Site-specific mutagenesis of the Ti plasmid by transformation of Agrobacterium tumefaciens with mutagenized T-DNA fragments cloned in E. coli plasmids

Summary A DNA fragment covering the complete T-region of the Ti plasmid from Agrobacterium tumefaciens strain C58 was cloned in the Escherichia coli cosmid pHC79. This fragment was mutagenized by insertion of transposon Tn5. The isolated DNA from hybrid plasmids was used to transform cells of A. tumefaciens strain C58 applying the freeze-thaw method. Although the E. coli plasmids with the mutagenized Ti plasmid fragment cannot replicate in these cells, they can be rescued by recombination with the homologous region of the Ti plasmid. The cointegrates formed were resolved in a second recobination event, which was detected by loss of the drug resistance marker of the E. coli plasmid. Subcloning of the Ti plasmid fragments labeled with Tn5 showed that the frequency of rescue of the hybrid plasmid as a cointegrate and its segregation in agrobacteria depend on the degree of homology with the Ti plasmid. We also applied the strategy for site-directed Tn5 mutagenesis to insert specifically the replication origin of bacteriophage fd and the thymidine kinase gene from Herpes virus into the T-DNA of Ti plasmid-C58.     

Structure and function of the F plasmid genes essential for partitioning

The F plasmid in Escherichia coli has its own partition mechanism controlled by the sopA and sopB genes, and by the cis-acting sopC region. The DNA sequence of the entire partition region and its flanking regions is described here. Two large open reading frames coding for 43,700 Mr and 35,400 Mr proteins correspond to sopA and sopB, respectively. The sopB reading frame is located immediately downstream from the sopA reading frame. Twelve 43 base-pair direct repeats exist in the sopC region without any spacer regions, and one pair of seven base-pair inverted repeats exists in each of the direct repeats. Analysis of deletions in the sopC region showed that the direct repeats play an important role in plasmid partition and IncD incompatibility. IncG incompatibility is exhibited by pBR322 derivatives carrying the sopB gene alone. When compared with the partition genes parA and parB of plasmid P1, homology in amino acid sequence was found between the SopA protein of F and the ParA protein of P1, and also between SopB protein of F and ParB protein of P1. In addition, homology was found between Rep proteins of F and P1.     

Partition of the linear plasmid N15: interactions of N15 partition functions with the sop locus of the F plasmid

A locus close to one end of the linear N15 prophage closely resembles the sop operon which governs partition of the F plasmid; the promoter region contains similar operator sites, and the two putative gene products have extensive amino acid identity with the SopA and -B proteins of F. Our aim was to ascertain whether the N15 sop homologue functions in partition, to identify the centromere site, and to examine possible interchangeability of function with the F Sop system. When expressed at a moderate level, N15 SopA and -B proteins partly stabilize mini-F which lacks its own sop operon but retains the sopC centromere. The stabilization does not depend on increased copy number. Likewise, an N15 mutant with most of its sop operon deleted is partly stabilized by F Sop proteins and fully stabilized by its own. Four inverted repeat sequences similar to those of sopC were located in N15. They are distant from the sop operon and from each other. Two of these were shown to stabilize a mini-F sop deletion mutant when N15 Sop proteins were provided. Provision of the SopA homologue to plasmids with a sopA deletion resulted in further destabilization of the plasmid. The N15 Sop proteins exert effective, but incomplete, repression at the F sop promoter. We conclude that the N15 sop locus determines stable inheritance of the prophage by using dispersed centromere sites. The SopB-centromere and SopA-operator interactions show partial functional overlap between N15 and F. SopA of each plasmid appears to interact with SopB of the other, but in a way that is detrimental to plasmid maintenance.     

Abnormal Reaction Product from Condensation of Phloroaceto-phenone Dimethylether with p-Methoxybenzaldehyde

We identified and analyzed a DNA region that is required for the stable maintenance of plasmids in the genus Sphingomonas. This DNA fragment, a 244?bp, is localized in the upstream region of the repA gene of low-copy-number small plasmid pYAN-1 (4896?bp) of Sphingobium yanoikuyae. It has four inverted repeats and one direct repeat for possible secondary structures. We were able to stabilize not only another unstable plasmid, pYAN-2, in the genus Sphingomonas, but also the unstable plasmid pSC101 without par locus in Escherichia coli. The copy-number levels between the unstable plasmid and the parental plasmid were similar, and these results suggest that the stabilization of unstable plasmids by this DNA region of pYAN-1 was not due to an increase in plasmid copy number. We concluded that the stabilization of the plasmid was due to a plasmid partition mechanism encoded by a DNA fragment of pYAN-1.     

