Identification of regions of the Streptococcus faecalis plasmid pCF-10 that encode antibiotic resistance and pheromone response functions

The conjugative plasmid pCF-10 (58 kb) of Streptococcus faecalis has been mapped with restriction enzymes. By restriction mapping and Southern hybridization analysis, a 16-kb segment of the plasmid was shown to resemble closely the conjugative tetracycline resistance transposon, Tn916. Mutagenesis of the plasmid with the erythromycin resistance transposon Tn917 was used to localize a tetracycline resistance determinant and several regions involved in conjugal transfer. Fifty Tn917 insertions (outside the region of the plasmid homologous to Tn916) affecting mating behavior and the ability of donor cells to respond to the sex pheromone cCF-10 were mapped to nine distinct segments, or tra regions. Insertions into tra regions 1-3 and 7-9 led to an enhanced transfer ability of mutant plasmids relative to the transfer frequency obtained for the wild-type plasmid. Cells carrying these mutant plasmids differed in colony morphology or growth in broth culture from cells carrying pCF-10. Insertions into tra regions 4-6 resulted in reduced plasmid transfer, or completely eliminated the mating potential of donor cells. Insertions generating transfer-defective plasmids could be grouped further according to the ability of strains harboring the mutant plasmids to respond to cCF-10. HindIII fragments of pCF-10 coding for transfer functions have been cloned into Escherichia coli.     

Transposon mutagenesis analysis of meta-cleavage pathway operon genes of the TOL plasmid of Pseudomonas putida mt-2.

Hybrid plasmids containing the regulated meta-cleavage pathway operon of TOL plasmid pWWO were mutagenized with transposon Tn1000 or Tn5. The resulting insertion mutant plasmids were examined for their ability to express eight of the catabolic enzymes in Escherichia coli. The physical locations of the insertions in each of 28 Tn1000 and 5 Tn5 derivative plasmids were determined by restriction endonuclease cleavage analysis. This information permitted the construction of a precise physical and genetic map of the meta-cleavage pathway operon. The gene order xylD (toluate dioxygenase), L (dihydroxycyclohexidiene carboxylate dehydrogenase), E (catechol 2,3-dioxygenase), G (hydroxymuconic semialdehyde dehydrogenase), F (hydroxymuconic semialdehyde hydrolase), J (2-oxopent-4-enoate hydratase), I (4-oxalocrotonate decarboxylase), and H (4-oxalocrotonate tautomerase) was established, and gene sizes were estimated. Tn1000 insertions within catabolic genes exerted polar effects on distal structural genes of the operon, but not on an adjacent regulatory gene xylS.     

Structural-functional organization of the incompatibility group P plasmid pBS221

Plasmid pBS221 was physically mapped for restriction endonucleases EcoRI, BamHI, BglII, HindIII. The regions essential for the plasmid existence and participating in replication (oriV trfA*) and mobilization (mob) were cloned. The tet determinant and oriV trfA* regions were localized on the physical map of the plasmid. A DNA sequence homologous to genes of Tn501 mer operon was detected in this plasmid. The studies on homology of plasmids RP4 (IncP alpha), R751 (IncP beta) and pBS221 plasmid suggest that the latter belongs to the IncP beta subgroup.     

Analysis of the promoter-distal region of the tra operon of the F sex factor of Escherichia coli K-12 encoded by EcoRI restriction fragments f17, f19, and f2.

The promoter-distal region of the tra operon of the F sex factor Escherichia coli K-12 was analyzed, using the chimeric plasmid pRS31, which contains the F EcoRI restriction fragments f17, f19, and f2 cloned into the EcoRI site of pSC101. A series of deletion plasmids of pRS31, extending increasing distances from a site in f17 through f19 and ending in f2, were isolated. These plasmids were examined by heteroduplex analysis with the parent DNA, and a restriction map of this region of DNA was constructed. A series of Tn5 insertion derivatives of pRS31 were also isolated and mapped, using both heteroduplex analysis and restriction mapping. Both the insertion and deletion mutants were tested in minicells for the synthesis of radioactively labeled proteins. This allowed the identification of the individual gene products and mapping of the genes. The result is a saturated physical map of this region of DNA from fragment f17 through to the IS3 insertion sequence near the promoter-distal end of f2.     

