Incompatibility among alpha-hemolytic plasmids studied after inactivation of the alpha-hemolysin gene by transposition of Tn802.

Five α-hemolytic plasmids were studied with respect to their molecular and genetic properties. Their molecular weights ranged from 48 to 93 Mdal. Digestion with HindIII restriction endonuclease indicated that they were all clearly different plasmids although similarities in their band patterns were observed. Plasmids pSU1, pSU105, and pSU316 produce F-like pili. Incompatibility studies between Hly plasmids were prevented by lack of markers other than α-hemolysin production. In order to overcome this problem, the inactivating properties of the transposable element Tn802 were used. Several Hly plasmids that have lost the ability to produce α-hemolysin were isolated after insertion of the ampicillin transposon Tn802. Incompatibility between the parental plasmids and their Tn802 derivatives suggests that α-hemolytic plasmids have spread over, at least, four incompatibility groups. Plasmids pSU1 and pSU105 were found to be incompatible with Hly-P212, the only representative, so far, of IncFVI. Plasmid pSU316 was incompatible both with ColB-K98 and R124, which suggests the existance of a FIII-FIV incompatibility complex. In addition, pSU5 and pSU233 were compatible with each other and with pSU316, pSU1, pSU105, and Hly-P212. They also produce a different type of pili from this test plasmids.     

Relationship of the replication and incompatibility genes of an IncFVI haemolysin plasmid with other F-like haemolysin plasmids

The replication and incompatibility region of the IncFVI plasmid pSU502 has been isolated by in vitro DNA manipulation as part of a 12.6 kb plasmid, denominated pSU503. Plasmid pSU503 was strongly incompatible with its parental plasmid, pSU1, but was fully compatible with the haemolytic plasmids pSU316 (IncFIII/IV), pHly152 (IncI2) and pSU233 (Inc-pSU233). Furthermore, the 6.9 kb EcoRI fragment of pSU503 which carries the replication and incompatibility determinants of pSU1 did not show any detectable homology (less than 70%) with any of the haemolysin-determining plasmids with which it is compatible. Thus, homologous haemolysin determinants have become linked to apparently unrelated replicons.     

Analysis of IncF plasmids evolution: nucleotide sequence of an IncFIII replication region

We determined the nucleotide sequence of RepFIII, the IncFIII replication region of the plasmid pSU316. Our data confirmed that RepFIII belongs to the RepFIIA family. The comparison of the nucleotide sequences from several RepFIIA-family plasmids revealed that pSU316 and R1 replicons are almost identical (96% similarity). Most of the differences between them are clustered in the incompatibility determinant. Analysis of the rest of the sequence suggested that the divergence between R1 and pSU316 replicons is very recent.     

Incompatibility among α-hemolytic plasmids studied after inactivation of the α-hemolysin gene by transposition of Tn802

Five α-hemolytic plasmids were studied with respect to their molecular and genetic properties. Their molecular weights ranged from 48 to 93 Mdal. Digestion with HindIII restriction endonuclease indicated that they were all clearly different plasmids although similarities in their band patterns were observed. Plasmids pSU1, pSU105, and pSU316 produce F-like pili. Incompatibility studies between Hly plasmids were prevented by lack of markers other than α-hemolysin production. In order to overcome this problem, the inactivating properties of the transposable element Tn802 were used. Several Hly plasmids that have lost the ability to produce α-hemolysin were isolated after insertion of the ampicillin transposon Tn802. Incompatibility between the parental plasmids and their Tn802 derivatives suggests that α-hemolytic plasmids have spread over, at least, four incompatibility groups. Plasmids pSU1 and pSU105 were found to be incompatible with Hly-P212, the only representative, so far, of IncFVI. Plasmid pSU316 was incompatible both with ColB-K98 and R124, which suggests the existance of a FIII-FIV incompatibility complex. In addition, pSU5 and pSU233 were compatible with each other and with pSU316, pSU1, pSU105, and Hly-P212. They also produce a different type of pili from this test plasmids.     

