Replication of the R factor Rts1 in Proteus mirabilis

A comprehensive list of genes required for the efficient conjugation of plasmid Rts1 was determined by systematic deletion analysis

While conjugation-related genes have been identified in many plasmids by genome sequencing, functional analyses have not yet been performed in most cases, and a full set of conjugation genes has been identified for only a few plasmids. Rts1, a prototype IncT plasmid, is a conjugative plasmid that was originally isolated from Proteus vulgaris. Here, we conducted a systematic deletion analysis of Rts1 to fully understand its conjugation system. Through this analysis along with complementation assays, we identified 32 genes that are required for the efficient conjugation of Rts1 from Escherichia coli to E. coli. In addition, the functions of the 28 genes were determined or predicted; 21 were involved in mating-pair formation, three were involved in DNA transfer and replication, including a relaxase gene belonging to the MOBH12 family, one was involved in coupling, and three were involved in transcriptional regulation. Among the functionally well-analysed conjugation systems, most of the 28 genes showed the highest similarity to those of the SXT element, which is an integrative conjugative element of Vibrio cholerae. The Rts1 conjugation gene set included all 23 genes required for the SXT system. Two groups of plasmids with conjugation systems nearly identical or very similar to that of Rts1 were also identified.

Bacterial toxin HigB associates with ribosomes and mediates translation-dependent mRNA cleavage at A-rich sites

Most pathogenic Proteus species are primarily associated with urinary tract infections, especially in persons with indwelling catheters or functional/anatomic abnormalities of the urinary tract. Urinary tract infections caused by Proteus vulgaris typically form biofilms and are resistant to commonly used antibiotics. The Rts1 conjugative plasmid from a clinical isolate of P. vulgaris carries over 300 predicted open reading frames, including antibiotic resistance genes. The maintenance of the Rts1 plasmid is ensured in part by the HigBA toxin-antitoxin system. We determined the precise mechanism of action of the HigB toxin in vivo, which is distinct from other known toxins. We demonstrate that HigB is an endoribonuclease whose enzymatic activity is dependent on association with ribosomes through the 50 S subunit. Using primer extension analysis of several test mRNAs, we showed that HigB cleaved extensively across the entire length of coding regions only at specific recognition sequences. HigB mediated cleavage of 100% of both in-frame and out-of-frame AAA sequences. In addition, HigB cleaved approximately 20% of AA sequences in coding regions and occasionally cut single As. Remarkably, the cleavage specificity of HigB coincided with one of the most frequently used codons in the AT-rich Proteus spp., AAA (lysine). Therefore, the HigB-mediated plasmid maintenance system for the Rts1 plasmid highlights the intimate relationship between host cells and extrachromosomal DNA that enables the dynamic acquisition of genes that impart a spectrum of survival advantages, including those encoding multidrug resistance and virulence factors.

Complete nucleotide sequence of plasmid Rts1: implications for evolution of large plasmid genomes

Rts1, a large conjugative plasmid originally isolated from Proteus vulgaris, is a prototype for the IncT plasmids and exhibits pleiotropic thermosensitive phenotypes. Here we report the complete nucleotide sequence of Rts1. The genome is 217,182 bp in length and contains 300 potential open reading frames (ORFs). Among these, the products of 141 ORFs, including 9 previously identified genes, displayed significant sequence similarity to known proteins. The set of genes responsible for the conjugation function of Rts1 has been identified. A broad array of genes related to diverse processes of DNA metabolism were also identified. Of particular interest was the presence of tus-like genes that could be involved in replication termination. Inspection of the overall genome organization revealed that the Rts1 genome is composed of four large modules, providing an example of modular evolution of plasmid genomes.

Function of the N-terminal half of RepA in activation of Rts1 ori

The RepA protein of the Rts1 plasmid, consisting of 288 amino acids, is a trans-acting protein essential for replication. A mutant repA gene, repA delta C143, carrying a deletion that removed the 143 C-terminal amino acids of RepA, could transform, but at a low frequency, an Escherichia coli polA strain, JG112, when repA delta C143 was cloned into pBR322 with Rts1 ori in the natural configuration. The transformation was less efficient without the dyad DnaA box in the ori region, and no transformation occurred at 42 degrees C, characteristic of Rts1 replication. A fusion of the 3'-terminal half of repA of the P1 plasmid to repA delta C143 yielded a pBR322 chimeric plasmid that contained Rts1 ori through hybrid (Rts1-P1) repA. This plasmid was maintained much more stably in JG112 at 37 degrees C. At 42 degrees C, however, it was quite unstable. The overproduced hybrid RepA protein showed interference with mini-Rts1 replication in trans and also exhibited an autorepressor function, although both activities were decreased. These findings suggest that the N-terminal half of the RepA molecule of Rts1 is involved in the activation of the replication origin.

