Identification and characterization of RP1 Tra1 cistrons involved in pilus function and plasmid mobilization.

Transfer-defective mutants of the Tra1 region of RP1 were isolated. Complementation studies involving stable heterozygotes combined with the mapping of Tn5 insertion mutations revealed two pilus cistrons, pilA and pilB, at positions 46.9 to 48.2 kb and 46.0 to 46.4 kb, respectively. All pilB mutants were Dps- (i.e., resistant to donor-specific phages PR4 and PRR1), whereas pilA mutants were Dps- (promoter-proximal mutations), Dps+/- (sensitive only to PR4 [more centrally located mutations]), or Dps+ (sensitive to both phages [promoter-distal mutations]). The correlation between the site mutated and the Dps phenotype, together with the finding that certain Dps+ pilA mutants continued to mobilize nonconjugative plasmids, suggested that pilA is bifunctional, contributing both to pilus function (at the promoter-proximal end) and to RP1 mobilization. It was also shown that the 43.5- to 49.5-kb region that includes pilA and pilB encodes all of the Tra1 pilus functions required for propagation of donor-specific phages and hence, probably, for pili that are active in conjugation. Finally, three cistrons that specifically affect RP1 mobilization were identified. Two of these, mobA and mobB, occur immediately anticlockwise to oriT and probably correspond to the traJ and traI genes characterized by other workers. The third cistron, mobC, occurs clockwise to oriT and may be a new mobilization gene, since its function can be substituted by IncP beta plasmids, a feature different from that of the traK mobilization gene which occurs in the same region but is RP1 specific. None of the mob cistrons was required for mobilization of nonconjugative plasmids, except for mobB, which was required by pVS99.     

Ordering of the flagellar genes in Pseudomonas aeruginosa by insertions of mercury transposon Tn501.

The flagellar genes of Pseudomonas aeruginosa PAO cluster on the chromosome at two distinct regions, region I and region II. The order of the flagellar cistrons in this organism was established by using transducing phage G101 and plasmids FP5 and R68.45. A method to insert transposon Tn501 near the fla genes was devised. We obtained two strains in which Tn501 was inserted at sites close to the flagellar cistrons in region II. We isolated Fla mutants in which the chromosomal segment between the two Tn501 insertion sites was deleted. Using Tn501-encoded mercury resistance as an outside marker, we determined the order of 9 of the 11 flagellar cistrons in region II as follows: puuF-region I-flaG-flaC-flaI-flaH-flaD-flaB-flaA-flaF-flaE-pur-67. By using phage G101-mediated transduction, the mutation converting monoflagellated bacteria into the multiflagellated (mfl) form was closely linked to the five fla cistrons in region I. Using mfl as an outside marker, we determined the order of the five cistrons as follows: puuF-flaV-flaZ-flaW-flaX-flaY-region II. The mfl mutation was shown to be either located within the flaV cistron or linked very closely to this cistron. No linkage was observed in transductions between any of the fla cistrons in region I and any of the fla cistrons in region II.     

Physical mapping of the conjugative bacteriocin plasmid pPD1 of Enterococcus faecalis and identification of the determinant related to the pheromone response.

The pheromone-responding conjugative bacteriocin plasmid pPD1 (59 kb) of Enterococcus faecalis was mapped physically by using a relational clone approach, and transposon analysis with Tn917 (Emr) or Tn916 (Tcr) facilitated the location of the bacteriocin-related genes in a segment of about 6.7 kb. Tn917 insertions within a 3-kb region resulted in constitutive clumping. The nucleotide sequence of the region that included the insertions giving rise to constitutive clumping was determined. The region of pPD1 spanned about 8 kb and was found to contain a number of open reading frames, some of which were named on the basis of homologies with two other pheromone-responding plasmids, pAD1 and pCF10. The genes were arranged in the sequence repB-repA-traC-traB-traA-ipd-traE-traF- orfY-sea-1 with all but repB and traA oriented in the same (left-to-right) direction. traC and traB corresponded, respectively, to traC and traB of pAD1 and to prgY and prgZ of pCF10.     

