Genetic studies of F plasmid maintenance genes involved in copy number control, incompatability, and partitioning

Intra- and interpopulation transposition of mobile genetic elements driven by antibiotic selection

The spread of genes encoding antibiotic resistance is often mediated by horizontal gene transfer (HGT). Many of these genes are associated with transposons, a type of mobile genetic element that can translocate between the chromosome and plasmids. It is widely accepted that the translocation of antibiotic resistance genes onto plasmids potentiates their spread by HGT. However, it is unclear how this process is modulated by environmental factors, especially antibiotic treatment. To address this issue, we asked whether antibiotic exposure would select for the transposition of resistance genes from chromosomes onto plasmids and, if so, whether antibiotic concentration could tune the distribution of resistance genes between chromosomes and plasmids. We addressed these questions by analysing the transposition dynamics of synthetic and natural transposons that encode resistance to different antibiotics. We found that stronger antibiotic selection leads to a higher fraction of cells carrying the resistance on plasmids because the increased copy number of resistance genes on multicopy plasmids leads to higher expression of those genes and thus higher cell survival when facing antibiotic selection. Once they have transposed to plasmids, antibiotic resistance genes are primed for rapid spread by HGT. Our results provide quantitative evidence for a mechanism by which antibiotic selection accelerates the spread of antibiotic resistance in microbial communities.

Characterization of a replicon of the moderately promiscuous plasmid, pGSH5000, with features of both the mini-replicon of pCU1 and the ori-2 of F

The dominant, polA1-independent replicon of pGSH500, rep beta (1.8 kb), consists of a cis-acting oriV region of 245 bp; a repB gene that is essential for autonomous replication and 18, 30 to 36 bp iterons which constitute the inc/cop region. The molecular organization of rep beta resembles that of mini-pCU1 (IncN). Furthermore, there is a 58% identity between the Rep proteins of these replicons. RepB also shows a 31% identity with RepE of mini-F. In addition, an 80% identity over 200 bp was identified between the cis-acting beta oriV region and the equivalent region of ori-2 (mini-F). Replicons with deletions of repB could be complemented by Rep (pCU1) and RepE (mini-F) in trans, supporting the hypothesis that rep beta is a natural hybrid between a pCU1-like and F-like replicon.

Site-specific proteolysis of mini-F plasmid replication protein RepE destroys initiator function and generates an incompatibility substance

Plasmid F replication is controlled by a plasmid-specified Rep protein with both autorepressor and initiator functions. The mechanism by which these two functions of a Rep protein are balanced to achieve stable replication is unknown; however, we speculated in prior work that Rep protein modification could be involved. We report here that naturally proteolyzed F RepE protein has been detected and characterized. The processed molecule lost the first 17 N-terminal aminoacyl residues and initiator function but acquired increased specific DNA-binding affinity in the presence of Escherichia coli chromosomal DNA. When supplied in trans, the altered protein acts as an incompatibility substance and eliminates maintenance of F'lac. These findings indicate that protein processing has the potential to contribute to the overall control of DNA replication.

Mini-F plasmid mutants able to replicate in the absence of sigma 32: mutations in the repE coding region producing hyperactive initiator protein

Mini-F plasmids cannot replicate in Escherichia coli strains (delta rpoH) lacking sigma 32, presumably because transcription of the repE gene encoding the replication initiator protein (RepE protein) depends mostly on RNA polymerase containing sigma 32. We have isolated and characterized mini-F mutants able to replicate in delta rpoH cells. Contrary to the initial expectation, five mutants with mutations in the repE coding region that produce altered RepE proteins were obtained. The mutations caused replacement of a single amino acid: the 92nd glutamic acid was replaced by lysine (repE10, repE16, and repE25) or glycine (repE22) or the 109th glutamic acid was replaced by lysine (repE26). These plasmids overproduced RepE protein and exhibited very high copy numbers. Two major activities of mutated RepE proteins have been determined in vivo; the autogenous repressor activity was significantly reduced, whereas the initiator activity was much enhanced in all mutants. These results indicate the importance of a small central region of RepE protein for both initiator and repressor activities. Thus the decreased repE transcription in delta rpoH cells can be compensated for by an increased initiator activity and a decreased repressor activity of RepE, resulting in the increased synthesis of hyperactive RepE protein.

