Identification of a novel membrane-associated gene product that suppresses toxicity of a TrfA peptide from plasmid RK2 and its relationship to the DnaA host initiation protein

The toxicity of a peptide derived from the amino-terminal portion of 33-kDa TrfA, one of the initiation proteins encoded by the broad-host-range plasmid RK2, was suppressed by a host protein related to DnaA, the initiation protein of Escherichia coli. The newly identified 28.4-kDa protein, termed a DnaA paralog (Dp) because it is similar to a region of DnaA but likely has a different function in initiation of plasmid RK2 replication, interacts physically with the 33-kDa TrfA initiation protein, including the initiation-active monomeric form. The Dp has a cellular distribution similar to that of the 33-kDa TrfA initiation protein, being found primarily in the inner membrane fraction, with lesser amounts detected in the outer membrane fraction and almost none in the soluble fraction of E. coli. Maintenance and inner membrane-associated replication of plasmid RK2 were enhanced in a Dp knockout strain and inhibited in strains containing extra copies of the Dp gene or in membrane extracts to which a tagged form of Dp was added. Recently, the Dp was independently shown to help prevent overinitiation in E. coli and was termed Hda (S. Kato and T. Katayama, EMBO J. 20:4253-4262, 2001).     

Isolation of an inner membrane-derived subfraction that supports in vitro replication of a mini-RK2 plasmid in Escherichia coli

Previous results have demonstrated that the inner, but not the outer, membrane fraction of Escherichia coli is the site of membrane-associated DNA replication of plasmid RK2, a broad-host-range plasmid capable of replication in a wide variety of gram-negative hosts (K. Michaels, J. Mei, and W. Firshein, Plasmid 32:19-31, 1994). To resolve the inner membrane replication site further, the procedure of Ishidate et al. (K. Ishidate, E. S. Creeger, J. Zrike, S. Deb, G. Glauner, T. J. MacAlister, and L. I. Rothfield, J. Biol. Chem. 261:428-443, 1986) was used to separate the inner membrane into a number of subfractions, of which only one, a small subfraction containing only 10% of the entire membrane, was found to synthesize DNA inhibited by antibody prepared against the plasmid-encoded initiation protein TrfA. This is the same subfraction that was also found to bind oriV and TrfA to the greatest extent in filter binding assays (J. Mei, S. Benashski, and W. Firshein, J. Bacteriol. 177:6766-6772, 1995).     

Replication of an RK2 miniplasmid derivative in vitro by a DNA/membrane complex extracted from Escherichia coli: involvement of the dnaA but not dnaK host proteins and association of these and plasmid-encoded proteins with the inner membrane

A DNA/membrane complex extracted from a miniplasmid derivative of the broad host range plasmid RK2 cultured in Escherichia coli capable of synthesizing new plasmid supercoiled DNA in vitro was treated with antibodies that were made against or reacted with the dnaA and dnaK host-encoded proteins, respectively. Anti-dnaA protein antibody inhibited total plasmid DNA synthesis significantly and the synthesis of supercoil plasmid DNA almost completely. In contrast, anti-dnaK protein antibody and nonimmune serum had little or no effect on total plasmid DNA synthesis. Both proteins were found to be present in the inner but not outer membrane fraction of E. coli. A variety of miniplasmid-encoded proteins which had previously been found in the DNA/membrane complex have also been localized to the inner but not outer membrane fraction. These include an essential initiation protein of 32 kDa (and an overlapping protein of 43 kDa coded for by the same gene), as well as a 30-kDa protein that may be linked to incompatibility functions. Various extraction methods were used to distinguish between the associated and the integral nature of the plasmid-encoded proteins. The results demonstrated that the essential replication proteins (32 and 43 kDa) as well as the 30-kDa protein was tightly bound to the inner membrane. Computer analysis of the amino acid sequence of the 32 (and 43)-kDa protein revealed a hydrophobic region that is only half that normally required to span the membrane. Other interactions are discussed with respect to attaching this protein to the membrane.     

