Prevalence of recombinational versus mutational events in damaged plasmid DNA containing regions of homology with the chromosome.

Plasmid DNA modified by in vitro treatments was transformed in E. coli bacterial cells. A streptomycin-resistant strain, carrying the peculiar rpsL421 mutation, was used as a recipient for the cloning vector pNO1523, which carries the wild-type (streptomycin-sensitive) rpsL allele. Transformants were streptomycin-sensitive unless a change in plasmid sequence had occurred. The analysis of the MaeI restriction pattern of plasmids isolated from streptomycin-resistant transformants, together with the detection of the phenotype that they conferred to a streptomycin-dependent strain, allowed us to identify plasmids that had undergone recombination with the host chromosome. The number of these plasmids exceeded by far that of plasmids resulting from mutational events.     

Use of a dominant rpsL allele conferring streptomycin dependence for positive and negative selection in Thermus thermophilus

A spontaneous rpsL mutant of Thermus thermophilus was isolated in a search for new selection markers for this organism. This new allele, named rpsL1, encodes a K47R/K57E double mutant S12 ribosomal protein that confers a streptomycin-dependent (SD) phenotype to T. thermophilus. Models built on the available three-dimensional structures of the 30S ribosomal subunit revealed that the K47R mutation directly affects the streptomycin binding site on S12, whereas the K57E does not apparently affect this binding site. Either of the two mutations conferred the SD phenotype individually. The presence of the rpsL1 allele, either as a single copy inserted into the chromosome as part of suicide plasmids or in multicopy as replicative plasmids, produced a dominant SD phenotype despite the presence of a wild-type rpsL gene in a host strain. This dominant character allowed us to use the rpsL1 allele not only for positive selection of plasmids to complement a kanamycin-resistant mutant strain, but also more specifically for the isolation of deletion mutants through a single step of negative selection on streptomycin-free growth medium.     

Efficient introduction of cloned mutant alleles into the Escherichia coli chromosome.

An efficient method for moving mutations in cloned Escherichia coli DNA from plasmid vectors to the bacterial chromosome was developed. Cells carrying plasmids that had been mutated by the insertion of a resistance gene were infected with lambda phage containing homologous cloned DNA, and resulting lysates were used for transduction. Chromosomal transductants (recombinants) were distinguished from plasmid transductants by their ampicillin-sensitive phenotype, or plasmid transductants were avoided by using a recBC sbcB E. coli strain as recipient. Chromosomal transductants were usually haploid when obtained in a nonlysogen because of selection against the lambda vector and partially diploid when obtained in a lysogen. Pure stocks of phage that carry the resistance marker and transduce it at high frequency were obtained from transductant bacteria. The lambda-based method for moving mutant alleles into the bacterial chromosome described here should be useful for diverse analyses of gene function and genome structure.     

Analysis of merodiploid strains of Sh. flexneri that have lost virulence]

Episome F'13 introduced into the genome of a virulent Sh. flexneri strain brought about changes in a number of properties of the recipient strain. The expression of these properties was not connected with the chromosome area allelic to the plasmid genome. These changes seem to be induced by the mobilization of the chromosome genes of E. coli. The loss of virulence in Sh. flexneri strains carrying episome F'13 seemed to be the consequence of two reasons: the overlapping of kcpA gene by its dominant avirulent allele and abnormal synthesis of cell wall lipopolysaccharide due to the transfer of the mobilized genes from the donor strain F'13. When the preliminary mapping of genes on the chromomome was made with the use of plasmids, it was found necessary to use F-episomes which had no influence on the changes occurring in the phenotypic characteristics of the recipient.     

Plasmid and transposon transfer to Thiobacillus ferrooxidans.

The broad-host-range IncP plasmids RP4, R68.45, RP1::Tn501, and pUB307 were transferred to acidophilic, obligately chemolithotrophic Thiobacillus ferrooxidans from Escherichia coli by conjugation. A genetic marker of kanamycin resistance was expressed in T. ferrooxidans. Plasmid RP4 was transferred back to E. coli from T. ferrooxidans. The broad-host-range IncQ vector pJRD215 was mobilized to T. ferrooxidans with the aid of plasmid RP4 integrated in the chromosome of E. coli SM10. pJRD215 was stable, and all genetic markers (kanamycin/neomycin and streptomycin resistance) were expressed in T. ferrooxidans. By the use of suicide vector pSUP1011, transposon Tn5 was introduced into T. ferrooxidans. The influence of some factors on plasmid transfer from E. coli to T. ferrooxidans was investigated. Results showed that the physiological state of donor cells might be important to the mobilization of plasmids. The transfer of plasmids from E. coli to T. ferrooxidans occurred in the absence of energy sources for both donor and recipient.     

