Structural and functional analysis of the par region of the pSC 10 1 plasmid

A versatile one-step CRISPR-Cas9 based approach to plasmid-curing

BACKGROUND

Plasmids are widely used and essential tools in molecular biology. However, plasmids often impose a metabolic burden and are only temporarily useful for genetic engineering, bio-sensing and characterization purposes. While numerous techniques for genetic manipulation exist, a universal tool enabling rapid removal of plasmids from bacterial cells is lacking.

RESULTS

Based on replicon abundance and sequence conservation analysis, we show that the vast majority of bacterial cloning and expression vectors share sequence similarities that allow for broad CRISPR-Cas9 targeting. We have constructed a universal plasmid-curing system (pFREE) and developed a one-step protocol and PCR procedure that allow for identification of plasmid-free clones within 24 h. While the context of the targeted replicons affects efficiency, we obtained curing efficiencies between 40 and 100% for the plasmids most widely used for expression and engineering purposes. By virtue of the CRISPR-Cas9 targeting, our platform is highly expandable and can be applied in a broad host context. We exemplify the wide applicability of our system in Gram-negative bacteria by demonstrating the successful application in both Escherichia coli and the promising cell factory chassis Pseudomonas putida.

CONCLUSION

As a fast and freely available plasmid-curing system, targeting virtually all vectors used for cloning and expression purposes, we believe that pFREE has the potential to eliminate the need for individualized vector suicide solutions in molecular biology. We envision the application of pFREE to be especially useful in methodologies involving multiple plasmids, used sequentially or simultaneously, which are becoming increasingly popular for genome editing or combinatorial pathway engineering.

Real-time transposable element activity in individual live cells

The excision and reintegration of transposable elements (TEs) restructure their host genomes, generating cellular diversity involved in evolution, development, and the etiology of human diseases. Our current knowledge of TE behavior primarily results from bulk techniques that generate time and cell ensemble averages, but cannot capture cell-to-cell variation or local environmental and temporal variability. We have developed an experimental system based on the bacterial TE IS608 that uses fluorescent reporters to directly observe single TE excision events in individual cells in real time. We find that TE activity depends upon the TE's orientation in the genome and the amount of transposase protein in the cell. We also find that TE activity is highly variable throughout the lifetime of the cell. Upon entering stationary phase, TE activity increases in cells hereditarily predisposed to TE activity. These direct observations demonstrate that real-time live-cell imaging of evolution at the molecular and individual event level is a powerful tool for the exploration of genome plasticity in stressed cells.

New quantitative methods for measuring plasmid loss rates reveal unexpected stability

Plasmid loss rate measurements are standard in microbiology and key to understanding plasmid stabilization mechanisms. The conventional assays eliminate selection for plasmids at the beginning of the experiment and screen for the appearance of plasmid-free cells over long-term population growth. However, it has been long appreciated in plasmid biology that the growth rate differential between plasmid-free and plasmid-containing cells at some point overshadows the effect of primary loss events, such that the assays can greatly over-estimate inherent loss rates. The standard solutions to this problem are to either consider the very early phase of loss where the fraction of plasmid-free cells increases linearly, or to measure the growth rate difference either by following the population for longer time or by measuring growth rates separately. Here we mathematically show that in all these cases, seemingly small experimental errors in the growth rate estimates can overshadow the estimates of the loss rates. For many plasmids, loss rates may thus be much lower than previously thought, and for some plasmids, the estimated loss rate may have nothing to do with actual loss rates. We further modify two independent experimental methods to separate inherent losses from growth differences and apply them to the same plasmids. First we use a high-throughput microscopy-based approach to screen for plasmid-free cells at extremely short time scales--tens of minutes rather than tens of generations--and apply it to a par⁻ version of mini-R1. Second we modify a counterselection-based plasmid loss assay inspired by the Luria-Delbrück fluctuation test that completely separates losses from growth, and apply it to various R1 and pSC101 derivatives. Concordant results from the two assays suggest that plasmids are lost at a lower frequency than previously believed. In fact, for par⁻ mini-R1 the observed loss rate of about 10⁻³ per cell and generation seems to be so low as to be inconsistent with what we know about the R1 stabilization mechanisms, suggesting these well characterized plasmids may have some additional and so far unknown stabilization mechanisms, for example improving copy number control or partitioning at cell division.

Tetracycline resistance gene maintenance under varying bacterial growth rate, substrate and oxygen availability, and tetracycline concentration

Neither amplification nor attenuation of antibiotic resistance genes (ARG) in the environment are well understood processes. Here, we report on continuous culture and batch experiments to determine how tetracycline (TC), aerobic vs anaerobic conditions, bacterial growth rate, and medium richness affect the maintenance of plasmid-borne TC resistance (Tet(R)) genes. The response of E. coli (a model resistant strain excreted by farm animals) versus Pseudomonas aeruginosa (a model bacterium that could serve as a reservoir for ARGs in the environment) were compared to gain insight into response variability. Complete loss of the Tet(R) RP1 plasmid (56 kb) occurred for P. aeruginosa in the absence of TC, and faster loss was observed in continuous culture at higher growth rates. In contrast, E. coli retained its smaller pSC101 plasmid (9.3 kb) after 500 generations without TC (albeit at lower levels, with ratios of resistance to 16S rDNA genes decreasing by about 2-fold). A higher rate of ARG loss was observed in P. aeruginosa when grown in minimal growth medium (M9) than in richer Luria broth. Faster ARG loss occurred in E. coli under anaerobic (fermentative) conditions than under aerobic conditions. Thus, in these two model strains it was observed that conditions that ease the metabolic burden of plasmid reproduction (e.g., higher substrate and O2 availability) enhanced resistance plasmid maintenance; such conditions (in the presence of residual antibiotics) may be conducive to the establishment and preservation of ARG reservoirs in the environment. These results underscore the need to consider antibiotic concentrations, redox conditions, and substrate availability in efforts to evaluate ARG propagation and natural attenuation.