Incompatibility properties of the IncFIII/FIV haemolytic plasmid pSU316 when integrated in the Escherichia coli chromosome

The haemolytic plasmid pSU316 is incompatible with members of the IncFIII and IncFIV incompatibility groups. Plasmid pSU307 (pSU316 hlyC::Tn5) was inserted by integrative suppression into the chromosome of JW112, a temperature-sensitive dnaA mutant of Escherichia coli. The incompatibility properties of this strain (SU51) were studied and it was found that: (1) plasmid pSU306 (pSU316 hlyA::Tn802) was rapidly lost from strain SU51 both at 30 degrees C and 42 degrees C; (2) the IncFIII plasmid pSU397 (ColB-K98::Tn802) was lost from strain SU51 and at 42 degrees C but not at 30 degrees C; and (3) the IncFIV plasmid R124 was stably maintained in strain SU51 at both temperatures. Revertants of pSU307 to the autonomous state could be obtained from SU51. These revertants exerted incompatibility towards the prototype plasmids pSU306, pSU397 and R124 in the same way as pSU307 itself. Thus, strain SU51 provided a suitable method for distinguishing the three different incompatibility determinants of plasmid pSU316.     

Genetics of the replication and maintenance functions of the hemolytic plasmid pSU316. Cloning of an IncFIII determinant

Two miniplasmids have been constructed from pSU306, a Tn802 insertion derivative of the IncFIII-IncFIV hemolytic plasmid pSU316. One of these, pSU3027, is a low copy number plasmid expressing both IncFIII and IncFIV incompatibilities, but is rather unstable, and probably lacks a putative par gene. The other, pSU3025, is maintained in about 340 copies per genome equivalent and expresses only IncFIII incompatibility. Most of the PstI-generated fragments from pSU3027 have been cloned in pBR322. One of the resulting plasmids, pSU3135, contains an insertion of 0.5 kb in the vector molecule, and expresses IncFIII, but not the IncFIV incompatibility. These results allowed us to identify and locate several genes involved in the control of pSU316 replication and stable plasmid maintenance.     

Identification and expression of a copy number control gene in the IncFIII hemolytic plasmid pSU316.

A DNA fragment carrying both the IncFIII determinant and a copy number control gene of the hemolytic plasmid pSU316 has been cloned in pBR322. Deletion derivatives of the hybrid plasmid generated by Bal 31 digestion, which no longer exhibit the IncFIII phenotype, fall into two complementation groups when tested against a pSU316 miniplasmid derivative. Type 1 mutants exhibit the copy number control (Cop+) phenotype whereas type 2 mutants do not. Restriction analysis of type 1 and type 2 mutants allowed us to locate the cop gene of pSU316 in a 700-base-pair fragment adjacent to the IncFIII determinant. Plasmid expression in a minicell system suggests that the product of the cop gene of pSU316 could be a 13,000-dalton protein.     

Isolation and evolutionary analysis of a RepFVIB replicon of the plasmid pSU212

We have isolated at least two different replication regions from pSU401, a Tn802 insertion derivative of the IncFVI plasmid pSU212. One of the replication regions (RepFVIB) is highly homologous to the RepFIIA replicon of IncFII plasmids, and thus belongs to the RepFIIA family. We have also cloned the incompatibility determinant (incFVI) and the copy number control gene (cop) from RepFVIB and determined their nucleotide sequences. The analysis of the sequences supports the idea of a modular evolution of RepFIIA plasmids.     

Molecular characterization of a small Haemophilus influenzae plasmid specifying beta-lactamase and its relationship to R factors from Neisseria gonorrhoeae.

The ampicillin-resistant Haemophilus influenzae strain Ve445 which caused purulent meningitis and septicaemia in a newborn child in Germany contained a 4.4 megadalton (Mdal) plasmid (pVe445) and produced a TEM type beta-lactamase. The transformation to ampicillin resistance of a sensitive Escherichia coli strain with isolated pVe445 DNA proved that the structural gene for the beta-lactamase resided on this plasmid genome. Molecular DNA-DNA hybridization studies and electron microscope DNA heteroduplex analysis indicated that pVe445 probably contained 38 to 41% of the ampicillin translocation DNA segment (TnA) found on R factors of enteric origin. The TnA fragment present in pVe445 most likely does not contain both of the inverted repeat sequences of TnA. DNA-DNA polynucleotide sequence studies indicated that the 4.4 Mdal plasmid pVe445 was unrelated to the 30 to 38 Mdal H. influenzae R plasmids but was closely related to the 4.1 Mdal ampicillin resistance specifying H. influenzae plasmid RSF0885 isolated in the U.S.A. The H. influenzae plasmid pVe445 shared 91% of its base sequences with the beta-lactamase specifying Neisseria gonorrhoeae plasmid pMR0360 (4.4 Mdal) and had 85% of its base sequences in common with the beta-lactamase specifying N. gonorrhoeae plasmid pMR0200 (3.2 Mdal). All of the four 3.2 to 4.4 Mdal beta-lactamase specifying R plasmids of H. influenzae and N. gonorrhoeae investigated probably have a common evolutionary origin.     

