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.     

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.     

Properties and incompatibility behavior of miniplasmids derived from the bireplicon plasmid pCG86

Summary Many plasmids belonging to the F incompatibility groups contain more than one basic replicon. The chimeric plasmid pCG86 is an example of such a multireplicon plasmid. The two basic replicons of pCG86, RepFIIA/FIC and RepFIB have been cloned and re-ligated, the copy numbers of the clones have been determined, and the incompatibility behavior of plasmids containing the ligated replicons and the individual replicons has been studied. The bireplicon plasmids are not expected to be incompatible as recipients with monoreplicon RepFIB or RepFIIA/RepFIC plasmids, since when one replicon is challenged by an incoming replicon, the other should be able to handle the plasmid's replication. In our studies, we found that challenge with either monoreplicon plasmid resulted in incompatibility. This incompatibility was increased in bireplicon plasmids in which RepFIB was duplicated. We conclude that in the bireplicon plasmids, challenging the replication control of one replicon by an incompatible plasmid can interfere with the replication originating from the second replicon.     

The molecular relatedness among alpha-hemolytic plasmids from various incompatibility groups

Deoxyribonucleic acid (DNA) reassociation studies among α-hemolytic (Hly) plasmids from FVI and FIII–IV incompatibility groups showed a close similarity between the nucleotide sequences of plasmids from the same group. With respect to R plasmids from the F overgroup, they have 20–26 Mdal in common, an amount of DNA close to the amount involved in the traF operon. No more extensive sequence homology was found between pSU316 (IncFIII–IV) and the incompatible plasmids ColB-K98 (IncFIII) or R124 (IncFIV). The IncIα I2 plasmid pSU5 has only the α-hemolytic region (5 Mdal) in common with plasmid pSU316 but it is much more closely related to IncFVI plasmids where the DNA in common amounts to 22 Mdal. Finally, the genetically unrelated plasmid pSU233 shares 66% of its nucleotide sequences (40 Mdal) with the IncFVI plasmids and has 16–23 Mdal in common with various F-like plasmids.     

The isolation and characteristics of plasmids derived from the insertion of MupAp1 into pML2: their behavior during transposition

Three independent insertions of the phage Mu variant MupAp1 into the ColE1 derivative pML2 have been isolated. From one of these hybrid plasmids (pSU1), two mini-Mu plasmids have been generated. These have lost internal regions of the Mu genome but retain the ends of the prophage. In pSU17 all but one kilobase pair of the early region and most of the late region have been deleted whereas in pSU123 most of the early region is still present but the deletion covers nearly all the late region. Mu immunity, host killing, and transposition functions are located in the DNA present in pSU123 but absent from pSU17. Transposition of Mu and the mini-Mu from the hybrid plasmids to the sex factor R388 is usually associated with the formation of cointegrates between the two parental plasmids.     

Characterization of the basic replicons of the chimeric R/Ent plasmid pCG86 and the related Ent plasmid P307

Restriction-enzyme fragments that can replicate autonomously after circularization were isolated from the chimeric R/Ent plasmid pCG86 and the Ent plasmid P307. Two such regions containing a basic replicon were located in each plasmid. One of the basic replicons of P307, RepFIB, is almost identical with one of the basic replicons of pCG86. The other basic replicon in P307, RepFIC, is partly homologous with the second basic replicon in pCG86, RepFIIA/RepFIC. The latter is a hybrid basic replicon and is in addition partly homologous with RepFIIA, a basic replicon present in IncFII R plasmids. By restriction-enzyme mapping and nucleotide-sequence analysis we have determined a site in the hybrid replicon where it ceases to be homologous with the RepFIIA basic replicon contained in the IncFII miniplasmid pSM1. The 2410-bp region of homology with pSM1 corresponds with a segment containing the origin of replication and all the genes responsible for replication control of pSM1.     

Nucleotide sequence analysis of RepFIC, a basic replicon present in IncFI plasmids P307 and F, and its relation to the RepA replicon of IncFII plasmids.

