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1.
DNA segregation ensures the stable inheritance of genetic material prior to cell division. Many bacterial chromosomes and low‐copy plasmids, such as the plasmids P1 and F, employ a three‐component system to partition replicated genomes: a partition site on the DNA target, typically called parS, a partition site binding protein, typically called ParB, and a Walker‐type ATPase, typically called ParA, which also binds non‐specific DNA. In vivo, the ParA family of ATPases forms dynamic patterns over the nucleoid, but how ATP‐driven patterning is involved in partition is unknown. We reconstituted and visualized ParA‐mediated plasmid partition inside a DNA‐carpeted flowcell, which acts as an artificial nucleoid. ParA and ParB transiently bridged plasmid to the DNA carpet. ParB‐stimulated ATP hydrolysis by ParA resulted in ParA disassembly from the bridging complex and from the surrounding DNA carpet, which led to plasmid detachment. Our results support a diffusion‐ratchet model, where ParB on the plasmid chases and redistributes the ParA gradient on the nucleoid, which in turn mobilizes the plasmid.  相似文献   

2.
Bouet JY  Funnell BE 《The EMBO journal》1999,18(5):1415-1424
The partition system of P1 plasmids is composed of two proteins, ParA and ParB, and a cis-acting site parS. parS is wrapped around ParB and Escherichia coli IHF protein in a higher order nucleoprotein complex called the partition complex. ParA is an ATPase that autoregulates the expression of the par operon and has an essential but unknown function in the partition process. In this study we demonstrate a direct interaction between ParA and the P1 partition complex. The interaction was strictly dependent on ParB and ATP. The consequence of this interaction depended on the ParB concentration. At high ParB levels, ParA was recruited to the partition complex via a ParA-ParB interaction, but at low ParB levels, ParA removed or disassembled ParB from the partition complex. ADP could not support these interactions, but could promote the site-specific DNA binding activity of ParA to parOP, the operator of the par operon. Conversely, ATP could not support a stable interaction of ParA with parOP in this assay. Our data suggest that ParA-ADP is the repressor of the par operon, and ParA-ATP, by interacting with the partition complex, plays a direct role in partition. Therefore, one role of adenine nucleotide binding and hydrolysis by ParA is that of a molecular switch controlling entry into two separate pathways in which ParA plays different roles.  相似文献   

3.
L Radnedge  B Youngren  M Davis    S Austin 《The EMBO journal》1998,17(20):6076-6085
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.  相似文献   

4.
5.
The P1 plasmid prophage is faithfully partitioned by a high affinity nucleoprotein complex assembled at the centromere-like parS site. This partition complex is composed of P1 ParB and Escherichia coli integration host factor (IHF), bound specifically to parS. We have investigated the assembly of ParB at parS and its stoichiometry of binding. Measured by gel mobility shift assays, ParB and IHF bind tightly to parS and form a specific complex, called I + B1. We observed that as ParB concentration was increased, a second, larger complex (I + B2) formed, followed by the formation of larger complexes, indicating that additional ParB molecules joined the initial complex. Shift Western blotting experiments indicated that the I + B2 complex contained twice as much ParB as the I + B1 complex. Using mixtures of ParB and a larger polyhistidine-tagged version of ParB (His-ParB) in DNA binding assays, we determined that the initial I + B1 complex contains one dimer of ParB. Therefore, one dimer of ParB binds to its recognition sequences that span an IHF-directed bend in parS. Once this complex forms, a second dimer can join the complex, but this assembly requires much higher ParB concentrations.  相似文献   

6.
7.
The partition system of the P1 plasmid, P1 par consists of the ParA and ParB proteins and a cis -acting site, parS . It is responsible for the orderly segregation of plasmid copies to daughter cells. Plasmids with null mutations in parA or parB replicate normally, but missegregate. ParB binds specifically to the parS site, but the role of ParA and its ATPase activity in partition is unclear. We describe a novel class of parA mutants that cannot be established or maintained as plasmids unless complemented by the wild-type gene. One, parAM314I , is conditional: it can be maintained in cells in minimal medium but cannot be established in cells growing in L broth. The lack of plasmid propagation in L broth-grown cells was shown to be caused by a ParB-dependent activity of the mutant ParA protein that blocks plasmid propagation by an interaction at the parS site. Thus, ParA acts to modify the ParB– parS complex, probably by binding to it. Partition is thought to involve selection of pairs of plasmids before segregation, either by physical pairing of copies or by binding of copies to paired host sites. We suggest that ParA is involved in this reaction and that the mutant ParA protein forms paired complexes that cannot unpair.  相似文献   