Characterization of plasmids from antibiotic-resistant Shigella isolates by agarose gell electrophoresis.

Gel electrophoresis of DNA from 95 clinical isolates of Shigella sonnei and Shigella flexneri resistant to antibiotics revealed a heterogeneous plasmid population. Most of the plasmids were smaller than 6 megadaltons (Mdal). Six S. sonnei isolates with the most common antibiotic resistance pattern were characterized. They had two plasmids in common: one was a self-transmissible Fi+ plasmid of 46 Mdal encoding resistance to streptomycin and sulphafurazole. In addition, several cryptic plasmids ranging in size from 1.0 to 24.5 Mdal were present. Mobilization of the 5.5 Mdal SuSm plasmid and a 1.0 Mdal cryptic plasmid was demonstrated with all six S. sonnei isolates during conjugation. This mobilization was mediated by the 46 Mdal self-transmissible Fi+ R plasmid and also by a 24.5 Mdal Fi- plasmid carrying no known drug resistance determinants.     

Characteristics of Ti plasmids from broad-host-range and ecologically specific biotype 2 and 3 strains of Agrobacterium tumefaciens.

Agrobacterium tumefaciens strains isolated from crown gall tumors on grapevines in California were consistently of the biotype 3 group. All 11 of these strains were limited in their host range and harbored Ti plasmids with molecular masses between 119 and 142 megadaltons (Mdal) as well as a larger cryptic plasmid of greater than 200 Mdal; occasionally a smaller cryptic plasmid of 65 Mdal was also present. Ti plasmids o these strains have DNA sequences in common with Ti plasmids of octopine and nopaline strains belonging to the biotype 1 group and exhibited sequence homologies with the conserved region of the T-DNA. Ten of the 11 strains utilized octopine as a sole source of carbon and nitrogen and 3 strains catabolized both octopine and nopaline, whereas 1 strain catabolized only nopaline. All of these strains were resistant to the bacteriocin agrocin-84, except one grapevine strain that belonged to the biotype 1 group and was agrocin sensitive; it is also differed in its plasmid and virulence characteristics. Isolations from Rubus ursinus ollalieberry galls yielded exclusively biotype 2 strains. These strans were insensitive to agrocin-84, utilized nopaline as a sole carbon and nitrogen source, and were highly virulent on all host plants tested. They contained Ti plasmids ranging between 100 and 130 Mdal and occasionally a cryptic plasmid of 69 Mdal. Their Ti plasmids have DNA sequences in common with Ti plasmids of biotype 1 strains and with the conserved region of the T-DNA.     

Comparison of the Deoxyribonucleic Acid Molecular Weights and Homologies of Plasmids Conferring Linked Resistance to Streptomycin and Sulfonamides

Bacterial strains showing linked resistance to streptomycin (Sm) and sulfonamides (Su) were chosen representing a wide taxonomic and geographical range. Their SmSu resistances were transferred to Escherichia coli K-12 and then plasmid deoxyribonucleic acid (DNA) was isolated by ethidium bromide CsCl centrifugation. The plasmid DNA was examined by electron microscopy and analyzed by sedimentation through 5 to 20% neutral sucrose gradients. Plasmid DNA from strains having transmissible SmSu resistance consisted of two or three molecular species, one of which had a molecular mass of about 5.7 Mdal (10(6) daltons), the others varying between 20 to 60 Mdal. By using transformation or F' mobilization, we isolated the SmSu-resistance determinant from any fellow resident plasmids in each strain and again isolated the plasmid DNA. Cosedimentation of each of these with a differently labeled reference plasmid DNA (R300B) showed 9 out of 12 of the plasmids to have a molecular mass not significantly different from the reference (5.7 Mdal); two others were 6.3 and 9.2 Mdal, but PB165 consisted of three plasmids of 7.4, 14.7, and 21.4 Mdal. Three separate isolations of the SmSu determinant from PB165 gave the same three plasmids, which we conclude may be monomer, dimer, and trimer, respectively. DNA-DNA hybridizations at 75 C demonstrated 80 to 93% homology between reference R300B DNA and each isolated SmSu plasmid DNA, except for the 9.2-Mdal plasmid which had 45% homology and PB165 which had 35%. All the SmSu plasmids were present as multiple copies (about 10) per chromosome. The conjugative plasmid of R300 (present as 1.3 copies per chromosome) has been shown to have negligible effect on the number of copies of its accompanying SmSu plasmid R300B. We conclude that the SmSu plasmids are closely related and probably have a common evolutionary origin.     