RepFIC is a basic replicon of IncFI plasmid P307 which is located within a 3.09-kilobase SmaI fragment. The nucleotide sequence of this region has been determined and shown to be homologous with the RepFIIA replicon of IncFII plasmids. The two replicons share three homologous regions, HRI, HRII, and HRIII, which are flanked by two nonhomologous regions, NHRI and NHRII. A comparison of coding regions reveals that the two replicons have several features in common. RepFIC, like RepFIIA, codes for a repA2 protein with its amino-terminal codons in HRI and its carboxy-terminal codons in NHRI. Although the codons for the repA1 proteins are located in NHRII, the DNA region containing a putative promoter, ribosomal binding site, and initiation codons is located in HRII. This region also codes for an inc RNA. There are nine base-pair differences between the inc RNA of RepFIIA and that of RepFIC, and as a result, RepFIC and RepFIIA replicons are compatible. An EcoRI fragment from the F plasmid which shows homology with RepFIC of P307 has also been sequenced. This fragment contains only a portion of RepFIC, including the genes for the putative repA2 protein and inc RNA. The region coding for a putative repA1 protein is interrupted by the transposon Tn1000 and shows no homology with the repA1 region of RepFIIA and RepFIC of P307. Our comparative and structural analyses suggest that RepFIC and RepFIIA, although different, have a similar replication mechanism and thus can be assigned to the same replicon family, which we designate the RepFIIA family.     

Structural and functional features of cis-acting sequences in the basic replicon of plasmid ColIb-P9.

We have structurally and functionally analyzed the cis-elements essential for ColIb-P9 plasmid DNA replication. The putative oriV region encompassed a region of 172 base pairs (bp) located 152 bp downstream of the repZ gene. A typical dnaA box found in this region proved nonessential for the DNA replication of ColIb-P9. The ssi signal of ColIb-P9 is a homologue of the G-sites of R1 and R100 plasmids. Deletion of the G-site led to 1.5-fold reduction of the copy number, suggesting that although this G-site is not essential, it is important for efficient ColIb-P9 DNA replication. In addition, the ColIb-P9 replicon is highly and extensively homologous with the P307 (RepFIC) replicon, and highly homologous with the R100 (RepFIIA) replicon around the G-site region. These facts imply a common ancestry from which the plasmids have evolved.     

RepFIC, a basic replicon of IncFI plasmids that has homology with a basic replicon of IncFII plasmids

It was found that a DNA segment containing genes for autonomous replication and its control (basic replicon) present in the IncFI plasmid P307 has homology with RepA, a basic replicon present in IncFII plasmids. The basic replicon in P307 is referred to as RepFIC and the homologous basic replicon in IncFII plasmids is referred to as RepFIIA. In 11 other IncFI plasmids studied a region that has homology with RepFIC and RepFIIA was demonstrated. Thus, of the several basic replicons present in IncFI plasmids, RepFIC is evolutionarily related to a basic replicon of IncFII plasmids.     

Identification of the origin of replications and partial characterization of plasmid pRK100

In search for the evolutionary origin of the conjugative F-like plasmid pRK100, the plasmid's functional replication regions were identified. Additionally targeted genetic analysis was used to investigate origins of other regions of the plasmid. Construction of minireplicons via ligation of Tn1725 with plasmid fragments and targeted cloning of putative replication regions, followed by sequence analysis indicated two functional replication regions, a F plasmid related RepFIB and a R1 plasmid related RepFIIA replication region. Partial nucleotide sequencing of regions of the plasmid revealed genes that encode a putative enterochelin iron uptake system previously associated with an Escherichia coli pathogenicity island, PAI III536, and the pColV-like aerobactin genes. In addition, a homologue of the R100 plasmid related rmoA gene was found that exhibits strong similarity to hha/ymoA encoding the Hha/YmoA class of modulators of gene expression. PCR and hybridization experiments further demonstrated that pRK100 harbors multiple IS2 and IS3 insertion sequences that may have facilitated in the acquisition of elements from other DNA molecules. These data together with the previous identification of a F-like tra region and a pColIa-like colicin Ia, indicate that pRK100 has a highly mosaic structure with elements derived from many different known large natural plasmids.     