A repeat sequence causes competition of ColE1-type plasmids

Plasmid pSW200 from Pantoea stewartii contains 41 copies of 15-bp repeats and has a replicon that is homologous to that of ColE1. Although deleting the repeats (pSW207) does not change the copy number and stability of the plasmid. The plasmid becomes unstable and is rapidly lost from the host when a homoplasmid with the repeats (pSW201) is present. Deleting the repeats is found to reduce the transcriptional activity of RNAIp and RNAIIp by about 30%, indicating that the repeats promote the transcription of RNAI and RNAII, and how the RNAI that is synthesized by pSW201 inhibits the replication of pSW207. The immunoblot analysis herein demonstrates that RNA polymerase β subunit and σ(70) in the lysate from Escherichia coli MG1655 bind to a biotin-labeled DNA probe that contains the entire sequence of the repeat region. Electrophoretic mobility shift assay also reveals that purified RNA polymerase shifts a DNA probe that contains four copies of the repeats. These results thus obtained reveal that RNA polymerase holoenzyme binds to the repeats. The repeats also exchange RNA polymerase with RNAIp and RNAIIp in vitro, revealing the mechanism by which the transcription is promoted. This investigation elucidates a mechanism by which a plasmid prevents the invasion of an incompatible plasmid and maintains its stability in the host cell during evolution.

New pSC101-derivative cloning vectors with elevated copy numbers

Mutations that increase the copy number of the pSC101 replicon have been used for construction of new cloning vectors. Replacement of glutamate at position 93 in RepA yields plasmids that replicate at medium (27 copies/cell) and high (approximately 240 copies/cell) copy numbers. Based on the crystal structure of RepE, a structurally similar replication initiator protein from the F factor, the pSC101 repA mutants are predicted to be defective in dimerization. The cloning vectors permit increased expression of gene products along with the advantages of pSC101-derivative plasmids, including stable maintenance and compatibility with ColE1 plasmids. The plasmids also allow blue/white screening for DNA inserts and impart resistance to ampicillin, chloramphenicol and kanamycin. The vectors were used in a genetic assay to suppress temperature-sensitive mutants of ffh, encoding the protein component of the Escherichia coli signal recognition particle, by overproduction of 4.5S RNA. While expression of 4.5S RNA from a wild type pSC101-derivative plasmid was not sufficient for suppression, use of the new vectors did suppress the temperature-sensitive phenotype.

Initiation of RNA decay in Escherichia coli by 5' pyrophosphate removal

The common belief that endonucleolytic cleavage is the initial, rate-determining step of mRNA decay in Escherichia coli fails to explain the influence of 5' termini on the half-lives of primary transcripts. We have re-examined the initial events of RNA degradation in that organism by devising an assay to probe the 5' phosphorylation state of RNA and by employing a self-cleaving hammerhead ribozyme to investigate the degradative consequences of an unphosphorylated 5' end. These studies have identified a previously unrecognized prior step in decay that triggers subsequent internal cleavage by the endonuclease RNase E and thereby governs RNA longevity: the rate-determining conversion of a triphosphorylated to a monophosphorylated 5' terminus. Our findings redefine the role of RNase E in RNA degradation and explain how unpaired 5'-terminal nucleotides can facilitate access to internal cleavage sites within primary transcripts. Moreover, these results reveal a striking parallel between the mechanisms of mRNA decay in prokaryotic and eukaryotic organisms.

Construction of highly efficient E. coli expression systems containing low oxygen induced promoter and partition region

A series of high-copy-number Escherichia coli expression vectors equipped with an oxygen-sensitive promoter P(vgb) of Vitreoscilla hemoglobin (encoded by the vgb gene) were constructed and characterized. Plasmid pKVp containing P(vgb) was inducible by low oxygen tension, while plasmid pKVpP containing a partition (par) region from plasmid pSC101 ligated to P(vgb) provided inheritable stability for the vectors in the absence of ampicillin. Plasmid pKVpV had the Vitreoscilla hemoglobin operon vgb ligated to P(vgb), while a construct containing P(vgb), the vgb operon and a par region constituted plasmid pKVpPV. Shake-flask studies demonstrated that plasmids pKVpV and pKVpPV expressed higher levels of Vitreoscilla hemoglobin under low aeration condition (5% air saturation in water) compared with the levels observed under strong aeration (20% air saturation in water). Introduction of either the enhanced green fluorescent protein (eGFP) gene egfp or the toluene dioxygenase (TDO) gene tod into either pKVpV (P(vgb), vgb operon) or pKVpPV (P(vgb), vgb operon, par) slightly attenuated (approximately 30%) the strong expression of VHb under low aeration. However, all displayed approximately a three-fold increase versus that observed for strong aeration. Recombinant E. coli harboring either pKVp-E (P(vgb), egfp) or pKVpP-E (P(vgb), par, egfp) displayed at least a two-fold increase in eGFP expression under conditions of low aeration and absence of antibiotic, compared with that under strong aeration after 24 h of cultivation. Strong expression of TDO was also observed using low aeration in recombinant E. coli harboring pKVpPV-T (P(vgb), vgb operon, par, tod) or pKVpP-T (P(vgb), par, tod). Plasmids containing the par region were stable over 100 generations. These results indicate that the novel expression system combining plasmid stability over the cell growth phase and a promoter inducible by low oxygen tension will be very useful for high-density production of foreign proteins.

DpiA binding to the replication origin of Escherichia coli plasmids and chromosomes destabilizes plasmid inheritance and induces the bacterial SOS response

The dpiA and dpiB genes of Escherichia coli, which are orthologs of genes that regulate citrate uptake and utilization in Klebsiella pneumoniae, comprise a two-component signal transduction system that can modulate the replication of and destabilize the inheritance of pSC101 and certain other plasmids. Here we show that perturbed replication and inheritance result from binding of the effector protein DpiA to A+T-rich replication origin sequences that resemble those in the K. pneumoniae promoter region targeted by the DpiA ortholog, CitB. Consistent with its ability to bind to A+T-rich origin sequences, overproduction of DpiA induced the SOS response in E. coli, suggesting that chromosomal DNA replication is affected. Bacteria that overexpressed DpiA showed an increased amount of DNA per cell and increased cell size-both also characteristic of the SOS response. Concurrent overexpression of the DNA replication initiation protein, DnaA, or the DNA helicase, DnaB-both of which act at A+T-rich replication origin sequences in the E. coli chromosome and DpiA-targeted plasmids-reversed SOS induction as well as plasmid destabilization by DpiA. Our finding that physical and functional interactions between DpiA and sites of replication initiation modulate DNA replication and plasmid inheritance suggests a mechanism by which environmental stimuli transmitted by these gene products can regulate chromosomal and plasmid dynamics.