Site-directed mutations in the repA C-terminal region of plasmid Rts1: pleiotropic effects on the replication and autorepressor functions

We induced site-directed mutations near the 3' terminus of the gene repA, which encodes the protein of 288 amino acid residues essential for plasmid Rts1 replication, and obtained seven repA mutants. Three of them contained small deletions at the 3' terminus. Mutant repAz delta C4, which encodes a RepA protein that lacks the C-terminal four amino acids, expressed a high-copy-number phenotype and had lost both autorepressor and incompatibility functions. Deletion of one additional amino acid residue to form the RepAz delta C5 protein caused restoration of the wild-type copy number and strong incompatibility. Studies of the remaining four repA mutants, each of which contained a single amino acid substitution near the RepA C terminus, suggested that Lys-268 is involved in both ori(Rts1) activation and autorepressor-incompatibility activities and that Arg-279 contributes to ori(Rts1) activation but not to incompatibility. Lys-268 is part of a dual-lysine sequence with Lys-267 and is located 21 amino acids upstream of the RepA C terminus. A dual-lysine sequence is also found at a similar position in both mini-F RepE and mini-P1 RepA proteins.

Effects of mutations in the repA gene of plasmid Rts1 on plasmid replication and autorepressor function

We constructed a system in which wild-type RepA or RepAcop1 protein was supplied in trans in various amounts to coexisting mini-Rts1 plasmids by clones of the repA or repAcop1 gene under the control of the native promoter with or without its operator sequence. RepAcop1 protein which contains a single amino acid substitution (Arg-142 to Lys) within its 288 amino acids could initiate the replication of the mini-Rts1 plasmid efficiently at both 37 and 42 degrees C even if it was supplied in excess. In contrast, excess wild-type RepA inhibited plasmid replication at 37 degrees C but supported replication at 42 degrees C. Therefore, it appears that the initiator activity of RepA is not related to the incompatibility phenotype associated with an excess of RepA protein. An immunoblot analysis revealed that neither RepA nor RepAcop1 synthesis was temperature sensitive and that both were autogenously regulated to a similar extent because of the presence of an operator located immediately upstream of the promoter. Two mutant RepA proteins, each of which contains a 4-amino-acid insertion in the middle of the protein, maintained the autorepressor and incompatibility activities but lost the ori(Rts1)-activating function.

Purification of Rts1 RepA protein and binding of the protein to mini-Rts1 DNA

RepA protein, essential for the replication of plasmid Rts1, was purified, and its binding to mini-Rts1 subregions was examined by a DNase I protection assay. RepA protected the incI and incII iterons, a region immediately upstream of the repA promoter, and a 10-base-pair region located between the most external incII iteron and a GATC box. The protection was less efficient when preheated RepA was used.

Incompatibility properties of Col E1 and pMB1 derivative plasmids: random replication of multicopy replicons

The incompatibility properties of Col E1-like plasmids have been examined in Rec+ and RecA- bacteria. Two Col E1- (or two pMB1-) derivative plasmids coreplicated in the same clone for many cell doublings, irrespective of the rec genotype of host bacteria. Their kinetics of segregation were found to be consistent with models that assume a random choice of template molecule for each plasmid replication event, but with models based on a single (master) template molecule per cell. In contrast, minimal coreplication of a Col E1- and a pMB1-derivative plasmid occurred, with the latter type rapidly excluding the former. We suggest here that the pMB1 derivatives, pMB9 and pBR322, are less sensitive than Col E1 derivatives to the putative inhibitor that regulates plasmid replication, due to base sequence differences in their target for the inhibitor, and consider one mechanism whereby the duplication of Col E1-like plasmids might be regulated.

