Gyrase inhibitors and thymine starvation disrupt the normal pattern of plasmid RK2 localization in Escherichia coli

Multicopy plasmids in Escherichia coli are not randomly distributed throughout the cell but exist as defined clusters that are localized at the mid-cell, or at the 1/4 and 3/4 cell length positions. To explore the factors that contribute to plasmid clustering and localization, E. coli cells carrying a plasmid RK2 derivative that can be tagged with a green fluorescent protein-LacI fusion protein were subjected to various conditions that interfere with plasmid superhelicity and/or DNA replication. The various treatments included thymine starvation and the addition of the gyrase inhibitors nalidixic acid and novobiocin. In each case, localization of plasmid clusters at the preferred positions was disrupted but the plasmids remained in clusters, suggesting that normal plasmid superhelicity and DNA synthesis in elongating cells are not required for the clustering of individual plasmid molecules. It was also observed that the inhibition of DNA replication by these treatments produced filaments in which the plasmid clusters were confined to one or two nucleoid bodies, which were located near the midline of the filament and were not evenly spaced throughout the filament, as is found in cells treated with cephalexin. Finally, the enhanced yellow fluorescent protein-RarA fusion protein was used to localize the replication complex in individual E. coli cells. Novobiocin and nalidixic acid treatment both resulted in rapid loss of RarA foci. Under these conditions the RK2 plasmid clusters were not disassembled, suggesting that a completely intact replication complex is not required for plasmid clustering.     

The incC korB region of RK2 repositions a mini-RK2 replicon in Escherichia coli

Analysis by fluorescence microscopy has established that plasmid RK2 in Escherichia coli and other gram-negative bacteria is present as discrete clusters that are located inside the nucleoid at the mid- or quarter-cell positions. A mini-RK2 replicon containing an array of tetO repeats was visualized in E. coli cells that express a TetR-EYFP fusion protein. Unlike intact RK2, the RK2 mini-replicon (pCV1) was localized as a cluster at the cell poles outside of the nucleoid. Insertion of the O(B1)incC korB partitioning (par) region of RK2 into pCV1 resulted in a shift of the mini-replicon to within the nucleoid region at the mid- and quarter-cell positions. Despite the repositioning of the mini-RK2 replicon to the cellular positions where intact RK2 is normally located, the insertion of the intact O(B1) incC korB region did not significantly stabilize the mini-RK2 plasmid during cell growth. Deletions within the O(B1)incC or the korB region resulted in a failure of this par region to move pCV1 out of its polar position. The insertion of the par system of plasmid F into pCV1 resulted in a similar shift in the location of pCV1 to the nucleoid region. Unlike O(B1)incC korB, the insertion of the RK2 parABC resolvase system into pCV1 did not affect the polar positioning of pCV1. This effect of O(B1)incC korB on the location of pCV1 provides additional evidence for a partitioning role of this region of plasmid RK2. However, the failure of this region to significantly increase the stability of the mini-RK2 plasmid indicates that the localization of the plasmid to the mid- and quarter cell positions in E. coli is not in itself sufficient for the stable maintenance of plasmid RK2.     

Compatible bacterial plasmids are targeted to independent cellular locations in Escherichia coli

Targeting of DNA molecules to specific subcellular positions is essential for efficient segregation, but the mechanisms underlying these processes are poorly understood. In Escherichia coli, several plasmids belonging to different incompatibility groups (F, P1 and RK2) localize preferentially near the midcell and quartercell positions. Here we compare the relative positions of these three plasmids using fluorescence in situ hybridization. When plasmids F and P1 were localized simultaneously using differentially labeled probes, the majority of foci (approximately 75%) were well separated from each other. Similar results were found when we compared the subcellular localization of F with RK2, and RK2 with P1: regardless of the number of foci per cell or growth conditions, most of the foci (70-80%) were not in close proximity to one another. We also localized RK2 in Pseudomonas aeruginosa and Vibrio cholerae, and found that plasmid RK2 localization is conserved across bacterial species. Our results suggest that each plasmid has its own unique subcellular address, implying a mechanism for the stable co-existence of plasmids in which subcellular targeting plays a major role.     

