Amplification of different ColE1 plasmids in an Escherichia coli relA strain

Plasmid DNA vaccine vector design: impact on efficacy, safety and upstream production

Critical molecular and cellular biological factors impacting design of licensable DNA vaccine vectors that combine high yield and integrity during bacterial production with increased expression in mammalian cells are reviewed. Food and Drug Administration (FDA), World Health Organization (WHO) and European Medical Agencies (EMEA) regulatory guidance's are discussed, as they relate to vector design and plasmid fermentation. While all new vectors will require extensive preclinical testing to validate safety and performance prior to clinical use, regulatory testing burden for follow-on products can be reduced by combining carefully designed synthetic genes with existing validated vector backbones. A flowchart for creation of new synthetic genes, combining rationale design with bioinformatics, is presented. The biology of plasmid replication is reviewed, and process engineering strategies that reduce metabolic burden discussed. Utilizing recently developed low metabolic burden seed stock and fermentation strategies, optimized vectors can now be manufactured in high yields exceeding 2 g/L, with specific plasmid yields of 5% total dry cell weight.

Replication of plasmids during bacterial response to amino acid starvation

Amino acid starvation of bacterial cells leads to expression of the stringent (in wild-type strains) or relaxed (in relA mutants) response (also called the stringent or relaxed control, respectively). The stringent control is a pleiotropic response which changes drastically almost the entire cell physiology. Although starvation is a rule rather than an exception in natural environments of bacteria, and DNA replication is a fundamental cell process, until recently our knowledge about regulation of DNA replication in amino acid-starved cells has been unexpectedly poor. Within recent years the stringent control of DNA replication has been investigated mainly on plasmid models. Several plasmid replicons have been studied, including oriC plasmids, ColE1-like replicons, pSC101, F, R1, RK2, and R6K, and plasmids derived from bacteriophages lambda and P1. However, molecular models of replication regulation in amino acid-starved cells have been proposed to date only for lambda plasmids and ColE1-like replicons. Although further extensive studies are necessary in the understanding of molecular mechanisms of the stringent and relaxed control of replication of other plasmids, the results obtained to date (summarized and discussed in this review) show that studies on DNA replication in amino acid-starved cells may provide new insights into the regulatory mechanisms and lead to more general conclusions.

Replication of plasmids derived from P1, F, R1, R6K and RK2 replicons in amino acid-starved Escherichia coli stringent and relaxed strains

Replication of mini-plasmids derived from bacteriophage P1 and naturally existing plasmids F, R1, R6K and RK2 in otherwise isogenic relA+ and relA- Escherichia coli strains during amino acid starvation and limitation was investigated. Since it was previously demonstrated that inhibition of DNA synthesis or amplification of plasmid DNA may depend on the nature of deprived amino acid, we starved bacteria for five different amino acids. We found differential replication of all these plasmids but RK2 (which did not replicate at all in amino acid-starved bacteria) during the stringent and relaxed response. While in almost all cases plasmid DNA replication was inhibited during the stringent response irrespective of the nature of deprived amino acid, wild-type or copy-up mini-P1, mini-F and mini-R1 plasmids replicated in relA- bacteria depending on the kind of starvation. R6K-derived plasmids harbouring ori beta and gamma (but not those containing ori alpha, beta and gamma or only ori gamma) were able to replicate in relA- bacteria starved for all tested amino acids. Possible explanations for the mechanisms of regulation of replication of plasmids derived from P1, F, R1, R6K and RK2 during amino acid starvation are discussed. Our results also indicate that, like in the case of some other replicons, appropriate amino acid starvation or limitation may be used as a method for efficient amplification of plasmids derived from P1, F, R1 and R6K.

Differential amplification efficiency of pMB1 and p15A (ColE1-type) replicons in Escherichia coli stringent and relaxed strains starved for particular amino acids

It was demonstrated previously that ColE1-type plasmids, the most commonly used vectors in molecular cloning, can be amplified in amino acid-starved relA mutants of Escherichia coli. Subsequent studies demonstrated that replication of at least some plasmids during amino acid starvation depends not only on the host relA allele but also on temperature and on the nature of deprived amino acid. Therefore, we investigated efficiency of amplification of two types of ColE1 plasmids (pMB1- and p15A-derived replicons) in E. coli relA+ and relA- hosts starved for different amino acids at 30 degrees C, 37 degrees C and 43 degrees C. We found differential amplification efficiency of plasmids pBR328 (pMB1-derived replicon) and pACYC184 (p15A-derived replicon) in the relA mutant during starvation for particular amino acids. Although amplification of pBR328 was negligible in the relA+ host, significant increase in pACYC184 content was observed in this strain starved for some (but not all) amino acids. The amplification efficiency of pBR328 and pACYC184 was found to be dependent on temperature. These results indicate that for maximal amplification of particular plasmid appropriate amino acid starvation and optimal temperature should be chosen. Our findings are in agreement with recently proposed model of the regulation of ColE1-type plasmid replication in amino acid-starved E. coli cells.

