Chromosomal mutations that increase the production of a plasmid-encoded haemolysin in Escherichia coli

Transposon mutagenesis was used to isolate two Escherichia coli mutants which express very large amounts of haemolysin when carrying the multicopy plasmid pANN202-312. E. coli strain Hha-2 was isolated by Mud1 mutagenesis, and strain Hha-3 by Tn5 mutagenesis. The transposon insertion was chromosomal in both mutants and could be demonstrated to be unrelated to the haemolytic region of the plasmid. The substantial increase in both extracellular and intracellular haemolysin production was dependent upon plasmid copy number and was drastically reduced when either mutant carried the low-copy-number haemolytic plasmid pHly152. In both mutants, the marked increase in extracellular production was dependent upon the specific haemolysin transport genes, hlyB and hlyD. The lack of either gene function resulted in no external haemolysin production. SDS-PAGE analysis showed no change in the pattern of outer-membrane proteins of the mutants, although changes (differing between the two mutants) were seen in their periplasmic proteins. The mutations of both strains (termed hha-2 and hha-3) were mapped at minute 10.5 of the E. coli chromosome. No relation to any known gene affecting gene regulation in E. coli could be found.     

Prevotella intermedia native plasmid can be mobilized by an Escherichia coli conjugal IncP plasmid

We have determined the nucleotide sequence of a small Prevotella intermedia cryptic plasmid, pYHBi1, which consisted of sequences that were highly homologous to the amino acid sequence of the replication and mobilization proteins found in related organisms. We have also demonstrated that chimeric plasmids derived from this P. intermedia native plasmid can be mobilized between Escherichia coli strains by using a broad-host-range E. coli conjugative plasmid, IncP plasmid RP4. The results suggest that pYHBi1 possesses gene(s) responsible for conjugal transfer.     

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.     

Functional structures of the recA protein found by chimera analysis.

We developed a novel genetic method for finding functional regions of a protein by the analysis of chimeras formed between homologous proteins. Sets of chimeric genes were made by intramolecular homologous recombination in a linearized plasmid DNA carrying both recA genes of Escherichia coli and Pseudomonas aeruginosa. A recBCsbcA strain of E. coli was used for isolation of plasmids carrying recombinants between these genes. Examination of properties of E. coli strains deleting the recA gene and carrying a plasmid with a chimeric gene shows that chimera formation at certain positions inactivates a RecA function. Frequently, all chimeras with a junction in a certain region of the protein inactivate a function. Rather than a direct effect of the presence of the junction at a particular position, mismatching of the regions both sides of the junction that are derived from the different species is responsible for the inactivation. For a chimeric protein to be functional, certain pairs of sequences in different regions of the protein must derive from the same parent. Four pairs of such sequences were found: two are involved in activities for genetic recombination and for resistance to ultraviolet light irradiation and the others in formation of active oligomers. Regions defined by these sequences are located in the looped regions of the protein. A pair of regions may co-operate to form a functional folded structure.     

The replication origin region of Escherichia coli: nucleotide sequence and functional units

The minichromosome pCM959 contains the DNA segment from bp -677 (left) to bp + 3335 (right) of the Escherichia coli replication origin, oriC. The nucleotide sequence of this plasmid was determined. The coding regions for proteins were identified, and the possible function of those proteins is discussed. Within oriC two extended systems of dyad symmetry were found, and their possible significance is considered.     

Specific proteolysis by fibrinolysin-coagulase from Yersinia pestis of Yersinia pseudotuberculosis outer membrane proteins coded by the Ca(2+)-dependence plasmid]

The pesticinogenicity 9.5 kb plasmid from Yersinia pestis strain EV76 has been marked by the kanamycin phosphotransferase gene inserted into PstI site and designated pP3. The obtained plasmid pP3 determines the synthesis of 45 kd pesticin, alpha and beta-forms of fibrinolysin coagulase (37 and 35 kd) and the 29, 19 and 13 kd proteins in Escherichia coli mini cells. When transferred into Yersinia pseudotuberculosis strain 6933 the plasmid causes the proteolysis of outer membrane proteins. The 150 kd protein is reduced to 138 kd, the 48.5 kd protein is reduced to 45 kd. The proteins secreted into the cultural medium (51 and 38 kd) are also cleaved. The proteolysis of the 150 kd protein was found to occur at the stage of secretion via the inner membrane. The purified fibrinolysin coagulase from Escherichia coli strain JM83 harbouring the plasmid pP3 induces the proteolysis in vitro of the isolated membrane proteins from Yersinia pseudotuberculosis strain 6953 similar to the proteolysis registered in vivo.     