Mating due to loss of surface exclusion as a cause for thermosensitive growth of bacteria containing the Rtsl plasmid

At 25 degrees C, Rtsl+ bacteria grow to about 5 X 10(9) bacterial/ml before leveling off, whereas at 42 degrees C they grow from 2.6 X 10(8) bacteria/ml for only 2-3 generations after temperature shift before the growth is inhibited with a zig-zag pattern at the plateau. When diluted, Rtsl+ bacteria grow rapidly at 42 degrees C, until the concentration reaches as high as the undiluted 42 degrees C culture when growth measured by colony counts stops and the zig-zag pattern again appears. This density-dependent growth inhibition is not due to the presence of stable growth inhibitor(s). Mating experiments show that at 42 degrees C, Rtsl+ bacteria retain good donor ability; at the same time, they become good recipients in mating with Hfr (Rtsl) bacteria. SDS-PAGE reveals that membranes are altered at 42 degrees C. Examination of DNA synthesis indicates that chromosomal DNA is synthesized at both 25 degrees C and 42 degrees C at high bacterial concentration, but that of the Rtsl plasmid is slowed down at 42 degrees C. The labeling experiments suggest that in 2 h there are 2 rounds of plasmid replication at 25 degrees C, 3.5 rounds at 42 degrees C when bacteria are diluted, and 0.6 rounds at 42 degrees C when bacteria are not diluted. These results suggest that the growth inhibition of Rtsl+ bacteria at 42 degrees C is probably the consequence of mating initiated due to loss of surface exclusion.

Further characterization of the R plasmid Rts1 and its mutant pTW2: replication and incompatibility of the plasmid

Incompatibility of the R plasmid Rts1 and its replication mutant pTW2 was studied in recA host cells of Escherichia coli. When the R plasmid R401, belonging to the same incompatibility group as Rts1, was used as a test plasmid, R401 was eliminated preferentially from (Rts-R401)+ cells irrespective of the direction of transfer. In contrast, pTW2 and R401 were mutually excluded. The decreased incompatibility of pTW2 was confirmed by a direct incompatibility test in which a derivative of Rts1 expelled pTW2 exclusively. Alkaline sucrose gradients of pTW2 and Rts1 DNA indicated that approximately one-fourth of the Rts1 genome was deleted in pTW2. In addition, both the various temperature-dependent properties of Rts1 and the inhibitory effect on phage T4 development were also lost in pTW2. A possible mechanism that regulates the stringent replication of Rts1 is discussed.

Host-dependent, thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae

The thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae, was studied. pJY5 consisted of 61 million daltons of covalently closed circular (CCC) deoxyribonucleic acid (DNA) with a buoyant density of 1.714 g/cm3 (55 mol % guanine plus cytosine). In Escherichia coli, this plasmid replicated stringently at 32 degrees C, but ceased its CCC DNA replication after a short incubation at 42 degrees C, resulting in production of R- segregants. The thermosensitive replication of pJY5 was not overcome by the coexistence of non-thermosensitive R plasmids. The plasmid manifested an inhibitory effect on host bacterial cell growth at 42 degrees C, although the effect was less prominent than that of R plasmids belonging to the T-incompatibility group, Rts1, R401, and R402. When the pJY5 plasmid was transferred into E. cloacae, however, no R- segregants were detected at any culture temperature, even 42 degrees C. Alkaline sucrose gradient analysis revealed that a significant amount of pJY5 CCC DNA was synthesized in E. cloacae at the high temperature but not in E. coli. Furthermore, the growth-inhibitory effect of pJY5 on hosts at 42 degrees C was not observed in E. cloacae. On the other hand, Rts1 and R401 were found to be thermosensitive in E. cloacae as well as in E. coli.

Temperature sensitive R plasmids isolated from Proteus strains

Out of 32 R plasmids isolated from Proteus strains, 17 were found to be temperature sensitive with respect to inheritance in E. coli cells. They were fi- and classified into incompatibility group T or V. Cells carrying T group Rms273 plasmid were temperature sensitive with respect to growth and conjugal transfer in both E. coli and Proteus. The V group YOR-10 plasmid was stable in Proteus even at 42 C. However, the loss frequency of YOR-10 plasmid in E. coli reached 100% after 4 hr of incubation at 42 C, in spite of stable inheritance at 25 C. Conjugal transfer of the YOR-10 plasmid in E. coli was also strongly inhibited at 42 C. It has been concluded that instability of V group R plasmids in E. coli is due to their thermosensitive inheritance in the progeny cells at high temperatures.