Identification of a potential membrane-targeting region of the replication initiator protein (TrfA) of broad-host-range plasmid RK2

Plasmid RK2 codes for two species of the replication initiator protein TrfA (33 and 44 kDa). Both polypeptides are strongly associated with membrane fractions of Escherichia coli host cells (W. Firshein and P. Kim, Mol. Microbiol. 23, 1-10, 1997). We investigated the role of a 12-amino-acid hydrophobic region (HR) in the membrane association of TrfA. Epitope-tagged polypeptide fragments of TrfA that contained HR were expressed and found to be associated with membrane fractions. Site-directed mutagenesis of trfA revealed that changes of specific amino acids in HR can affect both TrfA association with the membrane and its ability to support replication of an RK2 oriV plasmid in vivo. These results are consistent with the hypothesis that membrane association of TrfA is functionally relevant and that the HR region of TrfA is involved in membrane association and DNA replication in vivo.     

Roles of long and short replication initiation proteins in the fate of IncP-1 plasmids

Broad-host-range IncP-1 plasmids generally encode two replication initiation proteins, TrfA1 and TrfA2. TrfA2 is produced from an internal translational start site within trfA1. While TrfA1 was previously shown to be essential for replication in Pseudomonas aeruginosa, its role in other bacteria within its broad host range has not been established. To address the role of TrfA1 and TrfA2 in other hosts, efficiency of transformation, plasmid copy number (PCN), and plasmid stability were first compared between a mini-IncP-1β plasmid and its trfA1 frameshift variant in four phylogenetically distant hosts: Escherichia coli, Pseudomonas putida, Sphingobium japonicum, and Cupriavidus necator. TrfA2 was sufficient for replication in these hosts, but the presence of TrfA1 enhanced transformation efficiency and PCN. However, TrfA1 did not contribute to, and even negatively affected, long-term plasmid persistence. When trfA genes were cloned under a constitutive promoter in the chromosomes of the four hosts, strains expressing either both TrfA1 and TrfA2 or TrfA1 alone, again, generally elicited a higher PCN of an IncP1-β replicon than strains expressing TrfA2 alone. When a single species of TrfA was produced at different concentrations in E. coli cells, TrfA1 maintained a 3- to 4-fold higher PCN than TrfA2 at the same TrfA concentrations, indicating that replication mediated by TrfA1 is more efficient than that by TrfA2. These results suggest that the broad-host-range properties of IncP-1 plasmids are essentially conferred by TrfA2 and the intact replication origin alone but that TrfA1 is nonetheless important to efficiently establish plasmid replication upon transfer into a broad range of hosts.     

Components of the RP4 conjugative transfer apparatus form an envelope structure bridging inner and outer membranes of donor cells: implications for related macromolecule transport systems

During bacterial conjugation, the single-stranded DNA molecule is transferred through the cell envelopes of the donor and the recipient cell. A membrane-spanning transfer apparatus encoded by conjugative plasmids has been proposed to facilitate protein and DNA transport. For the IncPalpha plasmid RP4, a thorough sequence analysis of the gene products of the transfer regions Tra1 and Tra2 revealed typical features of mainly inner membrane proteins. We localized essential RP4 transfer functions to Escherichia coli cell fractions by immunological detection with specific polyclonal antisera. Each of the gene products of the RP4 mating pair formation (Mpf) system, specified by the Tra2 core region and by traF of the Tra1 region, was found in the outer membrane fraction with one exception, the TrbB protein, which behaved like a soluble protein. The membrane preparation from Mpf-containing cells had an additional membrane fraction whose density was intermediate between those of the cytoplasmic and outer membranes, suggesting the presence of attachment zones between the two E. coli membranes. The Tra1 region is known to encode the components of the RP4 relaxosome. Several gene products of this transfer region, including the relaxase TraI, were detected in the soluble fraction, but also in the inner membrane fraction. This indicates that the nucleoprotein complex is associated with and/or assembled facing the cytoplasmic site of the E. coli cell envelope. The Tra1 protein TraG was predominantly localized to the cytoplasmic membrane, supporting its potential role as an interface between the RP4 Mpf system and the relaxosome.     