Physical and genetic map of the organomercury resistance (Omr) and inorganic mercury resistance (Hgr) loci of the IncM plasmid R831b

Tn7 insertion mutagenesis has been used to facilitate the generation of a physical (restriction endonuclease) and genetic map of the IncM plasmid, R831b. The only selectable phenotypes carried by this 90-kb conjugative plasmid are resistances to inorganic mercury [Hg(II)] and to organomercury compounds. Mutants in the Hgr locus of R831b complemented previously described mutants in the mer operon of the IncFII plasmid R100, indicating functional homology of the locus in each of these different plasmids. However, the R831b Hgr locus is not notably similar in restriction site pattern to either the mer operon of R100 or the mercury resistance transposon, Tn501. Although the enzymes they encode are co-ordinately regulated, the Omr locus of R831b maps approx. 13.5 kb away from the Hgr locus. Three insertions which affect neither phenotype lie between the Hgr and Omr loci; thus, the loci are separated both physically and genetically. One mutant was obtained which tentatively identifies the position of the Tra locus of R831b as adjacent to the Hgr locus.     

Broad-host-range IncP-4 plasmid R1162: effects of deletions and insertions on plasmid maintenance and host range

R1162 is an 8.7-kilobase (kb) broad-host-range replicon encoding resistance to streptomycin and sulfa drugs. In vitro deletion of 1.8-kb DNA between coordinates 3.0 and 5.3 kb did not affect plasmid maintenance, but a Tn1 insertion at coordinate 6.3 kb led to a recessive defect in plasmid maintenance. The only cis-acting region necessary for plasmid replication appears to lie between the Tn1 insertion at coordinate 6.3 kb and a second Tn1 insertion at coordinate 6.5 kb. All R1162 sequences between position 6.5 kb and the EcoRI site at coordinate 8.7/0 kb were dispensible for replication in Escherichia coli and Pseudomonas putida. Plasmids carrying insertions in a variety of restriction sites in an R1162::Tn1 derivative were unstable in P. putida but stable in E. coli. Tn5 insertions in R1162 showed a hot spot at coordinate 7.5 kb. A Tn5 insertion at coordinate 8.2 kb appeared to mark the 3' end of the streptomycin phosphotransferase coding sequence. All R1162::Tn5 derivatives showed specific instability in Pseudomonas strains but not in E. coli. The instability could be relieved by internal deletions of Tn5 sequences. In the haloaromatic-degrading Pseudomonas sp. strain B13, introduction of an unstable R1162::Tn5 plasmid led to loss of ability to utilize m-chlorobenzoate as a growth substrate. Our results showed that alteration of plasmid sequence organization in nonessential regions can result in restriction of plasmid host range.     

Cloning the Tra1 region of RP1

The Tra1 region of RP1 from a derivative with Tn7 inserted into the kanamycin resistance determinant was cloned, using EcoRI, into the multicopy vector plasmid pBR325. For one orientation of the cloned fragment the resultant chimeric plasmid was very frequently lost from the cell, but in the other orientation it was much more stable and also compatible with RP1. Complementation by the stable chimeric plasmid, pED800, of a series of RP1 tra mutants showed that the mutations of all those retaining sensitivity to the P-specific phages PRR1, Pf3, and PR4, or only to PR4, mapped in the Tra1 region, while only 2 out of 20 amber mutations leading to full P-specific phage-resistance did so.     

Identification and mapping of nitrogen fixation genes of Rhodobacter capsulatus: duplication of a nifA-nifB region.