Effects of inhibition of the B subunit of DNA gyrase on conjugation in Escherichia coli

Antagonism of the DNA gyrase B subunit in the donor bacterium by coumermycin or thermal inactivation inhibited transfer of plasmid R64drd-11. Coumermycin also inhibited Hfr transfer, with kinetics after drug removal suggesting that transfer resumed from the point of inhibition, in contrast to inhibition with nalidixic acid, after which transfer reinitiated from the origin of transfer.

An initiator protein for plasmid R6K DNA replication. Mutations affecting the copy-number control

Two kinds of mutations affecting the copy-number control of plasmid R6K were isolated and identified in an initiator pi protein by DNA sequencing. Firstly, a temperature-sensitive replication mutation, ts22, with decreased copy number results in a substitution of threonine to isoleucine at position 138 of the 305-amino-acid pi protein. Secondly, a high-copy-number (cop21) mutant was isolated from this ts mutant and was identified by an alteration of alanine to serine at position 162. This cop21 mutation suppressed the Ts character and was recessive to the wild-type allele in the copy control.

Nucleotide sequence and copy control function of the extension of the incI region (incI-b) of Rts 1

An Rts1 derivative, pTW20, contains three incompatibility (inc) regions, incI-a (incI in previous studies), incII, and newly determined incI-b loci. By restriction analysis, we have located the incI-b adjacent to the incI-a region on the pTW20 map. Nucleotide sequence analysis of the minimal incI-b region revealed the presence of four repeated sequences, each consisting of 18 bp, which is similar to the incI-a and incII repeats existing on mini-Rts1. All four repeating units were required for expression of a strong incompatibility. In addition, RepA protein, essential for the replication of Rts1, bound specifically to the repeated sequences, suggesting that the repeats would titrate out RepA protein as do incI-a and IncII. Insertion of the incI-b to a mini-Rts1 plasmid in a natural arrangement decreases the copy number of mini-Rts1 to the same level as that of mini-F. The incI-a and incI-b might be a single constituent in incompatibility and copy number control of Rts1.

The Inc3B determinant of plasmid pT181. A mutational analysis

A region encompassing the origin of replication of staphylococcal plasmid pT181 has previously been shown to express an incompatibility effect denoted Inc3B, when cloned into another replicon (Novick et al. 1984). In an attempt to understand the mechanism of this incompatibility effect, and its relationship with the function of the replication origin, mutants deficient in this property were isolated and characterized. The results obtained suggest that the Inc3B effect is due to the competition for replication between the replication origin cloned in a hybrid and the origin of an autonomous plasmid. The Inc3B-deficient mutants isolated expressed different degrees of residual incompatibility. The inc3B mutations which did not express any incompatibility were found also to inactivate the function of the replication origin. All the other mutants which expressed residual Inc3B had a functional origin but presented a significantly reduced ability to use this origin when coexisting with a plasmid using a wild-type pT181 origin. It is suggested that these inc3B mutations represent a new type of origin mutation which affects the ability of the origin to compete with other origins using the same replication system, though the function per se of the origin is not significantly impaired.

Characterization of the maintenance functions of IncFIV plasmid R124

The genetic arrangement of the regions involved in R124 replication and incompatibility have been located and their homology to the IncFI basic replicons has been assessed. We show that R124 has homology with all three basic replicons, RepFIA, RepFIB, and RepFIC, and that these regions, FIVA, RepFIVB, and RepFIVC, are widely separated on the R124 genome. Cloning of autonomously replicating fragments has shown that RepFIVB and RepFIVC are functional in R124 and express incompatibility. The FIVA region was unable to form a functional replicon and when cloned into pUC8 lacked incompatibility activity. A fourth region of R124 was identified, which although not essential for replication stabilized mini-R124 plasmid replication and exhibited incompatibility with R124. This region, designated IncIV, showed no homology to RepFIA, RepFIB, or RepFIC. Incompatibility expression of IncIV required only the EcoRI fragment E13 but the strength of the reaction was modified in the presence of other fragments. The replication and incompatibility properties of an R124 deletion derivative indicated that R124 can switch its replication to either RepFIVB or RepFIVC when in the presence of an incompatible plasmid. The ambiguous incompatibility reactions reported for R124 is a result of the expression of the two functional replicons, RepFIVB and RepFIVC, and that expressed by IncIV.