Localization of the naturally occurring plasmid ColE1 at the cell pole

The naturally occurring plasmid ColE1 was found to localize as a cluster in one or both of the cell poles of Escherichia coli. In addition to the polar localization of ColE1 in most cells, movement of the plasmid to the midcell position was observed in time-lapse studies. ColE1 could be displaced from its polar location by the p15A replicon, pBAD33, but not by plasmid RK2. The displacement of ColE1 by pBAD33 resulted in an almost random positioning of ColE1 foci in the cell and also in a loss of segregational stability, as evidenced by the large number of cells carrying pBAD33 with no visible ColE1 focus and as confirmed by ColE1 stability studies. The addition of the active partitioning systems of the F plasmid (sopABC) or RK2 (O(B1) incC korB) resulted in movement of the ColE1 replicon from the cell pole to within the nucleoid region. This repositioning did not result in destabilization but did result in an increase in the number of plasmid foci, most likely due to partial declustering. These results are consistent with the importance of par regions to the localization of plasmids to specific regions of the cell and demonstrate both localization and dynamic movement for a naturally occurring plasmid that does not encode a replication initiation protein or a partitioning system that is required for plasmid stability.     

Replication of an RK2 miniplasmid derivative in vitro by a DNA/membrane complex extracted from Escherichia coli: involvement of the dnaA but not dnaK host proteins and association of these and plasmid-encoded proteins with the inner membrane

A DNA/membrane complex extracted from a miniplasmid derivative of the broad host range plasmid RK2 cultured in Escherichia coli capable of synthesizing new plasmid supercoiled DNA in vitro was treated with antibodies that were made against or reacted with the dnaA and dnaK host-encoded proteins, respectively. Anti-dnaA protein antibody inhibited total plasmid DNA synthesis significantly and the synthesis of supercoil plasmid DNA almost completely. In contrast, anti-dnaK protein antibody and nonimmune serum had little or no effect on total plasmid DNA synthesis. Both proteins were found to be present in the inner but not outer membrane fraction of E. coli. A variety of miniplasmid-encoded proteins which had previously been found in the DNA/membrane complex have also been localized to the inner but not outer membrane fraction. These include an essential initiation protein of 32 kDa (and an overlapping protein of 43 kDa coded for by the same gene), as well as a 30-kDa protein that may be linked to incompatibility functions. Various extraction methods were used to distinguish between the associated and the integral nature of the plasmid-encoded proteins. The results demonstrated that the essential replication proteins (32 and 43 kDa) as well as the 30-kDa protein was tightly bound to the inner membrane. Computer analysis of the amino acid sequence of the 32 (and 43)-kDa protein revealed a hydrophobic region that is only half that normally required to span the membrane. Other interactions are discussed with respect to attaching this protein to the membrane.     

Replication of the broad-host-range plasmid RK2: direct measurement of intracellular concentrations of the essential TrfA replication proteins and their effect on plasmid copy number.

The trfA gene of the broad-host-range plasmid RK2 is essential for initiation of plasmid replication. Two related TrfA proteins of 43 and 32 kilodaltons (kDa) are produced by independent translation initiation at two start codons within the trfA open reading frame. These proteins were o overproduced in Escherichia coli and partially purified. Rabbit antisera raised against the 32-kDa TrfA protein (TrfA-32) and cross-reacting with the 43-kDa protein (TrfA-43) were used in Western blotting (immunoblotting) assays to measure intracellular TrfA levels. In logarithmically growing E. coli HB101, RK2 produced 4.6 +/- 0.6 ng of TrfA-32 and 1.8 +/- 0.2 ng of TrfA-43 per unit of optical density at 600 nm (mean +/- standard deviation). On the basis of determinations of the number of cells per unit of optical density at 600 nm, this corresponds to about 220 molecules of TrfA-32 and 80 molecules of TrfA-43 per cell. Dot blot hybridizations showed that plasmid RK2 is present in about 15 copies per E. coli cell under these conditions. Using plasmid constructs that produce different levels of TrfA proteins, the effect of excess TrfA on RK2 replication was tested. A two- to threefold excess of total TrfA increased the copy number of RK2 by about 30%. Additional increases in TrfA protein concentration had no further effect on copy number, even at levels 170-fold above normal. An RK2 minimal origin plasmid showed a similar response to intracellular TrfA concentration. These results demonstrate that TrfA protein concentration is not strictly rate limiting for RK2 replication and that a mechanism that is independent of TrfA concentration functions to limit RK2 copy number in the presence of excess TrfA.     

Regions of broad-host-range plasmid RK2 involved in replication and stable maintenance in nine species of gram-negative bacteria.