Hemolysis determinant common to Escherichia coli hemolytic plasmids of different incompatibility groups

By using cloned deoxyribonucleic acid fragments from the hemolysis determinant of the hemolytic plasmid pHly152 as hybridization probes, a deoxyribonucleic acid segment of about 3.8 megadaltons was identified as a common sequence in several hemolytic (Hly) plasmids of Escherichia coli belonging in four different incompatibility groups. This segment contained the genetic information for the synthesis and secretion of the extracellular toxin alpha-hemolysin of E. coli. With the exception of pSU5, representing a composite plasmid, one part of which seems to be very similar to pHly152, the overall sequence homology of these Hly plasmids with pHly152 seems to be rather restricted. However, the Hly plasmid pSU316 showed sequence homology with pHly152 that did not extend beyond the hemolysis determinant. The two other plasmids, pSU233 and pSU105, also shared homology with pHly152 in the hemolysis determinant as well as in various other parts of this plasmid which did not seem to be directly linked to the hemolysis determinant. This suggests that the hemolysis determinant has spread to presumably unrelated plasmids of E. coli.     

Physical and functional map of the hemolytic plasmid pSU316

A restriction endonuclease analysis of the hemolytic plasmid pSU316 has allowed location of the cleavage sites for the endonucleases BamHI, XbaI, KpnI, BglII, SalGI, EcoRI, and HindIII. Hybridization experiments between pSU316 and pED100 have shown that the tra region of pSU316 lies in a segment comprising part of SalGI fragments S-1 and S-3 and the entire fragment S-4. The positions of other plasmid coded functions, namely the replication functions and α-hemolysin production, have been determined in the physical map.     

Molecular relationships among plasmids of Bacillus thuringiensis: conserved sequences through 11 crystalliferous strains

Summary Screening for the plasmid content of 11 strains belonging to nine different serotypes ofB. thuringiensis was carried out by electron microscope examination and electrophoresis in agarose gels. All the strains contained at least two covalently closed, circular (CCC) DNA species. In one strain (berliner 1715), 17 extrachromosomal elements could be distinguished with regard to their size, ranging from 3.9 to 180 Mdal. Southern hybridisation experiments showed that most of these plasmids fell into two categories (inferior to 15 Mdal and superior to 15 Mdal) which have no homology between them. Within these two size groups there is partial conservation of DNA sequences through various serotypes. Further relationships among the plasmids were investigated by a two dimensional version of the Southern's blotting technique.Possible homology between plasmids and the chromosomal DNA was studied. It was shown that the smaller plasmids from the berliner 1715 and kurstaki HD₁ strains contained no sequence related to chromosomal DNA, whereas among the larger plasmids a few showed homologous sequences.Abbreviations cry^- tacrystalliferous mutant - GCC covalently closed circular DNA - OC open circular DNA - Mdal megadalton - kb 1,000 base pairs     

Essential virulence determinants of different Yersinia species are carried on a common plasmid

Plasmids of 44.4–46 Mdal were identified in conditional virulent Yersinia species. All virulent strains studied are unable to grow on oxalate-containing plates at 37 °C (OX^? phenotype) which is a characteristic property of strains producing the essential virulence VW antigens. The phenotopic transition from OX^? to OX⁺ in these strains is concomitant with loss of virulence and loss of this plasmid. The similarity in size and in the DNA fragmentation patterns, generated by HindIII, of the plasmids isolated from either Y. pseudotuberculosis or two conditional virulent Y. pestis strains, suggests that a common plasmid—pSB2—is carried by these strains. A plasmid of a similar size, ~42 Mdal, and function was recently identified (P. Gemski, J. R. Lazere, and T. Casey, 1980, Infect. Immunity27, 682–685; D. L. Zink, J. C. Feeley, J. G. Wells, C. Vanderzant, J. C. Vickery, W. D. Roof, and G. A. O'Donovan, 1980, Nature (London)283, 224–225) in virulent Y. enterocolitica. We conclude that pSB2 in Y. pseudotuberculosis and Y. pestis and its counterpart in Y. enterocolitica carry genetic information essential for virulence common to the Yersinia species, probably related to VW antigen production. Several additional plasmids were identified in several strains of Y. pestis. One of these plasmids, designated pSB3 (12.5 Mdal), appears to be associated with pesticin production.     