Interactions of the origin of replication (oriV) and initiation proteins (TrfA) of plasmid RK2 with submembrane domains of Escherichia coli.

It has been possible to locate a submembrane domain representing less than 10% of the total membrane that appears to be responsible for sequestering some essential components required for plasmid RK2 DNA replication. This subfraction, whose cellular location in the membrane prior to extraction is still unknown, is derived from the inner membrane fraction, since it possesses enzyme marker activity (NADH oxidase) exclusively associated with the inner membrane. The subfraction was detected by a modification of the methods of Ishidate et al. (K. Ishidate, E. S. Kreeger, J. Zrike, S. Deb, B. Glauner, T. MacAlister, and L. I. Rothfield, J. Biol. Chem. 261:428-443, 1986) in which low pressure in a French pressure cell and lysozyme were used to preserve the supercoil plasmid DNA template during cell disruption. This was followed by successive cycles of sucrose gradient sedimentation and flotation density gradient centrifugation to reveal a number of subfractions, including the one of interest. The characteristics of plasmid interaction with the subfraction include the presence of supercoil DNA after extraction, the binding of the origin of plasmid replication (oriV) in vitro, and the association of the two plasmid-encoded initiation (TrfA) proteins (encoded by overlapping genes). However, another peak, the outer membrane fraction, also binds oriV in vitro, contains plasmid DNA in vivo, and associates with the TrfA initiation proteins. Nevertheless, it contains much less of the initiation proteins, and the specific activity of binding oriV is also much reduced compared with the other subfraction. There is a strong correlation between the association of the TrfA initiation proteins with a particular membrane fraction and the binding of oriV in vitro or plasmid DNA in vivo. Since the proteins are known to bind to repeated sequences in oriV (S. Perri, D. R. Helinski, and A. Toukdarian, J. Biol. Chem. 266:12536-1254, 1991; M. Pinkney, R. Diaz, E. Lanka, and C. M. Thomas, J. Mol. Biol. 203: 927-938, 1988), it appears that the initiation proteins themselves could be responsible, at least in part, for the association of plasmid DNA to the membrane.     

Binding between the par region of plasmids R1 and pSC101 and the outer membrane fraction of the host bacteria

The binding between par+ and par plasmid DNA to different membrane fractions of Escherichia coli was investigated. Membrane material from cells carrying different Par+ and Par- derivatives of plasmids R1 and pSC101 was isolated and fractionated into an outer and a cytoplasmic membrane fraction. The presence of plasmid DNA in the two membrane fractions was measured either by nick-translation of the membrane-bound DNA, followed by filter-hybridization to homologous DNA, or by filter-hybridization of the membrane-bound DNA to nick-translated homologous purified plasmid DNA. The DNA of par derivatives of plasmids R1 and pSC101 could be detected only in the cytoplasmic membrane fraction, whereas the corresponding par+ plasmid DNA also appeared in the outer membrane material, indicating a specific binding between the R1 and pSC101 partition loci and the bacterial outer membrane. The experiment was then modified by fractionation of the membrane material from cells carrying hybrids between the vector pSF2124 and the par region or the basic replicon region of plasmid R1. The DNA of the membrane fractions were filter-hybridized to nick-translated probes. Again, the par+ region caused hybridization to the outer membrane material. Therefore, we may conclude that controlled partitioning involves binding of DNA to membrane material that has the same density as the outer membrane of the host bacteria. This finding offers a biochemical 'assay' for studies of the molecular biology of plasmid partitioning.     

Transfer of chromosomal genes mediated by plasmid r68.45 in Rhodopseudomonas sphaeroides.

Plasmid R68.45 was transferred from Pseudomonas aeruginosa PAO25 to the photosynthetic species Rhodopseudomonas gelatinosa and Rhodopseudomonas sphaeroides by selection for resistance to antibiotics. R. sphaeroides strains carrying the plasmid could transfer the plasmid and also chromosomal genes to other strains of R. sphaeroides.     

