Replication mutants of the F-plasmid of Escherichia coli. II. Cloned replication regions of temperature-sensitive mutants

Characterization of two autoreplicative regions of the IncHI2 plasmid R478: RepHI2A and RepHI1A((R478))

Plasmids of the incompatibility groups HI and HII (IncH plasmids) generally confer multiple antibiotic resistances upon their host pathogenic strain. IncHI group plasmids are distinguished by their property of optimal transfer by conjugation at temperatures below 30 degrees C, allowing for the spread of multiple antibiotic resistance outside their host natural environment, the gut. Plasmids of the IncHI1 subgroup encode multiple replicons. In the present study it is shown that the prototype IncHI2 subgroup plasmid, R478, contains at least two iteron-controlled autoreplicative regions, RepHI2A and RepHI1A((R478)). The DNA sequence and the molecular characteristics of each replicon region are described. RepHI2A is unique to plasmids of the IncHI2 subgroup and contains an unusually large number of iteron sequences downstream of the replication initiator gene. The nucleotide sequence of the replication initiator gene and of the iterons within RepHI1A((R478)) show very close similarity with those of the previously reported RepHI1A replicon of the IncHI1 subgroup plasmid R27. The presence of RepHI1A((R478)) on R478 most likely accounts for the observed incompatibility between R478 and plasmids of the IncHI1 subgroup. These are the first autoreplicative regions from an IncHI2 subgroup plasmid to be described.

Analysis of the F plasmid centromere

The nucleotide sequence of the cis-acting partition site (centromere) of the miniF plasmid has been determined. Its most notable feature is a reiterated 43 base pair unit. A series of plasmids deleted for portions of the repeat region was constructed and tested for incompatibility with R386 and for stability of inheritance. The extent of incompatibility with R386 was correlated with the number of repeat units. In contrast, the great majority of the repeats were not needed for miniF stability. An adjacent region of unique sequence was also found to be involved in centromere function.

Analysis of a region in plasmid R386 containing two functional replicons

A miniplasmid has been obtained from R386 by ligating EcoRI fragments with a fragment carrying a kanamycin-resistance gene. It contains a 6.8-kb Eco fragment of R386 which hybridizes strongly with several IncFI plasmid DNAs but not with the primary or secondary replicons of the F plasmid. This mini-R386 is incompatible with certain IncFI plasmids, and it appears to be one example of a previously unidentified replicon widely distributed in the IncFI group. A region of R386 not closely linked to the 6.8-kb fragment is involved in copy number control of the mini-R386, and a sequence in the same region interacts with mini-F partition functions to cause incompatibility. The 6.8-kb fragment also restricts growth of T7 bacteriophage, and an adjacent fragment restricts phage T4 growth. A further R386 sequence, sharing homology with the F secondary replicon, is capable of autonomous replication. Hence R386, like F, contains at least two functional replicons.

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.

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.

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.

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.

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.

Two mini-F-encoded proteins are essential for equipartition

The par region of mini-F is both necessary and sufficient to promote equipartition of plasmid copies to daughter cells. It is approximately 2.5 kb long and contains the coding sequences for two proteins, F1 (41 kDa) and F2 (37 kDa). We isolated 13 mutants of a phage lambda-mini-F hybrid that form unstable plasmids. Two of these putative Par- mutants are fully suppressible nonsense (amber) mutants. One of the amber mutants, par-41, eliminates the synthesis of F1, generating a large nonsense fragment of the protein. The other mutant, par-36, eliminates the synthesis of F2. Thus both proteins appear to be essential for plasmid equipartition.

IncD, a genetic locus in F responsible for incompatibility with several plasmids of the IncFI group

Cloning of mini-F DNA segments has led to the identification and mapping of a locus, incD, involved in incompatibility reactions with many IncFI plasmids. The cloned incD locus expressed incompatibility with F, R386, and six other IncFI plasmids but not with ColV3-K30 or pHH507 which lack sequence homology with the incD region. A sequence of 360 bp (48.66-49.02 FKB) was found to be sufficient for expression of incD incompatibility. Multicopy vectors containing incD are compatible with each other, but can be displaced by mini-F plasmids deleted for incD. These results indicate that incD-mediated incompatibility reactions require the presence of replication genes to which incD is normally linked. The degree of incompatibility exercised by incD is moderate compared with that of other inc loci in F, suggesting that incD is involved in an aspect of plasmid maintenance, such as partition, different from the functions of the other inc loci.

Effects of Tn5 insertion in the incD region on mini-F maintenance and polypeptide synthesis

The gene coding for the 33,000 dalton protein (B protein) of the mini-F plasmid has been mapped by minicell polypeptide analysis to 47.3-48.2 Fkb. Transcription of the gene is initiated near 47.3 Fkb. Gene B mutants overproduce the 42,000 dalton protein (A protein) of mini-F. Insertions of Tn5 in the B gene and in the incD region cause instability of plasmid inheritance. Mini-F plasmids deleted for part of gene B are not maintained in the absence of the incD region. B protein and the incD region appear to interact in promoting mini-F maintenance.

Construction and characterization of a novel two-plasmid system for accomplishing temperature-regulated, amplified expression of cloned adventitious genes in Escherichia coli

We describe a two-plasmid system that utilizes the lacZ gene promoter and temperature-responsive plasmid replicons to accomplish closely regulated high-level expression of heterologous genes in Escherichia coli. One of the plasmids fails to replicate at 42 degrees C and contains a gene encoding the lac repressor; the second plasmid, which undergoes multicopy "runaway" replication at elevated temperatures, contains an adventitious gene under control of the operator-promoter system of the lacZ gene. Concurrent derepression of lac promoter function and amplification of copy number of the lac-controlled gene occurs when the temperature is elevated. We have used a structural gene encoding chloramphenicol acetyltransferase to demonstrate that the gene product under control of the lacZ promoter represents a major fraction of the total protein synthesized at 43 degrees C, whereas only minimal quantities of this enzyme are made at 30 degrees C. The system described allows the controlled expression of gene products that may have detrimental effects on cell growth, and provides a simple method for identifying radioactivity-labeled protein products of cloned genes in bacterial whole-cell extracts. The system also offers an alternative to intragenic temperature-sensitive mutations for studying the function of various enzymatic or regulatory proteins.

Analysis of mini-F plasmid replication by transposition mutagenesis

Derivatives of a mini-F plasmid in which Tn3 is inserted in F deoxyribonucleic acid were obtained, and the sites of insertion for 40 of the derivatives were mapped. Tn3 was found to insert at many sites within mini-F, but most insertions were within the 43.0- to 43.7-kilobase (kb), 44.2- to 44.7-kb, and 45.9- to 46.3-kb segments. Hence, these segments are unnecessary for mini-F replication. Most of the Tn3 derivatives were similar to their parent miniplasmid with respect to copy number, stability, and incompatibility. Insertions at 45.15 kb and near 46.0 kb caused a moderate disruption of copy number control, and insertion at 47.6 kb resulted in unstable maintenance. Deletion derivatives lacking deoxyribonucleic acid between 40.3 and 44.76 kb and between 45.92 and 49.4 kb were obtained. This observation suggests either that mini-F contains a third origin, in addition to those already reported to be at 42.6 and 44.4 kb, or that the reported position of the secondary origin, 44.4 kb, is incorrect and that this origin is between 44.76 and 45.92 kb.