The replication and maintenance properties of the broad-host-range plasmid RK2 and its derivatives were examined in nine gram-negative bacterial species. Two regions of RK2, the origin of replication (oriV) and a segment that encodes for a replication protein (trfA delta kilD, designated trfA*), are sufficient for replication in all nine species tested. However, stable maintenance of this minimal replicon (less than 0.3% loss per generation under nonselection conditions) is observed only in Escherichia coli, Pseudomonas aeruginosa, Pseudomonas putida, and Azotobacter vinelandii. Maintenance of this minimal replicon is unstable in Rhizobium meliloti, Agrobacterium tumefaciens, Caulobacter crescentus, Acinetobacter calcoaceticus, and Rhodopseudomonas sphaeroides. A maintenance function has been localized to a 3.1-kilobase (kb) region of RK2 encoding three previously described functions: korA (trfB korB1 korD), incP1-(II), and korB. The 3.1-kb maintenance region can increase or decrease the stability of maintenance of RK2 derivatives dependent on the host species and the presence or absence of the RK2 origin of conjugal transfer (oriT). In the case of A. calcoaceticus, stable maintenance requires an RK2 segment that includes the promoter and the kilD (kilB1) functions of the trfA operon in addition to the 3.1-kb maintenance region. The broad-host-range maintenance requirements of plasmid RK2, therefore, are encoded by multiple functions, and the requirement for one or more of these functions varies among gram-negative bacterial species.     

Intracellular mobility of plasmid DNA is limited by the ParA family of partitioning systems

The highly conserved ParA family of partitioning systems is responsible for positioning DNA and protein complexes in bacteria. In Escherichia coli , plasmids that rely upon these systems are positioned at mid-cell and are repositioned at the quarter-cell positions after replication. How they remain fixed at these positions throughout the cell cycle is unknown. We use fluorescence recovery after photobleaching and time-lapse microscopy to measure plasmid mobility in living E. coli cells. We find that a minimalized version of plasmid RK2 that lacks its Par system is highly mobile, that the intact RK2 plasmid is relatively immobile, and that the addition of a Par system to the minimalized RK2 plasmid limits its mobility to that of the intact RK2. Mobility is thus the default state, and Par systems are required not only to position plasmids, but also to hold them at these positions. The intervention of Par systems is required continuously throughout the cell cycle to restrict plasmid movement that would, if unrestricted, subvert the segregation process. Our results reveal an important function for Par systems in plasmid DNA segregation that is likely to be conserved in bacteria.     

Physical and genetic studies with restriction endonucleases on the broad host-range plasmid RK2.

The cleavage map of the plasmid RK2 was determined for the five restriction endonucleases EcoRI, HindIII, BamH-I, SalI and HpaI. DNA has been inserted into several of these sites and cloned in Escherichia coli. Efforts to obtain derivatives of RK2 reduced in size by restriction endonuclease digestion of the plasmid were not successful and indicated that genes required for the maintenance of this plasmid in E. coli are not tightly clustered. An RK2 derivative possessing an internal molecular rearrangement was obtained by transformation with restriction endonuclease digests of the plasmid.     

A simplified vector system for visualization of localized RNAs in Schizosaccharomyces pombe

RNA localization is an important event that is essential for the polarization and differentiation of a cell. Although several methods are currently used to detect localized RNAs, a simplified detection system has not yet been developed for Schizosaccharomyces pombe. In the present study, we describe a new vector system for the visualization of localized RNAs in S. pombe using a U1A-tag-GFP system. A pREP1-U1A-tag vector plasmid to express U1A-tagged RNA and a pREP2-U1AGFP plasmid to produce a U1A-GFP fusion protein were constructed for this system. Since the U1A-GFP protein binds U1A-tagged RNA, fluorescence is observed at the location of U1A-tagged RNA in cells expressing both of these. The nucleolar localization of U3 snoRNA was successfully detected using this system, and a novel RNA localized at the DNA region of the nucleus was found by screening localized RNAs. This system will accelerate the study of localized RNAs in S. pombe.     

The postsynaptic 43K protein clusters muscle nicotinic acetylcholine receptors in Xenopus oocytes.

