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

Purification and DNA binding of the D protein, a putative resolvase of the F-factor of Escherichia coli

The D protein encoded by plasmid mini-F promotes resolution of plasmid cointegrates or dimers of the F-factor or mini-F. In addition, two rfsF sequences are essential for this site-specific, recA-independent recombination event. The D gene was cloned into an expression vector and the gene product was overproduced in Escherichia coli and purified to homogeneity. The sequence of the N-terminus of the D protein was determined, thus permitting identification of the correct translational start codon in the nucleotide sequence that results in a 29.6 kDa protein. The binding site for the purified D protein is located within the mini-F NcoI-HpaI DNA fragment (192 bp). Binding seems to be affected by DNA methylation, since the protein did not bind to DNA isolated from a dam mutant of E. coli. The binding site, which is a region of approximately 28 bp and is located 160 bp downstream of the rfsF site, was identified by DNase I footprinting using fluorescence labelled DNA.

Partitioning of a mini-F plasmid into anucleate cells of the mukB null mutant

The partition-proficient mini-F plasmid pXX325 was stably maintained in the mukB null mutant, which is defective in chromosome partitioning into the two daughter cells. In the null mutant, the plasmid was partitioned into both nucleate and anucleate daughter cells, independently of host chromosomes.

Cloning and sequencing of the sacA gene: characterization of a sucrase from Zymomonas mobilis

The Zymomonas mobilis gene (sacA) encoding a protein with sucrase activity has been cloned in Escherichia coli and its nucleotide sequence has been determined. Potential ribosome-binding site and promoter sequences were identified in the region upstream of the gene which were homologous to E. coli and Z. mobilis consensus sequences. Extracts from E. coli cells, containing the sacA gene, displayed a sucrose-hydrolyzing activity. However, no transfructosylation activity (exchange reaction or levan formation) could be detected. This sucrase activity was different from that observed with the purified extracellular protein B46 from Z. mobilis. These two proteins showed different electrophoretic mobilities and molecular masses and shared no immunological similarity. Thus, the product of sacA (a polypeptide of 58.4-kDa molecular mass) is a new sucrase from Z. mobilis. The amino acid sequence, deduced from the nucleotide sequence of sacA, showed strong homologies with the sucrases from Bacillus subtilis, Salmonella typhimurium, and Vibrio alginolyticus.

Participation of hup gene product in ori2-dependent replication of fertility plasmid F

The fertility plasmid F'gal was not stably maintained in a hupA-hupB double mutant of Escherichia coli. Moreover, mini-F plasmids pFZY1, pFTC1 and pFTC2 were unable to transform the double mutant, though these plasmids efficiently transformed cells harboring a hupA or hupB single mutation. The composite plasmid pFHS1, which consists of the f5 DNA fragment of F plasmid and the whole DNA of a pSC101 derivative that carries a temperature-sensitive mutation for DNA replication, was not stably maintained in the hup double mutant at 42 degrees C. These findings strongly suggest that HU protein is required for ori2-dependent replication of the F plasmid.

Plasmid pIMI38--the pBR322 derivative with increased stability in E. coli cells

Plasmid pIM138 which had been characterized by the higher resistance of its DNA replication to the action of clorobiocin in comparison with the progenitor plasmid, was tested for its stability in host cells in the absence of the antibiotic. Growing without selective pressure, pIM138 was better maintained in cells than pBR322. The stability in the presence and in the absence of clorobiocin can be unanimously assigned to the plasmid itself, but some influence of host cells cannot be excluded.

Mechanism of autonomous control of the Escherichia coli F plasmid: purification and characterization of the repE gene product

E protein, the 29 Kd repE gene product, is essential for the replication of the Escherichia coli F plasmid. The repE gene has been cloned and expressed in an inducible ATG-fusion vector, and the protein product has been purified to homogeneity. The purified E protein is present as a dimer in solution and binds specifically to both the 19-bp direct repeats (incB) found within the mini-F origin of replication ori2 and the repE operator DNA. Examination of the amino acid sequence of E protein revealed a consensus sequence for DNA binding.