A TnphoA insertion within the Bradyrhizobium japonicum sipS gene, homologous to prokaryotic signal peptidases, results in extensive changes in the expression of PBM-specific nodulins of infected soybean (Glycine max) cells

Bradyrhizobium japonicum mutant 132 was obtained by random TnphoA mutagenesis of strain 110spc4. A 6.5 kb BamHI kanamycin-resistance-coding DNA fragment of mutant 132 was used as a hybridization probe to clone the corresponding wild-type fragment. DNA sequence analysis of a 3213 bp BamHI—ClaI fragment revealed that three open reading frames (ORFs) were encoded in the same orientation. Based on sequence similarities to other proteins in the database, the second ORF was called sipS (signal peptidase). The TnphoA insertion in mutant 132 was found to be in frame near the 3′ end of sipS. The resulting SipS—PhoA hybrid polypeptide was shown to be expressed in free-living B. japonicum and in Escherichia coli cultures. An immunoblot analysis with a polyclonal antibody directed against the alkaline phosphatase revealed the appearance of a weak signal of a 70 kDa polypeptide both in B. Japonicum and in E. coli, in agreement with the calculated size of the hybrid polypeptide. A much stronger 52 kDa band was also detected. Mutant 132 was specifically disturbed in the interaction with soybean (Glycine max) when the bacteria were released from the infection threads. The bacteroids were not stably maintained within the symbiosome. Numerous vesicles were found in the plant cytosol, which finally resulted in the formation of large vacuoles within the infected nodule cells. Immunohistochemical analyses with antibodies directed against nodulins of the peribacteroid membrane indicated a lower expression of these proteins. The mutant phenotype was genetically complemented by 4.4 kb BamHI fragment including sipS. Subfragments thereof also complemented a temperature-sensitive E. coli lepB mutant, demonstrating that the B. japonicum fragment was functionally replacing Lep^ts in E. coli. Genetic studies suggested that the three genes are organized in one common operon which is expressed from a promoter upstream of the sequenced region. Inactivation of the gene downstream of sipS did not result in a detectable phenotype.     

Polymerization of SopA partition ATPase: regulation by DNA binding and SopB

In bacteria, mitotic stability of plasmids and many chromosomes depends on replicon-specific systems which comprise a centromere, a centromere-binding protein and an ATPase. Dynamic self-assembly of the ATPase appears to enable active partition of replicon copies into cell-halves, but for most ATPases (the Walker-box type) the mechanism is unknown. Also unknown is how the host cell contributes to partition. We have examined the effects of non-sequence-specific DNA on in vitro self-assembly of the SopA partition ATPase of plasmid F. SopA underwent polymerization provided ATP was present. DNA inhibited this polymerization and caused breakdown of pre-formed polymers. Centromere-binding protein SopB counteracted DNA-mediated inhibition by itself binding to and masking the DNA, as well as by stimulating polymerization directly. The results suggest that in vivo, SopB smothers DNA by spreading from sopC, allowing SopA-ATP polymerization which initiates plasmid displacement. We propose that SopB and nucleoid DNA regulate SopA polymerization and hence partition.     

The F factor of Escherichia coli carries a locus of stable plasmid inheritance stm, similar to the parB locus of plasmid RI

Summary We found that a 1.4 kb fragment of the F factor of Escherichia coli (coordinates 62.8–64.2) considerably increased the stable inheritance of different plasmids which carried it. The fragment has a 589 bp DNA sequence (coordinates 63.3–63.9) with extensive homology to the parB locus of plasmid RI and, probably like the parB region, ensures the presence of plasmids in bacterial populations by killing those cells which have lost the plasmid.     