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.     

Complete nucleotide sequences of 84.5- and 3.2-kb plasmids in the multi-antibiotic resistant Salmonella enterica serovar Typhimurium U302 strain G8430

The multi-antibiotic resistant (MR) Salmonella enterica serovar Typhimurium phage type U302 strain G8430 exhibits the penta-resistant ACSSuT-phenotype (ampicillin, chloramphenicol, streptomycin, sulfonamides and tetracycline), and is also resistant to carbenicillin, erythromycin, kanamycin, and gentamicin. Two plasmids, 3.2- and 84.5-kb in size, carrying antibiotic resistance genes were isolated from this strain, and the nucleotide sequences were determined and analyzed. The 3.2-kb plasmid, pU302S, belongs to the ColE1 family and carries the aph(3')-I gene (Kan(R)). The 84.5-kb plasmid, pU302L, is an F-like plasmid and contains 14 complete IS elements and multiple resistance genes including aac3, aph(3')-I, sulII, tetA/R, strA/B, bla(TEM-1), mph, and the mer operon. Sequence analyses of pU302L revealed extensive homology to various plasmids or transposons, including F, R100, pHCM1, pO157, and pCTX-M3 plasmids and TnSF1 transposon, in regions involved in plasmid replication/maintenance functions and/or in antibiotic resistance gene clusters. Though similar to the conjugative plasmids F and R100 in the plasmid replication regions, pU302L does not contain oriT and the tra genes necessary for conjugal transfer. This mosaic pattern of sequence similarities suggests that pU302L acquired the resistance genes from a variety of enteric bacteria and underscores the importance of a further understanding of horizontal gene transfer among the enteric bacteria.     

pGLO mutagenesis: a laboratory procedure in molecular biology for biology students

A five-session laboratory project was designed to familiarize or increase the laboratory proficiency of biology students and others with techniques and instruments commonly used in molecular biology research laboratories and industries. In this project, the EZ-Tn5 transposon is used to generate and screen a large number of cells transformed with mutagenized pGLO plasmid. EZ-Tn5 carries the kanamycin resistance (Kan(R)) gene, and the pGLO plasmid carries the β-lactamase gene for ampicillin resistance (Amp(R)), the gene encoding green fluorescent protein (GFP) and the arabinose operon repressor (araC). Insertion of the Tn5 transposon into pGLO occurs randomly, and any gene into which it inserts is knocked out. By screening cells transformed with mutagenized pGLO with kanamycin, ampicillin, arabinose and/or for GFP expression in different combinations, pGLO plasmids with mutations in different genes are identified. The locations of these insertions are then mapped approximately by restriction fragment analysis and precisely by sequence analysis of the pGLO plasmid.     

Insertions of the Transposon Tn1 into the PSEUDOMONAS AERUGINOSA Chromosome

The transposon Tn1 has been translocated to the chromosome of Pseudomonas aeruginosa from plasmid R18, following hydroxylamine mutagenesis of the plasmid. Twelve insertions were mapped to six distinct sites distal to 55 min of the origin of chromosome transfer by the plasmid FP2. These map locations were confirmed by host chromosome mobilization tests mediated by plasmids R18 or R91-5, due to Tn1 homology between plasmid and host chromosome. All the Tn1 chromosomal inserts were retransposable to other plasmids (Sa, R931 and R38). The behavior of Tn1 in P. aeruginosa was very similar to its behavior in Escherichia coli with respect to regional specificity, orientation of insertion and in serving as regions of homology for host chromosome mobilization by plasmids. This last property has permitted the demonstration that Tn1 on R18 and R91-5 is in opposite orientation with respect to the origin of transfer (oriT) of the two plasmids.     

Nucleotide sequence and characterization of the trbABC region of the IncI1 Plasmid R64: existence of the pnd gene for plasmid maintenance within the transfer region.