Replication of thermosensitive Rts1 plasmid deoxyribonucleic acid at the nonpermissive temperature

Replication of the thermosensitive drug resistance factor Rts1 was studied at the nonpermissive temperature (42 degrees C). It was concluded from the following observations that replication of this plasmid takes place at 42 degrees C without involving the covalently closed circular (CCC) form of deoxyribonucleic acid (DNA). (i) DNA-DNA- reassociation kinetics studies with purified Rts1 DNA showed that Rts1 DNA increased several-fold during cell growth at 42 degrees C while very little, if any, CCC DNA was synthesized. (ii) When Escherichia coli 20S0(Rts1) was labeled with [3H]thymidine at 42 degrees C, a significant amount of radioactive DNA hybridizable to Rts1 DNA was formed. This DNA was found in a fraction where DNA other than CCC DNA was expected in alkaline sucrose density gradient centrifugation analysis. When E. coli 20S0(Rts1) was labeled at 32 degrees C, the labeled CCC DNA did not disappear during a chase period at 42 degrees C. This indicates that preformed CCC DNA does not participate in replication at the nonpermissive temperature. These results are consistent with the hypothesis that there are two modes of replication of Rts1 DNA, one involving a CCC molecule and the other not involving this form, and that only the latter mode takes place at the nonpermissive temperature.

Requirement of cyclic adenosine 3',5'-monophosphate for the thermosensitive effects of Rts1 in a cyclic adenosine 3',5'-monophosphate-less mutant of Escherichia coli

Previous publications showed that a covalently closed circular (CCC) Rts1 plasmid deoxyribonucleic acid (DNA) that confers kanamycin resistance upon the host bacteria inhibits host growth at 42 degrees C but not at 32 degrees C. At 42 degrees C, the CCC Rts1 DNA is not formed, and cells without plasmids emerge. To investigate the possible role of cyclic adenosine 3',5'-monophosphate (cAMP) in the action of Rts1 on host bacteria, Rts1 was placed in an Escherichia coli mutant (CA7902) that lacks adenylate cyclase or in E. coli PP47 (a mutant lacking cAMP receptor protein). Rts1 did not exert the thermosensitive effect on these cells, and CCC Rts1 DNA was formed even at 42 degrees C. Upon addition of cAMP to E. coli CA7902(Rts1), cell growth and formation of CCC Rts1 DNA were inhibited at 42 degrees C. The addition of cAMP to E. coli PP47(Rts1) did not cause inhibitory effects on either cell growth or CCC Rts1 DNA formation at 42 degrees C. The inhibitory effect of cAMP on E. coli CA7902(Rts1) is specific to this cyclic nucleotide, and other cyclic nucleotides such as cyclic guanosine 3',5'-monophosphate did not have the effect. For this inhibitory effect, cells have to be preincubated with cAMP; the presence of cAMP at the time of CCC Rts1 DNA formation is not enough for the inhibitory effect. If the cells are preincubated with cAMP, one can remove cAMP during the [(3)H]thymidine pulse and still observe its inhibitory effect on the formation of CCC Rts1 DNA. The presence of chloramphenicol during this preincubation period abolished the inhibitory effect of cAMP. These observations suggest that cAMP is necessary to induce synthesis of a protein that inhibits CCC Rts1 DNA formation and cell growth at 42 degrees C.

Mouse L cell mitochondrial DNA molecules are selected randomly for replication throughout the cell cycle

The number of mitochondrial DNA molecules in a cell population doubles at the same rate as the cell generation time. This could occur by a random selection of molecules for replication or by a process that ensures the replication of each individual molecule in the cell. We have investigated the rate at which mouse L cell mitochondrial DNA molecules labeled with 3H-thymidine during one round of replication are reselected for a second round of replication. Mouse L cells were labeled with 3H-thymidine for 2 hr, chased for various periods of time and then labeled with 5-bromodeoxyuridine for 4 hr immediately before mitochondrial DNA isolation. A constant fraction of 3H-thymidine-labeled mitochondrial DNA incorporated 5-bromodeoxyuridine after chase intervals ranging from 1.5-22 hr. This result demonstrates that mitochondrial DNA molecules replicated in a short time interval are randomly selected for later rounds of replication, and that replication of mitochondrial DNA continues throughout the cell cycle in mouse L cells.

