Possible involvement of the ugpA gene product in the stable maintenance of mini-F plasmid in Escherichia coli

Summary The seg-3 mutant Escherichia coli does not support the maintenance of mini-F plasmid at 42° C. We cloned the chromosomal DNA segment of the wild-type strain W3110 that complements the Seg^– phenotype of this mutant. Cleavage mapping of this segment showed that it was derived from the 76-min region of the E. coli chromosome map. Complementation tests using plasmids carrying subcloned DNA segments suggested that the seg-3 mutant carried two mutations that additively affected the maintenance of mini-F plasmid; one was in the ugpA gene and the other was presumably in the rpoH gene. We generated a disrupted ugpA null mutant and found that the mini-F plasmid was unstable in this ugpA null mutant even at 30° C. This suggests that the ugpA gene product is required for the stable maintenance of mini-F plasmid.     

Roles of Escherichia coli heat shock proteins DnaK, DnaJ and GrpE in mini-F plasmid replication

Summary A subset of Escherichia coli heat shock proteins, DnaK, DnaJ and GrpE were shown to be required for replication of mini-F plasmid. Strains of E. coli K12 carrying a missense mutation or deletion in the dnaK, dnaJ, or grpE gene were virtually unable to be transformed by mini-F DNA at the temperature (30° C) that permits cell growth. When excess amounts of the replication initiator protein (repE gene product) of mini-F were provided by means of a multicopy plasmid carrying repE, these mutant bacteria became capable of supporting mini-F replication under the same conditions. However, the copy number of a high copy number mini-F plasmid was reduced in these mutant bacteria as compared with the wild type in the presence of excess RepE protein. Furthermore, mini-F plasmid mutants that produce altered initiator protein and exhibit a very high copy number were able to replicate in strains deficient in any of the above heat shock proteins. These results indicate that the subset of heat shock proteins (DnaK, DnaJ and GrpE) play essential roles that help the functioning of the RepE initiator protein in mini-F DNA replication.     

Maintenance of plasmids in HU and 1HF mutants of Escherichia coli

Summary Complementation and sequencing analyses revealed that the hopD mutants, which could not support stable maintenance of mini-F plasmids (Niki et al. 1988), had mutations in the hupB gene, and that the hopD410 mutation was an ochre mutation at the 5th Gln position of HU-1. Maintenance and stability of various plasmids, mini-P1 plasmids, mini-F plasmids, and oriC plasmids, were studied in the hupA and hupB mutants (HU mutants), and himA and hip mutants (IHF mutants). Mini-P1 plasmids and mini-F plasmids could not be introduced into the hupA-hupB double deletion mutant. Replication of mini-F plasmids was partially inhibited in the hupB mutants, including the hupB and hopD(hupB) mutants, whereas replication of oriC plasmids was not significantly affected even in the hupA-hupB double deletion mutant. The mini-P1 plasmid was slightly unstable in the himA-hip mutant, whereas the mini-F plasmid was stable.     

Linear multimer formation of plasmid DNA in Escherichia coli hopE (recD) mutants

Summary The hopE mutants of Escherichia coli, which cannot stably maintain a mini-F plasmid during cell division, have mutations in the recD gene coding for subunit D of the RecBCD enzyme (exonuclease V). A large amount of linear multimer DNA of mini-F and pBR322 plasmids accumulates in these hopE mutants. The linear multimers of plasmid DNA in the hopE (recD) mutants accumulate in sbc ⁺ genetic backgrounds and this depends on the recA ⁺ gene function. Linear plasmid multimers also accumulated in a recBC xthA triple mutant, but not an isogenic xthA mutant or an isogenic recBC mutant. The recBC xthA mutant is defective in the conjugative type of recombination. Linear plasmid multimers were not detected in the recBC strain. We propose models to account for linear multimer formation of plasmids in various mutants.     