The RepA protein of plasmid pSC101 controls Escherichia coli cell division through the SOS response

Although plasmid copy number varies widely among different plasmid species, normally copy number is maintained within a narrow range for any given plasmid. Such copy number control has been shown to occur by regulation of the rate of plasmid DNA replication. Here we report a novel mechanism by which the pSC101 plasmid also can detect an imbalance between the cellular level of its replication protein, RepA, and plasmid-borne RepA binding sites to inhibit bacterial DNA replication and delay host cell division when RepA is in relative excess. We show that delayed cell division occurs by RepA-mediated induction of the SOS response and can be reversed by over-expression of the host DNA primase, DnaG. The effects of RepA excess are prevented by introducing a surfeit of RepA binding sites. The mechanism reported here may help to limit variation in plasmid copy number and allow repopulation of cells with plasmids when copy number falls--potentially pre-empting plasmid loss in cultures of dividing cells.

Mechanistic aspects of DnaA-RepA interaction as revealed by yeast forward and reverse two-hybrid analysis

Using yeast forward and reverse two-hybrid analysis and biochemical techniques, we present novel and definitive in vivo and in vitro evidence that both the N-terminal domain I and C-terminal domain IV of the host-encoded DnaA initiator protein of Escherichia coli interact physically with plasmid-encoded RepA initiator of pSC101. The N-terminal, but not the C-terminal, region of RepA interacted with DnaA in vitro. These protein-protein interactions are critical for two very early steps of replication initiation, namely origin unwinding and helicase loading. Neither domain I nor IV of DnaA could individually collaborate with RepA to promote pSC101 replication. However, when the two domains are co-expressed within a common cell milieu and allowed to associate non-covalently with each other via a pair of leucine zippers, replication of the plasmid was supported in vivo. Thus, the result shows that physical tethering, either non-covalent or covalent, of domain I and IV of DnaA and interaction of both domains with RepA, are critical for replication initiation. The results also provide the molecular basis for a novel, potential, replication-based bacterial two-hybrid system.

Plasmid effects on Escherichia coli metabolism

The idea that plasmids replicate within hosts at the expense of cell metabolic energy and preformed cellular blocks depicts plasmids as a kind of molecular parasites that, even when they may eventually provide plasmid-carrying strains with growth advantages over plasmid-free strains, doom hosts to bear an unavoidable metabolic burden. Due to the consistency with experimental data, this idea was rapidly adopted and used as a basis of different hypotheses to explain plasmid-host interactions. In this article we critically discuss current ideas about plasmid effects on host metabolism, and present evidence suggesting that the complex interaction between plasmids and hosts is related to the alteration of the cellular regulatory status.

A set of temperature sensitive-replication/-segregation and temperature resistant plasmid vectors with different copy numbers and in an isogenic background (chloramphenicol, kanamycin, lacZ, repA, par, polA)

A set of plasmid vectors conferring chloramphenicol resistance (Cm(R)), 3064bp in size, or kanamycin resistance (Km(R)), 2972bp in size, were developed, having multiple cloning sites in lacZ' genes for alpha-complementation. pTH18cs1, pTH19cs1, pTH18ks1 and pTH19ks1 are temperature-sensitive (ts) in DNA replication (ts-Rep); pTH18cs5, pTH19cs5, pTH18ks5 and pTH19ks5 are ts in plasmid segregation (ts-Seg); and pTH18cr, pTH19cr, pTH18kr and pTH19kr are temperature resistant (tr) in both. They are based on the pSC101 replicon consisting merely of the replication origin and repA gene, compatible with ColE1/pMB1/p15-derived plasmids, and thus do not require polA function of host cells. The copy numbers of the ts-Rep, tr and ts-Seg plasmids were 14, 5 and 1 per chromosome at 30 degrees C, respectively. These plasmids are fairly stable when inherited at 30 degrees C, but not above 37 degrees C or 41.5 degrees C, depending on the repA mutations and host strains. They are isogenic apart from the ts mutations in the repA gene, and thus provide with useful tools for having appropriate controls in various experiments including bacterial gene-targeting, transposon mutagenesis, toxic gene expression, differential substitution on host functions, gene dosage analysis and so on.

Separate roles of Escherichia coli replication proteins in synthesis and partitioning of pSC101 plasmid DNA

We report here that the Escherichia coli replication proteins DnaA, which is required to initiate replication of both the chromosome and plasmid pSC101, and DnaB, the helicase that unwinds strands during DNA replication, have effects on plasmid partitioning that are distinct from their functions in promoting plasmid DNA replication. Temperature-sensitive dnaB mutants cultured under conditions permissive for DNA replication failed to partition plasmids normally, and when cultured under conditions that prevent replication, they showed loss of the entire multicopy pool of plasmid replicons from half of the bacterial population during a single cell division. As was observed previously for DnaA, overexpression of the wild-type DnaB protein conversely stabilized the inheritance of partition-defective plasmids while not increasing plasmid copy number. The identification of dnaA mutations that selectively affected either replication or partitioning further demonstrated the separate roles of DnaA in these functions. The partition-related actions of DnaA were localized to a domain (the cell membrane binding domain) that is physically separate from the DnaA domain that interacts with other host replication proteins. Our results identify bacterial replication proteins that participate in partitioning of the pSC101 plasmid and provide evidence that these proteins mediate plasmid partitioning independently of their role in DNA synthesis.

Mechanism of recruitment of DnaB helicase to the replication origin of the plasmid pSC101

Although many bacterial chromosomes require only one replication initiator protein, e.g., DnaA, most plasmid replicons depend on dual initiators: host-encoded DnaA and plasmid-encoded Rep initiator protein for replication initiation. Using the plasmid pSC101 as a model system, this work investigates the biological rationale for the requirement for dual initiators and shows that the plasmid-encoded RepA specifically interacts with the replicative helicase DnaB. Mutations in DnaB or RepA that disrupt RepA-DnaB interaction cause failure to load DnaB to the plasmid ori in vitro and to replicate the plasmid in vivo. Although, interaction of DnaA with DnaB could not substitute for RepA-DnaB interaction for helicase loading, DnaA along with integration host factor, DnaC, and RepA was essential for helicase loading. Therefore, DnaA is indirectly needed for helicase loading. Instead of a common surface of interaction with initiator proteins, interestingly, DnaB helicase appears to have at least a limited number of nonoverlapping surfaces, each of which interacts specifically with a different initiator protein.

