Suppression of an Escherichia coli dnaA mutation by the integrated R factor R.100.1: Change of chromosome replication origin in synchronized cultures.

We have followed, by deoxyribonucleic acid-deoxyribonucleic acid hybridization, the order of replication of three chromosomal markers during a synchronous round of replication in three strains of Escherichia coli carrying a dnaAts mutation: one strain in which the F-like R factor R.100.1 was established as a plasmid and two strains in which the dnaA mutation was suppressed by the integration of R.100.1 into the chromosome. In the R+ strain at 30C, replication of the plasmid took place simultaneously with the initiation of chromosome replication at the normal origin. In the integratively suppressed Hfr strains, at 42.5 C, chromosome replication was initiated preferentially from the integrated plasmid; little or no initiation occurred at the normal origin. Similar results were obtained for the one strain tested at 30 C. For both Hfr strains at 42.5 C, the data suggest that at least part of the population replicated bidirectionally. This conclusion had been confirmed using an autoradiographic procedure. Both types of experiment indicate a wide variation in the rate of travel of individual replication forks within the population.     

Suppression of an Escherichia coli dnaA mutation by the integrated R factor R100.1: origin of chromosome replication during exponential growth.

We have investigated the behavior, during exponential growth, of strains of Escherichia coli carrying a dnaA(Ts) mutation that has been suppressed by the integration of the F-like R plasmid R100.1. We present evidence showing that replication in these strains proceeds largely from the normal chromosome origin at 30 degrees C, a permissive temperature for the dnaA(Ts) gene product, whereas, at 42 degrees C, replication proceeds largely from the integrated plasmid. These conclusions are based on measurements made by deoxyribonucleic acid:deoxyribonucleic acid hybridization of the relative frequencies of the prophages Mu-1 and lambdaind- and R100.1 integrated at known locations on the E. coli chromosome in these Hfr strains.     

Isolation and characterization of plasmid-deletion derivatives from an Hfr made with Rts1 plasmid carrying a chromosomal mutation, plt

Summary Rts1 is a kanamycin-resistance plasmid and multiphenotypically thermosensitive. The detrimental host cell growth at 42° C is expressed only when it exitst autonomously but not in an integrated state. However, a cholate-resistant (plt) mutant of the Hfr with an integrated Rts1 plasmid was found to be thermosensitive like a strain with the same plasmid autonomoulsy. This thermosensitivity depends on the existence of the integrated plasmid. Deletion derivatives of integrated plasmid genome from this Hfr strain were isolated with or without thermal selective growth at 42° C and mapping of the plasmid was attempted by analyzing them. A total of 141 kanamycin-sensitive derivatives were independently isolated and examined for their thermosensitivity (genetic locus: tsg), incompatibility (genetic locus: incT), conjugal fertility (genetic locus: tra), restriction of T4 phase (two genetic loci: resA and resB) and for DNase activity (genetic locus: dns). On the basis of characterization of 141 deletion derivatives, they were divided into 15 patterns which would correspond to a linear map integrated into the chromosome: ... resA ... dns ... resB ... tra ... kan ... incT ... tsg ... It is noteworthy that restriction of T4D phage is determined by two distinct genes, resA and resB, intervened by dns and that propagation of T4D phage on a strain with a resA ⁺ resB ^- genome failed to produce modified progeny phages.     

Integration of the RP4 factor with the chromosome in Escherichia coli K12 and the formation of 2 types of Hfr-strains]

The mutant RP4ts12, derived from the R-factor RP4 and thermosensitive in replication, is incorporated into the chromosome A3dna(ts) of E. coli K12, thus suppressing dnaA mutation. The integration of this factor into the chromosome leads to the formation of Hfr strains of two types: the strains of the first type transfer plasmid markers to recipient cells earlier than to chromosomal ones; the strains of the second type transfer plasmid markers to recipient cells after chromosomal ones. During conjugation the R-factor integrated into the chromosome dissociates from chromosomal DNA introduced into the recipient cell and becomes autonomous.     

Reinitiation of chromosome replication in the presence of chloramphenicol under an integratively suppressed state by R6K.

