Evaluating metabolic stress and plasmid stability in plasmid DNA production by Escherichia coli

In the context of recombinant DNA technology, the development of feasible and high-yielding plasmid DNA production processes has regained attention as more evidence for its efficacy as vectors for gene therapy and DNA vaccination arise. When producing plasmid DNA in Escherichia coli, a number of biological restraints, triggered by plasmid maintenance and replication as well as culture conditions are responsible for limiting final biomass and product yields. This termed "metabolic burden" can also cause detrimental effects on plasmid stability and quality, since the cell machinery is no longer capable of maintaining an active metabolism towards plasmid synthesis and the stress responses elicited by plasmid maintenance can also cause increased plasmid instability. The optimization of plasmid DNA production bioprocesses is still hindered by the lack of information on the host metabolic responses as well as information on plasmid instability. Therefore, systematic and on-line approaches are required not only to characterise this "metabolic burden" and plasmid stability but also for the design of appropriate metabolic engineering and culture strategies. The monitoring tools described to date rapidly evolve from laborious, off-line and at-line monitoring to online monitoring, at a time-scale that enables researchers to solve these bioprocessing problems as they occur. This review highlights major E. coli biological alterations caused by plasmid maintenance and replication, possible causes for plasmid instability and discusses the ability of currently employed bioprocess monitoring techniques to provide information in order to circumvent metabolic burden and plasmid instability, pointing out the possible evolution of these methods towards online bioprocess monitoring.     

Fructose transport by Escherichia coli

The utilization of fructose by Escherichia coli involves, as first step, the uptake of the sugar, normally via the phosphoenolpyruvate-dependent phosphotransferase system (PTS). This fructose-specific PTS differs in several ways from that effecting the uptake of other sugars that also possess the 3,4,5-D-arabino-hexose configuration: these differences are discussed. Mutants that lack the genes ptsI and ptsH, which specify components of the PTS common to most PT-sugars, can mutate further to regain the ability to utilize fructose when this is present in relatively high concentration (i.e. greater than 2 mM) in the medium. Some of the properties of this unusual uptake system is discussed.     

Supercondensed structure of plasmid pBR322 DNA in an Escherichia coli DNA topoisomerase II mutant

An unusual structural component, supercondensed pBR322 DNA, has been found in plasmid pBR322 DNA samples isolated from a DNA topoisomerase II mutant of Escherichia coli, SD108 (topA+, gyrB225). The supercondensed pBR322 DNA moved faster than supercoiled pBR322 DNA as a homogeneous band in agrose gels when the DNA samples were analysed by electrophoresis. The mobility of the supercondensed DNA was not substantially affected by chloroquine intercalation. The supercondensed pBR322 DNA migrated as a high density "third DNA band" when the samples were subjected to caesium chloride/ethidium bromide gradient equilibrium centrifugation. The unusual pBR322 DNA visualized by electron microscopy was a globoid-shaped particle. These observations suggest that the pBR322 plasmid can assume a tertiary structure other than a supercoiled or relaxed structure. DNA topoisomerases may be involved in the supercondensation of plasmid DNA and chromosomal DNA.     

Degradation of Escherichia coli chromosomal and plasmid DNA in serum

Incubation of serum-sensitive [3H]thymidine labelled Escherichia coli PC2166 (RSF1030) and E. coli AM1281 (pBR322) harbouring small plasmids (mol. wt 5.5 X 10(6) and 2.6 X 10(6] in serum resulted in killing of 99.9% of the bacteria within 15 min and in the release of 85% of the radioactivity into the medium after 1 h incubation. The fate of chromosomal and plasmid DNA during incubation of the bacteria in serum was analysed by measurement of the amount of DNA-associated radioactivity, by TCA precipitation, by agarose gel electrophoresis and by the capacity of DNA to transform competent acceptor bacteria. Chromosomal DNA and high molecular weight plasmid DNA were rapidly degraded after 1 h incubation of bacteria in serum. However, low molecular weight plasmid DNA was virtually unaffected and remained physicochemically as well as biologically intact during up to 4 h of incubation of bacteria in serum.     