Isolation and characterization of plasmid pSW200 from Erwinia stewartii

The nucleotide sequence of pSW200 of Erwinia stewartii SW2 was determined. This plasmid is 4367 bp long, consisting of four mobilization genes, mobCABD, and an origin of replication homologous to those of ColE1-type plasmids. The plasmid also contains a region of forty-one 15-bp repeats. Deleting this region does not affect the stability or the copy number when maintained as sole plasmid in the cell. However, the plasmid is rapidly lost when a homoplasmid with the intact repeat region is introduced into the cell. The function of this region may provide pSW200 an advantage in competing with an incompatible plasmid in the cell.

The Escherichia coli dnaA gene: four functional domains

The Escherichia coli DnaA protein is a sequence-specific DNA binding protein that promotes the initiation of replication of the bacterial chromosome, and of several plasmids including pSC101. Twenty-eight novel missense mutations of the E. coli dnaA gene were isolated by selecting for their inability to replicate a derivative of pSC101 when contained in a lambda vector. Characterization of these as well as seven novel nonsense mutations and one in-frame deletion mutation are described here. Results suggest that E. coli DnaA protein contains four functional domains. Mutations that affect residues in the P-loop or Walker A motif thought to be involved in ATP binding identify one domain. The second domain maps to a region near the C terminus and is involved in DNA binding. The function of the third domain that maps near the N terminus is unknown but may be involved in the ability of DnaA protein to oligomerize. Two alleles encoding different truncated gene products retained the ability to promote replication from the pSC101 origin but not oriC, identifying a fourth domain dispensable for replication of pSC101 but essential for replication from the bacterial chromosomal origin, oriC.

Temperature-sensitive lesions in the Francisella novicida valA gene cloned into an Escherichia coli msbA lpxK mutant affecting deoxycholate resistance and lipopolysaccharide assembly at the restrictive temperature

The valAB locus of Francisella novicida has previously been found to be highly similar at the deduced amino acid level to msbA lpxK of Escherichia coli. Both ValA and MsbA are members of the superfamily of ABC transporters, and they appear to have similar functions. In this study we describe the isolation of a temperature-sensitive valAB locus. DNA sequence analysis indicates that the only changes to the ValAB deduced amino acid sequence are changes of S453 to an F and T458 to an I in ValA. E. coli strains defective in msbA and expressing temperature-sensitive ValA rapidly ceased growth when shifted from a permissive temperature to a restrictive temperature. After 1 h at the restrictive temperature, cells were much more sensitive to deoxycholate treatment. To test the hypothesis that ValA is responsible for the transport or assembly of lipopolysaccharide, we introduced gseA, a Kdo (3-deoxy-D-manno-octulosonic acid) transferase from Chlamydia trachomatis, into a strain with a temperature-sensitive valA allele and a nonfunctional msbA locus. These recombinants were defective in cell surface expression of the chlamydial genus-specific epitope within 15 min of a shift to the nonpermissive temperature. Also, there was enhanced association of the epitope with the inner membrane after a shift to the nonpermissive temperature. Thus, we propose that ValA is involved in the transport of lipopolysaccharide to the outer membrane.

Threonine 435 of Escherichia coli DnaA protein confers sequence-specific DNA binding activity

The Escherichia coli DnaA protein, as a sequence-specific DNA binding protein, promotes the initiation of chromosomal replication by binding to four asymmetric 9-mer sequences termed DnaA boxes in oriC. Characterization of N-terminal, C-terminal, and internal in-frame deletion mutants identified residues near the C terminus of DnaA protein required for DNA binding. Furthermore, genetic and biochemical characterization of 11 missense mutations mapping within the C-terminal 89 residues indicated that they were defective in DNA binding. Detailed biochemical characterization of one mutant protein bearing a threonine to methionine substitution at position 435 (T435M) revealed that it retained only nonspecific DNA binding activity, suggesting that threonine 435 imparts specificity in binding. Finally, T435M was inactive on its own for in vitro replication of an oriC plasmid but was able to augment limiting levels of wild type DnaA protein, consistent with the proposal that not all of the DnaA monomers in the initial complex are bound specifically to oriC and that direct interaction occurs among monomers.

Novel alleles of the Escherichia coli dnaA gene

The Escherichia coli dnaA gene is required for replication of the bacterial chromosome. To identify residues critical for its replication activity, a method to select novel mutations was developed that relied on lytic growth of lambda from an inserted pSC101 replication origin. Replication from the lambda origin was inhibited by lysogen-encoded cI repressor. Replication from the pSC101 origin that resulted in lytic growth was dependent on active DnaA protein encoded by a plasmid in a host strain lacking the chromosomal dnaA gene. With this approach, a large collection of missense, nonsense, and a few internal deletion mutations were obtained. Nucleotide sequence analysis of the missense mutations indicated that 28 of 50 were unique. Of these, one was identical to the dnaA205 allele whereas the remainder are novel. These missense mutations were clustered into three regions, suggesting three functional domains of DnaA protein required for its replication activity. Many of the missense mutations mapping to the C-terminal 61 residues were inactive for replication from the pSC101 origin. These are defective in DNA binding. Mutations that mapped elsewhere were temperature-sensitive.