Nicotinic acetylcholine receptors (AChRs) are localized at high concentrations in the postsynaptic membrane of the neuromuscular junction. A peripheral membrane protein of Mr 43,000 (43K protein) is closely associated with AChRs and has been proposed to anchor receptors at postsynaptic sites. We have used the Xenopus oocyte expression system to test the idea that the 43K protein clusters AChRs. Mouse muscle AChRs expressed in oocytes after injection of RNA encoding receptor subunits are uniformly distributed in the surface membrane. Coinjection of AChR RNA and RNA encoding the mouse muscle 43K protein causes AChRs to form clusters of 0.5-1.5 microns diameter. AChR clustering is not a consequence of increased receptor expression in the surface membrane or nonspecific clustering of all membrane proteins. The 43K protein is colocalized with AChRs in clusters when the two proteins are expressed together and forms clusters of similar size even in the absence of AChRs. These results provide direct evidence that the 43K protein causes clustering of AChRs and suggest that regulation of 43K protein clustering may be a key step in neuromuscular synaptogenesis.     

Replication of mini RK2 plasmid in extracts of Escherichia coli requires plasmid-encoded protein TrfA and host-encoded proteins DnaA, B, G DNA gyrase and DNA polymerase III

Soluble extracts of Escherichia coli capable of carrying out replication of the mini-RK2 derivative pCT461 have been prepared from cells carrying this plasmid or from plasmid-free bacteria. The latter are dependent upon exogenously added plasmid-encoded replication protein (TrfA) and require additional DnaA protein for optimum activity. This dependence upon DnaA was confirmed by the failure of DnaA-deficient cell extracts to support replication of pCT461 in the absence of added DnaA protein. Replication is unidirectional and begins at or near oriV, the vegetative replication origin of RK2. DNase I protection studies with purified TrfA indicate that this protein acts by binding to short (17 base-pairs) directly repeated DNA sequences present in oriV. The in vitro replication is resistant to rifampicin but can be abolished by antibodies against DnaG protein (E. coli primase) or DnaB protein (helicase) and by DNA gyrase inhibitors. Inhibition by arabinosyl-CTP suggests that DNA polymerase III is responsible for elongation of nascent DNA strands. These results are discussed in relation to the mechanism of RK2 replication and in the context of the host range of the plasmid.     

The sequence encoding the 43-kilodalton trfA protein is required for efficient replication or maintenance of minimal RK2 replicons in Pseudomonas aeruginosa

The trfA gene of the broad-host-range plasmid RK2 encodes two proteins of 43- and 32-kDa by initiating translation at either of two in-phase AUG codons in a single open reading frame. At least one of these proteins is essential for replication of RK2 derivatives. In order to study the role of the 43-kDa protein, Bal31 deletions into the 5' end of the trfA gene were constructed and incorporated into minimal RK2 replicons. When examined in Escherichia coli, replication and maintenance properties of plasmids encoding only the 32-kDa protein were indistinguishable from those of plasmids encoding both the 43- and the 32-kDa proteins. In four other gram-negative hosts deletion of sequences encoding only the 43-kDa protein did not have a substantial effect on plasmid establishment or stable maintenance. However, in Pseudomonas aeruginosa, deletion of 43-kDa coding sequences greatly reduced the efficiency of plasmid maintenance, suggesting a host-specific role for the 43-kDa TrfA protein in RK2 replication.     

A critical DnaA box directs the cooperative binding of the Escherichia coli DnaA protein to the plasmid RK2 replication origin.

The requirement of DnaA protein binding for plasmid RK2 replication initiation the Escherichia coli was investigated by constructing mutations in the plasmid replication origin that scrambled or deleted each of the four upstream DnaA boxes. Altered origins were analyzed for replication activity in vivo and in vitro and for binding to the E. coli DnaA protein using a gel mobility shift assay and DNase I footprinting. Most strikingly, a mutation in one of the boxes, box 4, abolished replication activity and eliminated stable DnaA protein binding to all four boxes. Unlike DnaA binding to the E. coli origin, oriC, DnaA binding to two of the boxes (boxes 4 and 3) in the RK2 origin, oriV, is cooperative with box 4 acting as the "organizer" for the formation of the DnaA-oriV nucleoprotein complex. Interestingly, the inversion of box 4 also abolished replication activity, but did not result in a loss of binding to the other boxes. However, DnaA binding to this mutant origin was no longer cooperative. These results demonstrate that the sequence, position, and orientation of box 4 are crucial for cooperative DnaA binding and the formation of a nucleoprotein structure that is functional for the initiation of replication.     

ompT encodes the Escherichia coli outer membrane protease that cleaves T7 RNA polymerase during purification.