Homology of the Gene Coding for Outer Membrane Lipoprotein Within Various Gram-Negative Bacteria

The mRNA for a major outer membrane lipoprotein from Escherichia coli was found to hybridize specifically with one of the EcoRI and one of the HindIII restriction endonuclease-generated fragments of total DNA from nine bacteria in the family Enterobacteriaceae: E. coli, Shigella dysenteriae, Salmonella typhimurium, Citrobacter freundii, Klebsiella aerogenes, Enterobacter aerogenes, Edwardsiella tarda, Serratia marcescens, and Erwinia amylovora. However, among the Enterobacteriaceae, DNA from two species of Proteus (P. mirabilis and P. morganii) did not contain any restriction endonuclease fragments that hybridized with the E. coli lipoprotein mRNA. Furthermore, no hybrid bands were detected in four other gram-negative bacteria outside the family Enterobacteriaceae: Pseudomonas aeruginosa, Acinetobacter sp. HO1-N, Caulobacter crescentus, and Myxococcus xanthus. Envelope fractions from all bacteria in the family Enterobacteriaceae tested above cross-reacted with antiserum against the purified E. coli free-form lipoprotein in the Ouchterlony immunodiffusion test. Both species of Proteus, however, gave considerably weaker precipitation lines, in comparison with the intense lines produced by the other members of the family. All of the above four bacteria outside the family Enterobacteriaceae did not cross-react with anti-E. coli lipoprotein serum. From these results, the rate of evolutionary changes in the lipoprotein gene seems to be closely related to that observed for various soluble enzymes of the Enterobacteriaceae.     

Characterization of the phospholipase C gene of Pseudomonas aeruginosa cloned in Escherichia coli

We have cloned a 4.9-kb fragment of Pseudomonas aeruginosa DNA containing the structural gene of phospholipase C (PLC), by inserting it into the BamHI site of plasmid pBR322. Strains of Escherichia coli carrying this recombinant plasmid produce PLC, but expression of the gene differs from that in P. aeruginosa in two respects: (i) synthesis of the enzyme appears to be constitutive, i.e., not repressible by the presence of inorganic phosphate in the growth medium, and (ii) most of the enzyme remains associated with the outer membrane instead of being secreted. Insertion mutagenesis at a unique restriction site within the PLC gene destroyed the ability of the plasmid to code, in maxicells, for phospholipase C activity and for an Mr 80000 polypeptide.     

The phenotypes of temperature-sensitive mini-RK2 replicons carrying mutations in the replication control gene trfA are suppressed nonspecifically by intragenic cop mutations.

The minimal replicon of the broad-host-range plasmid RK2 consists of the origin of vegetative replication (oriV) and a gene (trfA) encoding an essential replication protein that binds to short repeats in oriV. We report here the results of a DNA sequence analysis of seven unique mutants that are temperature sensitive for replication in Escherichia coli. The mutations (designated rts) were distributed throughout 40% of the downstream part of the trfA gene. Spontaneous revertants of the rts mutants were isolated, and further analysis of four such revertants demonstrated that the new phenotypes resulted from intragenic second-site copy up (cop) mutations. Subcloning experiments showed that all tested intragenic combinations of rts and cop mutations resulted in elimination or strong reduction of the temperature sensitivity of replication. This suppression was also observed under conditions where the mutant TrfA protein was provided in trans with respect to oriV, indicating that the reduction in temperature sensitivity could not be a TrfA protein dosage effect. The phenotypes of two of the cop mutants in Pseudomonas aeruginosa were analyzed; the results demonstrated that the mutants were either not functional or poorly functional in this host. The rts mutant plasmids were also reduced in their ability to replicate in P. aeruginosa, and the intragenic cop mutations did not improve the functionality of these mutants. The significance of the results is discussed in relation to current models of the mechanism of action of the TrfA protein.     

Outer membranes of gram-negative bacteria. XIX. Isolation from Pseudomonas aeruginosa PAO1 and use in reconstitution and definition of the permeability barrier.