Apparent and real recombination frequencies in multicopy plasmids: the need for a novel approach in frequency determination

Recombination studies of bacteria are often carried out with multicopy plasmids, and recombination frequencies are often deduced from the proportion of cells in the population that express a recombinant phenotype. These frequencies should however be called apparent frequencies, since detection of the recombinant cells requires not only the formation of a rearranged plasmid but also its establishment in the cell. The establishment of the recombinant plasmid can possibly be affected by its interaction with the parental plasmids. To test this hypothesis, we have used a plasmid system enabling the study of deletion formation between short direct repeats (18 bp) in Bacillus subtilis and developed a method by which deletion frequencies are measured under conditions under which interaction is abolished. Real deletion frequencies were thus determined and compared with apparent deletion frequencies. Real frequencies were underestimated by a factor ranging from 4- to 500-fold, depending upon the plasmid under study. This implies that a large majority of the recombinant molecules that are formed are generally not detected. We show that apparent deletion frequencies strongly depend upon (i) the parental plasmid copy number, (ii) the ability of the recombinant molecules to form heterodimeric plasmids, and (iii) the fitness of the recombinant molecules relative to that of parental molecules. Finally, we show that under conditions under which all recombinant molecules are scored, transcription can inhibit the deletion process 10-fold.

A DNA segment conferring stable maintenance on R6K gamma-origin core replicons

The plasmid R6K gamma origin consists of two adjacent modules, the enhancer and the core, and requires R6K initiator protein pi for replication. While the core alone can replicate at a low level of wild-type pi protein, we show here that host cells do not stably maintain core plasmids. The presence of the enhancer segment confers stable inheritance on core plasmids without a significant change in average plasmid copy number. Deletions and site-directed mutagenesis indicated that the stability of core plasmids is not mediated by binding sites or consensus sequences in the enhancer for DnaA, pi protein, gyrase, Fis, or Dcm methylase. Proper segregation of core plasmids requires only the R6K stb or stability-related region, which includes the 20-bp segment of the 100-bp enhancer adjacent to the core. The use of the pi 116 mutant protein, which increases plasmid copy number fourfold, does not stabilize core plasmids lacking the enhancer. We also show that at an elevated level of wild-type pi, the gamma-origin plasmid is unstable, even in the presence of the enhancer. We discuss the differences and similarities between the R6K stability system and those found in other plasmids.

Boundaries of the pSC101 minimal replicon are conditional

The DNA segment essential for plasmid replication commonly is referred to as the core or minimal replicon. We report here that host and plasmid genes and sites external to the core replicon of plasmid pSC101 determine the boundaries and competence of the replicon and also the efficiency of partitioning. Missense mutations in the plasmid-encoded RepA protein or mutation of the Escherichia coli topoisomerase I gene enable autonomous replication of a 310-bp pSC101 DNA fragment that contains only the actual replication origin plus binding sites for RepA and the host-encoded DnaA protein. However, in the absence of a repA or topA mutation, the DNA-bending protein integration host factor (IHF) and either of two cis-acting elements are required. One of these, the partitioning (par) locus, is known to promote negative DNA supercoiling; our data suggest that the effects of the other element, the inverted repeat (IR) sequences that overlap the repA promoter, are mediated through the IR's ability to bind RepA. The concentrations of RepA and DnaA, which interact with each other and with plasmid DNA in the origin region (T. T. Stenzel, T. MacAllister, and D. Bastia, Genes Dev. 5:1453-1463, 1991), also affect both replication and partitioning. Our results, which indicate that the sequence requirements for replication of pSC101 are conditional rather than absolute, compel reassessment of the definition of a core replicon. Additionally, they provide further evidence that the origin region RepA-DnaA-DNA complex initiating replication of pSC101 also mediates the partitioning of pSC101 plasmids at cell division.

RNAII transcribed by IPTG-induced T7 RNA polymerase is non-functional as a replication primer for ColE1-type plasmids in Escherichia coli

RNAII, an RNA species encoded by ColE1-type plasmids, serves as a primer for plasmid DNA replication. Previous work has shown that overproduction of RNAII transcribed by Escherichia coli RNA polymerase results in elevated plasmid copy number. To produce a plasmid in which the elevation of its copy number is inducible, we placed transcription of RNAII under the control of a bacteriophage T7 late promoter regulated by IPTG-inducible T7 RNA polymerase. During induction of T7 RNA polymerase by IPTG, we found that RNAII was overexpressed, but that, surprisingly, this increase in RNAII did not result in elevation of plasmid copy number. These results suggest that RNAII transcribed by T7 RNA polymerase does not function as a primer for plasmid DNA replication. Since RNAII function requires folding of its multiple stem-loop structures in a precise conformation and folding of RNAII can be influenced by its rate of transcription, the extremely rapid rate of travel of the T7 RNA polymerase may preclude proper folding of RNAII during its elongation.

Site-specific RNase E cleavage of oligonucleotides and inhibition by stem-loops

The enzyme RNase E (ref. 1) cuts RNA at specific sites within single-stranded segments. The role of adjacent regions of secondary structure in such cleavages is controversial. Here we report that 10-13-nucleotide oligomers lacking any stem-loop but containing the RNase E-cleaved sequence of RNA I, the antisense repressor of replication of ColE1-type plasmids, are cut at the same phosphodiester bond as, and 20 times more efficiently than, RNA I. These findings indicate that, contrary to previous proposals, stem-loops do not serve as entry sites for RNase E, but instead limit cleavage at potentially susceptible sites. Cleavage was reduced further by mutations in a non-adjacent stem-loop, suggesting that distant conformational changes can also affect enzyme access. Modulation of RNase E cleavages by stem-loop regions and to a lesser extent by higher-order structure may explain why this enzyme, which does not have stringent sequence specificity, cleaves complex RNAs at a limited number of sites.

Effects of the pSC101 partition (par) locus on in vivo DNA supercoiling near the plasmid replication origin

Previous work has shown that deletion of the partition (par) locus of plasmid pSC101 results in decreased overall superhelical density of plasmid DNA and concommitant inability of the plasmid to be stably inherited in populations of dividing cells. We report here that the biological effects of par correlate specifically with its ability to generate supercoils in vivo near the origin of pSC101 DNA replication. Using OsO4 reactivity of nucleotides adjoining 20 bp (G-C) tracts introduced into pSC101 DNA to measure local DNA supercoiling, we found that the wild type par locus generates supercoiling near the plasmid's replication origin adequate to convert a (G-C) tract in the region to Z form DNA. A 4 bp deletion that decreases par function, but produces no change in the overall superhelicity of pSC101 DNA as determined by chloroquine/agarose gel analysis, nevertheless reduced (G-C) tract supercoiling sufficiently to eliminate OsO4 reactivity. Mutation of the bacterial topA gene, which results in stabilized inheritance of par-deleted plasmids, restored supercoiling of (G-C) tracts in these plasmids and increased OsO4 reactivity in par+ replicons. Removal of par to a site more distant from the origin decreased supercoiling in a (G-C) tract adjacent to the origin and diminished par function. Collectively, these findings indicate that par activity is dependent on its ability to produce supercoiling at the replication origin rather than on the overall superhelical density of the plasmid DNA.

