High efficiency electroporation of intact Corynebacterium glutamicum cells

High-frequency electroporation of whole Corynebacterium glutamicum cells without enzymatic pretreatment was achieved. Under optimized conditions concerning growth stage, washing of cells, cell concentration and pulse parameter transformation efficiencies of far more than 10(7) transformants per microgram pWST4B plasmid DNA were reached. Using electroporation, linearised and subsequently religated plasmid as well as chimeric ligase reaction products were directly introduced into C. glutamicum with reasonable efficiencies. Electrotransformation efficiency was reduced about 10(5)-fold for plasmid DNA cycled through E. coli JM83. Restriction deficient mutants of C. glutamicum were isolated which could be efficiently transformed with foreign DNA.     

Intradermal delivery of interleukin-12 plasmid DNA by in vivo electroporation

Gene therapy depends on safe and efficient gene delivery. The skin is an attractive target for gene delivery because of its accessibility. Recently, in vivo electroporation has been shown to enhance expression after injection of plasmid DNA. In this study, we examined the use of electroporation to deliver plasmid DNA to cells of the skin in order to demonstrate that localized delivery can result in increased serum concentrations of a specific protein. Intradermal injection of a plasmid encoding luciferase resulted in low levels of expression. However, when injection was combined with electroporation, expression was significantly increased. When performing this procedure with a plasmid encoding interleukin-12, the induced serum concentrations of gamma-interferon were as much as 10 fold higher when electroporation was used. The results presented here demonstrate that electroporation can be used to augment the efficiency of direct injection of plasmid DNA to skin.     

Chemical and electroporated transformation of Edwardsiella ictaluri using three different plasmids

Transfer of DNA by conjugation has been the method generally used for genetic manipulation of Edwardsiella ictaluri because, previously, attempts to transform E. ictaluri by the uptake of naked DNA have apparently failed. We report here the successful transformation of seven strains of E. ictaluri using electroporation and two different chemical procedures [conventional calcium chloride (CaCl₂) and 'one-step' (polyethylene glycol, dimethyl sulfoxide and MgSO₄) protocols]. Seven strains of E. ictaluri were transformed using three different plasmids [pZsGreen, pUC18 and pET-30a(+)]. The highest transformation efficiency was achieved by electroporation (5.5±0.2 × 10⁴ transformants ng⁻¹ plasmid DNA) than with the CaCl₂ (8.1±6.1 × 10⁻¹ transformants ng⁻¹ plasmid) and the 'one-step transformation' protocol (2.5±2.7 transformants ng⁻¹ plasmid). An efficient transformation by electroporation required only 0.2 ng of plasmid compared with 200 ng required for the CaCl₂ and one-step protocols. The plasmids were stably maintained in E. ictaluri grown in the presence of antibiotic for 12 or more passages. The results of this study show that transformation of E. ictaluri by electroporation can be routinely used for the molecular genetic manipulation of this organism, and is a quicker and easier method than transformation performed by conjugation.     

Improved method for electroporation of Staphylococcus aureus

We have developed a significantly improved method for the electroporation of plasmid DNA into Staphylococcus aureus. The highest transformation efficiency achieved with this procedure was 4.0 x 10(8) transformants per microgram of plasmid pSK265 DNA. This represents a 530-fold improvement over the previously reported optimum efficiency of 7.5 x 10(5) transformants per microgram of plasmid DNA after electroporation of S. aureus cells [9]. Identical results were obtained when electrocompetent cells, which had been stored frozen at -80 degrees C, were used. The improved efficiency is due primarily to the use of a modified medium (designated as B2 medium) and secondarily to the use of 0.1-cm cuvettes. Several other plasmids (pI258, pMH109, and pSK270) were also electrotransformed into competent cells using our procedure, and for each plasmid, the transformation efficiency was significantly reduced compared to that observed when pSK265 DNA was used. With respect to plasmid pI258, the transformation efficiency was 3500-fold higher than that reported previously for transformation of this plasmid into S. aureus RN4220 [9]. The optimized electroporation procedure was less successful in transforming other staphylococci. Electrocompetent cells of S. aureus ATCC 29213 and S. epidermidis ATCC 12228 produced 5.5 x 10(5) and 5 x 10(3) transformants per microgram of pSK265 DNA, respectively.     

