A self-inducing runaway-replication plasmid expression system utilizing the Rop protein

A highly efficient prokaryotic expression system has been developed that produces proteins at levels exceeding 150 micrograms/ml of culture medium. The system consists of a temperature-sensitive-copy-number plasmid that carries the rop gene and promoter downstream from the trp promoter. Any sequence cloned into the PvuII site of the rop gene alters Rop protein activity and causes lethal runaway plasmid DNA replication. This plasmid replication can be suppressed in trans by complementation with a similar wild-type plasmid. Cells harboring both plasmids are quite stable, and induction of plasmid DNA synthesis occurs only after cells are grown for several generations under conditions that lead to the loss of the trans-acting repressor. Large amounts of Rop fusion proteins accumulate in the cell as the trp operon is gradually induced via repressor titration. All chimeric proteins accumulate as insoluble aggregates, and are therefore easily purified. They can be solubilized using relatively mild conditions, and the partially purified proteins are highly amenable to cleavage by chemical methods. Using this system we have made Rop fusions with the HIV Tat protein, the herpes simplex virus type-2 38K protein, and Chinese hamster metallothionin.     

The use of a partition locus to increase stability of tryptophan-operon-bearing plasmids in Escherichia coli

The stability of different derivatives of plasmid vectors pBR322 and pACYC184 carrying the tryptophan operon of Escherichia coli was monitored in various media. It was found that in the absence of any special selective pressure, all plasmids were lost from the culture. The stability varied depending both on the orientation of the inserted tryptophan fragment and the growth media used. The pBR322::trp+ plasmids were lost at an average frequency of 0.3 to 0.8% per cell generation, while the pACYC184::trp+ plasmid was lost at a rate higher than 5%. In all cases the whole plasmid was lost at a rate higher than 5%. In all cases the whole plasmid was lost, indicating a high stability of the plasmid::cloned DNA as such. To increase the stability of the cloning vectors, the partition locus of plasmid pSC101 was added to both the pBR322::trp+ and pACYC184::trp+ plasmids. The addition of this gene increased the replicon stability at least 3- to 10-fold, with the pBR322::trp+-par+ plasmids being the most stable. Also in this case, the stability was dependent on the plasmid type and on the growth medium. In no case was there a discoordinate loss of the antibiotic-resistance and tryptophan genes from the vectors.     

Deletion plasmids from transformants of Pseudomonas aeruginosa trp cells with the RSF1010-trp hybrid plasmid and high levels of enzyme activity from the gene on the plasmid.

A RSF1010-trp hybrid plasmid which contained the tryptophan operon of Escherichia coli was introduced into Pseudomonas aeruginosa trp cells by transformation. From the Trp+ transformants several deletion plasmids were obtained, and their physical maps with restriction endonucleases were constructed. P. aeruginosa trp cells with these plasmids showed at first more than 100 times higher levels of tryptophan synthetase beta activity over that of the control P. aeruginosa wild-type cells, but these levels were drastically decreased by 1 week of successive transfers of cultures. This decrease in enzyme activity was found to be due to the change on the plasmids but not to the host cells. The production of E. coli tryptophan synthetase beta enzyme in P. aeruginosa cells was proved by immunological test.     

Species differences in plasmid carriage in the Enterobacteriaceae

Modern concerns about the spread of antibiotic resistance raise questions about the effect of bacterial species on plasmid evolution and maintenance. We studied 223 Enterobacteriaceae isolated from wild mammals and determined the number of plasmids per isolate, the size of those plasmids, and the distribution of plasmid incompatibility groups N, P, W, FII, and A/C. All of these variables were non-randomly distributed with respect to bacterial species, suggesting that host-cell factors constrain the plasmids that a strain will carry. The implication for the evolution of multiple-resistance plasmids in a clinical setting is that although inter-generic plasmid transfer may introduce a novel resistance plasmid into a bacterial genus, it is likely to be modified to suit the requirements of the new host cell. This then further suggests that resistance plasmids will evolve independent lineages within bacterial species although the genes incorporated in them may have come from the same original source.     

Bacterial plasmid stability

Bacterial plasmids are ubiquitous ‘minichromosomes’ that have major importance in clinical microbiology, as agents of pathogenicity and as carriers of antibiotic resistance, and in molecular genetics, through their role as vectors in gene manipulation. Plasmids carry a wide range of dispensable, transiently useful and often bizarre functions.¹ Naturally occurring plasmids, in addition to modifying the host cell phenotype, carry genes involved in the control of their own vegetative replication, plasmid copy number² and stable inheritance. They may also carry determinants for the conjugal transfer of DNA between bacteria.³ Whereas low-copy-number plasmids must be partitioned by some active process during cell division, the evidence suggests that multicopy plasmids are distributed randomly between daughter cells. Two independent determinants are necessary for the stable inheritance of multicopy plasmids, and both of these appear to act by maximizing the number of independent plasmid molecules.     