Use of a Dominant rpsL Allele Conferring Streptomycin Dependence for Positive and Negative Selection in Thermus thermophilus

A spontaneous rpsL mutant of Thermus thermophilus was isolated in a search for new selection markers for this organism. This new allele, named rpsL1, encodes a K47R/K57E double mutant S12 ribosomal protein that confers a streptomycin-dependent (SD) phenotype to T. thermophilus. Models built on the available three-dimensional structures of the 30S ribosomal subunit revealed that the K47R mutation directly affects the streptomycin binding site on S12, whereas the K57E does not apparently affect this binding site. Either of the two mutations conferred the SD phenotype individually. The presence of the rpsL1 allele, either as a single copy inserted into the chromosome as part of suicide plasmids or in multicopy as replicative plasmids, produced a dominant SD phenotype despite the presence of a wild-type rpsL gene in a host strain. This dominant character allowed us to use the rpsL1 allele not only for positive selection of plasmids to complement a kanamycin-resistant mutant strain, but also more specifically for the isolation of deletion mutants through a single step of negative selection on streptomycin-free growth medium.     

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.     

Novel ribosomal mutations affecting translational accuracy, antibiotic resistance and virulence of Salmonella typhimurium

Many mutations in rpsL cause resistance to, or dependence on, streptomycin and are restrictive (hyperaccurate) in translation. Dependence on streptomycin and hyperaccuracy can each be reversed phenotypically by mutations in either rpsD or rpsE . Such compensatory mutations have been shown to have a ram phenotype (ribosomal ambiguity), increasing the level of translational errors. We have shown recently that restrictive rpsL alleles are also associated with a loss of virulence in Salmonella typhimurium . To test whether ram mutants could reverse this loss of virulence, we have isolated a set of rpsD alleles in Salmonella typhimurium . We found that the rpsD alleles restore the virulence of strains carrying restrictive rpsL alleles to a level close to that of the wild type. Unexpectedly, three out of seven mutant rpsD alleles tested have phenotypes typical of restrictive alleles of rpsL , being resistant to streptomycin and restrictive (hyperaccurate) in translation. These phenotypes have not been previously associated with the ribosomal protein S4. Furthermore, all seven rpsD alleles (four ram and three restrictive) can phenotypically reverse the hyperaccuracy associated with restrictive alleles of rpsL . This is the first demonstration that such compensations do not require that the compensating rpsD allele has a ribosomal ambiguity ( ram ) phenotype.     

Cloning and expression of 7.55 kb KPNI fragment of Burkholderia pseudomallei PPM1 plasmid in Escherichia coli

BamHI, SalI, PstI, and KpnI fragments of pPM1 (B. pseudomallei 12.95 kb plasmid) were cloned in E. coli. The recombinant clones carrying a 7.55 kb KpnI fragment of pPM1 were highly resistant to several aminoglycosides (streptomycin, kanamycin, and gentamycin) and fluoroguinolones (perfloxacin, ofloxacin). Two outer membrane proteins (23 and 27 kDa) absent in E. coli and capable to form 120 kDa oligomer complex were detected by the Western blot method in the strain carrying recombinant pS19 plasmid. The integration of a cloned 7.55 kb sequence in the chromosome was observed by the dot and Southern hybridization analysis in the clones carrying recombinant plasmids pS12 and pS14.     

An rpsL cassette, janus, for gene replacement through negative selection in Streptococcus pneumoniae.