Rhodobacter capsulatus mutants unable to fix nitrogen were isolated by random transposon Tn5 mutagenesis. The Tn5 insertion sites of 30 Nif- mutants were mapped within three unlinked chromosomal regions designated A, B, and C. The majority of Tn5 insertions (21 mutants) map within nif region A, characterized by two ClaI fragments of 2.5 and 25 kilobases (kb). The 17-kb ClaI fragment of nif region B contains six nif::Tn5 insertions, and the three remaining mutations are located on a 32-kb ClaI fragment of nif region C. Hybridization experiments using all 17 Klebsiella pneumoniae nif genes individually as probes revealed homology to nifE, nifS, nifA, and nifB in nif region A. The nifHDK genes were localized in nif region B. About 2 kb away from this operon, a second copy of the DNA fragments homologous to nifA and nifB, originally found in nif region A, was identified.     

Mutagenesis of the Tra1 core region of RK2 by using Tn5: identification of plasmid-specific transfer genes.

The conjugation system of the IncP alpha plasmid RK2/RP4 is encoded by transfer regions designated Tra1, Tra2, and Tra3. The Tra1 core region, cloned on plasmid pDG4 delta 22, consists of the origin of transfer (oriT) and 2.6 kilobases of flanking DNA providing IncP alpha plasmid-specific functions that allow pDG4 delta 22 to be mobilized by the heterologous IncP beta plasmid R751. Tn5 insertions in pDG4 delta 22 define a minimal 2.2-kilobase region required for plasmid-specific transfer of oriT. The Tra1 core contains the traJ and traK genes as well as an 18-kilodalton open reading frame downstream of traJ. The traJ and traK genes were shown to be required for transfer by complementation of inserts within these genes. Genetic evidence for the role of the 18-kilodalton open reading frame in transfer was obtained, although this protein has not been detected in cell lysates. These studies indicate that at least three transfer proteins are involved in plasmid-specific interactions at oriT.     

Characterization of the Tra2 Region of the IncHI1 Plasmid R27

In this study, the DNA sequence of one of the transfer regions of the IncHI1 plasmid R27 was determined. This region, which corresponds to coordinates 0-40 on the R27 map has been called the Tra2 region, and is believed to be involved in mating pair formation. DNA sequence analysis of the transfer region identified 11 open reading frames which showed similarities to the transfer genes from other conjugative systems. The R27 transfer genes appear to most closely resemble the genes from the F plasmid and Sphingomonas aromaticivorans plasmid pNL1, both within the individual genes and in the overall gene order. The Tra2 region is also distinct in that replication, partitioning, and stability genes are found in the middle of the transfer region. The R27 Tra2 region also contains a gene, trhF, which appears to be related to the TraF genes of Agrobacterium and Rhizobium species. This, along with the temperature-sensitive transfer system found in both H plasmids and Agrobacterium, leads to the speculation that the R27 transfer region evolved from both ancestral F-like and P-like plasmids.     

Genetic Analysis of Transfer by the Escherichia coli Sex Factor F, Using P1 Transductional Complementation

P1 transduction has been used to perform a complementation analysis of a series of transfer-deficient mutants of Flac. The results define ten cistrons and are consistent with the results of a conjugational analysis presented in an accompanying report. Both sets of results are summarized here. Between them, they define eleven cistrons, traA through traK, necessary for conjugational deoxyribonucleic acid (DNA) transfer. Mutants in traI and traD and some in traG still make F-pili, although traD mutants are resistant to f2 phage; their products may be involved in conjugational DNA metabolism. Other mutants in traG and all mutants in the remaining eight cistrons do not make F-pili. One of these, traJ, may be a control cistron, and the others may specify a biosynthetic pathway responsible for synthesis and modification of the F-pilin subunit protein and its assembly into the F-pilus.     

Localization of a chromosomal mutation affecting expression of extracellular lipase in Staphylococcus aureus.