A 6.72-kb DNA sequence between the exc gene and the oriT operon within the transfer region of IncI1 plasmid R64 was sequenced and characterized. Three novel transfer genes, trbA, trbB, and trbC, were found in this region, along with the pnd gene responsible for plasmid maintenance. The trbABC genes appear to be organized into an operon located adjacent to the oriT operon in the opposite orientation. The trbA and trbC genes were shown to be indispensable for R64 plasmid transfer, while residual transfer activity was detected in the case of R64 derivatives carrying the trbB++ deletion mutation. The T7 RNA polymerase-promoter system revealed that the trbB gene produced a 43-kDa protein and the trbC gene produced an 85-kDa protein. The nucleotide sequence of the pnd gene is nearly identical to that of plasmid R483, indicating a function in plasmid maintenance. The plasmid stability test indicated that the mini-R64 derivatives with the pnd gene are more stably maintained in Escherichia coli cells under nonselective conditions than the mini-R64 derivatives without the pnd gene. It was also shown that the R64 transfer system itself is involved in plasmid stability to a certain degree. Deletion of the pnd gene from the tra+ mini-R64 derivative did not affect transfer frequency. DNA segments between the exc and trbA genes for IncI1 plasmids R64, Colb-P9, and R144 were compared in terms of their physical and genetic organization.     

Comparative analysis of the structure of incompatibility plasmids N, P and W

Evolutionary relationships of the IncN plasmid R15 and other broad host range plasmids (IncN plasmids N3 and R46, IncP plasmids RP4 and R906, IncW plasmids Sa and R388) were studied by Southern blot hybridization technique. The IncN plasmids were shown to harbour homologous determinants for replication and conjugation. No homology was found between the rep and tra genes in R15 and in the IncW and IncP plasmids, respectively. The second rep region of the N3 plasmid is distinctive from the corresponding determinants in the IncN plasmids. Homology was demonstrated for the plasmid genes that mediate restriction and modification in R15 and N3, mercury resistance in R15 and R906, sulfanilamide resistance in R15, N3, R46, Sa, R388, and R906, streptomycin resistance in R15, R46 and Sa. The latter genes are different from the R906 SmR gene. In addition to the three known mobile elements in the plasmid R15, the fourth one (IS46) that is a part of the transposon Tn2353 was identified in this study. Besides, the third copy of this insertion sequence was found in the N3 plasmid.     

A simple method for shortening a plasmid genome using a system of plasmid cointegration mediated by a Tn3 mutant

This paper describes a simple method for the isolation of small plasmids of various sizes from pSMI, a derivative of the resistance plasmid R 100. The method is based on the observation that a repressor-negative mutant of the ampicillin-resistance (amp^r) transposon Tn3, Tn3 No. 5, mediates cointegration of a plasmid carrying Tn 3 No. 5 (pMB8::Tn 3 No. 5) into virtually any site on pSMI. The resulting cointegrate plasmids contain the pSMI sequence which is joined with the amp^r gene of the Tn 3 mutant. This cointegration is so frequent that large cointegrate plasmids can be readily detected in the total plasmid DNA prepared from cells carrying pSMI and pMB8::Tn3 No. 5. We were able to isolate small plasmids of various sizes by digesting the total plasmid DNAs with restriction endonucleases which cut both pSM 1 and Tn3 No. 5 sequences present in the cointegrates and subsequently ligating the restriction fragment containing both the amp^r gene and the region necessary for replication of pSMI. Analysis of these plasmids, named pBV plasmids, with restriction endonucleases and by nucleotide sequencing allowed us to determine regions necessary or unnecessary for replication, thus defining a minimal replication region of pSMI. The present method is generally useful for the isolation of small derivatives from any large plasmid for the study of genes and sites adjacent to or within the minimal replication region of the plasmid.     

Analysis of plasmid genome evolution based on nucleotide-sequence comparison of two related plasmids of Escherichia coli

Plasmid Rsc13, a small derivative of the plasmid R1, contains a region necessary for replication as well as a complete copy (4957 bp) of the ampicillin resistance transposon, Tn3. We determined the nucleotide sequence of the replication region of Rsc13 to be 2937 bp and then compared this region (designated the 2.9-kb region) to the analogous region of pSM1, a small derivative of the plasmid R100 which has common ancestry with R1. Rsc13 and pSM1 were 96% homologous in this 2.9-kb region except for a discrete region of about 250 bp which showed only 44% homology. The sequence and distribution of nucleotide substitutions between Rsc13 and pSM1 supported a map of possible genes and sites which have previously been seen in the replication region of Rsc13 and pSM1 which showed only 44% homology. Analysis of the amino acid sequence and predicted conformation of the two RepA2 polypeptides, however, suggested that they were very similar. We proposed that the repA2 region of R1 and R100 was replaced by a substitution of a short DNA segment from another plasmid which was evolutionarily related to R1 and R100 but had more divergence. This event may have been mediated by a mechanism similar to that of gene conversion as described in eukaryotic systems.     