8.
9.
The plasmid partition process is essential for plasmid propagation and is mediated by par systems, consisting of centromere-like sites and two proteins, ParA and ParB. In the first step of partition by the archetypical P1 system, ParB binds a complicated centromere-like site to form a large nucleoprotein segrosome. ParB is a dimeric DNA-binding protein that can bridge between both A-boxes and B-boxes located on the centromere. Its helix-turn-helix domains bind A-boxes and the dimer domain binds B-boxes. Binding of the first ParB dimer nucleates the remaining ParB molecules onto the centromere site, which somehow leads to the formation of a condensed segrosome superstructure. To further understand this unique DNA spreading capability of ParB, we crystallized and determined the structure of a 1:2 ParB-(142-333):A3-B2-box complex to 3.35A resolution. The structure reveals a remarkable four-way, protein-DNA bridged complex in which both ParB helix-turn-helix domains simultaneously bind adjacent A-boxes and the dimer domain bridges between two B-boxes. The multibridging capability and the novel dimer domain-B-box interaction, which juxtaposes the DNA sites close in space, suggests a mechanism for the formation of the wrapped solenoid-like segrosome superstructure. This multibridging capability of ParB is likely critical in its partition complex formation and pairing functions.  相似文献   

10.
The partition operon of P1 plasmid encodes two proteins, ParA and ParB, required for the faithful segregation of plasmid copies to daughter cells. The operon is followed by a centromere analog, parS, at which ParB binds. ParA, a weak ATPase, represses the par promoter most effectively in its ADP-bound form. ParB can recruit ParA to parS, stimulate its ATPase, and significantly stimulate the repression. We report here that parS also participates in the regulation of expression of the par genes. A single chromosomal parS was shown to augment repression of several copies of the par promoter by severalfold. The repression increase was sensitive to the levels of ParA and ParB and to their ratio. The increase may be attributable to a conformational change in ParA mediated by the parS-ParB complex, possibly acting catalytically. We also observed an in cis effect of parS which enhanced expression of parB, presumably due to a selective modulation of the mRNA level. Although ParB had been earlier found to spread into and silence genes flanking parS, silencing of the par operon by ParB spreading was not significant. Based upon analogies between partitioning and septum placement, we speculate that the regulatory switch controlled by the parS-ParB complex might be essential for partitioning itself.  相似文献   

11.
The partition system of the low-copy-number plasmid/prophage of bacteriophage P1 encodes two proteins, ParA and ParB, and contains a DNA site called parS. ParB and the Escherichia coli protein IHF bind to parS to form the partition complex, in which parS is wrapped around ParB and IHF in a precise three-dimensional conformation. Partition can be thought of as a positioning reaction; the plasmid-encoded components ensure that at least one copy of the plasmid is positioned within each new daughter cell. We have used an E. coli chromosomal partition mutant to test whether this positioning is mediated by direct plasmid-chromosomal attachment, for example, by pairing of the partition complex that forms at parS with a bacterial attachment site. The E. coli MukB protein is required for proper chromosomal positioning, so that mukB mutants generate some cells without chromosomes (anucleate cells) at each cell division. We analyzed the plasmid distribution in nucleate and anucleate mukB cells. We found that P1 plasmids are stable in mukB mutants and that they partition into both nucleate and anucleate cells. This indicates that the P1 partition complex is not used to pair plasmids with the host chromosome and that P1 plasmids must be responsible for their own proper cellular localization, presumably through host-plasmid protein-protein interactions.  相似文献   