Identification of a partition region carried by the plasmid QpH1 of Coxiella burnetii

Coxiella burnetii is an intracellular bacterial pathogen which causes Q fever in humans and other animals. Most of the isolates found carry plasmids which share considerable homology. Unfortunately all of these plasmids remain cryptic. Initial attempts to look for secreted or membrane proteins encoded by these plasmids using TnphoA mutagenesis revealed an open reading frame on the EcoRI-fragment C of the plasmid QpH1. Upstream DNA sequencing of the TnphoA insertions revealed a deduced peptide sequence with homology to the SopA protein which is encoded by the F plasmid in Escherichia coli. Maxi-cell analysis showed that fragment C encoded two proteins: one was 43.5 kDa in size and designated QsopA, and a second was 38 kDa in size. These proteins are similar in molecular weight to the SopA and SopB proteins, which are essential components of the partition mechanism of the F plasmid. The region appears to be conserved in plasmids QpRS, QpDV, and QpDG, but is absent in a plasmidless isolate in which plasmid sequences have integrated into the chromosomal DNA. Complementation studies demonstrated that fragment C has a plasmid partitioning function and can restore maintenance stability of the partition-defective mini-F plasmid. These data suggest that fragment C carries the plasmid partition region of the plasmid QpH1.     

In vivo recombination and the production of hybrid genes

In vivo recombination between homologous genes is increasingly being favoured as a means of generating proteins with altered and novel specificities. The typical procedure requires the cloning of two related genes on a single replicative plasmid of Escherichia coli and the selection or screening of recombinants. Up to now the recombination process between the cloned genes was generally thought to involve the recA function and the availability of free ends in the DNA molecule to be recombined. Our results show that neither is necessary. Recombinants are obtained by simply growing the bacteria that host the plasmid carrying the two cloned genes.     

Expression of native rabbit light meromyosin in Escherichia coli. Observation of a powerful internal translation initiation site

The cDNA-sequence coding for rabbit skeletal muscle light meromyosin (LMM) was placed under the control of the lambda promoter (PL) of an Escherichia coli expression vector. The resulting plasmid pEXLMM74 expressed non-fused rabbit skeletal muscle LMM with yields ranging from 1 to 5% of the total proteins of E. coli. This LMM was specifically recognized by polyclonal antibodies raised against chicken pectoralis muscle myosin. It could be highly enriched from E. coli extracts by using two cycles of high and low ionic strength buffer. The partially purified protein contained a major side-product, with a calculated molecular mass of 59 kilodaltons, that is produced by translation initiation from a site in the coding region of LMM. After deletion of the translation initiation site derived from the expression plasmid, only the 59 kilodalton protein is expressed in E. coli from the resulting plasmid pEXLMM59. Both the 74 and 59 kilodalton proteins were shown to form paracrystals. They were studied by electron microscopy using negative staining and were found to show characteristic striations with an axial periodicity of about 43 nm. By circular dichroism measurement we showed that the purified 59 kilodalton protein is folded mostly as an alpha-helix.     

High-level synthesis of cowpea mosaic virus RNA polymerase and protease in Escherichia coli

An expression system for the production of polymerase proteins of cowpea mosaic virus (CPMV) in Escherichia coli cells is described. High-level synthesis of proteins containing protease and polymerase moieties (110-kDa protein) and polymerase alone (87-kDa protein) were obtained from cells containing different plasmid constructions. Precursor and processed forms of CPMV proteins were detected by immunoblotting with antisera directed against 170-kDa precursor polyprotein and 24-kDa viral protease. Crude lysates and supernatant fractions of the lysates from E. coli cells harboring the various plasmid constructions were analysed for poly(A)-oligo(U) polymerase activity and found to be negative for CPMV activity under conditions where similar expression systems for the production of poliovirus RNA polymerase activity were positive. Thus, conditions for CPMV RNA replication may indeed be different from those for poliovirus even though the genomic organization of these viruses is similar.     