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

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 accurate partitioning 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.

Regulation of mini-F plasmid DNA replication. A quantitative model for control of plasmid mini-F replication in the bacterial cell division cycle

A quantitative model for the regulation of replication of plasmid mini-F in the Escherichia coli cell division cycle has been developed. The essential repE gene of mini-F encodes a polypeptide that serves both as a positive replication initiation protein and as a regulatory repressor protein. The mini-F regulatory processes include the interaction of repressor with an operator site in the autogenous control of transcription of the repE gene, and the binding of initiator to repeated DNA sequences located both downstream from the repE gene and at the replication origin. A statistical thermodynamic model was used to predict probable configurations of the regulatory processes in a single growing cell. These probabilities were coupled by a kinetic model to events of the cell cycle such as mRNA transcription and protein translation, and the initiation of plasmid DNA replication. Parameter values were chosen so that the simulated values for plasmid copy number and repressor and initiator protein concentrations of the model agreed with experimentally determined estimates for mini-F. Simulations of deviations from regular segregation of plasmid copies at cell division and of premature or delayed initiation of plasmid replication suggest that mini-F replication control responds rapidly and precisely to these perturbations. The simulations also accurately mimic the response of plasmid mini-F to various plasmid copy number mutations and to various mini-F regulatory elements provided in trans. These simulations predict a stable pattern of inheritance for plasmid mini-F despite its low plasmid copy number, in agreement with experimental observation.

The miniF plasmid C protein: sequence, purification and DNA binding

The C (pifC) protein of miniF represses transcription of its own gene by binding to the pif operator (pifO); it is also needed for replication initiated from the miniF primary origin (ori-1). We have determined the nucleotide sequence of the C gene. The gene has been inserted into an expression vector under Ptrp control where it is expressed at high levels. The C protein has been purified from cells carrying the Ptrp-C plasmid, and a preliminary study of C protein-DNA binding properties has been carried out. C protein binds strongly to pifO, and weakly to sequences in the ori-1 region.

Structure and function of the F plasmid genes essential for partitioning

The F plasmid in Escherichia coli has its own partition mechanism controlled by the sopA and sopB genes, and by the cis-acting sopC region. The DNA sequence of the entire partition region and its flanking regions is described here. Two large open reading frames coding for 43,700 Mr and 35,400 Mr proteins correspond to sopA and sopB, respectively. The sopB reading frame is located immediately downstream from the sopA reading frame. Twelve 43 base-pair direct repeats exist in the sopC region without any spacer regions, and one pair of seven base-pair inverted repeats exists in each of the direct repeats. Analysis of deletions in the sopC region showed that the direct repeats play an important role in plasmid partition and IncD incompatibility. IncG incompatibility is exhibited by pBR322 derivatives carrying the sopB gene alone. When compared with the partition genes parA and parB of plasmid P1, homology in amino acid sequence was found between the SopA protein of F and the ParA protein of P1, and also between SopB protein of F and ParB protein of P1. In addition, homology was found between Rep proteins of F and P1.

Mechanism of autonomous control of the Escherichia coli F plasmid: different complexes of the initiator/repressor protein are bound to its operator and to an F plasmid replication origin

E protein, the 29 kd product of the F plasmid repE gene, plays both positive and negative roles in the autoregulation of F replication. We have cloned and expressed the repE gene in an inducible ATG-fusion vector and have detected specific binding of E protein to the repE operator and to four 19-base pair direct repeats (incB) within the F plasmid replication origin ori2. Binding of E protein at the repE operator occurs with higher affinity than at ori2(incB) and gives almost complete protection to at least 30 base pairs, whereas binding of E protein to the direct repeats in the ori2 region shows an alternating pattern of enhanced and reduced sensitivity to DNAase cleavage consistent with a protein-induced folding of the DNA. These results provide direct biochemical support for a model of F plasmid replication in which the E protein serves both as an initiator of replication and as an autorepressor of its own synthesis.