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.     

New shuttle vectors for Haemophilus influenzae and Escherichia coli: P15A-derived plasmids replicate in H. influenzae Rd

With the aim of identifying new plasmids useful for molecular cloning in Haemophilus influenzae, several P15A-derived plasmids were tested for their ability to transform H. influenzae Rd. The four plasmids tested, pACYC177, pACYC184, pSU2718, and pSU2719 were all able to establish in H. influenzae Rd. The plasmids were stable, could be purified by standard protocols, and were compatible with a plasmid carrying the RSF0885 origin of replication.     

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.     

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.     

New shuttle vectors for Haemophilus influenzae and Escherichia coli: P15A-derived plasmids replicate in H. influenzae Rd

With the aim of identifying new plasmids useful for molecular cloning in Haemophilus influenzae, several P15A-derived plasmids were tested for their ability to transform H. influenzae Rd. The four plasmids tested, pACYC177, pACYC184, pSU2718, and pSU2719 were all able to establish in H. influenzae Rd. The plasmids were stable, could be purified by standard protocols, and were compatible with a plasmid carrying the RSF0885 origin of replication.     

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.     

Location of determinants of stability to neomycin and kanamycin as well as DNA segments, responsible for amplification in Streptomyces plasmids pSU3 and pSU10

The S. rimosus amplifying sequence AUD-Sr1 encodes kanamycin and neomycin resistance, defined in the case of neomycin by aminoglycoside phosphotransferase. Its cloning on plasmid SLP1.2 makes possible the co-amplification of the obtained hybrid plasmids in S. lividans. In our study the regions responsible for resistance to aminoglycoside antibiotics and the capacity for amplification the two hybrid plasmids pSU10 and pSU3 were determined. Experiments on subcloning of the AUD-Sr1 sequence fragments on vector pIJ702 revealed localization of kanamycin and neomycin resistance determinants between PvuII(6) and BglII(7) on the AUD-Sr1 sequence fragments of 2.0 kb length. Two regions responsible for amplification of the hybrid plasmids were detected with deletion and insertion mapping. The first region is localized in the region of the plasmid SLP1.2 BamHI site and the second region is localized on the PstI(4)-PvuII(6) of the AUD-Sr1 sequence fragment of 1.1 kb length.     

Repetitive plasmid sequences generate DNA fingerprinting patterns in mammals

Bacterial plasmids with stringently regulated copy numbers have directly repeated DNA sequences, termed iterons, in the vicinity of their replication origins. These sequences bind a specific protein exerting a key role in the initiation of plasmid replication. Plasmids P1, pSC101 and RFS1010 have different iteron sequences and belong to three different incompatibility groups. Used as DNA probes each of these plasmids generates specific patterns in mammals similar to those obtained by the DNA fingerprinting technique. The iteron-containing regions were identified as the part of the plasmids responsible for those patterns by using polymerase chain reaction (PCR) amplified DNA segments that contained the iteron regions as probes.     

DNA environment of the aerobactin iron uptake system genes in prototypic ColV plasmids.

The aerobactin iron uptake system genes in the prototypic plasmid pColV-K30 are flanked by inverted copies of insertion sequence IS1 and by two distinct replication regions. To address the question of how these flanking regions may facilitate the maintenance and spread of the aerobactin system among the plasmids and chromosomes of enteric species, we investigated the DNA environment of 12 ColV plasmids. We found that the aerobactin system-specific genes are conserved in every plasmid phenotypically positive for the aerobactin system. The upstream IS1 and its overlapping replication region (REPI) are also conserved. This replication region was cloned from several ColV plasmids and found to be functional by transforming these cloned derivatives into a polA bacterial host. In contrast, the downstream flanking region is variable. This includes the downstream copy of IS1 and the downstream replication region (REPII). We infer from these results that sequences in addition to the two flanking copies of IS1, in particular the upstream region including REPI, have been instrumental in the preservation and possible spread of aerobactin genes among ColV plasmids and other members of the FI incompatibility group.     

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.