12.
Assembly of P1 plasmid partition complexes at the partition site, parS, is nucleated by a dimer of P1 ParB and Escherichia coli integration host factor (IHF), which promotes loading of more ParB dimers and the pairing of plasmids during the cell cycle. ParB binds several copies of two distinct recognition motifs, known as A- and B-boxes, which flank a bend in parS created by IHF binding. The recent crystal structure of ParB bound to a partial parS site revealed two relatively independent DNA-binding domains and raised the question of how a dimer of ParB recognizes its complicated arrangement of recognition motifs when it loads onto the full parS site in the presence of IHF. In this study, we addressed this question by examining ParB binding activities to parS mutants containing different combinations of the A- and B-box motifs in parS. Binding was measured to linear and supercoiled DNA in electrophoretic and filter binding assays, respectively. ParB showed preferences for certain motifs that are dependent on position and on plasmid topology. In the simplest arrangement, one motif on either side of the bend was sufficient to form a complex, although affinity differed depending on the motifs. Therefore, a ParB dimer can load onto parS in different ways, so that the initial ParB-IHF-parS complex consists of a mixture of different orientations of ParB. This arrangement supports a model in which parS motifs are available for interas well as intramolecular parS recognition.  相似文献   

13.
The P1 ParB protein is required for active partition and thus stable inheritance of the plasmid prophage. ParB and the Escherichia coli protein integration host factor (IHF) participate in the assembly of a partition complex at the centromere-like site parS. In this report the role of IHF in the formation of the partition complex has been explored. First, ParB protein was purified for these studies, which revealed that ParB forms a dimer in solution. Next, the IHF binding site was mapped to a 29-base pair region within parS, including the sequence TAACTGACTGTTT (which differs from the IHF consensus in two positions). IHF induced a strong bend in the DNA at its binding site. Versions of parS which have lost or damaged the IHF binding site bound ParB with greatly reduced affinity in vitro and in vivo. Measurements of binding constants showed that IHF increased ParB affinity for the wild-type parS site by about 10,000-fold. Finally, DNA supercoiling improved ParB binding in the presence of IHF but not in its absence. These observations led to the proposal that IHF and superhelicity assist ParB by promoting its precise positioning at parS, a spatial arrangement that results in a high affinity of ParB for parS.  相似文献   

14.
The P1 plasmid partition system is responsible for segregation of daughter plasmids during division of the Escherichia coli host cell. The P1-encoded elements consist of two essential proteins, ParA and ParB, and the cis-acting incB region. The incB region determines partition-mediated incompatibility and contains the centromere-like site parS. We have isolated and purified the two proteins. ParB binds specifically to the incB region in vitro. DNase I footprinting assays place a strong binding site over the 35-bp parS sequence previously shown to be sufficient for partition when the Par proteins are supplied in trans. A weaker site lies within the incB region in sequences that are important for specifying incompatibility, but are not essential for partition. Gel band retardation assays show that a host factor binds specifically to the incB sequence. The factor strongly stimulates binding of ParB. Cutting the region at a site between the two ParB binding sites yields two fragments that can bind ParB but not host factor. Thus, information for host-factor binding lies in the region determining the specificity of plasmid incompatibility. The roles of parB and the host factor in partition and the specificity of plasmid incompatibility are discussed.  相似文献   

15.
Plasmid-partition functions of the P7 prophage   总被引:12,自引:0,他引:12  
  相似文献   

16.
Biochemical activities of the ParA partition protein of the P1 plasmid   总被引:17,自引:0,他引:17  
The unit-copy P1 plasmid depends for stability on a plasmid-encoded partition region called par, consisting of the parA and parB genes and the parS site. ParA is absolutely required for partition, but its partition-critical role is not known. Purified ParA protein is shown to possess an ATPase activity in vitro which is specifically stimulated by purified ParB protein and by DNA. ParA is responsible for regulation of expression of parA and parB, and purified ParA has an ATP-dependent, site-specific DNA binding activity which recognizes a sequence that overlaps the parA promoter. The role of the ATP-dependence of the binding activity, as well as other possible functions of the ATPase activity in partition, is discussed.  相似文献   