Transformation of Staphylococcus epidermidis and other staphylococcal species with plasmid DNA by electroporation

In this paper, the influence of various parameters on plasmid transformation by electroporation of Staphylococcus epidermidis Tü3298 was investigated. Cell growth conditions, various concentrations and forms of plasmid DNA, field strength, pulse duration and media for electroporation and regeneration were tested. In order to obtain optimal transformation efficiency, the cells were incubated for 30 min with DNA before pulsing. With the optimized procedure, other staphylococcal species such as S. aureus, S. staphylolyticus and S. carnosus were transformed with an efficiency up to 3 X 10(5) transformants per micrograms pC194 plasmid DNA.     

Electroporation of Haemophilus influenzae is effective for transformation of plasmid but not chromosomal DNA.

Electroporation of plasmid and chromosomal DNAs were tested in Haemophilus influenzae because of an interest in introducing DNA into mutants that are deficient in competence for transformation. The initial experiments were designed to investigate and optimize conditions for electroporation of H. influenzae. Plasmid DNA was introduced into the competence proficient strain Rd and its competence-deficient uptake mutants com-52, com-59, and com-88, and the recombination deficient mutant rec1. Plasmid DNA could also be electroporated into the non-transforming strains Ra, Rc, Re and Rf. Plasmid DNA without sequences that are involved in tight binding (uptake) of DNA by competent cells of H. influenzae Rd was electroporated into both competent and non-competent cells. Competent cells were several orders of magnitude less efficient than non-competent cells for electroporation of plasmid DNAs. Electroporation of H. influenzae chromosomal DNA was not successful. Low levels of integration of chromosomal markers were observed following electroporation and these could be ascribed to transformation. The treatment of cells with DNasel following electroporation separated the effects due to electroporation from those due to transformation. The DNasel treatment did not affect the efficiency of plasmid incorporation, but severely restricted effects due to natural DNA transformation.     

Efficient DNA transformation of Bradyrhizobium japonicum by electroporation.

Intact cells of Bradyrhizobium japonicum USDA 110 were transformed with a 30-kilobase plasmid to efficiencies of 10(6) to 10(7) transformants per microgram by high-voltage electroporation. The technique was reliable and simple, with single colonies arising from transformed cells within 5 days of antibiotic selection. Plasmid DNA from B. japonicum transformed the Bradyrhizobium (Arachis) sp. with high efficiency, while the same plasmid extracted from Escherichia coli transformed B. japonicum at very low efficiency. The electrical conditions that resulted in the highest efficiencies were high voltage (10.5 to 12.5 kV/cm) and short pulse length (6 to 7 ms). A linear increase in the number of transformants was observed as DNA concentration was increased over 4 orders of magnitude; saturation appeared to begin between 120 ng/ml and 1.2 micrograms/ml. This novel method of transformation should enhance B. japonicum genetic research by providing a valuable alternative to conjugal mating, which is currently the only efficient, widely used means of introducing DNA into this organism.     

Efficient DNA transformation of Bradyrhizobium japonicum by electroporation

Intact cells of Bradyrhizobium japonicum USDA 110 were transformed with a 30-kilobase plasmid to efficiencies of 10(6) to 10(7) transformants per microgram by high-voltage electroporation. The technique was reliable and simple, with single colonies arising from transformed cells within 5 days of antibiotic selection. Plasmid DNA from B. japonicum transformed the Bradyrhizobium (Arachis) sp. with high efficiency, while the same plasmid extracted from Escherichia coli transformed B. japonicum at very low efficiency. The electrical conditions that resulted in the highest efficiencies were high voltage (10.5 to 12.5 kV/cm) and short pulse length (6 to 7 ms). A linear increase in the number of transformants was observed as DNA concentration was increased over 4 orders of magnitude; saturation appeared to begin between 120 ng/ml and 1.2 micrograms/ml. This novel method of transformation should enhance B. japonicum genetic research by providing a valuable alternative to conjugal mating, which is currently the only efficient, widely used means of introducing DNA into this organism.     