We describe a Tn551 chromosomal insertion in Staphylococcus aureus S6C that results in sharply reduced expression of extracellular lipase. With Tn917 as a probe, the insertion in the original mutant (KSI905) was localized to a 12.6-kb EcoRI DNA fragment. The 12.6-kb fragment was cloned and used as a probe to identify a 26-kb EcoRI fragment containing the Tn551 insertion site in the S6C parent strain. Restriction endonuclease analysis of the 12.6- and 26-kb EcoRI fragments confirmed that the Tn551 insertion in KSI905 was accompanied by a deletion of 18.7 kb of chromosomal DNA. Tn551 was transduced from KSI905 back into the S6C parent strain. All transductants exhibited the same lipase-negative (Lip-) phenotype and contained the same mutation with respect to both the insertion and the 18.7-kb deletion. The inability to produce lipase was not caused by disruption of the lipase structural gene, since all Lip- mutants carried intact copies of geh. Moreover, the Tn551 insertion was localized to a region of the staphylococcal chromosome at least 650 kb from geh. Taken together, these results suggest that the Tn551 insertion occurred in a region of the chromosome encoding a trans-active element required for the expression of extracellular lipase. A 20-bp oligonucleotide corresponding to a sequence within the region encoding RNA II near the Tn551 insertion site in ISP546 (H.L. Peng, R.P. Novick, B. Kreiswirth, J. Kornblum, and P. Schlievert, J. Bacteriol. 170:4365-4372, 1988) and a 1.75-kb DNA fragment representing the region encoding RNA III were used as gene probes to show that the Tn551 insertion did not occur in the agr locus. We conclude that the genetic element functions independently of agr or as an unrecognized part of that regulatory system.     

Mapping of transfer regions within incompatibility group HI plasmid R27.

Plasmids of incompatibility group HI are large (greater than 150 kilobases [kb]) and possess an unusual thermosensitive mode of conjugative transfer. R27, the prototype IncHi1 plasmid, encodes resistance to tetracycline via a determinant which is related to transposon Tn10. A restriction endonuclease map of R27 (size, 182 kb) was recently constructed with ApaI, PstI, and XbaI. Transfer genes within R27 were mapped by insertion of Tn5 and Tn7. At least two different regions of the plasmid were concerned with transfer functions. Insertions into either region completely abolished transfer. None of the insertions had any effect on entry exclusion (Eex) of other IncH plasmids. However, a deletion mutant which lacked the Eex function was obtained, allowing us to map the probable site of the gene encoding Eex to one of the two transfer regions. The tetracycline resistance determinant in R27 was located within an 8-kb region between the two main transfer regions. The transfer genes, therefore, are not located together in R27 but are situated in at least two major widely separated transfer regions.     

Properties of transposon Tn2555 carrying the genes for sucrose utilization

Tn2555, a new transposon coding for genes of sucrose utilization was studied. Tn2555 was shown to integrate into the plasmids RP4 and R6K, phage P1CmClr100 and Escherichia coli K12 chromosome. Tn2555 frequency of transposition to RP4 and R6K DNA is (2-5) X 10(-7) in Rec+-strain, (3-6) X 10(-8) in Rec--strain. Tn2555 integration site in phage P1CmClr100 Sac+-derivative studied has been localised within the C-segment of P1 DNA. In three independent cases of Tn2555 transposition to the chromosome the transposon was found to be integrated in the region between 29 and 32 min of Escherichia coli K12 linkage map. The restriction endonuclease analysis of seven independent isolates of RP4::Tn2555 has shown the grouping of Tn2555 integration sites in the Tn1 region of RP4. Frequent rearrangements occurring within Tn2555 have been revealed by the analysis. However, an invertible DNA segment of about 6-7 kb was preserved in all transposon structures.     

Map location of the Escherichia coli origin of replication.

Summary Working with restriction fragments obtained directly from the Escherichia coli K12 chromosome, the EcoRI-HindIII restriction map of the section of the chromosome containing the replication origin has been extended by 14 kilobase pairs (kb) to cover 56kb. Within this newly mapped portion, the liv and rrnC cistrons have been identified by (1) hybridization of individual restriction fragmenents to the ilv-transducing phage dilv5 and (2) a comparison of the restriction map of this region with the EcoRI map of dilv5 and the HindIII map of the plasmid pJC110, a ColE1-ilv hybrid. The replication origin is located approximately 30 kb from the ilvE gene and 20 kb from the rrnC 16S rRNA cistron. This places the origin near 82.7 min on the genetic map, close to uncA.