DNA sequencing of a pathogenicity-related plasmid of an avian septicemic Escherichia coli strain

A 43-MDa conjugative plasmid isolated from an avian septicemic Escherichia coli (APEC) strain possessing genes related to the adhesion and invasion capacities of in vitro-cultured cells was sequenced. The results demonstrated that the 43-MDa plasmid harbors bacterial pathogenicity-related sequences which probably allow the wild-type pathogenic strain to adhere to and invade tissues and to cause septicemia in poultry. The existence of homology sequences to sequences belonging to other human pathogenic Enterobacteriaceae like Escherichia coli O157:H7, Shigella and Salmonella was also observed. The presence of these sequences in this plasmid could indicate that there is horizontal genetic transfer between bacterial strains isolated from different host species. In conclusion, the present study suggests that APEC strains harbor high-molecular weight plasmids that present pathogenicity-related sequences and that these are probably responsible for the pathogenicity exhibited by these strains. The presence of human pathogenicity-associated sequences in APEC conjugative plasmids suggests that these strains could represent a zoonotic risk.     

Mutagenic effects of gamma-rays on plasmid DNA in Escherichia coli

A purified and dried DNA of plasmid pKO482 (galK+) is 10 times more resistant to the inactivating action of 60Co-gamma-rays than that of lambda phage. gamma-Irradiation of the plasmid DNA induces forward mutations of galK, the frequency of which increases linearly with the dose. The efficiency of the mutagenic action of gamma-rays on the plasmid galK locus is 10(-12) per 1 rad and per 1 base pair. The mutagenic effect of gamma-radiation but slightly depends upon bacterial recA+ gene and upon the SOS-repair system induced by UV-irradiation of the recipient cells. It is assumed that the premutational lesions induced in the purified DNA by the direct effect of gamma-radiation are fixed into mutations by misreplication.     

Cellular response to DNA damage is enhanced by the pR plasmid in mouse cells and in Escherichia coli.

The pR plasmid, which enhances the survival of Escherichia coli C600 exposed to UV light by induction of the SOS regulatory mechanism, showed the same effect when it transformed mouse LTA cells (tk-, aprt-). With Tn5 insertion mutagenesis which inactivates UV functions in the pR plasmid, we recognized two different regions of the plasmid, uvp1 and uvp2. These pR UVR- mutants exhibited the same effect in LTA transformed cells, demonstrating that resistance to UV light, carried by the pR plasmid, was really due to the expression of these two regions, which were also in the mouse cells. Statistical analysis showed that the expression of the uvp1 and uvp2 regions significantly increased (P less than 0.01) the survival upon exposure to UV light in mouse cells and bacteria. These results might suggest the presence of an inducible repair response to DNA damage in mouse LTA cells.     

Optimization of routine transformation of Escherichia coli with plasmid DNA

Methods to optimize resources and transformation efficiency of routine daily transformations of DH1 Escherichia coli prepared by three calcium chloride methods were investigated and compared with polyethylene glycol and Hanahan methods. The benefit of a heat-shock step, a preplating incubation step to allow expression of antibiotic resistance, use of log phase bacteria and prolonged storage of bacteria were investigated using pBR322 and pUC18 plasmid DNAs. Bacteria prepared by CaCl2 methods consistently gave efficiencies of 4 x 10(6) transformants/microgram of plasmid DNA or better and were overall the most labor- and resource-efficient methods. Use of log phase bacteria, a heat shock and an incubation step were found to be beneficial for freshly prepared bacteria for all methods. Prolonged storage of up to 30 days of bacteria prepared by the CaCl2 methods was beneficial, resulting in a sustained increase in transformation efficiency when selection was by ampicillin but not when by tetracycline resistance. Also found when using bacteria stored three days or longer was an increased transformation efficiency of stationary vs. log phase bacteria and an unchanged or even increased efficiency when the preplating incubation step was omitted. The Hanahan methods were the most labor and resource intensive and routinely gave efficiencies of 2 x 10(7). Higher efficiencies of 10(8) were obtained only with repeated trial and error and were not consistently reproducible. The polyethylene glycol method consistently gave efficiencies of 2 x 10(7), and bacteria could easily be prepared daily or frozen with a minimal decrease in efficiency.     