Identification of two new genes,mukE andmukF, involved in chromosome partitioning inEscherichia coli

We have previously reported that the MukB protein is essential for chromosome partitioning inEscherichia coli and thatmukB mutants produce anucleate cells and are temperature-sensitive for colony formation. ThemukB gene maps at 21 min on theE. coli chromosome andsmtA-mukF-mukE-mukB genes might comprise an operon, which is transcribed in a clockwise direction. Here, we report thatmukF andmukE null mutants are both temperature-sensitive for colony formation and produce anucleate cells even at the permissive temperature. These phenotypes are the same as those observed in themukB null mutant. The primary sequence of MukF includes a leucine zipper structure and an acidic domain. Mutational analysis revealed that both are required for MukF function. When the MukF protein was overproduced in the wild-type strain, anucleate cells were produced. In contrast, overproduction of either MukE or MukB did not cause the defect. In null mutants for themukF, mukE, andmukB genes, the synchronous initiation of chromosome replication was not affected. The mini-F plasmid was as stably maintained in these mutants as in the wild-type strain. These results indicate that the MukF, MukE, and MukB proteins are involved in the chromosome partitioning steps, but are not required for mini-F plasmid partitioning.     

Integrative suppression of dnaA(Ts) mutations mediated by plasmid F in Escherichia coli is a DnaA-dependent process

Summary The thermosensitivity of dnaA(Ts) mutations can be suppressed by integration of plasmid F (integrative suppression). In the light of the recent finding that F requires DnaA protein for both establishment and maintenance, integrative suppression of 11 dnaA(Ts) mutations by a mini-F, pML31, integrated near oriC was examined. The plating efficiency of integratively suppressed strains was dnaA(Ts) allele-dependent and medium-dependent. The initiation capability of suppressed dnaA(Ts) strains lacking the oriC site and their F^- counterparts was determined at various temperatures between 30°C and 42°C. The degree of integrative suppression measured by the initiation capability varied in a dnaA(Ts) allele-dependent manner. F-directed DNA replication was most affected by the dnaA(Ts) mutations mapping in the middle of the gene whereas oriC-dependent replication was most thermosensitive in strains carrying mutations mapping in the carboxy-terminal half of the gene. The results indicated that the integrative suppression by F plasmid is a DnaA-dependent process and suggested that the requirements for DnaA protein in the oriC-dependent replication and F replication processes are qualitatively different.     

In vitro roles of Escbericbia coli DnaJ and DnaK heat shock proteins in the replication of oriC plasmids

Summary Heat shock proteins have been shown to be involved in many cellular processes in procaryotic and eucaryotic cells. Using an in vitro DNA replication assay, we show that DNA synthesis initiated at the chromosomal origin of replication of Escherichia coli (oriC) is considerably reduced in enzyme extracts isolated from cells bearing mutations in the dnaK and dnaJ genes, which code for heat shock proteins. Furthermore, unlike DNA synthesis in wild-type extracts, residual DNA synthesis in dnaK and dnaJ extracts is thermosensitive. Although thermosensitivity can be complemented by the addition of DnaK and DnaJ proteins, restoration of near wild-type replication levels requires supplementary quantities of purified DnaA protein. This key DNA synthesis initiator protein is shown to be adsorbed to DnaK affinity columns. These results suggest that at least one of the heat shock proteins, DnaK, exerts an effect on the initiation of DNA synthesis at the level of DnaA protein activity. However, our observation of normal oriC plasmid transformation ratios and concentrations in heat shock mutants at permissive temperatures would suggest that heat shock proteins play a role in DNA replication mainly at high temperatures or under other stressful growth conditions.     

Temperature-sensitive mutations affecting the replication of F-prime factors in Escherichia coli K 12

Summary More temperature-sensitive mutants affecting the replication of the F-gal⁺ episome of Escherichia coli K12 have been isolated. Eight of the mutations were located on F itself and three were located on the chromosome.The temperature sensitive F-gal⁺'s have been integrated into the chromosome to produce Hfr strains. These Hfr strains have transfer origins similar to Hfr Cavalli, and all show aberrant excision and transfer of elongated segments of the chromosome including the integrated F-gal to generate long merodiploids.The chromosomal mutations that govern the replication of F have been termed seg (for segregation). Wild-type F-gal⁺ can be integrated into seg cells at 42° C to give Hfrs, in a process analogous to integrative suppression in the formation of Hfrs from cells carrying mutations that are temperature-sensitive for chromosomal DNA replication (dnaA). A curious feature of an Hfr derived from a seg strain is that it also shows F-genote enlargement as well as normal transfer of chromosomal genetic marker. Preliminary transductional mapping data show that the mutation seg-2 is linked to the threonine locus (minute 0).     