Isolation and characterization of plasmid mutations that enable partitioning of pSC101 replicons lacking the partition (par) locus

Second-site mutations that allow stable inheritance of partition-defective pSC101 plasmids mapped to seven distinct sites in the 5' half of the plasmid repA gene. While the mutations also elevated pSC101 copy number, there was no correlation between copy number increase and plasmid stability. Combinations of mutations enabled pSC101 DNA replication in the absence of integration host factor and also stabilized par-deleted plasmids in cells deficient in DNA gyrase or defective in DnaA binding. Our findings suggest that repA mutations compensate for par deletion by enabling the origin region RepA-DNA-DnaA complex to form under suboptimal conditions. They also provide evidence that this complex has a role in partitioning that is separate from its known ability to promote plasmid DNA replication.

Two enhancer elements for DNA replication of pSC101, par and a palindromic binding sequence of the Rep protein

The minimal replication origin (ori) of the plasmid pSC101 has been previously defined as an approximately 220-bp region by using plasmids defective in the par region, which is a cis-acting determinant of plasmid stability. This ori region contains the DnaA binding sequence, three repeated sequences (iterons), and an inverted repeat (IR) element (IR-1), one of the binding sites of an initiator protein, Rep (or RepA). In the present study, we show that plasmids containing par can replicate at a nearly normal copy number in the absence of IR-1 but still require a region (the downstream region) between the third iteron and IR-1. Because par is dispensable in plasmids retaining IR-1, par and IR-1 can compensate each other for efficient replication. The region from the DnaA box to the downstream region can support DNA replication at a reduced frequency, and it is designated "core-ori." Addition of either IR-1 or par to core-ori increases the copy number of the plasmid up to a nearly normal level. However, the IR-1 element must be located downstream of the third iteron (or upstream of the rep gene) to enhance replication of the plasmid, while the par region, to which DNA gyrase can bind, functions optimally regardless of its location. Furthermore, the enhancer activity of IR-1 is dependent on the helical phase of the DNA double helix, suggesting that the Rep protein bound to IR-1 stimulates the activation of ori via its interaction with another factor or factors capable of binding to individual loci within ori.

A locus involved in the regulation of replication in plasmid pSC101

The origin of replication of plasmid pSC101 contains three directly repeated sequences RS1, RS2, and RS3 separated by 22 bp from two palindromic sequences, IR1 and IR2, which are partially homologous to the direct repeats. These inverted repeat (IR) sequences overlap the promoter of the repA gene which encodes a protein essential for plasmid replication. We have shown that RepA binds to the RS sites as a monomer and to the IR sites as a dimer. The influence of the IR1 site, and of the DNA segment that separates it from RS3, on plasmid copy number control has been studied in detail. We show that the integrity of IR1 is essential for efficient replication and plasmid stability, the critical site extending to the left of IR1 proper. We also show that the presence of IR1 modifies profoundly the binding properties of purified RepA protein to a segment of DNA containing the RS sequences. IR1 is separated from its homologous site on RS3 by approximately four turns of the DNA helix. Replication is abolished if this distance is increased by half a turn of the helix but it is restored if the distance is increased by a whole turn. These results suggest a DNA looping interaction, in the initiation of replication, between the RepA dimer that binds IR1 and the RepA monomers that bind the RS sequences.

Excess intracellular concentration of the pSC101 RepA protein interferes with both plasmid DNA replication and partitioning

RepA, a plasmid-encoded gene product required for pSC101 replication in Escherichia coli, is shown here to inhibit the replication of pSC101 in vivo when overproduced 4- to 20-fold in trans. Unlike plasmids whose replication is prevented by mutations in the repA gene, plasmids prevented from replicating by overproduction of the RepA protein were lost rapidly from the cell population instead of being partitioned evenly between daughter cells. Removal of the partition (par) locus increased the inhibitory effect of excess RepA on replication, while host and plasmid mutations that compensate for the absence of par, or overproduction of the E. coli DnaA protein, diminished it. A repA mutation (repA46) that elevates pSC101 copy number almost entirely eliminated the inhibitory effect of RepA at high concentration and stimulated replication when the protein was moderately overproduced. As the RepA protein can exist in both monomer and dimer forms, we suggest that overproduction promotes RepA dimerization, reducing the formation of replication initiation complexes that require the RepA monomer and DnaA; we propose that the repA46 mutation alters the ability of the mutant protein to dimerize. Our discovery that an elevated intracellular concentration of RepA specifically impedes plasmid partitioning implies that the RepA-containing complexes initiating pSC101 DNA replication participate also in the distribution of plasmids at cell division.

Minimal essential origin of plasmid pSC101 replication: requirement of a region downstream of iterons

The minimal replication origin (ori) of the plasmid pSC101 was defined as an about 220-bp region under the condition that the Rep (or RepA) protein, a plasmid-encoded initiator protein, was supplied in trans. The DnaA box is located at one end of ori, as in other plasmids, like mini-F and P1. The other border is a strong binding site (IR-1) of Rep which is palindromic sequence and lies in an about 50-bp region beyond the repeated sequences (iterons) in ori. This IR-1 is located just upstream of another strong Rep binding site (IR-2), the operator site of the structure gene of Rep (rep), but its function has not been determined. The present study shows that the IR-1 sequence capable of binding to Rep is essential for plasmid replication with a nearly normal copy number. Furthermore, a region between the third iteron and IR-1 is also required in a sequence-specific fashion, since some one-base substitution in this region inactivate the origin function. It is likely that the region also is a recognition site of an unknown protein. Three copy number mutations of rep can suppress any one-base substitution mutation. On the other hand, the sequence of a spacer region between the second and the third iterons, which is similar to that of the downstream region of the third iteron, can be changed without loss of the origin function. The requirement of the region downstream of iterons in pSC101 seems to be unique among iteron-driven plasmid replicons.