The autonomous replication of an R plasmid, R6K (amp, str) was shown not to be affected by chloramphenicol. It provoked integrative suppression and gave rise to Hfr strains when integrated into the chromosome of a strain of Escherichia coli K-12 with a temperature-sensitive mutation in the gene, dnaA. An Hfr strain designated as Hfr(R6K) no. 1 was thus obtained and characterized. It was not completely stable as shown by a plating efficiency of 0.6 at 42 C relative to that at 30 C. The density labeling and the ultracentrifugation analysis suggested that the deoxyribonucleic acid replication in this Hfr strain did not stop immediately after completion of the round already started before temperature shift-up and the addition of chloramphenicol. These observations are discussed in relation to a possibility that the chromosome replication of this Hfr strain is under the control of the integrated plasmid at a nonpermissive temperature.     

Genetic loci responsible for incompatibility on a co-integrate plasmid, R100-1.

An R plasmid, R100-1, was mapped previously (Yoshikawa, 1974) by transduction from an integratively suppressed Hfr strain to a recipient with a mutation in gene dnaA. By this method various types of transductants of plasmid R100-1 that exist autonomously or in the integrated state were obtained. Seventy-one such transductants were used in the present study to map gene inc, which is responsible for incompatibility. The results obtained can be explained by either of the following: (i) R100-1 has only a single gene or gene cluster (inc) despite previous work suggesting that this plasmid is a co-integrate of two replicons; (ii) R100-1 possesses more than one inc locus located between the repA and tra loci.     

Involvement of the ribulosephosphate epimerase gene in the dnaA and dnaR functions for initiation of chromosome replication in Escherichia coli

Initiation of replication of the Escherichia coli chromosome is rendered temperature-sensitive by the dnaR130 mutation in the prs gene that encodes phosphoribosylpyrophosphate synthetase. The thermosensitivity of the dnaR mutant is suppressed by a spontaneous mutation in rpe , the gene encoding ribulosephosphate epimerase. Disruption of the rpe gene reverses the thermosensitive growth of the dnaR mutant. The rpe -disrupted dnaR mutant exhibits extensive DNA synthesis at low and high temperatures, as does the dnaR  ⁺ rpe disruptant and the dnaR  ⁺ rpe ⁺ strain. The thermoresistant DNA synthesis in the rpe dnaR double mutant is dnaA dependent, because the dnaA167 mutation renders the synthesis thermosensitive. The rpe -knockout mutation abolishes the ability of the dnaA115 allele to complement the defect of the dnaA167 mutant with or without the dnaR mutation and diminishes the dnaR -complementing ability of the dnaR224 allele. These results show that the rpe product is involved in the functions of the products of both dnaA and dnaR for initiation of replication of the bacterial chromosome.     

Two types of cold sensitivity associated with the A184-->V change in the DnaA protein

Multicopy dnaA(Ts) strains carrying the dnaA5 or dnaA46 allele are high-temperature resistant but are cold sensitive for colony formation. The DnaA5 and DnaA46 proteins both have an A184-->V change in the ATP binding motif of the protein, but they also have one additional mutation. The mutations were separated, and it was found that a plasmid carrying exclusively the A184-->V mutation conferred a phenotype virtually identical to that of the dnaA5 plasmid. Strains carrying plasmids with either of the additional mutations behaved like a strain carrying the dnaA+ plasmid. In temperature downshifts from 42 degrees C to 30 degrees C, chromosome replication was stimulated in the multicopy dnaA46 strain. The DNA per mass ratio increased threefold, and exponential growth was maintained for more than four mass doublings. Strains carrying plasmids with the dnaA(A184-->V) or the dnaA5 gene behaved differently. The temperature downshift resulted in run out of DNA synthesis and the strains eventually ceased growth. The arrest of DNA synthesis was not due to the inability to initiate chromosome replication because marker frequency analysis showed high initiation activity after temperature downshift. However, the marker frequencies indicated that most, if not all, of the newly initiated replication forks were stalled soon after the onset of chromosome replication. Thus, it appears that the multicopy dnaA(A184-->V) strains are cold sensitive because of an inability to elongate replication at low temperature. The multicopy dnaA46 strains, on the contrary, exhibit productive initiation and normal fork movement. In this case, the cold-sensitive phenotype may be due to DNA overproduction.     