Role of DnaA protein during replication of plasmid pBR322 in Escherichia coli

Summary The in vivo role of the Escherichia coli protein DnaA in the replication of plasmid pBR322 was investigated, using a plasmid derivative carrying an inducible dnaA ⁺ gene. In LB medium without inducer, the replication of this plasmid, like that of pBR322, was inhibited by heat inactivation of chromosomal DnaA46 protein so that plasmid accumulation ceased 1 to 2 h after the temperature shift. This inhibition did not occur when the plasmid dnaA ⁺ gene was expressed in the presence of the inducer isopropyl-1-thin--d-galactopyranoside (IPTG). Inhibition was also not observed in glycerol minimal medium or in the presence of low concentrations of rifampicin or chloramphenicol. Deletion of the DnaA binding site and the primosome assembly sites (pas, rri) downstream of the replication origin did not affect the plasmid copy number during exponential growth at 30° C, or after inactivation of DnaA by a shift to 42° C in a dnaA46 host, or after oversupply of DnaA, indicating that these sites are not involved in a rate-limiting step for replication in vivo. The accumulation of the replication inhibitor, RNAI, was independent of DnaA activity, ruling out the possibility that DnaA acts as a repressor of RNAI synthesis, as has been suggested in the literature. Changes in the rate of plasmid replication in response to changes in DnaA activity (in LB medium) could be resolved into an early, rom-dependent, and a late, rom-independent component. Rom ^– plasmids show only the late effect. After heat inactivation of DnaC, plasmid replication ceased immediately. These results, together with previously published reports, suggest that DnaA plays no specific role during in vivo replication of ColE1 plasmids and that the gradual cessation of plasmid replication after heat inactivation of DnaA in LB medium results from indirect effects of the inhibition of chromosome replication and the ensuing saturation of promoters with RNA polymerase under nonpermissive growth conditions.     

recA Gene dependence of replication of the Escherichia coli chromosome initiated by plasmid pUC13 integrated at predetermined sites

Summary Plasmid pUC13 was used to clone DNA fragments of known sites from the chromosome of Escherichia coli. Each chimeric plasmid was introduced individually into the same dnaA46 mutant strain LC381 and suppressive integration (Sin) strains were selected. By means of cotransduction the null mutation recA56 was then introduced into each Sin strain and growth of each recA56 derivative at 42° C was scored. Strains that failed to grow at 42° C depended upon the recA gene for replication. Three factors were shown to limit the viability of LC381 harboring different chimeric plasmids and affect the degree of recA gene dependence of chromosome replication in the Sin strains at 42° C. It is suggested that these three constraints are the consequence of the organization of the E. coli chromosome, particularly the unique ability of terC to retard the progression of replication forks. Two classes of hypotheses concerning the function of the recA gene are considered.     

Mutations in a Saccharomyces cerevisme host showing increased holding stability of the heterologous plasmid pSRI

Summary We have isolated Saccharomyces cerevisiae mutants, smp, showing stable maintenance of plasmid pSRI, a Zygosaccharomyces rouxii plasmid. The smp mutants were recessive and were classified into at least three different complementation groups. The three mutants also showed increased stability of YRp plasmids and the mutations are additive for plasmid stability. One mutation, smp1, confers a respiration-deficient (rho ⁰) phenotype and several Rho^– mutants independently isolated by ethidium bromide treatment of the same yeast strain also showed increased stabilities of pSR1 and YRp plasmids. The wild-type S. cerevisiae cells showed a strongly biased distribution of pSR1 molecules as well as YRp plasmids to the mother cells at mitosis, while the smpf mutant did not show this bias. Another mutation, smp3, at a locus linked to ade2 on chromosome XV, confers temperature-sensitive growth. The SMP3 gene encodes a 59.9 kDa hydrophobic protein and disruption of the gene is lethal.     