Purification and properties of the mini-F plasmid-encoded E protein needed for autonomous replication control of the plasmid

Mini-F plasmid encodes a protein, E protein, that is indispensable for its autonomous replication. We have constructed a plasmid that overproduces the E protein and have purified the protein to apparent homogeneity. Using nitrocellulose filter binding and nuclease digestion assays, we demonstrated that the E protein binds to three unique regions of the mini-F DNA sequence: the replication origin (ori2) and an incompatibility locus (incB), another incompatibility locus (incC), and the promoter for the E gene. These binding sites have a common 8-base-pair sequence. These findings suggest the direct role of the E protein in initiation of mini-F replication and copy number control. They are also in line with the in vivo evidence that the incompatibility phenotype caused by incB and incC DNA is due to titration of a factor(s) indispensable for replication and that the production of the E initiator protein of the mini-F plasmid is under autoregulatory control.

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.

Twelve 43-base-pair repeats map in a cis-acting region essential for partition of plasmid mini-F

The nucleotide sequence of the DNA region involved in partitioning of plasmid mini-F has been determined. The sequence consists of 12 direct tandemly arranged repeats of 43 base pairs (the two flanking repeats, 43 plus 1 base pairs) with extensive homology to each other. Each repeat contains an additional inverted repeat of 7 base pairs.

Expression of recombinant DNA functional products in Escherichia coli anucleate minicells

This review covers the use of anucleate minicells of Escherichia coli for expressing the recombinant DNA encoded proteins. We briefly discuss the methods being used for preparation of anucleate minicells, incorporation of cloned DNA and assessment of gene expression. While the largest use has been that of microbially derived cloned functional DNA, examples of eukaryotic gene product synthesis have also been reviewed. This technology may represent some interesting commercial opportunities.

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.

Identification and antigenic characterization of virulence-associated, plasmid-coded proteins of Shigella spp. and enteroinvasive Escherichia coli

Seven plasmid-coded polypeptides, designated a through g, were identified by two-dimensional nonequilibrium pH gradient electrophoresis of radiolabeled extracts from minicells of virulent Shigella flexneri serotypes 2a and 5 and enteroinvasive Escherichia coli O143. These polypeptides were deemed to be products of 140-megadalton (MDa) virulence-associated plasmids because they were not synthesized in minicells which were not harboring a 140-MDa plasmid or in minicells which were carrying an F lac plasmid of the same incompatibility group. Synthesis of these polypeptides was repressed in minicells incubated at 30 degrees C and in minicells isolated from a noninvasive opaque colonial variant, even though these strains harbored a 140-MDa plasmid. Enriched fractions of polypeptides b, c, and d were obtained from S. flexneri serotype 5 by preparative isoelectric focusing, and polyclonal rabbit antisera recognizing each polypeptide were raised. These antisera were able to detect cross-reacting plasmid-coded polypeptide antigens in S. flexneri serotype 3, Shigella sonnei, and enteroinvasive E. coli O143. In addition, Western blots of minicell extracts from S. flexneri serotype 5 or E. coli O143 indicated that plasmid-coded polypeptides a through d were recognized by convalescent antiserum from a monkey infected with S. flexneri serotype 2a.

Partition of unit-copy miniplasmids to daughter cells. III. The DNA sequence and functional organization of the P1 partition region

The boundaries of the P1 par (plasmid partition) region of the unit-copy plasmid P1 were defined to within 2.7 X 10(3) base-pairs of DNA. The DNA sequence of the region revealed two large open reading frames that could encode proteins of Mr 44,000 and Mr 38,000. Both would be read in the same direction. The first open reading frame corresponds to the par A gene, the Mr 44,000 protein product of which was shown to be trans acting and essential for partition. The second open reading frame (parB) follows closely and may be cotranscribed with par A. The codon usage frequency for parB is consistent with its producing a protein product. The ParB protein was identified in cell extracts as a product with an apparent Mr of 45,000, suggesting that it behaves anomolously on gel electrophoresis. Following parB is the incB region, an incompatibility determinant thought to be the cis acting site that constitutes the putative attachment point on the DNA for the cellular partition apparatus. Subcloning of this site showed it to consist of a maximum of 174 base-pairs. The incB sequence is highly A + T-rich and contains a 20 base-pair inverted repeat. Another A + T-rich inverted repeat of similar size but different sequence is found between the putative parA promoter and the ribosome initiation sequence at the start of the parA open reading frame and may be involved in the autoregulation of ParA synthesis. The par region appears to contain a functional analog of the centromere of eukaryotic chromosomes. It is responsible for ensuring that newly replicated plasmids are properly distributed to daughter cells during cell division of its Escherichia coli host.