Improved transformation of Pseudomonas putida KT2440 by electroporation

Summary An electric field-mediated transformation (i.e. electroporation) was performed to determine optimal conditions for P. putida transformation. The effects of culture age, electroporation buffer composition, electric field strength, pulse time constant and DNA concentration on transformation efficiency were examined. When plasmid DNA of 8 to 11 kb in size was used with an electroporation buffer containing 1 mM HEPES (pH 7.0), maximum transformation efficiency of 1.0 × 10⁷ transformants/g DNA was obtained at field strength of 12 kV/cm with pulse time of 2.5 millisecond. A linear increase in the number of transformants was observed as DNA concentration was increased over 4 orders of magnitude. A linear relationship was observed between growth phase and transformation efficiency up to OD₆₀₀ = 2.0. This reliable and simple method should be useful for introduction of plasmid DNA into intact P. putida cells.     

Transformation of bacteria with plasmid DNA by electroporation

The possibility of electric field-mediated transformation ("electroporation") of a gram-positive bacterium (Enterococcus faecalis) and two gram-negative bacteria (Escherichia coli and Pseudomonas putida) with plasmid DNA was investigated. E. faecalis protoplasts could be transformed by electroporation with a transformation frequency of 10(4) to 10(5) transformants/micrograms plasmid. Untreated--i.e., washed--cells of E. coli could be transformed with rates of 1 X 10(5) transformants/micrograms plasmid DNA. Transformation rates for P. putida cells were up to 3 X 10(4) if the method developed for E. coli was used. Detailed protocols for these systems, including the results of various optimization experiments, are given.     

Transformation ofHaemophilus influenzae following electroporation with plasmid and chromosomal DNA

Naturally transformable species, such asHaemophilus influenzae, have evolved systems for the efficient uptake and integration of DNA from the surrounding environment. We compared this competence-dependent DNA uptake system to electroporation, which has been widely used in the past few years to introduce DNA into cells, for transformingHaemophilus influenzae. Electroporation improved transformation efficiency when noncompetent cells were used and when DNA lackingHaemophilus-specific uptake sequences was used for transformation of competent cells. An increase in plasmid-to-chromosome recombination was seen when plasmid DNA containing chromosomal inserts was introduced into competent cells by electroporation, as observed previously for natural transformation.     

Electroporation-mediated transformation of lysostaphin-treated Clostridium perfringens

A reliable and efficient method has been developed for the electroporation-mediated transformation of Clostridium perfringens with plasmid DNA. Transformation of vegetative cells of C. perfringens strain 13 with the 7.9-kb Escherichia coli-C. perfringens shuttle plasmid pHR 106 required pretreatment with lysostaphin (2 to 20 micrograms/ml) for 1 h at 37 degrees C. Cells harvested early in the logarithmic stage of growth were transformed more efficiently than cells at other growth phases. The transformation frequency increased with the DNA concentration, to a saturating level at 5 to 10 micrograms DNA/ml. The transformation frequency was proportional to the field strength and time constant of the electroporation pulse; however, the field strength was a far more important parameter. A cell density between 1 x 10(8) and 5 x 10(8) cells/ml proved to be optimal for transformation. The procedure was capable of generating up to 3.0 x 10(5) transformants per micrograms DNA. The potential value of the method for the cloning of C. perfringens genes was demonstrated by the cloning of the clostridial tetracycline-resistance determinant, tetP, from the E. coli recombinant plasmid pJIR71, into C. perfringens strain 13.     