A method for separating the outer and inner membranes of Pseudomonas aeruginosa PAO1 in the absence of added ethylenediaminetetraacetic acid was devised. The method yields two outer membrane fractions which show the same protein pattern on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, but differ substantially in their relative contents of phospholipids. One of these outer membrane fractions and the inner membrane fraction are less than 4% cross-contaminated, as judged by the content of typical inner and outer membrane markers. The outer membrane contains four major protein bands with apparent molecular weights of 37,000, 35,000, 21,000 and 17,000. Vesicles reconstituted from lipopolysaccharide and phospholipids were impermeable to all saccharides included in the vesicles during vesicle formation. When the vesicles contained outer membrane proteins, they fully retained only those saccharides of greater than 9,000 molecular weight, suggesting that the exclusion limit of the outer membrane of P. aeruginosa for saccharides is substantially larger than the figure (500 to 600 daltons) obtained for certain enteric bacteria. The advantages and potential disadvantages of having an outer membrane with a higher exclusion limit for hydrophilic substances are discussed.     

Interaction of TonB with the outer membrane receptor FpvA of Pseudomonas aeruginosa

Pyoverdine-mediated iron uptake by the FpvA receptor in the outer membrane of Pseudomonas aeruginosa is dependent on the inner membrane protein TonB1. This energy transducer couples the proton-electrochemical potential of the inner membrane to the transport event. To shed more light upon this process, a recombinant TonB1 protein lacking the N-terminal inner membrane anchor (TonB(pp)) was constructed. This protein was, after expression in Escherichia coli, purified from the soluble fraction of lysed cells by means of an N-terminal hexahistidine or glutathione S-transferase (GST) tag. Purified GST-TonB(pp) was able to capture detergent-solubilized FpvA, regardless of the presence of pyoverdine or pyoverdine-Fe. Targeting of the TonB1 fragment to the periplasm of P. aeruginosa inhibited the transport of ferric pyoverdine by FpvA in vivo, indicating an interference with endogenous TonB1, presumably caused by competition for binding sites at the transporter or by formation of nonfunctional TonB heterodimers. Surface plasmon resonance experiments demonstrated that the FpvA-TonB(pp) interactions have apparent affinities in the micromolar range. The binding of pyoverdine or ferric pyoverdine to FpvA did not modulate this affinity. Apparently, the presence of either iron or pyoverdine is not essential for the formation of the FpvA-TonB complex in vitro.     

Comparison of methods used to separate the inner and outer membranes of cell envelopes of Campylobacter spp

The outer membrane of Campylobacter coli, C. jejuni and C. fetus cell envelopes appeared as three fractions after sucrose gradient centrifugation. Each outer membrane fraction was contaminated with succinate dehydrogenase activity from the cytoplasmic membrane fraction. Similarly the inner membrane fraction was contaminated with 2-ketodeoxyoctonate and outer membrane proteins including the porin(s). The separation of these two membranes was not facilitated by variations in lysozyme treatment, cell age, presence or absence of flagella, or longer lipopolysaccharide chain length. Sodium lauroyl sarcosinate extraction resulted in an outer membrane fraction which contained some inner membrane contamination and produced multiple bands upon sucrose gradient centrifugation. Triton X-100 extraction removed the inner membrane from the outer membrane and Triton X-100/EDTA treatment extracted lipopolysaccharide-rich regions of the outer membrane which contained almost exclusively the Campylobacter porin(s). These data indicated that the inner and outer membranes of the Campylobacter cell envelope were very difficult to separate, possibly because of extensive fusions between these two membranes.     

Peptidase activity in the inner membrane of Pseudomonas aeruginosa

The location of peptidase activity within the cell envelope structure of Pseudomonas aeruginosa has been studied. Inner and outer membrane fractions were separated on the basis of buoyant density using two consecutive sucrose steps gradients and identified on the basis of known components. The inner membrane was shown to contain peptidase activity while the outer membrane contained none. These data support the hypothesis that P. aeruginosa transports intact peptides.     

Evidence for the specific association of the chromosomal origin with outer membrane fractions isolated from Escherichia coli.