Regulation of expression of the cloned repE gene from the F plasmid of Escherichia coli

The repE gene of the Escherichia coli F plasmid has been fused to an N-terminal fragment of the Salmonella typhimurium araB gene in the plasmid expression vector pING1. A fusion protein is expressed at high levels upon addition of arabinose to E. coli hosts containing the recombinant plasmid and has been purified to homogeneity. Antibodies prepared against the fusion protein react with both araB' and repE-coded proteins and can be used to detect their synthesis by immunoblotting methods. In vitro as well as in vivo expression of the repE gene from chimeric plasmids indicate a very tight control of the expression of this replication initiator protein.

Requirement of the Escherichia coli dnaA gene product for plasmid F maintenance

There are DnaA protein-binding sites in at least one F origin of replication, and only potentially leaky dnaA(Ts) mutations had ever been used in previous studies indicating that F replication was independent of the dnaA gene product. Here we show that an Escherichia coli dnaA::Tn10 host which does not make a dnaA gene product cannot sustain autonomous or integrated F plasmid maintenance.

Mini-F E protein: the carboxy-terminal end is essential for E gene repression and mini-F copy number control

Mini-F is a segment of the conjugative plasmid F consisting of two origins of replication flanked by regulatory regions, which ensure a normal control of replication and partitioning. Adjacent to the ori-2 origin is a complex coding region that consists of the E gene overlapped by three open reading frames with the coding potential for 9000 Mr polypeptides here designated 9 kd-1, 9 kd-2 and 9 kd-3. In this paper, we show that open reading frame 9 kd-3 is preceded by active promoter and Shine-Dalgarno sequences. The E coding region specifies: an initiator of replication, which acts at the ori-2 site; a function that negatively regulates the expression of the E gene; and a function involved in mini-F copy number control. To assign one of these functions to one of the overlapping coding sequence, we have isolated, characterized and sequenced mutations mapping in the E coding region. In this paper, we analyse two mutations (cop5 and pla25) that abolish the repression of the E gene. As these mutations affect the primary structure of protein E itself but not the 9 kd polypeptides, we conclude that protein E takes part in the negative regulation of its own synthesis. In addition, the localization of the cop5 and pla25 mutations indicates that the carboxy-terminal end of the E protein is involved in the autorepression function. The cop5 mutation causes an eightfold increase of the mini-F copy number. The pla25 mutation leads to the inability of the derived mini-F plasmid to give rise to plasmid-harbouring bacteria. The ways in which the cop5 and pla25 mutations may lead to such phenotypes are discussed in relation to the different functions mapping in the E coding sequence.

Two functions of the E protein are key elements in the plasmid F replication control system

By using a plasmid carrying a translational fusion between the E gene of the IncFI plasmid F and the lacZ gene, we located the operator of the autogenously regulated E gene to an inverted repeat overlapping the E-gene promoter and showing perfect homology to part of the sequence found in all the direct repeats of two regions exerting an inhibitory effect on F replication, incB and incC. Excess E protein provided in trans to an F plasmid increased the replication frequency of the F plasmid. This stimulatory effect was counteracted by increased dosages of incB or incC. A model is proposed for the replication control system of F in which the key elements are autoregulation of E-gene expression and titration of E protein by incB and incC.

SOS induction by thermosensitive replication mutants of miniF plasmid

MiniF, a 9.3 kb fragment of the dispensable F plasmid, carries genes necessary for its replication and partition as well as for the expression of an SOS signal. The arrest of replication of a thermo-sensitive miniFts at 42 degrees C induced SOS functions such as prophage lambda, sfiA expression, W-reactivation of UV-irradiated phage lambda. Two miniF ts9 and ts17 mutations were located within the KpnI fragment (43.6-46.9) in the minimal oriS replicon. Blocking miniF replication by incBC+ incompatibility genes situated in trans on a second plasmid also induced SOS functions. In contrast, if miniFts17 plasmid escaped the replication block at 42 degrees C by being inserted into pR325, there was no SOS induction. SOS induction by the arrest of miniF replication required the miniF lynA+ locus in cis, the host recA+ and lexA+ genes. We found that SOS induction was increased greatly near the stationary phase and that cell viability declined. During host cell exponential growth, miniFts9 and miniFts17 plasmids were lost rapidly, although SOS induction persisted for several cell generations. We postulate that lynA expresses a persistent product that may lead to the unwinding of chromosomal DNA.