The region controlling the thermosensitive effect of plasmid Rts1 on host growth is separate from the Rts1 replication region.

Rts1 is a high-molecular-weight (126 x 10(6)) plasmid encoding resistance to kanamycin. It expresses unusual temperature-sensitive phenotypes, which affect plasmid maintenance and replication, as well as host cell growth. We have cloned the essential replication region of Rts1 from pAK8, a smaller derivative which is phenotypically similar to Rts1. Restriction endonuclease digests of isolated pAK8 deoxyribonucleic acid were allowed to "self-ligate" (ligation without an additional cloning vector) and subsequently were used to transform Escherichia coli strain 20SO to kanamycin resistance. Screening of these strains for the phenotypes of thermosensitive host growth and temperature-dependent plasmid elimination demonstrated that these two properties were expressed independently. Furthermore, it was shown that the Rts1 replication locus per se is not necessarily responsible for altered host growth at the nonpermissive temperature. The kanamycin resistance fragment of pAK8 was also cloned into pBR322. Electrophoretic analysis of BamHI restriction enzyme digests of this plasmid and similar digests of an Rts1 miniplasmid has allowed the identification of an 18.6-megadalton fragment carrying the replication locus and a 14.1-megadalton fragment carrying the kanamycin resistance gene.     

Transposon (Tn5)-mediated suppressive integration of ColE1 derivatives into the chromosome of Escherichia coli K12 (dnaA)

While integration of ColE1 had not been observed previously by ordinary suppressive integration, a $\text{dnaA}$ (Ts) $\text{E. coli}$ strain with Tn$\text{5}$ at various sites of the chromosome and ColE1 or its mini-derivative, pAO3, but not pSC101, inserted by the same transposon produced integratively suppressed strains depending on the RecA function. In contrast to Hfr strains made with a stringently controlled plasmid, they contained the plasmid not only in an integrated but in an autonomous state at an amount comparable to the strain containing the plasmid only autonomously. Introduction of a RecA-deficient mutation to the strain with an integrated ColE1 derivative through conjugation failed. This is likely to be due to lethality of such a strain without RecA-dependent excision of the integrated high copy number plasmid or to quantitative deficiency of DNA polymerase I in addition to the $\text{recA}$ mutation.     

Spontaneous emergence of an Hfr strain with a cit plasmid from natural isolates of citrate-positive Escherichia coli bovine origin.

From citrate-utilizing (Cit+) Escherichia coli strain C53 of bovine origin, strains C53A and C53B were obtained. Upon mating with recA+ but not with recA mutant recipients of K-12, C53A produced chromosomal recombinants at quite high frequencies, leading to the following conclusions: (i) C53A is an Hfr strain; (ii) the site of integration of the Cit plasmid (IncH1) is between metA (89 min) and ara (1 min); (iii) the direction of chromosome transfer is clockwise; and (iv) the plasmid-associated determinants are transferred as the terminal markers. A transductant of a dnaA(Ts) strain, CRT46, which acquired Cit determinants from a recombinant, SG13, was also an Hfr strain similar to SG13, and thermoresistant due to suppressive integration. On the other hand, unstable C53B did not produce recombinants, but the frequency of RecA-independent transfer of the Cit plasmid was high, indicating that the Cit plasmid (IncH1) exists autonomously in C53B. Attempts to isolate an Hfr strain from C53B failed.     

IS21 insertion in the trfA replication control gene of chromosomally integrated plasmid RP1: a property of stable Pseudomonas aeruginosa Hfr strains