Mutations affecting replication and copy number control in plasmid mini-F both reside in the gene for the 29-kDa protein

We have isolated and characterized cop, copts, and repam mutants of plasmid mini-F after in vitro mutagenesis with hydroxylamine. cop mutants exhibit a copy number of about 10 per cell. The copts mutants are cold-sensitive and have, at 25 degrees C, a copy number of about 30-40 copies per cell, which drops to 4 copies at 42 degrees C. The cop and repam mutations affect the 29-kDa E protein. The Copts phenotype results from the simultaneous occurrence of two mutations, a cop mutation in the E protein and a temperature-dependent mutation (termed ecp) enhancing the Cop phenotype at low temperature. The latter new type of mutation is located within the DNA region 44.1-44.85F. Complementation experiments with plasmid cointegrates show that the wild-type gene is dominant over the cop allele. The nucleotide sequences of the cop and the repam mutations have been determined.

Mini-F protein that binds to a unique region for partition of mini-F plasmid DNA

A mini-F-coded protein, named F2 protein, binds specifically to mini-F DNA. This protein has a molecular weight of 37,000 and is coded by the A2 segment of the mini-F genome (47.3 to 49.4 kilobases on the F coordinate map). The binding site is located also in the A2 segment of mini-F. This binding site is lost by spontaneous deletion when the A2 segment alone, but not A2 together with its neighboring segment, is cloned in a multicopy plasmid pBR322. These data are discussed in connection with incompatibility and plasmid stability.

Identification of a gene, tir of R100, functionally homologous to the F3 gene of F in the inhibition of RP4 transfer

We detected a gene of R100 functionally homologous to the F3 gene of F in the inhibition of RP4 transfer. Using in vitro recombinant DNA techniques, we located the gene, designated tir, in a 0.9 kb region, 2,392-3,293 in the nucleotide sequence coordinate of R100. From the DNA sequence analysis of R100 (Ohtsubo unpublished results), a coding frame of polypeptides, whose molecular weight is estimated to be 24.1 kilodaltons (kd), was inferred to be the region tir. Furthermore, we showed that tir could not repress expression of the F3 gene.

Additional genes essential for replication of the mini-F plasmid from origin I

We isolated a series of Tn5-insertional mutants from the mini-F plasmid, which has a deletion in the origin II region and replicates exclusively from origin I, and found that the mutants that had Tn5 in either the F4 or the F5 gene were defective in their replication. It is concluded that, in addition to the F3 gene on which we have reported previously, both the F4 and the F5 genes are essential for the replication from origin I.

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.

Mechanisms essential for stable inheritance of mini-F plasmid

The F plasmid has its own partition mechanism and ccd mechanism (coupled cell division), besides its own replication mechanism, in order to be stably inherited into daughter cells through cell division. These 3 mechanisms are independent of one another. Therefore, when a DNA segment essential and sufficient for a mechanism is jointed to other heterologous plasmids, the segment is also functional. Most of natural low copy number plasmids might also have their own replication, partition, and ccd mechanisms. These 3 mechanisms may be fundamental to ensure stable inheritance for low copy-number replicons in prokaryotes.