An essential replication gene, repA, of plasmid pSC101 is autoregulated

Measurements of the rate of replication of a mutant pSC101 plasmid, cloned into a ColE1 vector, showed that insertions of the transposon Tn1000 into the repA gene of pSC101 abolished replication activity, but could be complemented in trans, albeit at a low level. The promoter of the repA gene was mapped by the construction of repA-lacZ gene fusions, and one of the fusions was used to demonstrate that repA protein, provided in trans, could repress expression of beta-galactosidase activity. This repression was primarily due to reduction of transcription of the repA-lacZ fusion. The sequence analysis of mutants of the repA-lacZ fusion gene which were no longer sensitive to the presence of repA protein showed that the site of action of repA was a 22 base-pair sequence, present as an inverted repeat, overlapping the repA promoter. The repA gene is thus autoregulated.

A two-stage molecular model for control of mini-F replication

It is known that mini-F replication requires production of a 29,000-Da protein, protein E, and origin of replication sequences mapping around 45. kb. Further, control of replication is determined by two genes, copA and copB. In the present work a description is given of the cloning of an F restriction fragment containing the amino terminal portion of the protein E gene, repE, and associate promoter activity. It is shown that expression of this promoter is negatively regulated in trans by sequences taken from the F replication region of copA+ plasmids. However, the same sequences taken from six different copA- plasmids failed to repress expression of the promoter. Since prior studies have shown that copA+ determines a repressor of replication, it is now suggested that the above results are an accounting of where this repressor works. A hypothesis is also proposed to explain control of F replication by the copA and copB regulatory genes.

Control of F plasmid replication by a host gene: evidence for interaction of the mafA gene product of Escherichia coli with the mini-F incC region

Replication of F (including mini-F) and some related plasmids is known to be specifically inhibited in mafA mutants of Escherichia coli K-12. We have now isolated and characterized mini-F mutants that can overcome the replication inhibition. Such plasmids, designated pom (permissive on maf), were obtained spontaneously or after mutagenesis with hydroxylamine or by transposon (Tn3) insertion. In addition to their ability to replicate in mafA mutant bacteria, the pom mutant plasmids exhibit an increased copy number and resistance to "curing" by acridine dye in the mafA+ host. In agreement with these results, Tn3-induced pom mutants were found to carry Tn3 inserted at the incC region of mini-F DNA, known to be involved in incompatibility, control of copy number, and sensitivity to acridine dye. Furthermore, three of the seven mini-F plasmids tested that carry Tn3 within the tandem repeat sequences of the incC region (previously isolated by other workers) exhibit all the phenotypes of pom plasmids, the ability to replicate in the mafA strain, and high copy number and acridine resistance in the mafA+ strain. The rest of the plasmids that contain Tn3 just outside the tandem repeats remain wild type in all these properties. These results strongly suggest that the putative mafA gene product of host bacteria controls mini-F replication through interaction with the incC region.

Indirect SOS induction is promoted by ultraviolet light-damaged miniF and requires the miniF lynA locus