F plasmid partition depends on interaction of SopA with non-specific DNA

Bacterial ATPases belonging to the ParA family assure partition of their replicons by forming dynamic assemblies which move replicon copies into the new cell-halves. The mechanism underlying partition is not understood for the Walker-box ATPase class, which includes most plasmid and all chromosomal ParAs. The ATPases studied both polymerize and interact with non-specific DNA in an ATP-dependent manner. Previous work showed that in vitro, polymerization of one such ATPase, SopA of plasmid F, is inhibited by DNA, suggesting that interaction of SopA with the host nucleoid could regulate partition. In an attempt to identify amino acids in SopA that are needed for interaction with non-specific DNA, we have found that mutation of codon 340 (lysine to alanine) reduces ATP-dependent DNA binding > 100-fold and correspondingly diminishes SopA activities that depend on it: inhibition of polymer formation and persistence, stimulation of basal-level ATP hydrolysis and localization over the nucleoid. The K340A mutant retained all other SopA properties tested except plasmid stabilization; substitution of the mutant SopA for wild-type nearly abolished mini-F partition. The behaviour of this mutant indicates a causal link between interaction with the cell's non-specific DNA and promotion of the dynamic behaviour that ensures F plasmid partition.     

Identification of functional regions of the colicinogenic plasmid ColA

Summary ColA is a colicinogenic plasmid of 6.72 kb. It is compatible with ColE1 but not with ColK. Transposon insertion mutagenesis as well as complementation studies have been carried out to investigate the location of the various functional regions of this plasmid. Four independent ColA::Tn1 and one ColA::Tn3 plasmids were isolated and the locations of insertions were determined. From these plasmids, six different deletion mutants were constructed. In addition, various restriction fragments of ColA have been cloned into pUC8 to carry out complementation studies. We have thus confirmed the location of the DNA regions involved in colicin production, colicin release and immunity function. The DNA region involved in conjugal mobility promoted by R64 drd11 has been identified and we have demonstrated that the ColE1 mobility proteins can act in trans on the bom (basis of mobility) site of ColA. The location of this site, as well as the region involved in stable maintenance of ColA, have also been determined. These results are discussed with regard to the homology in nucleotide sequence between ColA and ColE1.     

A cluster of fourteen genes from enteropathogenic Escherichia coli is sufficient for the biogenesis of a type IV pilus

Enteropathogenic Escherichia coli (EPEC) adhere to epithelial cells in microcolonies, a pattern termed localized adherence (LA). LA is dependent upon the presence of 50–70MDa plasmids, termed EPEC adherence factor (EAF) plasmids. Expression of an EAF plasm id-encoded type IV fimbria, the bundle-forming pilus (BFP), is associated with the LA phenotype. TnphoA insertions in bfpA, the gene encoding the major structural subunit of the BFP, abolish LA. While bfpA::TnphoA mutants cannot be complemented for LA by plasmids carrying the bfpA gene alone in trans, this work shows that they can be complemented by plasmids carrying the bfpA gene, as well as approximately 10kb of downstream sequence, suggesting that such mutations have polar effects on downstream genes. The identification and characterization of a cluster of 13 genes immediately downstream of bfpA are described. The introduction into a laboratory Escherichia coli strain of a plasmid containing these 14 bfp gene cluster genes, along with pJPN14, a plasmid containing another fragment derived from the EAF plasmid, confers LA ability and BFP biogenesis. However, when a mutation is introduced into the last gene of the bfp cluster, neither LA nor BFP biogenesis is conferred. This work also provides evidence to show that the fragment cloned in pJPN14 encodes a factor(s) which results in increased levels of the pilin protein. Finally, it is shown that expression of the 14 genes in the bfp cluster from an IPTG-inducible promoter, in the absence of pJPN14, is sufficient to reconstitute BFP biogenesis in a laboratory E. cob strain, but is insufficient for LA. This is the first report demonstrating the reconstitution of a type IV pilus in a laboratory E. coli strain with a defined set of genes. The 8FP system should prove to be a useful model for studying the molecular mechanisms of type IV pilus biogenesis.     

Subcellular positioning of F plasmid mediated by dynamic localization of SopA and SopB

SopA, SopB proteins and the cis-acting sopC DNA region of F plasmid are essential for partitioning of the plasmid, ensuring proper subcellular positioning of the plasmid DNA molecules. We have analyzed by immunofluorescence microscopy the subcellular localization of SopA and SopB. The majority of SopB molecules formed foci, which localized frequently with F plasmid DNA molecules. The foci increased in number in proportion to the cell length. Interestingly, beside the foci formation, SopB formed a spiral structure that was dependent on SopA, which also formed a spiral structure, independent of the presence of SopB, and these two structures partially overlapped. On the basis of these results and previous biochemical studies together with our simulations, we propose a theoretical model named "the reaction-diffusion partitioning model", using reaction-diffusion equations that explain the dynamic subcellular localization of SopA and SopB proteins and the subcellular positioning of F plasmid. We hypothesized that sister copies of plasmid DNA compete with each other for sites at which SopB multimer is at the optimum concentration. The plasmid incompatibility mediated by the Sop system might be explained clearly by this hypothesis.     