Summary Broad host range IncP-1 plasmids are able to integrate into the chromosome of gram-negative bacteria. Strains carrying an integrated plasmid can be obtained when the markers of a temperature-sensitive (ts) plasmid derivative are selected at non-permissive temperature; in this way Hfr (high frequency) donor strains can be formed. The integrated plasmids, however, tend to be unstable in the absence of continuous selective pressure. In order to obtain stable Hfr donor strains of Pseudomonas aeruginosa PAO, we constructed a derivative of an RP1 (ts) plasmid, pME134, which was defective in the resolvase gene (tnpR) of transposon Tn801. Chromosomal integration of pME134 was selected in a recombination-deficient (rec-102) PAO strain at 43°C. Plasmid integration occurred at different sites resulting in a useful set of Hfr strains that transferred chromosomal markers unidirectionally. The tnpR and rec-102 mutations prevented plasmid excision from the chromosome. In several (but not all) Hfr strains that grew well and retained the integrated plasmid at temperatures below 43°C, the insertion element IS21 of RP1 was found to be inserted into the trfA locus (specifying an essential trans-acting replication funtion) of the integrated plasmid. One such Hfr strain was rendered rec ⁺; from its chromosome the pME134::IS21 plasmid (=pME14) was excised and transferred by conjugation to Escherichia coli where pME14 could replicate autonomously only when a helper plasmid provided the trfA ⁺ function in trans. Thus, it appears that trfA inactivation favours the stability of chromosomally integrated RP1 in P. aeruginosa.     

Formation of Escherichia coli Hfr strains by integrative suppression with the P group plasmid RP1.

Hfr strains of Escherichia coli were obtained by integrative suppression of a dnaA(Ts) mutation by the Inc P-1 plasmid RP1 without prior creation of an unnatural homology between the plasmid and the E. coli chromosome. Unmodified RP1 mobilized the polarized transfer of the chromosome in a counterclock-wise direction from a distinct origin between 81 min (pyrE) and 82 min (dnaA) with pyrE as a leading marker. Inheritance of RP1-Hfr chromosomal and antibiotic resistance genes was due to recombination with the recipient chromosome, as shown by the need for a functional recA system. The acquisition of temperature resistance and donor ability was accompanied by the disappearance of free plasmid when the selection pressure for integration was maintained (growth at 41 degrees C); the loss of temperature resistance and donor ability was accompanied by the reappearance of autonomous RP1 when the selection pressure was removed (growth at 30 degrees C).     

Identification and mapping of the replication genes of an R factor, R100-1, integrated into the chromosome of Escherichia coli K-12

A stable Hfr strain of Escherichia coli K-12 was obtained by integrative suppression by an R factor, R100-1. The R factor was integrated into the right of 81 min, and chromosome transfer occurred counterclockwise. Mating experiments revealed two linkage groups of genes on the R factor. Drug-resistant transductants of a dnaA-ts recipient from an R-factor Hfr and from an R(+) strain differ in their drug resistance patterns, temperature sensitivity, and transferability of drug resistance as well as chromosome markers. Transductants that transferred chromosome markers were further classified as to the origin and direction of chromosome transfer. For temperature-sensitive transductants, the reversion frequency to temperature resistance was determined, and these revertants were scored for transfer of drug resistance as well as chromosome markers. Two genes responsible for integrative suppression (designated as repA) and the other for autonomous replication (designated as repB) were identified and mapped. The arrangement of genes on the R factor is... (sul, str, cml)... repA... tra... (tet, repB).... The map of the autonomously replicating R factor is probably a circle connecting both sides of this linear map. Thus, a method has been established to map a plasmid that could not finely be analyzed under autonomous state by transduction. It also permits genetic analysis of genes responsible for replication of the plasmid without making use of a conditional mutant of itself but with that of the host, dnaA.     

Expression of a mutation affecting F incompatibility in the integrated but not the autonomous state of F.

Previously we have described a mutant Hfr strain in which incompatibility between the integrated F factor and an autonomous F-prime (F') factor was abolished. The mutation (inc) was located in the integrated F factor. F-prime factors isolated from the mutant Hfr strain have the same incompatibility behavior as those isolated from normal Hfr strains. Reintegration of these F' factors into the chromosome restores the Inc- phenotype characteristic of the mutant Hfr. The inc mutation thus affects incompatibility between integrated F and autonomous F(Fi-Fa incompatibility) but not incompatibility between two autonomous F factors (Fa-Fa incompatibility). The implications of this finding for the mechanism of plasmid incompatibility are discussed.     

Evidence for positive regulation of plasmid prophage P1 replication: integrative suppression by copy mutants.