Indirect prophage induction is produced by transfer to recipients of u.v.-damaged F plasmid (95 kb). We tested whether the SOS signal can be produced by miniF, a 9.3 kb restriction fragment, coding for the replication and segregation functions of plasmid F. We used lambda miniF, a hybrid phage-plasmid. u.v.-irradiated lambda miniF induced prophages phi 80 or lambda and sfiA, a chromosomal SOS gene, in more than 50% of the infected cells. The maximal inducing dose produced about 0.5 pyrimidine dimers per kb and left 1% of lambda miniF survivors. Thus, the SOS signal produced by u.v.-damaged lambda miniF was almost as potent as that resulting from direct u.v.-irradiation of the lysogens. The u.v.-damaged vector lambda, devoid of miniF, failed to promote SOS induction. In contrast, efficient induction was observed when u.v.-damaged lambda miniF infected a lambda immune host, in which replication and expression of the phage genome were repressed. When replication and expression of the miniF genome was repressed by Hfr incompatibility, SOS induction was largely prevented. All these facts indicate that, in the hybrid lambda-miniF, it is the u.v.-damaged miniF that generates an SOS signal. To locate on the miniF genome the loci that are involved in the production of the SOS signal, we isolated deletions spanning all the miniF restriction fragments. We characterized six mutant phenotypes (Par+, Rep-, Fid-, Par-2, Par-1 and SOS-) related to four functions; partition, copy number, replication and SOS induction. A locus, we call lynA, 800 bp long, located by deletion mapping between the two origins of replication oriP and oriS is required for the production of an inducing signal. We postulate that indirect SOS induction by u.v.-damaged miniF results from the disturbance of the lynA function that may be involved in the co-segregation of F plasmid with the host chromosome.

Plasmid P1 replication: negative control by repeated DNA sequences

The incompatibility locus, incA, of the unit-copy plasmid P1 is contained within a fragment that is essentially a set of nine 19-base-pair repeats. One or more copies of the fragment destabilizes the plasmid when present in trans. Here we show that extra copies of incA interfere with plasmid DNA replication and that a deletion of most of incA increases plasmid copy number. Thus, incA is not essential for replication but is required for its control. When cloned in a high-copy-number vector, pieces of the incA fragment that each contain only three repeats destabilize P1 plasmids efficiently. This result makes it unlikely that incA specifies a regulatory product. Our in vivo results suggest that the repeating DNA sequence itself negatively controls replication by titrating a P1-determined protein, RepA, that is essential for replication. Consistent with this hypothesis is the observation that the RepA protein binds to the incA fragment in vitro.

Control of cell division by sex factor F in Escherichia coli. II. Identification of genes for inhibitor protein and trigger protein on the 42.84-43.6 F segment

The genetic structure of the 42.84-43.6 F (BamHI-PstI) segment of the F plasmid, which contains all the F DNA sequences necessary for coupling cell division of F+ bacteria with plasmid DNA replication, was analyzed by isolating a series of amber mutants. Two cistrons were found in this region and they were designated letA and letD (an abbreviation for lethal mutation). The letA and letD cistrons were mapped on the 42.84-43.35 F (BamHI- XmaI ) segment and the 43.07-43.6 F (HincII-PstI) segment, respectively, and are presumed to correspond to the first (43.04-43.26 F) and second (43.26-43.57 F) open reading frames, respectively, which were found in this region by nucleotide sequencing. The letD gene product acts to inhibit cell division of the host bacteria and to induce prophages in lysogenic bacteria, whereas the letA gene product acts to suppress the activity of the letD gene product. Taking into consideration the fact that the 42.84-43.6 F segment carries all the F plasmid genes necessary for coupling cell division with plasmid DNA replication, and that the expression of the genes is likely to be controlled by plasmid DNA replication, we constructed the following hypothesis. Before completion of plasmid DNA replication, LetD protein acts to prevent cell division of the host bacteria. When plasmid DNA replication is completed, synthesis of LetA protein (and also LetD protein) takes place and the LetA protein synthesized acts to suppress the activity of LetD protein and make the cell ready for cell division. Actual cell division will take place when replication of both chromosomal and plasmid DNA is completed and the termination protein of the chromosome and the LetA protein of F plasmid are both synthesized. When cell division takes place LetA protein is consumed, and as a result LetD protein becomes active and prevents cell division until the next round of DNA replication is completed.

Control of cell division by sex factor F in Escherichia coli. I. The 42.84-43.6 F segment couples cell division of the host bacteria with replication of plasmid DNA