Natural genetic transformation offers a direct route by which synthetic gene constructs can be placed into the single circular chromosome of Streptococcus pneumoniae. However, the lack of a general negative-selection marker has hampered the introduction of constructs that do not confer a selectable phenotype. A 1.3-kb cassette was constructed comprising a kanamycin (Kn) resistance marker (kan) and a counterselectable rpsL(+) marker. The cassette conferred dominant streptomycin (Sm) sensitivity in an Sm-resistant background in S. pneumoniae. It was demonstrated that it could be used in a two-step transformation procedure to place DNA of arbitrary sequence at a chosen target site. The first transformation into an Sm-resistant strain used the cassette to tag a target gene on the chromosome by homologous recombination while conferring Kn resistance but Sm sensitivity on the recombinant. Replacement of the cassette by an arbitrary segment of DNA during a second transformation restored Sm resistance (and Kn sensitivity), allowing construction of silent mutations and deletions or other gene replacements which lack a selectable phenotype. It was also shown that gene conversion occurred between the two rpsL alleles in a process that depended on recA and that was susceptible to correction by mismatch repair.     

Isolation of the R'his plasmids of Vibrio cholerae

V. cholerae strain VT5104 capable of donor activity in conjugation has been constructed by the genetic technique based on plasmid RP4::Mucts62 integration into V. cholerae chromosome due to plasmid homology with Mucts62 inserted into the chromosome. The gene for histidine synthesis has been mobilized and transferred into the recipient cells from VT5104 donor. The conjugants obtained are able to efficiently transfer his+ gene included into the plasmid structure in conjugation with eltor recipient. Thus, the constructed strain VT5104 generates R' plasmids carrying V. cholerae chromosomal genes.     

Cloning of DNA segments of phage 2C, which allows autonomous plasmid replication in Bacillus subtilis

The chromosome of Bacillus subtilis phage 2C is a 100-MDa double-stranded DNA molecule, containing hydroxymethyluracil in place of thymine and carrying redundant ends each encompassing 10% of the genome. 2C DNA was cleaved with EcoRI and HindIII, and cloned in the shuttle plasmids pSC 540 and pCP 115, both containing segments originating from B. subtilis and Escherichia coli plasmids. These chimaerical plasmids, carrying the chloramphenicol resistance gene, were unable to replicate in B. subtilis; this ability was restored, however, after the insertion of viral DNA segments. Physical maps of the recombinant plasmids were made; a large deletion of the E. coli-derived segment of pSC 540 was observed (which paralleled a loss of replication in this host), whereas addition of 2C DNA segments in pCP 115 was not accompanied by deletion (replication in E. coli was conserved in this case). Cloned viral segments mapped mostly, but not exclusively, within the redundant ends of 2C DNA. It is suggested that the thirteen recombinant clones carried the replication origin region of phage 2C DNA, and that these sequences originated within or close to the redundant extremities of the viral chromosome.     

Spreading of streptomycin antibiotic resistance gene in Escherichia coli plasmids demonstrated by Southern blot analysis

Plasmids from E. coli strains of 38 donors were transconjugated to common recipient SY663 Escherichia coli K12. The restriction patterns of the isolated plasmids were highly heterogenous. However, the streptomycin (Sm) resistance genes of the plasmids were identical or closely homologous in 29 of the 33 plasmids conferring Sm resistance. These data were based on Southern blot analysis, using the Sm resistance gene (encoding aminoglycoside phosphoryl transferase) as probe cut out from pBP1 plasmid. Our data suggest an extensive spreading of streptomycin resistance gene of this type.     

Separation of the SOS-dependent and SOS-independent components of alkylating-agent mutagenesis.

Escherichia coli plasmids containing the rpsL+ gene (Strs phenotype) as the target for mutation were treated in vitro with N-methyl-N-nitrosourea. Following fixation of mutations in E. coli MM294A cells (recA+ Strs), an unselected population of mutant and wild-type plasmids was isolated and transferred into a second host, E. coli 6451 (recA Strr). Strains carrying plasmid-encoded forward mutations were then selected as Strr isolates, while rpsL+ plasmids conferred the dominant Strs phenotype in the second host. Mutation induction and reduced survival of N-methyl-N-nitrosourea-treated plasmids were shown to be dose dependent. Because this system permitted analysis and manipulation of the levels of certain methylated bases produced in vitro by N-methyl-N-nitrosourea, it afforded the opportunity to assess directly the relative roles of these bases and of SOS functions in mutagenesis. The methylated plasmid DNA gave a mutation frequency of 6 X 10(-5) (a 40-fold increase over background) in physiologically normal cells. When the same methylated plasmid was repaired in vitro by using purified O6-methylguanine DNA methyltransferase (to correct O6-methylguanine and O4-methylthymine), no mutations were detected above background levels. In contrast, when the methylated plasmid DNA was introduced into host cells induced by UV light for the SOS functions, rpsL mutagenesis was enhanced eightfold over the level seen without SOS induction. This enhancement of mutagenesis by SOS was unaffected by prior treatment of the DNA with O6-methylguanine DNA methyltransferase. These results demonstrate a predominant mutagenic role for alkylation lesions other than O6-methylguanine or O4-methylthymine when SOS functions are induced. The mutation spectrum of N-methyl-N-nitrosourea under conditions of induced SOS functions revealed a majority of mutagenic events at A . T base pairs.     