Mobilization and transfer of Azospirillum lipoferum plasmid by the Tn5-Mob transposon into a plasmid-free Agrobacterium tumefaciens strain

Azospirillum lipoferum 4B harbors five cryptic plasmids. Several suicide plasmids were used to transfer Tn5-Mob to A. lipoferum 4B. Tn5-Mob insertion mutations of this strain could be obtained at frequencies of 10(-8)-10(-7) per recipient cell. One hundred Tn5-Mob A. lipoferum 4B mutants were used in bacterial matings with a plasmid-free Agrobacterium tumefaciens recipient strain. This is the first report of mobilization, transfer, and replication of an Azospirillum plasmid in Agrobacterium tumefaciens. One transconjugant was found which had lost an indigenous plasmid.     

Isolation of Saccharomyces cerevisiae TRP3.

Several plasmids, isolated from two plasmid pools, complemented a Saccharomyces cerevisiae trp3 mutant with defective indole-3-glycerol-phosphate synthase activity. Restriction mapping indicated that a 1.2-kilobase StuI segment was common to all complementing plasmids. Southern blot hybridization established that a cloned 5.2-kilobase BamHI fragment was derived intact from chromosomal DNA. A yeast trp3 mutant transformed with trp3-complementing plasmids contained approximately 40-fold elevated indole-3-glycerol-phosphate synthase activity. These plasmids also complemented an Escherichia coli trpC mutant, and transformants exhibited enzyme activity. Yeast trp3 is therefore associated with a 1.2-kilobase StuI DNA segment.     

A specialized host-vector system for the in Vivo cloning of the trp operon of wild-type and mutant strains of Salmonella typhimurium by generalized transduction

Using in vitro methods, a 14.2-kb EcoRI fragment of the Salmonella typhimurium chromosome containing the trp operon plus associated flanking sequences from deletion mutant delta trpDCB763 was cloned into the EcoRI site of plasmid pBR322 in a S. typhimurium host. An in vivo cloning vector was constructed from the recombinant plasmid by the in vitro excision of a SalI fragment that contains the entire trp operon. The derived plasmid (pSTP21) carries a hybrid insert made up of the 5.4-kb EcoRI-SalI upstream flanking sequence and the 3.2-kb SalI-EcoRI downstream flanking sequence. Plasmid pSTP21 has been used as a receptor plasmid to clone a variety of mutant and wild-type trp operons by RecA-dependent in vivo recombination between the insert DNA of the plasmid and the homologous trp flanking sequences of transducing DNA fragments transferred into the cell by bacteriophage P22. The host-vector system developed for the in vivo cloning permits the differentiation of plasmid transductants from chromosomal transductants on the primary selective medium. Expression of the cloned trp operons is regulated normally by tryptophan. A substantial amplification of trp enzymes is attainable upon derepression. The recombinant plasmids are stably inherited in RecA+ and RecA- S. typhimurium hosts. However, conditions of high expression of the trp operon lead to a rapid loss of cellular viability and of plasmid stability.     

A Monte Carlo simulation of plasmid replication during the bacterial division cycle

Plasmids have cell cycle replication patterns that need to be considered in models of their replication dynamics. To compare current theories for control of plasmid replication with experimental data for timing of plasmid replication with the cell cycle, a Monte Carlo simulation of plasmid replication and partition was developed. High-copy plasmid replication was simulated by incorporating equations previously developed from the known molecular biology of ColE1-type plasmids into the cell-cycle simulation. Two types of molecular mechanisms for low-copy plasmid replication were tested: accumulation of an initiator protein in proportion to cell mass and binding of the plasmid origin to the cell membrane. The low-copy plasmids were partitioned actively, with a specific mechanism to mediate the transfer from mother to daughter cells, whereas the high-copy plasmids were partitioned passively with cell mass.The simulation results and experimental data demonstrate cell-cycle-specific replication for the low-copy F plasmid and cell-cycle-independent replication for the high-copy pBR322, ColBM, and R6K plasmids. The simulation results indicate that synchronous replication at multiple plasmid origins is critical for the cell-cycle-specific pattern observed in rapidly growing cells. Variability in the synchrony of initiation of multiple plasmid origins give rise to a cell-cycle-independent pattern and is offered as a plausible explanation for the controversy surrounding the replication pattern of the low-copy plasmids. A comparison of experimental data and simulation results for the low-copy F plasmid at several growth rates indicates that either initiation mechanism would be sufficient to explain the timing of replication with the cell cycle. The simulation results also demonstrate that, although cell-cycle-specific and cell-cycle independent replication patterns give rise to very different gene-expression patterns during short induction periods in age-selected populations, long-term expression of genes encoded on low-copy and high-copy plasmids in exponentially growing cells have nearly the same patterns. These results may be important for the future use of low-copy plasmids as expression vectors and validate the use of simpler models for high-copy plasmids that do not consider cell-cycle phenomena. (c) 1996 John Wiley & Sons, Inc.     

