wild-type, Ser, and Cys substitution mutants complemented the yeast defect. Interestingly, at the permissive temperature other mutants (e.g., Val, Gly, and Glu substitutions) showed the dominant negative effect to the top2-1 allele, which was not observed by the control alpha 4-helix mutants. T792E mutant was 10-fold less active than wild-type and the T792P had no decatenation activity in vitro. These results suggest that Thr792 in human TOP2 alpha is involved in enzyme catalysis.     

The uvp1 gene of plasmid pR cooperates with mucAB genes in the DNA repair process

Summary We show that a DNA fragment that contains the uvp1 gene of the plasmid pR directs the synthesis in Escherichia coli minicells of a protein of apparent molecular weight 20 kDa. Inspection of the nucleotide sequence of the region reveals an open reading frame that has the capacity to encode a protein of 198 amino acids. The uvp1 gene product has been found, in two different systems, to enhance the recombination activity of E. coli cells. We have also observed a striking similarity to resolvase and invertase proteins. The significance of this finding for the function of the uvp1 gene product requires further investigation. We conclude that the uvp1 gene encodes a 20 kDa protein which appears to be responsible for enhancement of both UV survival and recominational activity in E. coli.