The partition functions of P1, P7, and F miniplasmids

The partition regions of P1, P7, and F miniplasmids are discrete DNA sequences of about 3 kb in length that will promote accurate partition of hybrid plasmids independent of the source of replication functions or the position or orientation of the elements. Each of the par regions seems to be very similarly organized, with open reading frames for essential proteins and a terminal site which appears to be analogous to the centromere of eukaryotic cells. When cloned, these terminal sites exert incompatibility against their respective parent plasmids presumably because they can compete with the parent plasmids as substrates for partition. We have determined the complete DNA sequence of the P1 par region. In addition to the open reading frame for the essential parA protein (42-44 kd), the region contains a second open reading frame which could encode a 38-kd protein. The 2 large open reading frames appear to form an operon that is negatively regulated from a site adjacent to the promoter and responds to the par gene products in trans. Both this site and the downstream "centromere" site, incB, contain blocks of extremely AT-rich sequences, which are postulated to be binding sites for par proteins. The incB and upstream AT-rich regions both contain 20-bp imperfect inverted repeats. Further downstream from the minimal incB sequence (172 bp) lies an additional region which is essential for partition. The further analysis of the P1 par region should be greatly facilitated by the finding that it can function in cis to stabilize pBR322 vectors under conditions where the copy number of pBR322 is reduced.

The mini-F primary origin. Sequence analysis and multiple activities

The sequence of an 897 base-pair fragment (42.1 to 43.0 kilobase co-ordinates on the F genetic map) containing the primary origin (ori-1) of mini-F replication has been determined. It contains one significant open reading frame, which probably codes for part of the C protein thought to be necessary for ori-1 replication activity. Tests of the ability of the sequenced ori-1 region to direct replication of DNA polymerase I-dependent replicons revealed that ori-1 replication requires adjacent mini-F sequences, 43.0 to 43.9 kilobase co-ordinates on the F genetic map in cis as well as a trans-acting gene product, probably the E protein, from the essential replication region of mini-F. In addition, a sequence required for control of pif gene expression has been mapped to a 160 base-pair region immediately upstream from the C (pifC) gene, and the crossover site of a specific recA-independent recombination mechanism has been mapped to a 220 base-pair region on the side of the pif control sequence distal to the C gene.

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.

Cloning and analysis of pif, replication and leading regions of the F plasmid

We describe the molecular cloning of BglII fragments of the hybrid plasmid pRS5 (pSC101 and EcoRI fragments of F; f7, f5, f3 and f6). The clones isolated were examined for the expression of F-specified replication, incompatibility, mobilization and inhibition of T7 bacteriophage multiplication. Proteins directed by the BglII clones were labelled in Escherichia coli K12 maxicells and analyzed by SDS-polyacrylamide gel electrophoresis. The sizes of previously reported proteins, encoded by the replication, incompatibility and leading regions encompassed by these plasmids have been confirmed in this study. In addition, the results demonstrate that a pif gene, which encodes an 80,000 dalton polypeptide essential for the inhibition T7 phage multiplication, is located on the BglII fragment that spans the junction of EcoRI fragments f7 and f5.

Molecular analysis of F plasmid pif region specifying abortive infection of T7 phage

We report the molecular cloning of the pif region of the F plasmid and its physical dissection by subcloning and deletion analysis. Examination of the polypeptide products synthesized in maxicells by plasmids carrying defined pif sequences has shown that the region specifies at least two proteins of molecular weights 80,000 and 40,000, the genes for which appear to lie in the same transcriptional unit. In addition, analysis of pif-lacZ fusion plasmids has detected a pif promoter and determined the direction of transcription across the pif region.

Identification of the minimal essential region for the replication origin of miniF plasmid

The minimal replication origin of miniF plasmid was found to lie within a region of 217 bp in length. This region contains an AT cluster and the four 19 bp direct repeats responsible for incompatibility, termed incB. Its location coincides with hat of ori2 of plasmid F, previously inferred to be the replication starting point by electron microscopic analysis (Eichenlaub et al. 1981).