Bacteriophage T7 RNA polymerase is stable in Escherichia coli but very susceptible to cleavage by at least one endoprotease after cell lysis. The major source of this endoprotease activity was found to be localized to the outer membrane of the cell. A rapid whole-cell assay was developed to screen different strains for the presence of this proteolytic activity. Using this assay, we identified some common laboratory strains that totally lack the protease. Genetic and Southern analyses of these null strains allowed us to conclude that the protease that cleaves T7 RNA polymerase is OmpT (formerly termed protein a), a known outer membrane endoprotease, and that the null phenotype results from deletion of the OmpT structural gene. A recombinant plasmid carrying the ompT gene enables these deletion strains to synthesize OmpT and converts them to a protease-positive phenotype. The plasmid led to overproduction of OmpT protein and protease activity in the E. coli K-12 and B strains we used, but only weak expression in the E. coli C strain, C1757. This strain-dependent difference in ompT expression was investigated with respect to the known influence of envZ on OmpT synthesis. A small deletion in the ompT region of the plasmid greatly diminishes the amount of OmpT protein and plasmid-encoded protease present in outer membranes. Use of ompT deletion strains for production of T7 RNA polymerase from the cloned gene has made purification of intact T7 RNA polymerase routine. Such strains may be useful for purification of other proteins expressed in E. coli.     

Conditional lethal mutants of the kilB determinant of broad host range plasmid RK2

We have examined the relationship of kilB to the other known determinants which map in the 14'-22' region of RK2. These are trfA, which encodes a diffusible replication function, and tra3, which specifies a function required for plasmid transmissibility. We found that, in addition to kilB, both tra3 and trfA functions are expressed by the cloned 14'-22' region of RK2. Four temperature-sensitive mutants of kilB were isolated by in vitro mutagenesis of the cloned segment. At 42 degrees C these mutant plasmids can be maintained in Escherichia coli cells which lack a korB+ helper plasmid. At 30 degrees C the helper plasmid is required. Our analysis of these mutants revealed that kilB function is distinct from those of trfA and tra3. One mutant plasmid was temperature-sensitive for maintenance of an RK2 ori plasmid, but this phenotype was shown to be independent of the KilB(ts) phenotype. Thus, kilB appears to be a separate new locus in this portion of the RK2 genome. In addition, these mutants allowed us to test for the existence of an essential replication determinant (trfB) in the 50.4'-56.4' region of RK2. Our results demonstrate that this region is non-essential for replication from the RK2 ori in E. coli. We propose an alternative hypothesis to explain the role of the RK2 trfB region for plasmid maintenance in E. coli.     

Distribution of the partitioning protein KorB on the genome of IncP-1 plasmid RK2

The ParB family partitioning protein, KorB, of plasmid RK2 is central to a regulatory network coordinating replication, maintenance and transfer genes. Previous immunofluorescence microscopy indicated that the majority of KorB is localized in plasmid foci. The 12 identified KorB binding sites on RK2 are differentiated by: position relative to promoters; binding strength; and cooperativity with other repressors and so the distribution of KorB may be sequestered around a sub-set of sites. However, chromatin immunoprecipitation analysis showed that while RK2 DNA molecules appear to sequester KorB to create a higher local concentration, cooperativity between DNA binding proteins does not result in major differences in binding site occupancy. Thus under steady state conditions all operators are close to fully occupied and this correlates with gene expression on the plasmid being highly repressed.     

Mutations in the trfA replication gene of the broad-host-range plasmid RK2 result in elevated plasmid copy numbers.

Mutated forms of trfA, the replication protein gene of plasmid RK2, that support a minimal RK2 origin plasmid in Escherichia coli at copy numbers up to 23-fold higher than normal have been isolated. Six such high-copy-number (copy-up) mutations were mapped and sequenced. In each case, a single base transition led to an amino acid substitution in the TrfA protein primary sequence. The six mutations affected different residues of the protein and were located within a 69-base-pair region encoding 24 amino acids. Dominance tests showed that each of the mutants can be suppressed by wild-type trfA in trans, but suppression is highly dependent on the amount of wild-type protein produced. Excess mutant TrfA protein provided in trans significantly increased the copy number of RK2 and other self-replicating derivatives of RK2 that contain a wild-type trfA gene. These observations suggest that the mutations affect a regulatory activity of the TrfA replication protein that is a key factor in the control of initiation of RK2 replication.