Cold-active DnaK of an Antarctic psychrotroph Shewanella sp. Ac10 supporting the growth of dnaK-null mutant of Escherichia coli at cold temperatures

Shewanella sp. Ac10 is a psychrotrophic bacterium isolated from the Antarctica that actively grows at such low temperatures as 0°C. Immunoblot analyses showed that a heat-shock protein DnaK is inducibly formed by the bacterium at 24°C, which is much lower than the temperatures causing heat shock in mesophiles such as Escherichia coli. We found that the Shewanella DnaK (SheDnaK) shows much higher ATPase activity at low temperatures than the DnaK of E. coli (EcoDnaK): a characteristic of a cold-active enzyme. The recombinant SheDnaK gene supported neither the growth of a dnaK-null mutant of E. coli at 43°C nor phage propagation at an even lower temperature, 30°C. However, the recombinant SheDnaK gene enabled the E. coli mutant to grow at 15°C. This is the first report of a DnaK supporting the growth of a dnaK-null mutant at low temperatures.     

Isolation and sequence analysis of a small cryptic plasmid pRK10 from a corrosion inhibitor degrading strain Serratia marcescens ACE2

The nucleotide sequence of a smallest cryptic plasmid pRK10 of Serratia marcescens ACE2 was determined. When compared to the all other plasmids reported so far from S. marcescens in sizes of over 70 kb, pRK10 is only 4241 bp long with 53% G + C content and has five coding sequences representing a coding percentage of 65.41. This small plasmid consists of one Tdh gene, four mobilization genes, mobCABD, and an origin of replication homologous to those of ColE1-type plasmids. Analysis of the five open reading frames identified on the plasmid suggests the presence of genes involved in replication and mobilization containing sequences homologous to the bom region and mobCABD genes of ColE1 and Tdh from Acinetobacter baumannii str. AYE. Results also indicate that pRK10 does not encode any gene for antibiotic/heavy metal resistance. Copy number and incompatibility of the plasmid with plasmids of ColE1 origin of replication was determined and it is quite stable in its natural host as well as in Escherichia coli DH5α. This relatively small plasmid will be useful for construction of shuttle vectors to facilitate the genetic analysis.     

Interdependence and nodule specificity of cis-acting regulatory elements in the soybean leghemoglobin lbc3 and N23 gene promoters

Summary A composite plasmid comprising the mini-F and pBR322 replicons was found to inhibit cell growth of a host with conditional mutations in dnaA and rnh under restrictive conditions, where the normal initiation of replication from oriC was inactivated, but the alternative replication initiation from oriK was active. It was further shown that the composite plasrnid inhibited stable DNA replication (SDR) which occurs constitutively in cells mutant for rnh. Neither pBR322 nor mini-F alone produced these inhibitory effects. Deletion analyses revealed that the mini-F segment responsible for the inhibition of both processes was the promoter region of the sopA gene which had been cloned into a site upstream of the bla gene on pBR322 in such an orientation as to cause overexpression of bla. Inserting the promoter of the Escherichia coli lac gene into the same site had the same effect. Introduction of a deletion and a frameshift mutation into bla abolished the inhibition. Thus, the inhibition of growth and SDR appear to be due to overproduction of the bla gene product, -lactamase.     

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.     

Temperature-sensitive,lipopolysaccharide-deficient mutants of Salmonella typhimurium

Two mutants of Salmonella typhimurium LT2, which were temperature-sensitive for lipopolysaccharide (LPS) synthesis, were isolated from a galE ^- strain based on their resistance to phage C21 and sensitivity to sodium deoxycholate at 42°C. They produced LPS of chemotype Rc at 30°C and deep-rough LPS at 42°C. P22-mediated transductional analysis showed that the mutations responsible for temperature sensitivity are located in the rfa cluster where several genes involved in the synthesis of the LPS core are mapped. A plasmid, carrying rfaC, D and F genes of Escherichia coli K-12, complemented these mutations. These genes are responsible for the synthesis of the inner-core region of the LPS molecule. This indicates that genetic defects in these temperature-sensitive mutants affect the inner-core region of LPS.     

Plasmid replication and Hfr formation in strains of Escherichia coli carrying seg mutations.