An essential gene for replication of the mini-F plasmid from origin I

We constructed a series of defective mini-F plasmids, which have deletion(s) in the replication origin I and/or origin II, and their derivatives, which do not produce F3 protein, by insertion of the XhoI fragment of Tn5 into the XhoI site at 41.0 F (kilobases on the coordinate map of F-plasmid). Using these mutant mini-F plasmids, we found that F3 protein is essential for the replication of mini-F from origin I, but not from origin II.

Transcription in the trfA region of broad host range plasmid RK2 is regulated by trfB and korB

Transcription at various points in the trf A region of broad host range plasmid RK2 has been analysed by measuring expression of the galK gene inserted at EcoRI sites introduced previously by TB1723 transposition mutagenesis. Rightward transcription (anti-clockwise on RK2) probably from a single promoter, proceeds across two open reading frames coding for a 13 kD polypeptide of unknown function, and the trf A gene, which provides a protein(s) essential for plasmid replication. This transcription is not auto-regulated by the products of either open reading frame and is also not subject to significant attenuation prior to the end of the trfA open reading frame. Leftward transcription appears to be directed by at least two well separated promoters, the more leftward being three to four times stronger than the more rightward. Rightward, but not leftward, transcription is repressed about 9-fold by the trfB locus of RK2 alone (so far not separable from the loci korA and korD) in trans while the combination of the korB and trfB loci in trans represses both rightward transcription (about 100-fold) and leftward transcription (the stronger activity by 10 to 15-fold). Regulation of these operons is therefore qualitatively different. The kilD locus in the trfA region, which is suppressed by korD (trfB) is thus probably part of the rightward (trfA) operon, while leftward transcription may represent the start of an operon containing kilB. The results suggest that RK2kor loci act by repressing transcription of kil loci and that the kil and kor control circuits may be part of an interlocking system of RK2 genes involved in replication and stable maintenance.

Analysis of the trfA region of broad host-range plasmid RK2 by transposon mutagenesis and identification of polypeptide products

Broad host-range plasmid RK2 is a member of the Escherichia coli incompatibility group P. Unlike most other groups of plasmids, members of the P group are capable of efficient transfer between and maintenance in most gram-negative bacterial species. It is of interest whether this broad host-range results from differences between the mechanism of replication of broad and narrow host-range plasmids. The regions of RK2 required for replication in E. coli have previously been defined as an origin of vegetative replication, oriVRK2 , and a gene, trfA , specifying a positively required trans-acting product. In this study Tn1723 transposon insertions have been used to map the trfA gene and determine its functional gene product. The Tn1723 insertions define the outer limits of the gene, a promoter region, a "leader" region not essential for trfA activity and a coding region. Three polypeptides of 13 X 10(3), 43 X 10(3) and 32 X 10(3) molecular weight are produced from this region and the production of a 32 X 10(3) Mr polypeptide is shown to be correlated with trfA activity in E. coli. Analysis of polypeptides produced from transposon insertion derivatives in which all but 35 base-pairs of inserted DNA is deleted, along with the effect of these insertions on trfA activity, suggest that the 43 X 10(3) and 32 X 10(3) Mr polypeptide coding sequences overlap in the same reading frame and that all three polypeptides (13 X 10(3), 32 X 10(3) and 43 X 10(3) Mr) may be translated from the same initial transcript.

Stabilization of the cloning vector pACYC184 by insertion of F plasmid leading region sequences

The leading region of the F plasmid is, by definition, the first part of the plasmid DNA to be transferred to the recipient cell during conjugation. Restriction fragments of the leading region, when cloned into the plasmid vector pACYC184, extended the maintenance of the normally unstable p15A-derived vector replicon in rec+ Escherichia coli K-12 cells. Mutations in the host's general recombination systems were found to influence the maintenance of these hybrid plasmids.

Transcriptional analysis of the leading region in F plasmid DNA transfer

Transcriptional activity associated with the leading region (53.8-66.7F) in F DNA transfer has been shown by RNA-DNA hybridization studies to occur on the anterior segment extending from 59.4 to 66.7F. Promoter-probe analysis of cloned leading region segments detected two promoters within the transcribed portion of the leading region. The promoter active across the 64.7F EcoRI site on the transferred F strand was associated with the expression of two polypeptides, 6d and 13.5p, located between 64.7-66.6F. However, no definite role could be ascribed to the second promoter operative through the 66.6F Bg/II site located in close proximity to oriT, the origin of transfer.