Identification of a centromeric activity in the autonomously replicating TRA region allows improvement of the host-vector system for Candida maltosa

A centromeric activity was identified in the previously isolated 3.8 kb DNA fragment that carries an autonomously replicating sequence (ARS) from the yeast Candida maltosa. Plasmids bearing duplicated copies of the centromeric DNA (dicentric plasmids) were physically unstable and structural rearrangements of the dicentric plasmids occurred frequently in the transformed cells. The centromeric DNA activity was dissociated from the ARS, which is 0.2 kb in size, and was delimited to a fragment at least 325 by in length. The centromeric DNA region included the consensus sequences of CDEI (centromeric DNA element I) and an AT-rich CDEII-like region of Saccharomyces cerevisiae but had no homology to the functionally critical CDEIII consensus. A plasmid bearing the whole 3.8 kb fragment was present in 1–2 copies per cell and was maintained stably even under non-selective culture conditions, while a plasmid having only the 0.2 kb ARS was unstable and accumulated to high copy numbers. The high-copy-number plasmid allowed us to overexpress a gene to a high level, which had never been attained before, under the control of both constitutive and inducible promoters in C. maltosa.     

The large plasmids found in enterohemorrhagic and enteropathogenic Escherichia coli constitute a related series of transfer-defective Inc F-IIA replicons

Forty-six of 52 (88.5%) enterohemorrhagic Escherichia coli (EHEC) strains screened carried a “common” plasmid of about 90 kb which encoded sequences homologous to the Inc F-IIA replicon. A similarly high incidence of Inc F-IIA plasmid-containing strains was observed in other groups of diarrheagenic E. coli, but not in random environmental coliform isolates. Enteropathogenic E. coli (EPEC) contain plasmids of similar properties and share a 23-kb DNA fragment with plasmids from EHEC. The common region encodes the F-IIA replication region and sequences homologous to the transfer operon of the Inc F-II plasmid R1. Sequence homology varied between plasmids isolated from different EHEC/EPEC strains with >80% showing homology to the regions encoding the rep and par genes. Only 5% of plasmids from EHEC strains had intact sequences homologous to the DNA between these two regions, including the oriT site. Some plasmids with an apparently intact tra operon still failed to plaque F-pilus-specific phages. This is consistent with observations that the large plasmids of EHEC and EPEC are phenotypically nonconjugative. These results suggest that the large plasmids of EHEC/EPEC constitute a family of transfer-deficient Inc F-IIA plasmids with varying degrees of deletion in tra function. The evolutionary ramifications of this finding are considered.     

R46 encodes a site-specific recombination system interchangeable with the resolution function of TnA

Transposition of TnA onto the IncN plasmid R46 generates unstable DNA molecules. The R46::TnA recombinant plasmids undergo further DNA rearrangements which depend on the orientation in which the TnA element is inserted into the plasmid, and deletions and inversions of R46 and TnA sequences have been observed. Both types of rearrangement have the same specific endpoints, one within TnA and one located between the R46 coordinates, 36.0 and 37.0. The results are consistent with the operation of arecA-independent, site-specific recombination system utilizing, at least in part, the transposon cointegrate resolution system of TnA, together with R46-encoded functions. Data are presented that indicate that R46 encodes analogs of both theres site of TnA and itstnpR gene, although little homology between this element and the plasmid is apparent. Models for the TnA-induced generation of site-specific deletions and inversions upon transposition of TnA to R46 are presented.     

Transposon Tn21 encodes a RecA-independent site-specific integration system

Summary The IncW plasmid R388 and the DNA region of Tn21 containing the Sm^r and the Su^r genes are capable of RecA-independent recombination. This recombination occurs at a relatively high frequency (up to 10^-4 recombinants per recipient molecule) and results in integration of the two plasmids. No detectable repeats are formed in the process. The crossover points have been confined to a 0.4-kb homologous segment in both plasmids which contains a 59-bp DNA sequence presumably involved in the acquisition of new genes by Tn21 and its relatives (Cameron et al. 1986). It is likely that the recombination occurs precisely at this point. At least one trans-acting function (an integrase) is required for the site-specific recombination. It has been localized to a 1456-bp BstEII-BamHI fragment of Tn21 and can efficiently complement the integration of plasmids containing the integration site.     