Molecular mechanism of Ti plasmid mobilization by R plasmids: isolation of Ti plasmids with transposon-insertions in Agrobacterium tumefaciens

The mechanism of R plasmid-mediated Ti plasmid mobilization was investigated. The results show that Ti plasmids that have been mobilized by conjugative plasmids frequently—possibly always—carry an insertion sequence or a transposon originating from the mobilizing R plasmid. Based on this and other results a model is put forward for R plasmid-mediated Ti plasmid mobilization. The results reveal generally applicable methods for the discovery of new transposons and for the isolation of transposon-insertion derivatives of large Tra plasmids. One new transposon was already discovered during these studies, viz., a DNA unit of about 11 Mdal coding for Hg^rSm^rSp^r. This transposable element has been named Tn 1831.     

Electron microscope heteroduplex studies of sequence relations among plasmids of Escherichia coli. V. ilv+ Deletion mutants of F14

The structure of a number of F′ilv episomes derived from F14 by bacteriophage P1-mediated transduction have been determined by the electron microscope heteroduplex method. F16, F25, F310 and F312 are all simple deletion mutants of F14. F316 is essentially the same but contains a small insertion (0.8 kilobase) of DNA of unknown origin within the F sequences at 78.6 F. The length of these plasmids are all about the same as that of phage P1 DNA itself. The sequences of F and the sequences of bacterial DNA that are present on the episomes are contiguous on the parental F14. Thus, their structures are consistent with the usual model for the mechanism of P1 transduction. The physical order of ilv genes is also consistent with previous genetic mapping. From this order one can determine the polarity of the Escherichia coli K12 chromosomal sequences on F14 and its F′ilv derivatives relative to the F sequences. This order is consistent with the known counterclockwise transfer order of the parental Hfr AB313. F′ilv episomes carry only one copy of the 2.8 to 8.5 F sequence, which is present as a direct duplication on F14. The F′ilv episomes are genetically stable, whereas F14 is unstable because of reciprocal recombination between the two duplicate sequences. The strain F316/AB2070 is different in several respects. All of the bacteria carry P1 phage DNA. As noted above, F316 itself carries a small insertion. Two transfer-defective deletion mutants, F316Δ(65.4-78.6) and F316Δ-(78.6-0.6) are also present in the population of F316/AB2070 cells. In each case, the deletion borders on one of the junctions of inserted DNA and F14 DNA in F316. Thus, these junctions appear to be hot spots for deletion formation.     

Isolation of large bacterial plasmids and characterization of the P2 incompatibility group plasmids pMG1 and pMG5.

Large plasmids from Agrobacterium tumefaciens, Salmonella typhimurium, Escherichia coli, Pseudomonas putida, and Pseudomonas aeruginosa were routinely and consistently isolated using a procedure which does not require ultracentrifugation but includes steps designed to separate large-plasmid DNA from the bacterial folded chromosome. It also selectively removes fragments of broken chromosome. A variety of large plasmids was readily visualized with agarose gel electorphoresis, including five between 70 and 85 megadaltons (Mdal) in size, six between 90 and 143 Mdal, one that was larger than 200 Mdal, and one that was larger than 300 Mdal. This isolation procedure allowed initial estimation of the molecular sizes of the two IncP2 plasmids, pMG1 and pMG5, which were 312 and 280 Mdal, respectively. A standard curve for size determination by gel electrophoresis including plasmids between 23 and 143 Mdal in size did not extrapolate linearly for plasmids of the 300-Mdal size range. Unique response of different plasmids to the isolation procedure included sensitivity of IncP1 plasmids to high pH and the co-isolation of a 20-Mdal "cryptic" plasmid in conjunction.     

Characterization of plasmids from plant pathogenic pseudomonads

Physical characterization of the resident plasmids from Pseudomonas tabaci, P. angulata, and P. coronafaciens strains indicated that they harbored five different plasmid DNA species. Two ATCC strains of P. tabaci contained indistinguishable plasmids that we have named pJP1 and pJP2. An isolate of one of these strains contained a spontaneous variant of pJP1, pJP1¹, which contains an insertion of 3.9 Mdal. This 3.9-Mdal region did not hybridize to pJP1 indicating that the region was foreign DNA and not a duplication of a segment of DNA already present in pJP1. Another P. tabaci strain, PT27881, contained a third plasmid species, pJP27, which had few similarities to pJP1 or pJP2, but was indistinguishable from the plasmids from all three P. angulata strains. pJP27 and pJP1 had a small region, 8.8 Mdal, of sequence homology. The one strain of P. coronafaciens examined contained a plasmid, pJP50, which was different from the P. tabaci plasmids, but had the 8.8-Mdal region and additional regions of sequence homology with pJP1 and pJP27 as well as homology with a portion of the pJP1¹ insertion. A fourth strain of P. tabaci, PTBR-2, a pathogen on beans, contained plasmid pBW, the only plasmid that lacked detectable regions of homology with the other plasmids.