Mini-F plasmid mutants able to replicate in Escherichia coli deficient in the DnaJ heat shock protein.

A subset of Escherichia coli heat shock proteins, DnaJ, DnaK, and GrpE, is required for mini-F plasmid replication, presumably at the step of functioning of the RepE initiator protein. We have isolated and characterized mini-F plasmid mutants that acquired the ability to replicate in the Escherichia coli dnaJ259. The mutant plasmids were found to replicate in any of dnaJ, dnaK, and grpE mutant hosts tested. In each case, the majority of the mutant plasmids carried a unique amino acid alteration in a localized region of repE coding sequence and showed an increased copy number, whereas the minority contained a common single base change (C to T) in the promoter/operator region and produced an increased amount of RepE. All RepE proteins with altered residues (between 92 and 134) exhibited increased initiator activities (hyperactive), and many showed reduced repressor activities as well, indicating that this region is important for the both major functions of RepE protein. These results together with evidence reported elsewhere indicate that the subset of heat shock proteins serves to activate RepE protein prior to or during its binding to the replication origin and that the mutant RepE proteins are active even in their absence. We also found that a C-terminal lesion (repE602) reduces the initiator activity particularly of some hyperactive mutant RepE proteins but does not affect the repressor activity. This finding suggests a functional interaction between the central and C-terminal regions of RepE in carrying out the initiator function.     

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).     

Production of the siderophore aerobactin by a halophilic pseudomonad.

A bacterial strain, isolated from a cyanobacterial culture, was identified as Pseudomonas sp. strain X40. Under iron-limiting conditions, the Pseudomonas sp. produced aerobactin, a dihydroxamate siderophore previously found only in the family Enterobacteriaceae. Aerobactin was identified by electrophoretic mobility, spectrophotometric titration, proton nuclear magnetic resonance spectroscopy, mass spectrometry, acid hydrolysis, and biological activity. Aerobactin was used as a siderophore in the Pseudomonas sp. and Escherichia coli. Two iron-repressed outer membrane proteins were observed in the Pseudomonas sp., neither of which had electrophoretic mobility identical to that of the aerobactin outer membrane receptor protein from E. coli. DNA hybridization assays showed no hybridization to the aerobactin genes from the E. coli plasmid pColV, indicating that the genetic determinants for aerobactin production by Pseudomonas strain X40 differ substantially from those found in the archetypic enteric plasmid pColV-K30.     

Novel high- and low-copy stable cosmids for use in Agrobacterium and Rhizobium

Presented are a set of cosmids based on the unit copy Agrobacterium plasmid, pTAR, and the high-copy-number mutant plasmid, pUCD500, of pTiC58. The addition of a par function derived from pTAR to the vectors allowed them to be stably maintained throughout the cell population in the absence of selective pressure. These vectors, designed for Agrobacterium and Rhizobium, also work in Escherichia coli. The vectors can be cotransferred to Rhizobiaceae from E. coli with the helper plasmid, pRK2013. The pTiC58 origin containing vectors, pUCD1000 and pUCD1001 were found to be incompatible with a 250-kb plasmid harbored by R. meliloti RM102Z1. RM102Z1(pUCD1000) was still capable of nodulating roots in alfalfa.     

Production of the siderophore aerobactin by a halophilic pseudomonad.

A bacterial strain, isolated from a cyanobacterial culture, was identified as Pseudomonas sp. strain X40. Under iron-limiting conditions, the Pseudomonas sp. produced aerobactin, a dihydroxamate siderophore previously found only in the family Enterobacteriaceae. Aerobactin was identified by electrophoretic mobility, spectrophotometric titration, proton nuclear magnetic resonance spectroscopy, mass spectrometry, acid hydrolysis, and biological activity. Aerobactin was used as a siderophore in the Pseudomonas sp. and Escherichia coli. Two iron-repressed outer membrane proteins were observed in the Pseudomonas sp., neither of which had electrophoretic mobility identical to that of the aerobactin outer membrane receptor protein from E. coli. DNA hybridization assays showed no hybridization to the aerobactin genes from the E. coli plasmid pColV, indicating that the genetic determinants for aerobactin production by Pseudomonas strain X40 differ substantially from those found in the archetypic enteric plasmid pColV-K30.     

