DNA plasmid production in different host strains of Escherichia coli

Singer, Adam; Eiteman, Mark A.; Altman, Elliot

doi:10.1007/s10295-008-0522-7

Cited by 33 publications

(17 citation statements)

References 48 publications

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“…A few high yield fed-batch processes (0.5–2.2 g/L, up to 51 mg plasmid/g DCW) have been described that enable cost effective plasmid manufacture. These processes all couple reduced growth rate during plasmid production with high copy replication origins in cells grown at 37°C (Listner et al, 2006; Huber et al, 2005b)or 42°C (Singer et al, 2009; Carnes et al, 2006; Carnes and Williams, 2006; reviewed in Carnes and Williams, 2007). Reduced growth rate increases copy number (Lin-Chao and Bremer, 1986; Seo and Bailey, 1985), % supercoiling (O’Kennedy et al, 2003) and plasmid retention.…”

Section: Fermentation Processes For Plasmid Productionmentioning

confidence: 99%

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

Williams

Carnes

Hodgson

2009

Biotechnology Advances

155

131

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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 followon 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.

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Section: Fermentation Processes For Plasmid Productionmentioning

confidence: 99%

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

Williams

Carnes

Hodgson

2009

Biotechnology Advances

155

131

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“…A few high yield fed-batch plasmid fermentation processes (500-2,200 mg/L) have been described (Carnes et al, 2006;Listner et al, 2006;Mairhofer et al, 2010;Phue et al, 2008;Singer et al, 2009;Williams et al, 2009c). These processes all couple reduced growth rate (which generally increases copy number) with high copy replication origins (reviewed in Carnes and Williams, 2007).…”

Section: Introductionmentioning

confidence: 96%

Plasmid DNA fermentation strain and process‐specific effects on vector yield, quality, and transgene expression

Carnes

Luke

Vincent

et al. 2010

Biotech & Bioengineering

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Industrial plasmid DNA manufacturing processes are needed to meet the quality, economy, and scale requirements projected for future commercial products. We report development of a modified plasmid fermentation copy number induction profile that increases gene vaccination/therapy vector yields up to 2,600 mg/L. We determined that, in contrast to recombinant protein production, secretion of the metabolic byproduct acetate into the media had only a minor negative effect on plasmid replication. We also investigated the impact of differences in epigenetic dcm methylase-directed cytosine methylation on plasmid production, transgene expression, and immunogenicity. While Escherichia coli plasmid production yield and quality are unaffected, dcm- versions of CMV and CMV-HTLV-I R promoter plasmids had increased transgene expression in human cells. Surprisingly, despite improved expression, dcm- plasmid is less immunogenic. Our results demonstrate that it is critical to lock the plasmid methylation pattern (i.e., production strain) early in product development and that dcm- strains may be superior for gene therapy applications wherein reduced immunogenicity is desirable and for in vitro transient transfection applications such as AAV production where improved expression is beneficial.

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“…The common host for pDNA production is the bacterium Escherichia coli . Several E. coli strains have been reported for pDNA production, such as DH5α [2-4], DH5 [5], DH1 [6,7], JM108 [8]; SCS1-L [9] and DH10B [10]. Most of the strains used for pDNA production are selected by its previous use in laboratory-scale protocols [11,12] and may be not suitable for process-like conditions.…”

Section: Introductionmentioning

confidence: 99%

“…Aerobic acetate production -known as overflow metabolism- results from an imbalance between glycolysis and tricarboxylic acids cycle [13,14]. Some of the strains commonly used for pDNA production present elevated overflow metabolism, including E. coli DH5α and DH1 [9]. While the conventional way of avoiding overflow metabolism is reducing the glucose uptake in the so called fed-batch mode, the constant supply of glucose to the bioreactor requires additional equipment, results in a decrease of growth rate and frequently causes substrate gradients at the feeding zone in production bioreactors that trigger undesirable physiological effects [15-17].…”

Section: Introductionmentioning

confidence: 99%

Engineering Escherichia coli to increase plasmid DNA production in high cell-density cultivations in batch mode

Borja¹,

Mora

Barrón

et al. 2012

Microb Cell Fact

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BackgroundPlasmid DNA (pDNA) is a promising molecule for therapeutic applications. pDNA is produced by Escherichia coli in high cell-density cultivations (HCDC) using fed-batch mode. The typical limitations of such cultivations, including metabolic deviations like aerobic acetate production due to the existence of substrate gradients in large-scale bioreactors, remain as serious challenges for fast and effective pDNA production. We have previously demonstrated that the substitution of the phosphotransferase system by the over-expressed galactose permease for glucose uptake in E. coli (strain VH33) allows efficient growth, while strongly decreases acetate production. In the present work, additional genetic modifications were made to VH33 to further improve pDNA production. Several genes were deleted from strain VH33: the recA, deoR, nupG and endA genes were inactivated independently and in combination. The performance of the mutant strains was evaluated in shake flasks for the production of a 6.1 kb plasmid bearing an antigen gene against mumps. The best producer strain was cultivated in lab-scale bioreactors using 100 g/L of glucose to achieve HCDC in batch mode. For comparison, the widely used commercial strain DH5α, carrying the same plasmid, was also cultivated under the same conditions.ResultsThe various mutations tested had different effects on the specific growth rate, glucose uptake rate, and pDNA yields (YP/X). The triple mutant VH33 Δ (recA deoR nupG) accumulated low amounts of acetate and resulted in the best YP/X (4.22 mg/g), whereas YP/X of strain VH33 only reached 1.16 mg/g. When cultivated at high glucose concentrations, the triple mutant strain produced 186 mg/L of pDNA, 40 g/L of biomass and only 2.2 g/L of acetate. In contrast, DH5α produced only 70 mg/L of pDNA and accumulated 9.5 g/L of acetate. Furthermore, the supercoiled fraction of the pDNA produced by the triple mutant was nearly constant throughout the cultivation.ConclusionThe pDNA concentration obtained with the engineered strain VH33 Δ (recA deoR nupG) is, to the best of our knowledge, the highest reported for a batch cultivation, and its supercoiled fraction remained close to 80%. Strain VH33 Δ (recA deoR nupG) and its cultivation using elevated glucose concentrations represent an attractive technology for fast and efficient pDNA production and a valuable alternative to fed-batch cultivations of commercial strains.

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DNA plasmid production in different host strains of Escherichia coli

Cited by 33 publications

References 48 publications

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

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

Plasmid DNA fermentation strain and process‐specific effects on vector yield, quality, and transgene expression

Engineering Escherichia coli to increase plasmid DNA production in high cell-density cultivations in batch mode

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