Adenosine monophosphate-induced amplification of ColE1 plasmid DNA in Escherichia coli

ColE1 plasmid copy number was analyzed in relaxed (relA) and stringent (relA(+)) Escherichia coli cells after supplementation of culture media with adenosine monophosphate (AMP). When a relaxed E. coli strain bearing ColE1 plasmid was cultured in LB medium for 18 h and induced with AMP for 4h, the plasmid DNA yield was significantly increased, from 2.6 to 16.4 mgl(-1). However no AMP-induced amplification of ColE1 plasmid DNA was observed in the stringent host. Some plasmid amplification was observed in relA mutant cultures in the presence of adenosine, while adenine, ADP, ATP, ribose, potassium pyrophosphate and sodium phosphate caused a minor, if any, increase in ColE1 copy number. A mechanism for amplification of ColE1 plasmid DNA with AMP in relA mutant bacteria is suggested, in which AMP interferes with the aminoacylation of tRNAs, increases the abundance of uncharged tRNAs, and uncharged tRNAs promote plasmid DNA replication. According to this proposal, in relA(+) cells, the AMP induction could not increase ColE1 plasmid copy number because of lower abundance of uncharged tRNAs. Our results suggest that the induction with AMP can be used as an effective method of amplification of ColE1 plasmid DNA in relaxed strains of E. coli.     

Enhanced production of plasmid DNA by engineered Escherichia coli strains

Escherichia coli strains VH33 (PTS? GalP? strain displaying a strongly reduced overflow metabolism) and VH34 (additionally lacking the pyruvate kinase A) were evaluated for the production of a plasmid DNA (pDNA) vaccine. The parent (W3110) and mutant strains were cultured using 10 g of glucose/L. While the specific growth rates of the three strains were similar, they presented differences in the accumulation of acetate. W3110 accumulated up to 4 g/L of acetate, VH33 produced 1.4 g/L, and VH34 only 0.78 g/L. VH33 and VH34 produced 76% and 300% more pDNA than W3110. Moreover, VH34 demanded 33% less oxygen than VH33 and W3110, which can be advantageous for large-scale applications.     

Acclimation and repair of DNA damage in recombinant bioluminescent Escherichia coli

AIMS: The aim of this study is to understand different adaptive responses in bacteria caused by three different mutagens, namely, an intercalating agent, an alkylating agent and a hydroxylating agent, and the repair systems according to the type of DNA damage, that is, DNA cross-linking and delayed DNA synthesis, alkylation and hydroxylation of DNA. A recombinant bioluminescent Escherichia coli, DPD2794 with the recA promoter fused to luxCDABE originating from Vibrio fischeri, was used in this study. METHODS AND RESULTS: The recombinant bioluminescent E. coli strain DPD2794, containing a recA promoter fused to luxCDABE from V. fischeri, was used to detect adaptive and repair responses to DNA damage caused by mitomycin C (MMC), and these responses were compared with those when the cells were induced with N-methyl-N-nitro-N-nitrosoguanidine (MNNG) and hydrogen peroxide (H2O2). The response ratio between the induced samples and that of the controls decreased suddenly when the induced culture was used in further inductions, indicating a possible adaptive response to DNA damage. DNA damage, or the proteins produced, because of MMC addition does not appear to be completely resolved until the seventh sub-culture after the initial induction, whereas simple damage, such as the base modification caused by MNNG and H2O2, appears to be repaired rapidly as evidenced by the quick recovery of sensitivity. CONCLUSIONS: These results suggest that it takes more time to completely repair DNA damage caused by MMC, as compared with a simple repair such as that required for the damage caused by MNNG and H2O2. Therefore, repair of the damage caused by these three mutagens is controlled by different regulons, even though they all induced the recA promoter. SIGNIFICANCE AND IMPACT OF THE STUDY: Using a bioluminescent E. coli harbouring a recA promoter-lux fusion, it was found that different adaptive responses and repair systems for DNA damage caused by several mutagens exists in E. coli.