Genetic transformation of Geobacillus kaustophilus HTA426 by conjugative transfer of host-mimicking plasmids

We established an efficient transformation method for thermophile Geobacillus kaustophilus HTA426 using conjugative transfer from Escherichia coli of host-mimicking plasmids that imitate DNA methylation of strain HTA426 to circumvent its DNA restriction barriers. Two conjugative plasmids, pSTE33T and pUCG18T, capable of shuttling between E. coli and Geobacillus spp., were constructed. The plasmids were first introduced into E. coli BR408, which expressed one inherent DNA methylase gene (dam) and two heterologous methylase genes from strain HTA426 (GK1380-GK1381 and GK0343-GK0344). The plasmids were then directly transferred from E. coli cells to strain HTA426 by conjugative transfer using pUB307 or pRK2013 as a helper plasmid. pUCG18T was introduced very efficiently (transfer efficiency, 10(-5)-10(-3) recipient(-1)). pSTE33T showed lower efficiency (10(-7)-10(-6) recipient(-1)) but had a high copy number and high segregational stability. Methylase genes in the donor substantially affected the transfer efficiency, demonstrating that the host-mimicking strategy contributes to efficient transformation. The transformation method, along with the two distinguishing plasmids, increases the potential of G. kaustophilus HTA426 as a thermophilic host to be used in various applications and as a model for biological studies of this genus. Our results also demonstrate that conjugative transfer is a promising approach for introducing exogenous DNA into thermophiles.     

Experimental genome evolution: large-scale genome rearrangements associated with resistance to replacement of a chromosomal restriction-modification gene complex

Type II restriction enzymes are paired with modification enzymes that protect type II restriction sites from cleavage by methylating them. A plasmid carrying a type II restriction-modification gene complex is not easily replaced by an incompatible plasmid because loss of the former leads to cell death through chromosome cleavage. In the present work, we looked to see whether a chromosomally located restriction-modification gene complex could be replaced by a homologous stretch of DNA. We tried to replace the PaeR7I gene complex on the Escherichia coli chromosome by transducing a homologous stretch of PaeR7I-modified DNA. The replacement efficiency of the restriction-modification complex was lower than expected. Some of the resulting recombinant clones retained the recipient restriction-modification gene complex as well as the homologous DNA (donor allele), and slowly lost the donor allele in the absence of selection. Analysis of their genome-wide rearrangements by Southern hybridization, inverse polymerase chain reaction (iPCR) and sequence determination demonstrated the occurrence of unequal homologous recombination between copies of the transposon IS3. It was strongly suggested that multiple rounds of unequal IS3-IS3 recombination caused large-scale duplication and inversion of the chromosome, and that only one of the duplicated copies of the recipient PaeR7I was replaced.     

Temperature-Sensitive Mutants for the Replication of Plasmids in Escherichia coli: Requirement for Deoxyribonucleic Acid Polymerase I in the Replication of the Plasmid ColE1