The pSC101 par locus alters protein-DNA interactions in vivo at the plasmid replication origin

We report here direct evidence that mutations in the par locus affect protein-DNA interactions in vivo at the replication origin of plasmid pSC101. Concomitant with par-mediated plasmid stabilization, two sites in the origin region show an altered methylation pattern as detected by in vivo footprinting with dimethyl sulfate. One site is located near an integration host factor-binding sequence adjacent to the first of three direct repeats known to be involved in the initiation of pSC101 replication; the second site is within the third direct repeat.

The partition (par) locus of pSC101 is an enhancer of plasmid incompatibility

The incompatibility that pSC101-derived plasmids express toward each other is mediated by directly repeated sequences (iterons) located near the plasmid's replication origin. We report here that the pSC101 par locus, which stabilizes plasmid inheritance in dividing cell populations and alters DNA superhelicity, can function as a cis-acting enhancer of incompatibility, which we show is determined jointly by the copy number of the plasmid and the number of iterons per copy. A single synthetic 32 bp iteron sequence carried by the pUC19 plasmid confers strong pSC101-specific incompatibility in the absence of any other pSC101 sites but requires the par locus to express strong incompatibility when carried by a lower-copy-number plasmid. We propose a model by which the par locus can enhance the apparently antagonistic processes of incompatibility and pSC101 DNA replication while concurrently facilitating plasmid distribution during cell division.

Plasmid replication and maintenance in binary fissile microorganisms

The mechanisms of nonconjugative plasmid replication (in the single cell) and maintenance (at the population level) are of concern to the microbiologist and to the genetic engineer who wishes to exploit their ability to express cloned genes. This article concentrates mainly on Escherichia coli as the host organism and examines the mechanisms by which both naturally occurring and genetically engineered plasmids persist in populations during periods of growth. Additional strategies to ensure high yields of recombinant product are briefly considered.

Random diffusion can account for topA-dependent suppression of partition defects in low-copy-number plasmids

The maintenance of partition-defective (Par-) mini-P1 and mini-F plasmids was studied in topA strains of Escherichia coli, which are defective in topoisomerase I activity. The partition defects were substantially but not completely suppressed in broth-grown cultures. This suppression was not due to a large increase in copy number. However, the absolute number of copies of Par- mini-P1 plasmids per average dividing cell is sufficiently high to account for the modest stability observed if a random distribution of the copies to daughter cells is assumed. The similar number of Par- plasmid copies in wild-type cells are distributed in a considerably worse-than-random fashion. Thus, it is unnecessary to propose, as was suggested previously, that an active, par-independent pathway operates in topA strains to ensure proper segregation of the plasmids to daughter cells. Rather, it seems likely that the lack of topoisomerase I activity aids the random distribution of the partition-defective plasmids, perhaps by facilitating their separation after replication. The results of studies carried out at reduced growth rates were consistent with this view; when topA cells containing Par- mini-P1 plasmids were cultured in minimal medium, in which the copy number of the plasmids per average cell is sharply reduced, very little suppression of the partition defect was observed.

Propagation of pSC101 plasmids defective in binding of integration host factor

Integration host factor (IHF), a multifunctional protein of E. coli, normally is required for the replication of plasmid pSC101. T. T. Stenzel, P. Patel, and D. Bastia (Cell 49:709-717, 1987) have reported that IHF binds to a DNA locus near the pSC101 replication origin and enhances a static bend present in this region; mutation of the IHF binding site affects the plasmid's ability to replicate. We report here studies indicating that the requirement for IHF binding near the pSC101 replication origin is circumvented partially or completely by (i) mutation of the plasmid-encoded repA (replicase) gene or the chromosomally encoded topA gene, (ii) the presence on the plasmid of the pSC101 partition (par) locus, or (iii) replacement of the par locus by a strong transcriptional promoter. With the exception of the repA mutation, the factors that substitute for a functional origin region IHF binding site are known to alter plasmid topology by increasing negative DNA supercoiling, as does IHF itself. These results are consistent with the proposal that IHF binding near the pSC101 replication origin promotes plasmid replication by inducing a conformational change leading to formation of a repA-dependent DNA-protein complex. A variety of IHF-independent mechanisms can facilitate formation of the putative replication-initiation complex.

Genetic and functional analysis of the basic replicon of pPS10, a plasmid specific for Pseudomonas isolated from Pseudomonas syringae patovar savastanoi

The sequence of a 1823 base-pair region containing the replication functions of pPS10, a narrow host-range plasmid isolated from a strain of Pseudomonas savastanoi, is reported. The origin of replication, oriV, or pPS10 is contained in a 535 base-pair fragment of this sequence that can replicate in the presence of trans-acting function(s) of the plasmid. oriV contains four iterons of 22 base-pairs that are preceded by G+C-rich and A+T-rich regions. A dnaA box located adjacent to the repeats of the origin is dispensable but required for efficient replication of pPS10; A and T are equivalent bases at the 5' end of the box. repA, the gene of a trans-acting replication protein of 26,700 Mr has been identified by genetic and functional analysis. repA is adjacent to the origin of replication and is preceded by the consensus sequences of a typical sigma 70 promoter of Escherichia coli. The RepA protein has been identified, using the minicell system of E. coli, as a polypeptide with an apparent molecular mass of 26,000. A minimal pPS10 replicon has been defined to a continuous 1267 base-pair region of pPS10 that includes the oriV and repA sequences.

Analysis of a copy number mutant of plasmid pSC101: co-maintenance of wild type and mutant plasmids

We have isolated a high copy number mutant of plasmid pSC101 which is maintained at a level 4 times higher than that of the wild type. The mutation is a single base change that maps in codon 93 of the initiation protein RepA. We find that the mutation relaxes the autoregulation of the protein but increases its affinity for the repeated sequences in the origin. The wild type and the mutant repA genes are co-dominant and the mutated protein acts in trans even in the presence of the wild type protein. Co-maintenance of the two types of plasmids results in an intermediate copy number. Computer simulation indicates that simple models can explain the behaviour of the two plasmids.