Role and specificity of plasmid RP4-encoded DNA primase in bacterial conjugation.

The role of the DNA primase of IncP plasmids was examined with a derivative of RP4 containing Tn7 in the primase gene (pri). The mutant was defective in mediating bacterial conjugation, with the deficiency varying according to the bacterial strains used as donors and recipients. Complementation tests involving recombinant plasmids carrying cloned fragments of RP4 indicated that the primase acts to promote some event in the recipient cell after DNA transfer and that this requirement can be satisfied by plasmid primase made in the donor cell. It is proposed that the enzyme or its products or both are transmitted to the recipient cell during conjugation, and the role of the enzyme in the conjugative processing of RP4 is discussed. Specificity of plasmid primases was assessed with derivatives of RP4 and the IncI1 plasmid ColIb-P9, which is known to encode a DNA primase active in conjugation. When supplied in the donor cell, neither of the primases encoded by these plasmids substituted effectively in the nonhomologous conjugation system. Since ColIb primase provided in the recipient cell acted weakly on transferred RP4 DNA, it is suggested that the specificity of these enzymes reflects their inability to be transmitted via the conjugation apparatus of the nonhomologous plasmid.     

Paradigms of plasmid organization

Plasmids are extrachromosomal elements built from a selection of generally quite well understood survival and propagation functions, including replication, partitioning, multimer resolution, post-segregational killing and conjugative transfer. Evolution has favoured clustering of these modules to form plasmid cores or backbones. Co-regulation of these core genes can also provide advantages that favour retention of the backbone organization. Tumour-inducing and symbiosis-determining plasmids appear to co-regulate replication and transfer in response to cell density, both being stimulated at high density. Broad-host-range plasmids of the IncP-1 group, on the other hand, have autogenous control circuits, which allow a burst of expression during establishment in a new host, but a minimum of expression during maintenance. The lessons that plasmids have for clustering and co-regulation may explain the logic and organization of many small bacterial genomes currently being investigated.     

Mobilization of R387 Inc K conjugative plasmid by the conjugative plasmid R64 Inc I

Plasmid aggregate (R387, R64) was constructed in E. coli K12 strain. Plasmid R387 Inc K was stimulated to conjugational transfer by plasmid R64 Inc I. This stimulation was caused neither by recombination between both plasmids nor by trans-complementation of R387 conjugational systems by gene(s) product(s) of R64 plasmid. The observed phenomenon resembled rather mobilization of nonconjugative plasmids by conjugative ones. As in mobilization, the observed increase in R387 transfer frequency could take place only when both interacting plasmids were present in donor cells. Moreover, the entry exclusion system functioning in recipient cells, toward stimulating R64 plasmid affected strongly the conjugational transfer of stimulated R387 plasmid. Analogous phenomenon was observed during mobilization of nonconjugative plasmids by conjugative ones.     

Transformation of Bacillus polymyxa with plasmid DNA

A plasmid transformation system was developed for Bacillus polymyxa ATCC 12321 and derivatives of this strain. The method utilizes a penicillin-treated-cell technique to facilitate uptake of the plasmid DNA. Low-frequency transformation (10(-6) per recipient cell) of plasmids pC194, pBD64, and pBC16 was accomplished with this method. Selection for the transformants was accomplished on both hypertonic and nonhypertonic selective media, with the highest rates of recovery occurring on a peptone-glucose-yeast extract medium containing 0.25 M sucrose. Several additional plasmids were shown to be capable of transferring their antibiotic resistance phenotypes to B. polymyxa through the use of a protoplast transformation procedure which allowed for a more efficient transfer of the plasmid DNA. However, cell walls could not be regenerated on the transformed protoplasts, and the transformants could not be subcultured from the original selective media.     

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.     

Simultaneous regulation of plasmid replication and heterologous gene expression in Escherichia coli.