Summary Several conditional-lethal mutations that do not permit the replication of F-factors ofEscherichia coli K-12 are located at a site calledseg. This gene is located on theE. coli chromosome betweenserB andthr. It is unrelated to other known genes involved in DNA replication. Strains carryingseg mutations were unable to replicate F-lac⁺, several F-gal⁺s, F-his⁺ and bacteriophage at 42°. However, neither phage T4, ColE1, nor any of the R factors tested were prevented from replicating at 42°C.When the kinetics of the loss of F-primes is studied inseg strains, it is found that the rate of curing depends on the size of the plasmid, larger F factors curing faster than smaller ones, and that Hfrs are formed at high frequencies. The Hfrs showed both F-genote enlargement and normal transfer of chromosomal markers. The F-genotes are unstable and segregate chromosomal markers at high frequencies. Some orthodox Hfrs were examined, and two that were known to revert to the F⁺ condition relatively frequently were found to generate enlarged F-genotes on mating, whereas two strains that were very stable with respect to reversion to the F⁺ state did not show F-genote formation.F-genote formation fromseg Hfr strains is dependent of a functionalrecA gene, as F-genote formation was not seen with aseg-2, recA-1 Hfr. This is in contrast to F-genote enlargement shown by both orthodox Hfrs and an Hfr strain constructed by integration of a temperature-sensitive F-gal⁺, whose F-genote enlargement is Rec-independent. Thus there may be more than one mechanism for the formation of enlarged F-genotes.     

A general method for the construction of Escherichia coli mutants by homologous recombination and plasmid segregation

Summary A technique is presented by which mutations can be introduced into the Escherichia coli chromosome by gene replacement between the chromosome and a plasmid carrying the mutant gene. The segregational instability of plasmids in E. coli is used with high efficiency to isolate E. coli mutants. The method should be applicable to construction of mutants for any E. coli chromosomal gene provided it is dispensable, and for any E. coli strain provided it is capable of homologous recombination. The use of the method was demonstrated by constructing E. coli mutants for the glycogen branching enzyme gene (glgB) and the -galactosidase gene (lacZ). The results show that recombination occurs via a reciprocal mechanism indicating that the method should, in a slightly modified form, also be useful in transferring chromosomal mutations onto multicopy plasmids in vivo.     

Gene disruption by plasmid integration in Listeria monocytogenes: insertional inactivation of the listeriolysin determinant lisA

Summary A plasmid integration technique was developed for insertional inactivation of chromosomal Listeria monocytogenes genes. A Listeria-Escherichia coli shuttle vector (pLSV1) was constructed which carried the temperature-sensitive gram-positive replication origin from plasmid pTV32(Ts). An internal fragment of the listeriolysin gene (IisA) was cloned into pLSV1 to create pLSV2. In L. monocytogenes pLSV2 transformants, plasmid pLSV2 integrated into the L. monocytogenes chromosome at a frequency of 2 × 10^–3 via lisA homology and these cells could be selected at 42° C using a plasmid-encoded erythromycin resistance. Plasmid integration resulted in disruption of the lisA gene, production of a truncated, immunologically cross-reactive listeriolysin protein and loss of the hemolytic phenotype. An improved Listeria protoplast transformation method is also described which facilitates genetic manipulation of Listeria species.     

Genetic recombination of homologous plasmids catalysed by cell-free extracts of topo-isomerase mutant strains of Saccharomyces cerevisiae

Cell-free extracts of the yeast Saccharomyces cerevisiae can be used to catalyse the recombination of bacterial plasmids in vitro. Recombination between homologous plasmids containing different mutations in the gene encoding tetracycline resistance is detectable by the appearance of tetracycline-resistance following transformation of the recombinant plasmid DNA into Escherichia coli DH5. This in vitro recombination system was used to determine the involvement of eukaryotic topo-isomerases in genetic recombination. Cell-free extracts prepared from a temperature-sensitive topo-isomerase II mutant (top2-1) of S. cerevisiae yielded tetracycline-resistant recombinants, when the recombination assays were performed at both a non-restrictive temperature (30°C) and the restrictive temperature (37°C). This result was obtained whether or not ATP was present in the recombination buffer. Extracts from a non-conditional topo-isomerase I mutant (top1-1) of S. cerevisiae yielded tetracycline-resistant recombinants, as did a temperature-sensitive double mutant (top2-1/top1-8) at the restrictive temperature. The results of this study indicate that neither topo-isomerase I nor topo-isomerase II was involved in the recombinational activity examined.