Blocking the dengue virus 2 infections on BHK-21 cells with purified recombinant dengue virus 2 E protein expressed in Escherichia coli

Dengue viruses (DVs) are mosquito-borne infectious pathogens. They have become an expanding public health problem in the tropics and subtropics. The dengue envelope (E) protein is one of the viral structure proteins responsible mainly for the virus attachment and entry onto host cells. It is also the major immunogen for virus neutralization. In this study, we have constructed a recombinant plasmid expressing a truncated E protein of DV-2 virus PL046 strain. The C-terminal hydrophobic domain of the E protein was removed and replaced with the sequence of S peptide to facilitate expression and purification. When expressed in Escherichia coli, the recombinant E proteins were found to be in the form of aggregated state. Through denaturation and dialysis processes, the receptor-interacting function of the purified recombinant E proteins was maintained, which was demonstrated by its ability to inhibit the DV-2 plaque-forming efficiency on mammalian BHK-21 host cells.     

Molecular characterization of the gene coding for major outer membrane protein OmpA from Enterobacter aerogenes

The ompA gene from Enterobacter aerogenes was subcloned into a low-copy-number plasmid vector and the resultant plasmid, pTU7En, used to study its expression in Escherichia coli K12. Although the gene was strongly expressed and large amounts of OmpA protein were present in the outer membrane its product was not functionally identical to the E. coli polypeptide. In particular, the E. aerogenes OmpA protein was unable to confer sensitivity to OmpA-specific phages of E. coli. When the primary structure of the protein was deduced from the nucleotide sequence of its gene it was found that three domains differed extensively from the corresponding regions of the E. coli protein. As two of these are known to be exposed on the cell surface we inferred that these alterations are responsible for differences in the biological activity of the two proteins.     

Expression of the alpha and beta tubulin genes of the African trypanosome in Escherichia coli

The African trypanosome, Trypanosoma brucei, contains multiple genes for both alpha- and beta-tubulins, which code for similar if not identical proteins. Studies of the structure and function of trypanosome microtubules have been limited due to the difficulties in obtaining sufficient amounts of purified tubulin. To produce large amounts of purified tubulin for studies of structure and function and to begin developing a system for producing systematic alterations of tubulin structure we have cloned and expressed the alpha- and beta-tubulin genes of T. brucei in Escherichia coli to produce the unfused proteins. Controlled high-level expression of both alpha- and beta-tubulin was achieved using a plasmid vector, pOTS, in which expression is controlled by phage lambda promoter/operator and a temperature-sensitive lambda repressor. The tubulins produced are insoluble, as has been found for many other proteins expressed to high levels in E. coli; they are readily purified to near homogeneity by chromatography on DEAE-cellulose in 7 M urea. N-terminal analysis of the purified proteins indicates that they are initiated correctly and that the N-formyl group is removed from the initiating methionine. This factor will probably prove important in the reconstitution of biologically active tubulin.     

System for the expression of recombinant hemoproteins in Escherichia coli

Expression of recombinant hemoproteins in Escherichia coli is often limited because a vast majority of the protein produced lacks the heme necessary for function. This is compounded by the fact that standard laboratory strains of E. coli have a limited capacity to withdraw heme from the extracellular environment. We are developing a new tool designed to increase the heme content of our proteins of interest by simply supplementing the expression medium with low concentrations of hemin. This hemoprotein expression (HPEX) system is based on plasmids (pHPEX1-pHPEX3) that encode an outermembrane-bound heme receptor (ChuA) from E. coli O157:H7. This heme receptor, and others like it, confers on the host the ability to more effectively internalize exogenous heme. Transformation of a standard laboratory E. coli protein expression strain (BL-21 [DE3]) with the pHPEX plasmid led to the expression of a new protein with the appropriate molecular weight for ChuA. The receptor was functional as demonstrated by the ability of the transformant to grow on iron-deficient media supplemented with hemin, an ability that the unmodified expression strain lacked. Expression of our proteins of interest, catalase-peroxidases, using this system led to a dramatic and parallel increase in heme content and activity. On a per-heme basis, the spectral and kinetic properties of HPEX-derived catalase-peroxidase were the same as those observed for catalase-peroxidases expressed in standard E. coli-based systems. We suggest that the pHPEX plasmids may be a useful addition to other E. coli expression systems and may help address a broad range of problems in hemoprotein structure and function.