17.
P1par family members promote the active segregation of a variety of plasmids and plasmid prophages in gram-negative bacteria. Each has genes for ParA and ParB proteins, followed by a parS partition site. The large virulence plasmid pWR100 of Shigella flexneri contains a new P1par family member: pWR100par. Although typical parA and parB genes are present, the putative pWR100parS site is atypical in sequence and organization. However, pWR100parS promoted accurate plasmid partition in Escherichia coli when the pWR100 Par proteins were supplied. Unique BoxB hexamer motifs within parS define species specificities among previously described family members. Although substantially different from P1parS from the P1 plasmid prophage of E. coli, pWR100parS has the same BoxB sequence. As predicted, the species specificity of the two types proved identical. They also shared partition-mediated incompatibility, consistent with the proposed mechanistic link between incompatibility and species specificity. Among several informative sequence differences between pWR100parS and P1parS is the presence of a 21-bp insert at the center of the pWR100parS site. Deletion of this insert left much of the parS activity intact. Tolerance of central inserts with integral numbers of helical DNA turns reflects the critical topology of these sites, which are bent by binding the host IHF protein.  相似文献   

18.
The dynamic, mitosis-like segregation of bacterial chromosomes and plasmids often involves proteins of the ParA (ATPase) and ParB (DNA-binding protein) families. The conversion of multigenomic aerial hyphae of the mycelial organism Streptomyces coelicolor into chains of unigenomic spores requires the synchronous segregation of multiple chromosomes, providing an unusual context for chromosome segregation. Correct spatial organization of the oriC-proximal region prior to septum formation is achieved by the assembly of ParB into segregation complexes (Jakimowicz et al., 2005; J Bacteriol 187: 3572-3580). Here, we focus on the contribution of ParA to sporulation-associated chromosome segregation. Elimination of ParA strongly affects not only chromosome segregation but also septation. In wild type hyphae about to undergo sporulation, immunostained ParA was observed as a stretched double-helical filament, which accompanies the formation of ParB foci. We show that ParA mediates efficient assembly of ParB complexes in vivo and in vitro, and that ATP binding is crucial for ParA dimerization and interaction with ParB but not for ParA localization in vivo. We suggest that S. coelicolor ParA provides scaffolding for proper distribution of ParB complexes and consequently controls synchronized segregation of several dozens of chromosomes, possibly mediating a segregation and septation checkpoint.  相似文献   

19.
The segregational stability of bacterial, low-copy-number plasmids is promoted primarily by active partition. The plasmid-specified components of the prototypical P1 plasmid partition system consist of two proteins, ParA (44.3 kDa) and ParB (38.5 kDa), which, in conjunction with integration host factor, form a nucleoprotein complex at the plasmid partition site, parS. This complex is the probable substrate for the directed temporal and spatial intracellular movement of plasmids before cell division. The genetic organization of the partition cassette of the multidrug resistance plasmid TP228 differs markedly from that of the P1 paradigm. The TP228 system includes a novel member (ParF; 22.0 kDa) of the ParA superfamily of ATPases, of which the P1 ParA protein is the archetype. However, the ParF protein and its immediate relatives form a discrete subgroup of the ParA superfamily, which evolutionarily is more related to the MinD subgroup of cell division proteins than to ParA of P1. The TP228 and P1 partition modules differ further in that the former does not include a parB homologue, but does specify a protein (ParG; 8.6 kDa) unrelated to ParB. Homologues of the parF gene are widely disseminated on eubacterial genomes, suggesting that ParF-mediated partition may be a common mechanism by which plasmid segregational stability is achieved.  相似文献   

20.
DNA segregation, or partition, ensures stable genome transmission during cell division. In prokaryotes, partition is best understood for plasmids, which serve as tractable model systems to decipher the molecular underpinnings of this process. Plasmid partition is mediated by par systems, composed of three essential elements: a centromere-like site and the proteins ParA and ParB. In the first step, ParB binds the centromere to form a large segrosome. Subsequently, ParA, an ATPase, binds the segrosome and mediates plasmid separation. Recently determined ParB-centromere structures have revealed key insights into segrosome assembly, whereas ParA structures have shed light on the mechanism of plasmid separation. These structures represent important steps in elucidating the molecular details of plasmid segregation.  相似文献   

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