An Escherichia coli mutant (polA1), defective in deoxyribonucleic acid (DNA) polymerase I, (EC 2.7.7.7) is unable to maintain colicinogenic factor E1 (ColE1), whereas several sex factor plasmids are maintained normally in this strain. polA1 mutant strains containing these sex factor plasmids do not exhibit a readily detectable plasmid-induced polymerase activity. A series of E. coli mutants that are temperature sensitive for ColE1 maintenance, but able to maintain other plasmids, were isolated and shown to fall into two phenotypic groups. Mutants in one group are defective specifically in ColE1 maintenance at 43 C, but exhibit normal DNA polymerase I activity. Mutations in the second group map in the polA gene of E. coli, and bacteria carrying these mutations are sensitive to methylmethanesulfonate (MMS). Revertants that were selected either for MMS resistance or the ability to maintain ColE1 were normal for both properties. The DNA polymerase I enzyme of two of these mutants shows a pronounced temperature sensitivity when compared to the wild-type enzyme. An examination of the role of DNA polymerase I in ColE1 maintenance indicates that it is essential for normal replication of the plasmid. In addition, the presence of a functional DNA polymerase I in both the donor and recipient cell is required for the ColV-promoted conjugal transfer of ColE1 and establishment of the plasmid in the recipient cell.     

Plasmid vectors for selecting IS1-promoted deletions in cloned DNA: sequence analysis of the omega interposon.

We have constructed two plasmid vectors which allow selection for in vivo deletions within cloned DNA fragments. The plasmids are derivatives of pBR322 which carry the Escherichia coli rpsL (strA) gene, known to confer a dominant streptomycin (Sm)-sensitivity phenotype to the host cell, and a copy of the IS1 transposable element. Sm-resistant strains that harbor these plasmids display sensitivity to Sm. Spontaneous IS1-promoted deletions across the rpsL gene can be isolated simply by selection for Sm resistance. Hence, nested sets of deletions of a cloned DNA can be obtained and sequenced with an IS1-specific primer. Using this approach, we have determined the complete nucleotide sequence of the omega interposon [Prentki and Krisch, Gene 29 (1984) 303-313].     

Conjugation in Rhodopseudomonas sphaeroides mediated by R plasmids

Plasmids R68.45, RP4, RP4::Mu cts62, RP1ts::Tn10, RP1ts::Tn9, Rts1 and RP41 were transferred into cells of photosynthetic nitrogen-fixation bacterium Rhodopseudomonas sphaeroides from Escherichia coli and Pseudomonas aeruginosa. The transfer of plasmids occurred with high frequency of 10(-1) to 10(-2) per donor cell in all cases. Mobilization of R. sphaeroides 2R chromosome was obtained by RP4 and Rts1 plasmids at a frequency of 10(-7) to 10(-8) per donor cell in all cases. Mobilization of R. sphaeroides 2R chromosome was obtained by RP4 and Rts1 plasmids at a frequency of 10(-7) to 10(-8) per donor cell. Bacteriophage Mu cts62 could be induced from the plasmid DNA in R. sphaeroides 2R cells and was capable of the lytic growth and producing phage progeny. It was demonstrated that an increase in the efficiency of donor chromosomal genes transfer into recipient cells could be achieved in crosses with the donor carrying RP4::Mcts62 plasmid.     

Mutational inactivation of the Saccharomyces cerevisiae RAD4 gene in Escherichia coli.

The RAD4 gene of Saccharomyces cerevisiae is required for the incision of damaged DNA during nucleotide excision repair. When plasmids containing the wild-type gene were transformed into various Escherichia coli strains, transformation frequencies were drastically reduced. Most plasmids recovered from transformants showed deletions or rearrangements. A minority of plasmids recovered from E. coli HB101 showed no evidence of deletion or rearrangement, but when they were transformed into S. cerevisiae on centromeric vectors, little or no complementation of the UV sensitivity of rad4 mutants was observed. Deliberate insertional mutagenesis of the wild-type RAD4 allele before transformation of E. coli restored transformation to normal levels. Plasmids recovered from these transformants contained an inactive rad4 allele; however, removal of the inserted DNA fragment restored normal RAD4 function. These experiments suggest that expression of the RAD4 gene is lethal to E. coli and show that lethality can be prevented by inactivation of the gene before transformation. Stationary-phase cultures of some strains of E. coli transformed with plasmids containing an inactivated RAD4 gene showed a pronounced delay in the resumption of exponential growth, suggesting that the mutant (and, by inference, possibly wild-type) Rad4 protein interferes with normal growth control in E. coli. The rad4-2, rad4-3, and rad4-4 chromosomal alleles were leaky relative to a rad4 disruption mutant. In addition, overexpression of plasmid-borne mutant rad4 alleles resulted in partial complementation of rad4 strains. These observations suggest that the Rad4 protein is relatively insensitive to mutational inactivation.