Defining the Role of ATP Hydrolysis in Mitotic Segregation of Bacterial Plasmids

Hydrolysis of ATP by partition ATPases, although considered a key step in the segregation mechanism that assures stable inheritance of plasmids, is intrinsically very weak. The cognate centromere-binding protein (CBP), together with DNA, stimulates the ATPase to hydrolyse ATP and to undertake the relocation that incites plasmid movement, apparently confirming the need for hydrolysis in partition. However, ATP-binding alone changes ATPase conformation and properties, making it difficult to rigorously distinguish the substrate and cofactor roles of ATP in vivo. We had shown that mutation of arginines R36 and R42 in the F plasmid CBP, SopB, reduces stimulation of SopA-catalyzed ATP hydrolysis without changing SopA-SopB affinity, suggesting the role of hydrolysis could be analyzed using SopA with normal conformational responses to ATP. Here, we report that strongly reducing SopB-mediated stimulation of ATP hydrolysis results in only slight destabilization of mini-F, although the instability, as well as an increase in mini-F clustering, is proportional to the ATPase deficit. Unexpectedly, the reduced stimulation also increased the frequency of SopA relocation over the nucleoid. The increase was due to drastic shortening of the period spent by SopA at nucleoid ends; average speed of migration per se was unchanged. Reduced ATP hydrolysis was also associated with pronounced deviations in positioning of mini-F, though time-averaged positions changed only modestly. Thus, by specifically targeting SopB-stimulated ATP hydrolysis our study reveals that even at levels of ATPase which reduce the efficiency of splitting clusters and the constancy of plasmid positioning, SopB still activates SopA mobility and plasmid positioning, and sustains near wild type levels of plasmid stability.     

Genetic studies of F plasmid maintenance genes

We have used the mutagenic potential of the ampicillin resistance transposon Tn3 and in vitro deletion techniques to study essential regions for maintenance of mini-F plasmids. Our parental mini-F plasmid contains the 40.3 to 40.8F and 43.1 to 49.3F sequences, a total of 6.7 kilobases (kb). From a spectrum of insertion and deletion mutants, we find only two insertion regions; they map near the 45.8- and 46.4-kb coordinates. In each region the orientation of Tn3 insertion is unique and different from that of the other region. Spontaneous deletions extend from either region in a common direction which is toward the 49.3-kb coordinate. One deletion plasmid, pBK138-2, which arose from a combination of in vitro and spontaneous deletion events, contains just the 44- to 45.8-kb sequences and the ampicillin resistance gene of Tn3. As shown by J. Wechsler and B. C. Kline (1980, Plasmid 4, 276–280), the 45.8- to 46.3-kb sequences specify F sensitivity to the plasmid curing agent, acridine orange. Since sensitivity to acridine orange is a property of normal F maintenance, the 45.8- to 46.35-kb sequences also likely are required for normal plasmid maintenance.     

Refining the Plasmid-Encoded Type IV Secretion System Substrate Repertoire of Coxiella burnetii

The intracellular bacterial agent of Q fever, Coxiella burnetii, translocates effector proteins into its host cell cytosol via a Dot/Icm type IV secretion system (T4SS). The T4SS is essential for parasitophorous vacuole formation, intracellular replication, and inhibition of host cell death, but the effectors mediating these events remain largely undefined. Six Dot/Icm substrate-encoding genes were recently discovered on the C. burnetii cryptic QpH1 plasmid, three of which are conserved among all C. burnetii isolates, suggesting that they are critical for conserved pathogen functions. However, the remaining hypothetical proteins encoded by plasmid genes have not been assessed for their potential as T4SS substrates. In the current study, we further defined the T4SS effector repertoire encoded by the C. burnetii QpH1, QpRS, and QpDG plasmids that were originally isolated from acute-disease, chronic-disease, and severely attenuated isolates, respectively. Hypothetical proteins, including those specific to QpRS or QpDG, were screened for translocation using the well-established Legionella pneumophila T4SS secretion model. In total, six novel plasmid-encoded proteins were translocated into macrophage-like cells by the Dot/Icm T4SS. Four newly identified effectors are encoded by genes present only on the QpDG plasmid from severely attenuated Dugway isolates, suggesting that the presence of specific effectors correlates with decreased virulence. These results further support the idea of a critical role for extrachromosomal elements in C. burnetii pathogenesis.