The F plasmid of Escherichia coli was used to study the genetic background of the control circuit in the bacteria that co-ordinates DNA replication and cell division of the host cells. When DNA replication of the F plasmid was blocked by growing cells carrying an amber-suppressible replication-defective F plasmid mutant under restrictive conditions, the cells continued to divide for about one generation until F plasmid was supposedly diluted to one copy per cell, and then they stopped dividing and formed non-septated filamentous cells. These observations suggest that completion of a round of replication is a necessary and sufficient condition of F DNA synthesis in the cell division of F+ bacteria; i.e. cell division of the F+ bacteria is coupled with DNA replication of the F plasmid. The observation that Giemsa-stainable materials in the filamentous cells were clustered in the center indicates that partitioning of chromosomal DNA (and presumably of F plasmid DNA) is also coupled with plasmid DNA replication. The function necessary for this coupling is carried by the 42.84-43.6 F (BamHI-PstI) segment, which is located outside the region essential for replication of the F plasmid. The nucleotide sequence demonstrates the existence of two open reading frames in this region, which encode polypeptides of 72 and 101 amino acids, respectively. These two reading frames are most likely to be transcribed as a single polycistronic message in the direction from the BamHI site at 42.84 F to the PstI site at 43.6 F. The expression of this "operon" is likely to be controlled by plasmid DNA replication.

Characterization of a mini-F plasmid derived from an F mutant expressing incompatibility in the autonomous but not in the integrated state

Plasmid DNA from Escherichia coli F' ser/MA219 harboring an altered F' factor, which expressed incompatibility in the autonomous but not in the integrated state (DeVries and Maas, 1973, J. Bacteriol. 115, 213-220), was digested with the restriction endonuclease EcoRI and ligated to a nonreplicating trpED fragment. A miniplasmid was obtained containing a 5.7-kb EcoRI fragment capable of self-replication. This plasmid, designated pRE300, was incompatible with mini-F as well as with ColE1 derivatives. It represents a cointegrate formed in vivo between a 2.2-kb segment of the F replication region and a ColE1-type replicon of unknown derivation. The F-derived component of pRE300 corresponds to a minimalized F replicon (43.85-46.05 kb F) retaining oriII and the incB locus but missing the incC and incD functions. It is postulated that the Inc- mutation resulted from the insertion of a transposable DNA sequence into the incC locus of the parent F plasmid.

Novobiocin-induced elimination of F'lac and mini-F plasmids from Escherichia coli

Novobiocin eliminated (cured) F'lac and three low-copy-number mini-F plasmids (pML31, pMF21, and pMF45) from Escherichia coli to different extents. F'lac was cured 0 to 3%. pML31, whose replication region is contained on the 9-kilobase f5 EcoRI restriction enzyme fragment of F, was eliminated 10 to 92%. pMF21, deleted of the origin of mini-F replication at 42.6 kilobases on the F map and known to initiate from an origin at 45.1 kilobases, and its closely related derivative pMF45 were cured to the greatest extent (greater than 97%). pMF45 was eliminated from a wild-type bacterial strain but not from an isogenic novobiocin-resistant gyrB mutant strain, indicating involvement of the B subunit of DNA gyrase in the curing phenomenon. The number of bacteria containing pMF45 halved with each generation of growth in the presence of novobiocin, as is predicted for complete inhibition of plasmid DNA replication.

Identification and characterization of a second copy number control gene in mini-F plasmids

We previously reported the existence of a series of chemically induced trans recessive copy-number mutations (cop) for mini-F plasmids and the existence of a similar series of cop mutations induced by insertion of the ampicillin resistance transposon Tn3. In this paper we describe the experiments showing that these two series of mutations are in different genes. Briefly, the experiments show that the one mutant series can complement the other, that the mutations map in distinct but adjacent regions, that the copy numbers of double mutants are the products of the copy numbers determined by the single mutations, and that Tn3 does not elevate copy number by a polar effect on the adjacent cop gene defined by chemical mutagenesis. We term the latter gene copA and the gene mutated by Tn3, copB. We also demonstrate here that copB mutations are recessive to the wild type allele. Further, we have characterized copB by deletion and recombinational analysis as the series of five 19- to 22-base-pair directly repeated sequences that had previously been designated incC-that is, one of the incompatibility genes. The evidence for this conclusion is that plasmids lacking two, three or five direct repeats have their copy number elevated proportionately. Possible mechanisms for copB control of replication are discussed.