The replication of plasmid pSC101

The origin of replication of plasmid pSC101 presents features reminiscent of those found in a number of plasmids. As for those plasmids, many details about the way it initiates its replication are beginning to be known, but the regulation of this process will not be easily understood.

The par region of pSC101 affects plasmid copy number as well as stability

The par locus is a segment of pSC101 that has been identified as a cis-acting determinant of plasmid stability. We show that par also determines copy number and must, therefore, play a role in plasmid replication. The segregation defect, but not the copy-number reduction, of par- replication origins is completely suppressed by a short sequence from the bacteriophage lambda gene O which is present in plasmid pKO-4. Thus, replication and segregation functions are separable from each other.

Role of DNA superhelicity in partitioning of the pSC101 plasmid

Previous work has shown that a cis-acting locus (termed par for partitioning) on the pSC101 plasmid accomplishes its stable inheritance in dividing cell populations. We report here that the DNA of pSC101 derivatives lacking the par region shows a decrease in overall superhelical density as compared with DNA of wild-type pSC101. Chemicals and bacterial mutations that reduce negative DNA supercoiling increase the rate of loss of par plasmids and convert normally stable plasmids that have minimal par region deletions into unstable replicons. topA gene mutations, which increase negative DNA supercoiling, reverse the instability of partition-defective plasmids that utilize the pSC101, p15A, F, or oriC replication systems. Our observations show that the extent of negative supercoiling of plasmid DNA has major effects on the plasmid's inheritance and suggest a mechanism by which the pSC101 par region may exert its stabilizing effects.

Cyclic AMP stimulates transcription of the structural gene of the outer-membrane protein OmpA of Escherichia coli

To analyze the effect of cyclic AMP on the expression of the ompA gene of Escherichia coli, encoding the outer-membrane protein OmpA, a fusion between this gene and the lacZ gene was constructed in vitro by using a promoter-probe plasmid. The results obtained indicated that the presence of glucose in the culture medium decreased the transcription of the ompA gene. Likewise, cya and crp mutants exhibited lower levels of ompA gene expression than the wild-type strain. Furthermore, the addition of cyclic AMP increased the expression of the ompA gene in both cya and wild-type strains but not in a crp mutant. All these data show that the cyclic AMP receptor protein-cyclic AMP complex positively modulates ompA transcription in E. coli K-12.

Use of the Escherichia coli ssb Gene to Prevent Bioreactor Takeover by Plasmidless Cells

Reactor takeover by plasmidless cells is a major problem encountered when producing proteins from plasmid-borne genes in genetically engineered bacteria. We have approached this problem by deleting the essential ssb gene from the Escherichia coli chromosome and placing it on a plasmid. Plasmidless cells do not accumulate even after growing such strains under non-selective continuous culture conditions for extended periods of time. Other ssb-containing plasmids can be readily introduced into this E. coli strain by a plasmid-displacement technique. Using this system, we have achieved very high levels of beta-lactamase production in continuous culture without selective pressure.

Involvement of integration host factor (IHF) in maintenance of plasmid pSC101 in Escherichia coli: characterization of pSC101 mutants that replicate in the absence of IHF

Escherichia coli mutants defective in the stable maintenance of plasmid pSC101 have been isolated following Tn10 insertion mutagenesis. One class of mutations affecting pSC101 replication was located in the genes himA and himD (hip), which encode the two subunits of integration host factor (IHF), a small histonelike DNA-binding protein that has multiple cellular functions. Mutants of pSC101 that could replicate in the absence of IHF were isolated and characterized; four independent mutational alterations were found to affect the third codon of the pSC101 rep gene, resulting in the replacement of glutamic acid by lysine. The compensating alteration appears to function by altering the activity of the pSC101 rep protein in him mutants.

Involvement of integration host factor (IHF) in maintenance of plasmid pSC101 in Escherichia coli: mutations in the topA gene allow pSC101 replication in the absence of IHF

Integration host factor (IHF), encoded by the himA and himD genes, is a histonelike DNA-binding protein that participates in many cellular functions in Escherichia coli, including the maintenance of plasmid pSC101. We have isolated and characterized a chromosomal mutation that compensates for the absence of IHF and allows the maintenance of wild-type pSC101 in him mutants, but does not restore IHF production. The mutation is recessive and was found to affect the gene topA, which encodes topoisomerase I, a protein that relaxes negatively supercoiled DNA and acts in concert with DNA gyrase to regulate levels of DNA supercoiling. A previously characterized topA mutation, topA10, could also compensate for the absence of IHF to allow pSC101 replication. IHF-compensating mutations affecting topA resulted in a large reduction in topoisomerase I activity, and plasmid DNA isolated from such strains was more negatively supercoiled than DNA from wild-type strains. In addition, our experiments show that both pSC101 and pBR322 plasmid DNAs isolated from him mutants were of lower superhelical density than DNA isolated from Him+ strains. A concurrent gyrB gene mutation, which reduces supercoiling, reversed the ability of topA mutations to compensate for a lack of him gene function. Together, these findings indicate that the topological state of the pSC101 plasmid profoundly influences its ability to be maintained in populations of dividing cells and suggest a model to account for the functional interactions of the him, rep, topA, and gyr gene products in pSC101 maintenance.

Chromosomal genes essential for stable maintenance of the mini-F plasmid in Escherichia coli

We have isolated mutants of Escherichia coli which do not support stable maintenance of mini-F plasmids (delta ccd rep+ sop+). These host mutations, named hop, were classified into five linkage groups on the E. coli chromosome. Genetic analyses of these hop mutations by Hfr mating and P1 transduction showed their loci on the E. coli genetic map to be as follows: hopA in the gyrB-tnaA region, hopB in the bglB-oriC region, hopD between 8 and 15 min, and hopE in the argA-thyA region. Kinetics of stability of the sop+ and delta sop mini-F plasmids in these hop mutants suggest that the hopA mutants are defective in partitioning of mini-F rather than in plasmid replication. The hopB, hopC, and hopD mutants were partially defective in replication of mini-F. The physical structure of the plasmid DNA was normal in hopA, B, C, and D mutants. Large amounts of linear multimers of plasmid DNA accumulated in mutants of the fifth linkage group (hopE). None of the hop mutations in any linkage group affected the normal growth of cells.