DNA-envelope complexes isolated from osmotically lysed spheroplasts of Escherichia coli contained 0.2 to 1% of the total cellular DNA after labeling with [3H]thymidine. Molecular weight determinations indicated that the amount of bound DNA was equivalent in most cases to a maximum of three binding sites per chromosome. Bound DNA from E. coli B/r was distributed approximately equally between inner and outer membrane components when envelopes were fractionated on sucrose equilibrium gradients. Outer membrane-DNA complexes, in particular, fraction H1, with a density of 1.24 g/cm3, were quite stable against shearing and against Sarkosyl NL97. In the case of E. coli B/r, H1-DNA was also relatively resistant to deoxyribonuclease. Inner membrane-DNA complexes, in contrast, were quite labile and readily dissociated to release free DNA. The outer membrane fractions did not appear to contain replication fork DNA, but small amounts may have been present in the inner membrane complexes. A two- to eightfold enrichment for chromosomal origin DNA in the envelope was obtained when cultures of E. coli K-12, synchronized for DNA replication, were pulse labeled at different times in the replication cycle. This enrichment was found invariably in the outer membrane fractions. However, the data do not exclude the possibility that this DNA is bound to regions of adhesion between inner and outer membranes which sediment with a density indistinguishable from that of the outer membrane.     

Translocation of nascent non-signal sequence protein in heated Escherichia coli

Exposure of Escherichia coli to heat resulted in 1) selective inhibition of protein synthesis, 2) synthesis of heat shock proteins, and 3) altered subcellular distribution of newly synthesized proteins. Either 5 min or 1 h at 48 degrees C increases outer membrane proteins of Coomassie Blue-stained gels. After 1 h, there was a loss of stained proteins from the soluble fraction. Much greater changes in the distribution of radiolabeled (newly synthesized) proteins were observed, with marked increases in the number of outer membrane protein species and a corresponding loss of soluble fraction proteins. Three major species of radiolabeled proteins from heat-treated cells remain in the soluble fraction; these proteins have apparent Mr 56,000, 69,200, and 79,400. Cells were labeled with L-[35S] methionine at either 37 or 48 degrees C and chased with non-radiolabeled methionine before a temperature shift to either 48 or 37 degrees C, respectively. Only proteins synthesized at elevated temperature participated in translocation. It is suggested that heat disordering of membrane lipids promotes interlipidic connections between the inner and outer membrane providing pathways for protein movement to the outer membrane and may be the mechanism whereby a cell quickly responds to environmental temperature stress. The response does not require but may trigger synthesis of mRNA.     

Cloning of the protein D2 gene of Pseudomonas aeruginosa and its functional expression in the imipenem-resistant host

Protein D2 forms the water-filled pore across the outer membrane of Pseudomonas aeruginosa and allows the penetration of imipenem. We cloned the protein D2 gene by the antibody screening technique. When the imipenem-resistant mutant lacking protein D2 harbored the plasmid with the cloned D2 gene, the mutant overproduced protein D2 in the outer membrane. These transformants exhibited fully-restored imipenem susceptibility. The results prove unequivocally that protein D2 forms the imipenem-permeable pore in the P. aeruginosa outer membrane.     

Inhibition of DNA synthesis at the hemimethylated pBR322 origin of replication by a cell membrane fraction.

The replication of both ColE1-type plasmids and plasmids bearing the origin of replication of the Escherichia coli chromosome (oriC) has been shown to be inhibited by hemimethylation of adenine residues within GATC sequences. In the case of oriC plasmids, this inhibition was previously shown to be mediated by the specific affinity of the hemimethylated origin DNA for an outer cell membrane fraction. Here, we suggest that a similar mechanism is operating in the case of the ColE1-like plasmid pBR322 as (i) a hemimethylated DNA fragment carrying the promoter for the RNA which primes DNA synthesis (RNAII) is specifically bound by the same membrane fraction and, (ii) the addition of the membrane fraction to a soluble assay of pBR322 replication results in preferential inhibition of initiation on the hemimethylated template. We suggest that membrane sequestration of hemimethylated origin DNA and/or associated replication genes following replication may be a common element restricting DNA replication to precise moments in the cell cycle.