Control of replication and segregation of R plasmid Rts1

A mutant plasmid, pTW2, which was derived from the integrated Rst1 genome in the Escherichia coli chromosome, was studied as to its mode of replication at 30 degrees C. When Proteus mirabilis Pm17 harboring pTW2 was grown in broth at 30 degrees C, a considerable number of R- segregants (approximately 40%) were consistently observed. This indicates that pTW2 is unstable even at the permissive temperature for the replication of Rts1. The pTW2+ cells in a culture were heterogeneous with respect to the level of kanamycin resistance, ranging from 500 to 4,000 mug of the drug per ml. The amount of pTW2 deoxyribonucleic acid (DNA) relative to the Pm17 chromosomal DNA was about fivefold as large as that of Rts1 DNA in an exponentially growing culture. In addition, pTW2 in P. mirabilis continued to replicate after the chromosome had ceased to replicate, which was shown in the study of the inhibition of protein synthesis. Contrary to pTW2, the parent plasmid Rts1 is highly stable, and the relative percent Rts1 DNA is maintained at approximately 7% in any cultural conditions at a permissive temperature. These results suggest that copies of pTW2 may not segregate evenly into the host progeny upon cell division and that the replication of pTW2 does not coordinate with that of the chromosome. A remarkable instability of pTW2 as well as an increase in the relative percent pTW2 DNA was also shown when E. coli were used as the host cells. These results suggest the possibility that there is a gene or a gene cluster on the Rst1 genome responsible for the control of both replication and segregation of Rts1.

Plasmid mutations affecting self-maintenance and host growth in Escherichia coli

As reported in the accompanying paper, a number of mutants of the ColVBtrp plasmid that can not be maintained stably in the host cell of Escherichia coli have been isolated. Each of the mutated plasmids has been transferred to an isogenic Col minus strain, and the resulting Col+ strains were studied to examine the effects of plasmid mutations on some properties of the host bacteria. Many of the strains harboring a mutated plasmid were thus found to be temperature sensitive; they failed to grow and divide normally at high temperatures. Some of them formed "filaments" under these conditions. These abnormal growth characteristics were accompanied by an increased susceptibility to sodium deoxycholate and methylene blue, suggesting that the cytoplasmic membrane has been altered. Moreover, studies of temperature-independent revertants obtained from two of these temperature-sensitive Col+ strains suggested that a single mutation on the plasmid is responsible for the pleiotropic effects exerted on the host cell. The bearing of these findings on the mode of replication and segregated of stringent-type plasmids such as ColVBtrp in the host bacteria is discussed.

Integration of R plasmid Rts1 to the gal region of the Escherichia coli chromosome

An R plasmid Rts1 was integrated into the gal region of the chromosome of Escherichia coli XA-7012 (galE) strain by the directed transposition technique. The integration of the Rts1 genome was confirmed mainly by conjugation studies and also by transduction experiments using phage P1. As a result, it was found that the integrated genome contained genes responsible for kanamycin resistance, conjugal transferability, and for autonomous replication. As reported previously, Rts1 is temperature sensitive in replication and inhibits the growth of the host at nonpermissive temperature. However, although a plasmid derived from the integrated Rts1 genome still demonstrates temperature sensitivity upon transfer and high level of kanamycin resistance, this plasmid no longer displays temperature sensitivity in replication and the inhibitory effect on the host. These results indicate that the temperature sensitivity of replication of Rts1 and its inhibitory effect on the host cell are due to the presence of a gene or gene cluster on the Rts1 genome and that the gene(s) is clearly discriminated from the one responsible for the temperature sensitivity of transfer.

Molecular nature of the deoxyribonucleic acid of a thermosensitive R factor, Rts1

The deoxyribonucleic acid of the thermosensitive R factor, Rts1, has been examined by the technique of sedimentation in alkaline sucrose, electron microscopy, and radiation target size. All these methods yielded a molecular weight of approximately 120 million for Rts1 deoxyribonucleic acid in Escherichia coli. Sedimentation analysis revealed that Rts1 deoxyribonucleic acid in Proteus mirabilis was also 120 million daltons. Rts1 did not segregate into E. coli minicells under the conditions where another smaller non-thermosensitive R factor could.

The thermosensitive lesion in the replication of the drug resistance factor, Rts1

The DNA of the thermosensitive R factor, Rts1, has been examined by the technique of sedimentation in alkaline sucrose density gradients. Rts1 DNA was found as closed covalent circles in only a few copies per cell in an Escherichia coli host at the permissive temperature. Rts1 DNA appears to be synthesized at the nonpermissive temperature, but was not found as closed covalent circles. However, circular DNA could be recovered upon shift down to the permissive temperature. The large number of plasmid-negative cells which accumulate after prolonged culture at non-permissive temperature may be due to a strong selective pressure favoring the growth of rare R(-) segregants.