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.

DNA sequence of an amber replication mutant indicates that a 29 kd protein is the product of the F plasmid replication gene

DNA sequencing shows that the mutational alteration resulting from an amber-suppressible replication-defective mutation of F plasmid is a single base pair change from C:G to T:A which yields an amber codon in the coding frame for a 29 kd polypeptide located in the minimal replication region. We thus identified the gene indispensable for F DNA replication as the coding frame which encodes a 29 kd polypeptide. We will designate this gene repA.

P1 plasmid replication: replicon structure

Bacteriophage P1 lysogenizes Escherichia coli as a unit-copy plasmid. We have undertaken to define the plasmid-encoded elements implicated in P1 plasmid maintenance. We show that a 2081 base-pair fragment of the 90,000 base P1 plasmid confers the capacity for controlled plasmid replication. DNA sequence analysis reveals several open reading frames in this fragment. The largest is shown to encode a 32,000 Mr protein required for plasmid replication. The corresponding gene, repA, has been identified genetically. A set of five 19 base-pair repeats is located upstream from repA; a set of nine similar repeats is located immediately downstream from repA. Each set of repeats, when cloned into pBR322, exerts incompatibility towards a P1 replicon. The upstream set, designated incC, consists of direct repeats that are spaced about two turns of the DNA helix apart; the downstream set, designated incA, consists of nine repeats arranged three in one orientation and six in the other. Spacing between incA repeats were three or four turns of the helix apart. The organization of the plasmid maintenance regions of P1 and the unit-copy sex factor plasmid, F, is strikingly similar. Although the DNA sequences of this region in the two plasmids exhibit little homology, a 9 base-pair sequence that appears four times in the origin region of members of the Enterobacteriaceae also occurs twice as direct repeats in similar positions in P1 and F. This sequence, where it occurs in E. coli, has been postulated to be the binding site for the essential replication protein determined by dnaA. The dnaA protein appears not to be essential for the replication of either plasmid; therefore, the function of the sequence in P1 and F may be regulatory.

Replication of the broad host range plasmid RSF1010: requirement for three plasmid-encoded proteins

Cloning of specific regions of plasmid RSF1010, in conjunction with in vitro replication studies, has revealed three novel genes: repA, repB, and repC. They are clustered in one region of the plasmid, separated from the origin of replication by regions that are not essential for plasmid viability in an Escherichia coli host. In vivo, a 2.1-kilobase segment of the plasmid, bearing the replication origin, can establish itself as an autonomous replicon if the DNA region carrying the three rep genes is present in the same cell on an independent plasmid. In vitro, RSF1010 DNA is efficiently replicated by an ammonium sulfate fraction from the E. coli extract, provided the extracts are prepared from cells that can supply the required rep gene products. Using cells containing the cloned rep gene region as a source of elevated levels of the rep proteins, we have partially purified these proteins in functional form. When added to an enzyme fraction derived from plasmid-free cells, they specifically promote the replication of plasmid DNA bearing the RSF1010 origin.

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.

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.

Identification of the pifC gene and its role in negative control of F factor pif gene expression

The pif region of the F factor includes two genes, pifA and pifB, that lead to abortive T7 infection. We have identified a new gene in this region, pifC, by constructing an in vitro fusion of pif DNA at 41.6 kilobases on the F factor physical map to the lacZ gene. A PifC-LacZ fusion protein of 149,000 daltons has been identified by immunoprecipitation and polyacrylamide gel electrophoresis. This allows us to assign the N terminus of pifC to 42.5 kilobases on the F map. Using fusions of pifC, pifA, and pifB to lacZ, we have studied the regulation of pif gene expression and have shown that the product of pifC negatively controls its own expression and that of pifA and pifB.