Transformation of Intact Aspergillus niger by Electroporation

A new rapid transformation system for Aspergillus niger that uses electroporation to render intact germinating conidia permeable to DNA is described. The transformant colonies appeared earlier than transformants obtained by the protoplast-forming method. Without pretreatment of the conidia the transformation frequencies were 1.2 colonies per μg of integrative vector and 100 colonies per μg of plasmid DNA. When the conidia were treated with a dilute solution of fungal cell wall lytic enzyme, the frequency of transformation was increased by approx. 2-fold when using two vectors. Southern blot analysis of genomic DNA and restriction endonuclease-digested DNA from a random sample of transformants showed homologous and nonhomologous integration of the integrative vector into the genome, as is also observed with the protoplast-forming method. In transformation with the plasmid vector, the transformant DNA was shown to be mostly maintained in free form with minimal integration into the chromosome when transformed by either intact electroporation or the conventional method.     

Use of polymerase chain reaction and electroporation of Escherichia coli to monitor the persistence of extracellular plasmid DNA introduced into natural soils.

A modified protocol for DNA amplification by polymerase chain reaction (PCR) coupled with laser densitometric determination of the amount of PCR products, which allowed quantitation of target sequence numbers in soil extracts, was developed. The method was applied to monitor target loss during incubation of purified plasmid DNA in natural nonsterile soils. It revealed soil-specific kinetics of target loss. After 60 days, 0.2, 0.05, and 0.01% of the initially added nahA genes on plasmids were detectable by PCR in a loamy sand soil, a clay soil, and a silty clay soil, respectively. Electroporation of Escherichia coli was used in parallel to quantitate plasmid molecules in soil extracts by their transforming activity. It was found that transformation by electroporation was about 20 times more efficient and much less inhibited by constituents of soil extracts than transformation of Ca(2+)-treated cells (G. Romanowski, M.G. Lorenz, G. Sayler, and W. Wackernagel, Appl. Environ. Microbiol. 58:3012-3019, 1992). By electroporation, greater than 10,000-fold plasmid loss was monitored in nonsterile soils. Transforming activity was found up to 60 days after inoculation of the soils. The studies indicate that PCR and electroporation are sensitive methods for monitoring the persistence of extracellular plasmid DNA in soil. It is proposed that plasmid transformation by electroporation can be used for the monitoring in soil and other environments of genetically engineered organisms with recombinant plasmids. The data suggest that genetic material may persist in soil for weeks and even for months after its release from cells.     

Genetic transformation of Streptococcus thermophilus by electroporation

A rapid and convenient electroporation procedure was developed for the genetic transformation of intact cells of Streptococcus thermophilus with various species of plasmid DNA. Transformation frequency was influenced by the capacitance and voltage selected for electric pulsing, the pH and composition of the electroporation medium and the molecular mass of the transforming DNA. Electroporation is a simple and effective technique to introduce plasmid DNA into S. thermophilus and useful in the development of recombinant DNA technology for this important industrial microorganism.     

Optimization of electrotransformation conditions for Propionibacterium acnes

Propionibacterium acnes has been known to be involved in the pathology of acne. However, the definite mechanism in the development of acne and the inflammation are unknown. For P. acnes, a transformation method has not been established, although it is believed to be a basic tool for gene manipulation. This study attempted to develop a P. acnes transformation method by using electroporation. Various parameters were used to develop and optimize the transformation of P. acnes. Among them two factors were crucial in the transformation for P. acnes: one was the E. coli strain from which the plasmid DNA had been isolated and the other the growth temperature of P. acnes-competent cells. It was essential to prepare plasmid DNA from a dam(-) E. coli strain, ET12567. When plasmid DNAs isolated from the other E. coli strains such as JM109 and HB101 were tested, transformation efficiency was extremely low. When P. acnes cells were cultivated at 24 degrees C for competent cell preparation, transformation efficiency increased considerably. When plasmid DNA isolated from a dam(-) mutant strain of E. coli was used for transformation of P. acnes which had been grown at 24 degrees C, maximum transformation efficiency of 1.5 x 10(4) transformants per mug of plasmid DNA was obtained at a field strength of 15 kV/cm with a pulse time of 3.2 ms. This is believed to be the first report on the transformation of P. acnes which can be employed for gene manipulations including knock-out of specific genes.     