Like low-copy-number plasmids including P1 wild type, multicopy P1 mutants (P1 cop, maintained at five to eight copies per chromosome) can suppress the thermosensitive phenotype of an Escherichia coli dnaA host by forming a cointegrate. At 40 degrees C in a dnaA host suppressed by P1 cop, the only copy of P1 is the one in the host chromosome. Trivial explanations of the lack of extrachromosomal copies of P1 cop have been eliminated: (i) during integrative suppression, the P1 cop plasmid does not revert to cop+; (ii) the dnaA+ function of the host is not required to maintain P1 cop at a high copy number; and (iii) integrative recombination does not occur within the region of the plasmid involved in regulation of copy number. Since there are no more copies of the chromosomal origin (now located within the integrated P1 plasmid) than in a P1 cop+-suppressed strain, the extra initiation potential of the P1 cop is not used to provide multiple initiations of the chromosome. When a P1 cop-suppressed dnaA strain was grown at 30 degrees C so that replication could initiate from the chromosomal origin as well as from the P1 origin, multicopy supercoiled P1 DNA was found in the cells. This plasmid DNA was lost again when the temperature was shifted back to 40 degrees C.     

Suppression of initiation defects of chromosome replication in Bacillus subtilis dnaA and oriC-deleted mutants by integration of a plasmid replicon into the chromosomes.

We constructed Bacillus subtilis strains in which chromosome replication initiates from the minimal replicon of a plasmid isolated from Bacillus natto, independently of oriC. Integration of the replicon in either orientation at the proA locus (115 degrees on the genetic map) suppressed the temperature-sensitive phenotype caused by a mutation in dnaA, a gene required for initiation of replication from oriC. In addition, in a strain with the plasmid replicon integrated into the chromosome, we were able to delete sequences required for oriC function. These strains were viable but had a slower growth rate than the oriC+ strains. Marker frequency analysis revealed that both pyrD and metD, genes close to proA, showed the highest values among the markers (genes) measured, and those of other markers decreased symmetrically with distance from the site of the integration (proA). These results indicated that the integrated plasmid replicon operated as a new and sole origin of chromosome replication in these strains and that the mode of replication was bidirectional. Interestingly, these mutants produced anucleate cells at a high frequency (about 40% in exponential culture), and the distribution of chromosomes in the cells was irregular. A change in the site and mechanism (from oriC to a plasmid system) of initiation appears to have resulted in a drastic alteration in coordination between chromosome replication and chromosome partition or cell division.     

Isolation of Hfr Strains from R+ and ColV2+ Strains of Escherichia coli and Derivation of an R′lac Factor by Transduction

Temperature-resistant revertants were isolated from Escherichia coli strains carrying a temperature-sensitive dnaA mutation (initiation of chromosome replication) and either a repressed or a derepressed F-like R factor or a ColV2 factor. Many of the revertants had all the properties of Hfr strains, with a variety of directions and origins of transfer. From one such revertant, episomes carrying the R factor and part of the lac region (R'lac) could be isolated by transduction. This system offers a good selection for Hfr strains produced by integration of various episomes and for the isolation of R' factors.     

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.     

Genetic mapping of the chromosomal replication origin of Salmonella typhimurium.

Two hundred strains of Escherichia coli harboring Filv+ plasmids which carry a segment of the Salmonella typhimurium chromosome were isolated independently. Among them, two strains were found to harbor F' plasmids that are able to replicate in Hfr cells of E. coli; i.e., they carry a site designated poh (permissive on Hfr) of the S. typhimurium chromosome. The poh site is presumably identical with the replication origin (oriC) of the bacterial chromosome. These two plasmids carry the dnaA-uncA-rbs-ilv-cya-metE region of the chromosome of S. typhimurium. Other F' plasmids which only carried the ilv-cya-metE region were unable to be maintained in Hfr cells. The poh site (= oriC) of S. typhimurium thus is located in the uhp-ilv region of the chromosome. The two plasmids carrying the poh site of S. typhimurium can suppress the temperature-sensitive character of an E. coli mutant that carries the temperature-sensitive dnaA46 allele, when the plasmids exist in the mutant cells. This suggests that the dnaA chromosome in place of the dnaA gene product of E. coli itself. The ability of the plasmids carrying the poh site of S. typhimurium to replicate in Hfr cells of E. coli suggests that the replication system of E. coli can recognize the Salmonella replication origin.