Round of replication mutant of a drug resistance factor

A derivative of the R factor NR1 (called R12) has been isolated which undergoes an increased number of rounds of replication each division cycle in Proteus mirabilis, Escherichia coli, and Salmonella typhimurium. The alteration resulting in the increased number of copies (round of replication mutation) is associated with the transfer factor component of the R factor. R12 has the same drug resistance pattern as NR1, is the same size as shown by sedimentation in a sucrose gradient and electron microscopy (63 x 10(6) daltons), and has the same partial denaturation map. The level of the R factor gene product chloramphenicol acetyltransferase has been examined in P. mirabilis and was found to be consistent with gene dosage effects. The plasmid to chromosomal deoxyribonucleic acid ratio of NR1 increases several fold after entry into stationary phase, whereas this ratio for R12 remains approximately constant. Individual copies of R12 are selected at random for replication from a multicopy plasmid pool. A smaller percentage of R12 copies replicate during amino acid starvation than has previously been found for NR1 in similar experiments.

Effects of inhibition and restoration of protein synthesis on the replication of the R factor Rts1 in Proteus mirabilis

The effect of inhibition of protein synthesis on the replication of the R factor Rts1 in Proteus mirabilis was examined by using the technique of CsCl density gradient centrifugation. Only 12% of the copies of Rts1 were found to replicate during amino acid starvation, whereas there was a 30% increase in the amount of P. mirabilis chromosomal deoxyribonucleic acid (DNA) during the same period. Essentially the same amount of Rts1 and host chromosome replication was observed when chloramphenicol was used to inhibit protein synthesis. The replication of Rts1 DNA was also examined in experiments in which cultures were starved for amino acids in (14)N-labeled medium and then transferred to (15)N-labeled medium containing the required amino acids. These experiments showed that Rts1 replication took place throughout the first generation in (15)N-labeled medium and that each copy of Rts1 was replicated one time during the first generation of chromosomal DNA synthesis in (15)N-medium.

Host cell growth in the presence of the thermosensitive drug resistance factor, Rts1

We have confirmed and extended the observation of Terawaki et al. that the R factor, Rts1, alters the growth of its host at 42 C. In all media tested there was a period during which total cell numbers increased linearly, while viable counts remained constant. During this period the rate of precursor incorporation per cell particle into deoxyribonucleic acid, ribonucleic acid, and protein declined steadily. These patterns were a consequence of the accumulation of increasing numbers of cells which had lost colony-forming ability. A temperature shiftdown experiment showed that the colony formers could, after a lag, go on to divide normally, whereas most of the noncolony formers could not undergo even a limited number of divisions after shiftdown. The number of normal divisions which occurred after shiftup of Rts1 cells to 42 C was medium dependent. In rich medium there were, on the average, two or three doublings; in glucose medium, one; and in glycerol medium, only a fraction of a doubling. Even in glucose medium, however, no increase in viable counts was observed during growth at 42 C if the cells were first starved for glucose for 1 h at 42 C. A temperature shiftdown from 42 C to 27 C during glucose starvation reversed the effect of starvation at 42 C alone. These results are consistent with the hypothesis that the thermosensitive Rts1 component(s) responsible for the host effects is present at permissive temperature, but can undergo a reversible temperature-induced alteration which then interferes with some essential host function. The detrimental effects of this R factor on its host were also reflected in a heightened sensitivity to kanamycin and actinomycin D at 42 C. Electron microscope observations revealed changes in the appearance of the cell membrane. Membranous invaginations were noted at discrete sites in the cell.

Pattern of replication of a colicin factor during the cell cycle of Escherichia coli

The ColBM, trp, lac episome was transferred to a lacZ derivative of Escherichia coli B/r, and the manner of replication of this colicinogenic factor was followed through the cell cycle. The results suggest a pattern of replication not connected with any particular stage in the cell cycle.

Relationship of Flac replication and chromosome replication

The time of replication of a bacterial plasmid, Flac, during the division cycle of Escherichia coli has been estimated in exponentially growing cultures and at various times after a shift from minimal medium to a richer medium (a shift-up). There is a variation in the cell age at which the capacity to synthesize beta-galactosidase (beta-D-galactoside galactohydrolase, EC 3.2.1.23) doubles (assumed to be a measure of the time at which the Flac plasmid replicates) when this capacity is measured at various times during the shift-up, and with increasing steady-state exponential growth rate. Cells growing at slow and moderate growth rates exhibit Flac replication in the middle of the division cycle. With increasing time after a shift-up or with increasing growth rate the plasmid replicates at earlier times, eventually at cell division, and finally in the older cells. This variation in the cell age at which the plasmid replicates is similar to the variation in cell age at which chromosome initiation occurs during a shift-up, although plasmid replication occurs slightly before initiation of chromosome replication.