Optimization of technical conditions for the transformation of Lactobacillus acidophilus strains by electroporation

AIMS: To optimize the conditions for electroporating foreign plasmid DNA into Lactobacillus acidophilus ATCC 43121. METHODS AND RESULTS: The conditions of electroporation were optimized to improve the transformation efficiency. Plasmid pNZ123 containing multicloning site and chloramphenicol resistance was employed to construct a cloning vector. The optimum electroporation conditions for the maximum transformation efficiency were a pulse strength of 12.5 kV cm(-1), a pulse number of 10, a pulse interval of 500 ms, and pNZ123 plasmid DNA concentration of 25 ng microl(-1). Under the optimum conditions the transformation efficiency of L. acidophilus ATCC 43121 was 1.84 +/- 0.13 x 10(4) (+/- standard error of measurements) CFU per mug of plasmid DNA. Other strains of L. acidophilus showed transformation efficiencies ranging from 1.38 +/- 0.02 x 10(4) to 9.32 +/- 0.54 x 10(4) under these conditions. A green fluorescent protein (GFP) was successfully expressed and detected by fluorescence microscopy when the pKU::slpA-GFP, pNZ123 containing GFP gene, was transformed in L. acidophilus ATCC 43121 under the optimum conditions. CONCLUSIONS: The results suggest that electrical parameters, antibiotic concentration, and host specificity play important roles to determine transformation efficiency of lactobacilli. The optimum conditions for the transformation of L. acidophilus ATCC 43121 may be applied to improve transformation efficiency of other lactobacilli. SIGNIFICANCE AND IMPACT OF THE STUDY: The optimized conditions for electrotransformation may provide a mean to improve the introduction of foreign DNA into L. acidophilus to be used as a vehicle for a heterologous protein expression.     

Properties of electroporation-mediated DNA transfer in Escherichia coli

Efficient and reproducible DNA-transfection was attained in E. coli, by electroporation. The yield of the transfectants was affected by pretreatment of the recipient cells as well as by the composition of the electroporation medium. Using a single pulse procedure, relationships among the electrical parameters, the transfection efficiency, and the cellular viability were investigated in 10 mM Tris-HCl buffer (pH 7.5) containing 5% sucrose. Certain sodium salts (e.g., citrate, phosphate, and sulfate) were promotive, whereas Mg2+, DEAE-dextran, and polyvinylpyrrolidone were inhibitory to the transfection. Heterologous nucleic acids (native DNA, denatured DNA, and tRNA) exerted only a marginal effect on transfection with a viral replicative-form DNA. The efficiency of DNA transfer was affected by culture conditions, and bacteria grown at a higher temperature were more competent. The electroporation system was more efficient than an improved CaCl2 method, not only in transfection with viral single- and double-stranded DNAs, but also in transformation with plasmid DNAs.     

Factors affecting the electroporation of Bacillus subtilis

Bacillus subtilis 168 trp ^- was found to be transformable with the tetracycline resistance plasmid pAB124 by electroporation of whole cells, inconsistently and at very low frequencies. Supplementation of the growth medium with glycine, or particularly DL-threonine, produced cells that could be electrotransformed much more efficiently at frequencies up to 2.5 X 10³ transformants per μg plasmid DNA. Transformation was optimal with cells grown in medium containing a racemic mixture of the D- and L-isomers of threonine, and no transformants were obtained when pure forms of the D- and L-threonine isomers were used. The cell walls of B. subtilis grown in the presence or absence of D-, L- and DL-threonine had a similar amino acid composition which did not include threonine. A more complex biochemical explanation of the enhancement of electroporation by growth in DL-threonine is likely, and this is discussed. Lysozyme treatments to weaken the cell wall and possibly mimic the effect of DL-threonine did not yield any transformants. The effects of buffer composition and culture incubation time were also determined and the electroporation protocol optimized accordingly. The response of a range of other B. subtilis strains to electroporation by the method produced was found to be variable. In all cases, transformation was verified by recovery of the plasmid DNA from putative transformants.