An expression plasmid in which plasmid DNA replication and heterologous gene expression can be simultaneously regulated was constructed to avoid derepression prior to induction. This was achieved by placing a pBR322 origin of replication immediately downstream of an anthranilate synthase-human epidermal growth factor fusion gene (trpE-hEGF), both under the control of the promoter from the tryptophan biosynthetic operon. Regulation of plasmid copy number ensured tight repression of the trp promoter prior to induction. Upon induction, plasmid copy number increased up to six-fold and the fusion protein accumulated to approximately 12% of total cell protein. Induction experiments with a series of plasmid derivatives with sequentially lower copy numbers revealed that accumulation levels of the TrpE-hEGF fusion protein post-induction correlated well with plasmid copy number. Plasmid constructs where the native trp promoter had been replaced by derivatives deleted of the attenuator resulted in high levels of hEGF accumulation in the tryptophan-free medium prior to induction. Nevertheless, up to two-fold increase in TrpE-hEGF accumulation levels were obtained using the constructs lacking the attenuator compared to those bearing the native trp promoter.     

Rule-based modelling of conjugative plasmid transfer and incompatibility

COSMIC-rules, an individual-based model for bacterial adaptation and evolution, has been used to study virtual transmission of plasmids within bacterial populations, in an environment varying between supportive and inhibitory. The simulations demonstrate spread of antibiotic resistance (R) plasmids, both compatible and incompatible, by the bacterial gene transfer process of conjugation. This paper describes the behaviour of virtual plasmids, their modes of exchange within bacterial populations and the impact of antibiotics, together with the rules governing plasmid transfer. Three case studies are examined: transfer of an R plasmid within an antibiotic-susceptible population, transfer of two incompatible R plasmids and transfer of two compatible R plasmids. R plasmid transfer confers antibiotic resistance on recipients. For incompatible plasmids, one or other plasmid could be maintained in bacterial cells and only that portion of the population acquiring the appropriate plasmid-encoded resistance survives exposure to the antibiotics. By contrast, the compatible plasmids transfer and mix freely within the bacterial population that survives in its entirety in the presence of the antibiotics. These studies are intended to inform models for examining adaptive evolution in bacteria. They provide proof of principle in simple systems as a platform for predicting the behaviour of bacterial populations in more complex situations, for example in response to changing environments or in multi-species bacterial assemblages.     

The kinetics of conjugative plasmid transmission: fit of a simple mass action model.

A mass action model for the infectious transmission of conjugative plasmids and procedures to estimate its parameters are presented. The suitability of this model as an analog of the kinetics of conjugative plasmid transmission is examined with batch and chemostat populations of Escherichia coli K-12 and three of its plasmids, F-lac-pro, R1 (Km-Cm-Ap), and R1-drd-19 (Km-Cm-Ap). Evidence is presented that this mass action model, with a unique and constant rate parameter, represents a reasonable analog of the kinetics of plasmid transfer for bacterial populations dividing at a constant rate in either exponentially growing cultures or at equilibrium in chemostats. As anticipated from this model magnitudes of the transfer rate constant for these plasmids appear to be relatively insensitive to both total cell density and the donor-recipient ratio. For all plasmids, the value of the transfer rate constant in rapidly dividing (exponentially growing) cultures is considerably greater than its corresponding value in slowly dividing, chemostat equilibrium cultures and the values of the transfer rate constant of the permanently derepressed plasmids F-lac-pro and R1-drd-19 are considerably greater than that of the wild-type, repressed transfer plasmid R1. The implications of this apparent fit to a mass action model are discussed and a recommendation is made to use the transfer rate constant as the measure of the fertility of conjugative plasmids.     

Transformation of Bacillus polymyxa with plasmid DNA.

A plasmid transformation system was developed for Bacillus polymyxa ATCC 12321 and derivatives of this strain. The method utilizes a penicillin-treated-cell technique to facilitate uptake of the plasmid DNA. Low-frequency transformation (10(-6) per recipient cell) of plasmids pC194, pBD64, and pBC16 was accomplished with this method. Selection for the transformants was accomplished on both hypertonic and nonhypertonic selective media, with the highest rates of recovery occurring on a peptone-glucose-yeast extract medium containing 0.25 M sucrose. Several additional plasmids were shown to be capable of transferring their antibiotic resistance phenotypes to B. polymyxa through the use of a protoplast transformation procedure which allowed for a more efficient transfer of the plasmid DNA. However, cell walls could not be regenerated on the transformed protoplasts, and the transformants could not be subcultured from the original selective media.