Partition of unit-copy miniplasmids to daughter cells. I. P1 and F miniplasmids contain discrete, interchangeable sequences sufficient to promote equipartition

Hybrids formed by insertion of the plasmid maintenance regions of P1 or F into a lambda delta att vector form stable unit-copy plasmids in their Escherichia coli host. They must therefore both be substrates for an accurate cellular partition apparatus that ensures that all daughter cells inherit a plasmid copy. Analysis of deletion mutants of both types of hybrid showed that, although the P1 and F plasmid maintenance regions differ in sequence and specificity, they are similar in general organization. Each contains an approximately 3 X 10(3) base-pair region that is essential for replication (rep) and an adjacent but separable 3 X 10(3) base-pair region that is essential for the stability of plasmid maintenance (par). Each par region is thought to specify the recognition of the plasmid as a substrate for equipartition. The deletion mutants provide sources of isolated rep and par sequences from both P1 and F DNA. These elements were then used to construct composite plasmids with novel combinations and arrangements of rep and par sequences. Heterologous constructions containing P1 rep and F par or F rep and P1 par sequences were maintained faithfully. We conclude that par regions are both necessary and sufficient to promote equipartition of replicating plasmid DNA. This activity is exerted only in cis but otherwise seems to be independent of the position or orientation of the par sequences within the DNA. Both P1 and F par regions include DNA sequences (incB of P1, incD of F) that we propose are analogues of the centromeres of eukaryotic chromosomes. The remaining portions of the par regions are known to encode protein products that, we believe, act at the inc sites. Extra copies of these inc sites appear to exert incompatibility by competition for the cellular partition apparatus.

Genetics of the replication and maintenance functions of the hemolytic plasmid pSU316. Cloning of an IncFIII determinant

Two miniplasmids have been constructed from pSU306, a Tn802 insertion derivative of the IncFIII-IncFIV hemolytic plasmid pSU316. One of these, pSU3027, is a low copy number plasmid expressing both IncFIII and IncFIV incompatibilities, but is rather unstable, and probably lacks a putative par gene. The other, pSU3025, is maintained in about 340 copies per genome equivalent and expresses only IncFIII incompatibility. Most of the PstI-generated fragments from pSU3027 have been cloned in pBR322. One of the resulting plasmids, pSU3135, contains an insertion of 0.5 kb in the vector molecule, and expresses IncFIII, but not the IncFIV incompatibility. These results allowed us to identify and locate several genes involved in the control of pSU316 replication and stable plasmid maintenance.

An amber replication mutant of F plasmid mapped in the minimal replication region

We have constructed a mini-F derivative (pKP1013) consisting of a 5.4 kilobase pairs (kb) segment (44.0 to 49.4 kb) of mini-F and fragments carrying the chloramphenicol and spectinomycin resistance genes that originated from the R plasmid NR1. The plasmid pKP1013 replicates autonomously in a manner indistinguishable from that of the parental mini-F. An amber mutant defective in replication has been isolated from pKP1013 by localized mutagenesis using N-methyl-N'-nitro-N-nitrosoguanidine. The virtual absence of incorporation of [3H]-thymidine into the plasmid DNA as well as the kinetics of appearance of plasmid-free segregants suggest that plasmid DNA synthesis is primarily affected under nonpermissive conditions. The amber mutation has been mapped within the 530 base pairs (bp) region that extends from 45.25 (XmaI) to 45.78 Kb (PstI) by extensive analysis of in vitro recombinants constructed from rep+ and rep- plasmids.

Role of nine repeating sequences of the mini-F genome for expression of F-specific incompatibility phenotype and copy number control

An autonomously replicating 2,248-base-pair DNA segment of the mini-F plasmid carries nine 19-base-pair repeating sequences. Five of the repeats are arranged in one direction and form the right cluster, whereas the remaining four repeats are arranged in the opposite direction and form the left cluster (Murotsu et al., Gene 15:257-271, 1981). Each cluster, cloned separately into the multicopy plasmid vector pBR322, exhibited a strong F-specific incompatibility phenotype (FIP). These clusters were thought to be responsible for the expression of IncB and IncC phenotypes, causing a switchoff function on mini-F replication. Mini-F DNA fragments containing two, three, or more than four repeats were inserted into pBR322. Cells carrying these recombinant plasmids exhibited, respectively, no, intermediate, and strong FIP intensity. Cloning of five repeats into pSC101, whose copy number is about 6 in contrast to 20 for pBR322, resulted in an FIP of intermediate intensity. Thus, the intensity of FIP reflects the dosage of repeats in a cell. The five repeats in the right cluster were eliminated from the mini-F derivative without impairing its autonomous-replicating ability (Bergquist et al., J. Bacteriol. 147:888-889, 1981; Kline and Palchavdhuri, Plasmid 4:281-289). Such deletion, however, caused a sixfold elevation of the copy number. When the eliminated cluster of repeats was reinserted in the derivative, the copy number was lowered to the original value, viz., 1 to 2. The position and orientation of this insertion was not important in the copy number control. Thus, the repeats are also related to copy number control. A model to account for the role of the repeating sequences in the control of copy number and FIP is discussed.