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.     

Revised genetic map of the distal end of the F transfer operon: implications for DNA helicase I, nicking at oriT, and conjugal DNA transport.

The DNA transfer stage of conjugation requires the products of the F sex factor genes traMYDIZ and the cis-acting site oriT. Previous interpretation of genetic and protein analyses suggested that traD, traI, and traZ mapped as contiguous genes at the distal end of the transfer operon and saturated this portion of the F transfer region (which ends with an IS3 element). Using antibodies prepared against the purified TraD and TraI proteins, we analyzed the products encoded by a collection of chimeric plasmids constructed with various segments of traDIZ DNA. We found the traI gene to be located 1 kilobase to the right of the position suggested on previous maps. This creates an unsaturated space between traD and traI where unidentified tra genes may be located and leaves insufficient space between traI and IS3 for coding the 94-kilodalton protein previously thought to be the product of traZ. We found that the 94-kilodalton protein arose from a translational restart and corresponds to the carboxy terminus of traI; we named it TraI*. The precise physical location of the traZ gene and the identity of its product are unknown. The oriT nicking activity known as TraZ may stem from unassigned regions between traD and traI and between traI and IS3, but a more interesting possibility is that it is actually a function of traI. On our revised map, the position of a previously detected RNA polymerase-binding site corresponds to a site at the amino terminus of traI rather than a location 1 kilobase into the coding region of the gene. Furthermore, the physical and genetic comparison of the F traD and traI genes with those of the closely related F-like conjugative plasmids R1 and R100 is greatly simplified. The translational organization we found for traI, together with its identity as the structural gene for DNA helicase I, suggests a possible functional link to several other genes from which translational restart polypeptides are expressed. These include the primases of the conjugative plasmids ColI and R16, the primase-helicase of bacteriophage T7, and the cisA product (nickase) of phage phi X174.     

Nah-genes of Pseudomonas putida: molecular genetic analysis of the plasmid pBS286

The hybridization and restriction analysis of the plasmid pBS286 (73 Kb, the P-9 Inc group) as well as parental plasmids NPL-1, NPL-41 demonstrated that pBS286 plasmid (delta NPL-41::TnA) with the constitutive synthesis of naphthalene dioxygenase carried genes for naphthalene oxidation to salicylate and those participating in degradation of catechol. Restriction map of pBS286 using XhoI restriction endonuclease and that of the nah region using EcoRI, BamHI, SalI and XhoI were established. Structural peculiarities of nah genes from pBS286 are compared with previously described NAH7. Some nah genes were localized. An inverted DNA segment involved in nah gene regulation was shown to be closely linked to a proximal part of the nah1 operon or overlapped. Possible occurrence of a regulatory R locus in this region is suggested.     

Characterization of the gene products produced in minicells by pSM1, a derivative of R100

Summary At least ten polypeptides larger than 6 kilodaltons (K) are produced in minicells from the miniplasmid pSM1 in vivo. pSM1 (5804 bp) is a small derivative of the drug resistance plasmid R100 (ca. 90 kb) and carries the R100 essential replication region as well as some non-essential functions. Cloned restriction fragments of pSM1 and plasmids with deletions within pSM1 sequences were used to assign eight of the ten oberserved polypeptides to specific coding regions of pSM1. Two of these polypeptides were identified as RepA1 and RepA2, proteins encoded by the essential replication region of pSM1/R100. The nucleotide sequence consisting of 885 bp outside the essential replication region is presented here. This sequence contains an open reading frame,orf4, for a protein 22.9 K in size, and one of the pSM1-encoded polypeptides was identified as theorf4 gene product. Five additional polypeptides were shown to be the products of other open reading frames mapping outside the essential replication region. Specific functions have been assigned to four of these polypeptides and tentatively to the fifth.