Incompatibility of Escherichia coli rho mutants with plasmids is mediated by plasmid-specific transcription

The Escherichia coli rho-15 mutant (deficient in transcription termination) is known to be incompatible with pBR322 and other plasmids (J. S. Fassler, G. F. Arnold, and I. Tessman, Mol. Gen. Genet. 204:424-429, 1986). We show that failure of pBR322 to transform rho-15 is mediated by transcription from the tet promoter and readthrough from the tet gene into the rom region. Using an isopropyl-beta-D-thiogalactopyranoside-inducible promoter to replace the tet promoter, we have demonstrated that plasmid-specific transcription inhibits growth of the rho-15 host, possibly due to the expression of the Rom protein. The involvement of Rom protein in pBR322-rho-15 incompatibility is further indicated by the following two experiments. (i) Functional inactivation of the rom gene in pBR322 enabled plasmids to transform E. coli rho-15. (ii) Specific overexpression of the rom gene abolished plasmid transformation into E. coli rho-15. An rpoB8(Ts) mutant RNA polymerase which compensated for the termination defect in E. coli rho-15 also restored plasmid-host compatibility, suggesting that Rom-mediated plasmid-host incompatibility is linked to a defect in transcription termination.

Transcriptional pausing of RNA polymerase in the presence of guanosine tetraphosphate depends on the promoter and gene sequence

We have studied the response of the effector molecule guanosine 3',5'-bisdiphosphate (ppGpp) on RNA polymerase pausing during in vitro transcription elongation. Pausing was followed during single round extension of stalled ternary complexes excluding possible ppGpp effects on initiation. The ppGpp dependences of early pausing sites within different transcription systems controlled by promoters with known response to enhanced ppGpp levels in vivo were quantitatively characterized. Transcription of stable RNAs and mRNA genes were analyzed. In addition, the in vitro pausing behavior of two promoter variants directing the same sequence but differing in their in vivo ppGpp sensitivity were compared. In the presence of ppGpp we noted a slight general enhancement of specific pauses in all transcription systems. However, genes known to be under stringent or growth rate control in vivo revealed a notably stronger pausing enhancement. The sites of pausing are not changed by the presence of ppGpp but appear to be sequence-specific. The effect of ppGpp on the extent of pausing depends on the particular promoter and closely adjacent sequences that the RNA polymerase has passed during initiation. Pausing enhancement requires the presence of ppGpp during elongation but not during initiation. The results underline the importance of pausing for transcription regulation and offer a plausible explanation for inhibition of stable RNA expression under conditions of elevated concentrations of ppGpp.

Amplification of lambda plasmids in Escherichia coli relA mutants

It was previously demonstrated that, contrary to wild-type stringent (rel+) strains of Escherichia coli, in amino acid-starved relaxed (relA) mutants the replication of lambda plasmid proceeds for several hours. The replication leads to amplification of lambda plasmid DNA. Here, the conditions for this amplification have been optimized. The amplification efficiency depends on the temperature as well as on the nature of amino acid starvation, but it is only little or totally not dependent on the pH value of the medium in a range from 6.0 to 8.0. It seems that the most efficient amplification can be achieved by overnight cultivation of E. coli relA arg strain harbouring lambda plasmid at 36-39 degrees C in minimal medium containing Casamino acids. Under these conditions, the copy number of lambda plasmid increases from about 40 to about 300 per cell giving greater than 7-fold amplification.

Effect of increased ppGpp concentration on DNA replication of different replicons in Escherichia coli

The plasmids harbouring the relA gene under an inducible promoter allowed us to increase the guanosine 5'-diphosphate-3'-diphosphate (ppGpp) concentration in Escherichia coli cells without any starvation and thus, to directly investigate the effect of ppGpp on DNA replication. We studied all types of replicons which were investigated previously in amino acid-starved bacteria and found that ColE1, oriC, lambda plasmid and pSC101 but not RK2 replicons are sensitive to high ppGpp level. To our knowledge, this paper presents the first direct evidence that replication of most, but not all, replicons is dependent on ppGpp concentration and thus, is under stringent control.

Regulation of replication of plasmid pBR322 in amino acid-starved Escherichia coli strains

The stringent response causes inhibition of replication of plasmid pBR322 in amino acid-starved Escherichia coli cells whereas in relaxed mutants the replication of this plasmid proceeds for several hours. On the basis of density shift experiments and pulse-labelling experiments we showed that most of the pBR322 molecules begin replication during the relaxed response and the rate of plasmid DNA synthesis in unstarved and isoleucine-starved relA- bacteria is similar. We found that the Rom function plays a key role in the stringent control of plasmid pBR322 replication, as insertional inactivation of the rom gene causes amplification of pBR322rom- in both relA- and relA+ strains during amino acid starvation. Moreover, pUC19, which is a pBR322-derived plasmid lacking the rom gene, behaves like pBR322rom-, whereas introduction of the rom gene into the pUC19 replicon drives it into the pBR322 mode of replication in amino acid-starved bacteria. A model for the regulation of pBR322 plasmid DNA replication by Rom protein in amino acid-starved Escherichia coli strains is proposed.