Rapid method for screening large numbers of Escherichia coli colonies for production of plasmid-mediated beta-lactamases

A rapid, simple assay for screening large numbers of Escherichia coli colonies for production of certain plasmid-mediated beta-lactamases (including TEM-1, TEM-2, HMS-1, SHV-1, OXA-1, PSE-1, PSE-4, and CEP-2) is described. The technique, a modification of the method of Slack et al. for detection of beta-lactamase in limited numbers of Haemophilus influenzae clinical isolates (Lancet ii:906, 1977), uses filter paper impregnated with benzylpenicillin and a pH indicator dye (bromocresol purple) that changes color in the presence of beta-lactamase activity. The test paper is briefly applied to an agar surface containing bacterial colonies which are subsequently scored individually on the paper by color: yellow indicates the presence of beta-lactamase, dark green its absence, and variegation (yellow and dark green) a mixed population. Concordance of the results of this assay with those of replica plating for antibiotic resistance was over 99%. Hundreds of colonies per plate can be scored quickly and remain viable for further evaluation. The assay appears to be useful for studies of the stability of plasmids encoding beta-lactamases and in cloning with vectors such as pBR322 in which insertion of DNA fragments can be detected by inactivation of the beta-lactamase gene. Whenever the assay is to be used, results should always be confirmed initially by another method, such as replica plating, because the test paper assay does not detect three beta-lactamases (OXA-2, OXA-3, and PSE-2) and also would miss intrinsic penicillin resistance.

Partition mechanism of F plasmid: two plasmid gene-encoded products and a cis-acting region are involved in partition

Plasmids that replicate using the replication origin (oriC) of the E. coli chromosome are not stably inherited through cell division, but can be stabilized by joining with a particular segment of F plasmid that presumably provides the partition function. The segment necessary for stabilization has been located within a 3.0 kb segment outside of the region essential for autonomous replication of the F plasmid. This segment contains three functionally distinct regions: two of them (designated sopA and sopB) specify gene products that act in trans, whereas the third region (sopC) acts in cis. All three functions seem to be essential for normal partition of the plasmid into daughter cells during cell division. The cis-acting region also specifies plasmid incompatibility.

Genetic evidence that control of F replication is negative

We have taken advantage of two situations in which the incompatibility barrier between F plasmids is overcome to show that wild-type genes controlling F copy number (cop+) are dominant in trans over mutant genes. The simplest interpretation of our findings is that the cop mutations have inactivated a repressor gene that controls F replication. Since the cop. mutations all map in a region that others have shown by sequence analysis to theoretically encode four proteins, a strong possibility exists that one of these proteins is the repressor.

Detection and mapping of six miniF-encoded proteins by cloning analysis of dissected miniF segments

Various DNA subfragments were derived from miniF DNA by complete or partial PstI cleavage, and cloned in the plasmid vectors pBR322 or lambda dv1. The recombinant plasmids obtained were introduced into an Escherichia coli minicell-producing strain, and the plasmid-coded proteins were radiolabeled and analyzed by gel electrophoresis. Six miniF-encoded proteins, larger than 11 000 daltons, were detected and their coding regions were mapped on the F plasmid genome. Three of them were assigned by taking into account the known nucleotide sequences (Murotsu et al. 1981; K. Yoshioka, personal communication). The coding directions of some proteins were determined by inserting the lac promotor into one of the recombinant plasmids and analyzing the increase in production of the proteins. The coding direction of the five proteins analyzed so far was uniform. Comparison of these results with a functional map of miniF suggested possible roles of the proteins.