Molecular cloning of a human gene that regulates chromosome condensation and is essential for cell proliferation.

The tsBN2 cell line, a temperature-sensitive (ts) mutant of baby hamster kidney cell line BHK21/13, seems to possess a mutation in the gene that controls initiation of chromosome condensation. At the nonpermissive temperature (39.5 degrees C), the chromatin of tsBN2 cells is prematurely condensed, and the cells die. Using tsBN2 cells as a recipient of DNA-mediated gene transfer, we investigated a human gene that is responsible for regulation of chromosome condensation and cell proliferation. We found that the human gene complementing the tsBN2 mutation resides in the area of the 40- to 50-kilobase HindIII fragment, derived from HeLa cells. Based on this finding, we initiated cloning of a human gene complementing the tsBN2 mutation. From lambda and cosmid libraries carrying partial digests of DNA from the secondary transformants, the 41.8-kilobase HindIII fragment containing the human DNA was isolated. The cloned human DNA was conserved in ts+ transformants through primary and secondary transfections. Two cosmid clones convert the ts- phenotype of tsBN2 cells to ts+ with more than 100 times a higher efficiency, compared with cases of transfection with total human DNA. Thus, the cloned DNA fragments contain an active human gene that complements the tsBN2 mutation.     

The transformation of the unicellular alga Chlamydomonas reinhardtii by electroporation

The cell wall-lacking mutant CW-15 of the unicellular green alga Chlamydomonas reinhardtii was transformed by electroporation using plasmid pCTVHyg, which was constructed with the hygromycin phosphotransferase gene hpt as the selective marker and the Tn5 transposon of Escherichia coli under the control of the virus SV40 early gene promoter. Under optimal conditions (10(6) mid-exponential cells/ml; electric field strength 1 kV/cm; and pulse length 2 ms), the transformation yielded 10(3) HygR transformants per 10(6) recipient cells. The exogenous DNA integrated into the nuclear genome of Ch. reinhardtii was persistently inherited through more than 350 cell generations. The advantages of this system for the transformation of Ch. reinhardtii with heterologous genes are discussed.     

Isolation and characterization of a mildly thermophilic nonsulfur purple bacterium containing bacteriochlorophyll b

A method for transformation of whole Bacillus amyloliquefaciens cells by electroporation was developed. The procedure is as efficient as the protoplast transformation method, resulting in up to 10(5) transformants/micrograms plasmid DNA, but requires less effort and time. Cells for electroporation were grown to late exponential phase in a rich medium supplemented with 0.25 M sucrose, washed with and resuspended in 0.25 M sucrose, 1 mM HEPES, 1 mM MgCl2, 10% (v/v) glycerol, pH 7.0, at 3-5 x 10(10) cells/ml for storage at -80 degrees C. The highest transformation frequency was obtained at 7.5 kV/cm with a 25 microF capacitor. The transformation efficiency increased linearly with DNA concentration at least over the range 10 ng-12.5 micrograms/ml. Transformations with ligated DNA and of industrial strains were also successful. In addition, B. subtilis cells treated as above could be transformed by electroporation, resulting in 10(4) transformants/micrograms DNA at 12.5 kV/cm.     

DH10B菌株高效电转化条件探究

以pUC19、pECBAC1、pCLD04541DNA以及3个不同大小的BACDNA为材料,研究了E.coli DH10B菌株在5个不同脉冲电场下的转化效率。研究发现,随着DNA片段大小的增加,最高转化效率和最适场强迅速减小。利用DH10B细胞转化pUC19 DNA的最适场强是21kV/cm,而190kb BAC DNA仅为13kV/cm;在最适场强下,40kb BAC DNA的转化效率约是190kb BAC DNA的50倍。通过大量数据绘制了不同因素影响下转化效率的变化曲线,优化了E.coli DH10B菌株电转化条件,为质粒的重组转化以及大片段基因组文库的构建奠定了基础。     

Electrical behavior and pore accumulation in a multicellular model for conventional and supra-electroporation

Extremely large but very short (20 kV/cm, 300 ns) electric field pulses were reported recently to non-thermally destroy melanoma tumors. The stated mechanism for field penetration into cells is pulse characteristic times faster than charge redistribution (displacement currents). Here we use a multicellular model with irregularly shaped, closely spaced cells to show that instead overwhelming pore creation (supra-electroporation) is dominant, with field penetration due to pores (ionic conduction currents) during most of the pulse. Moreover, the model's maximum membrane potential (about 1.2 V) is consistent with recent experimental observations on isolated cells. We also use the model to show that conventional electroporation resulting from 100 microsecond, 1 kV/cm pulses yields a spatially heterogeneous electroporation distribution. In contrast, the melanoma-destroying pulses cause nearly homogeneous electroporation of cells and their nuclear membranes. Electropores can persist for times much longer than the pulses, and are likely to be an important mechanism contributing to cell death.     

Construction of a hybrid plasmid capable of replication in Amycolatopsis mediterranei

A new plasmid, pA387, has been isolated from "Amycolatopsis sp." (DSM 43387). This plasmid could be isolated from liquid culture as well as mycelium from agar plates by a modified procedure. Plasmid pA387 is about 29.6 kb and can be cured at low frequency by protoplasting and ethidium bromide and heat treatment. Hybridization experiments showed that this plasmid is present in free form and does not integrate into the chromosome. A hybrid plasmid was constructed by cloning a 5.1-kb fragment of pA387 into the Escherichia coli vector pDM10. This hybrid plasmid, termed pRL1, could be transformed into Amycolatopsis mediterranei and A. orientalis by electroporation. A transformation frequency of 2.2 x 10(3) transformants per micrograms of DNA at 12.5 kV/cm and a pulse duration of 10.8 ms was obtained in A. mediterranei, whereas 1.1 x 10(5) transformants per microgram of DNA were obtained at a field strength of 7.5 kV/cm and a pulse duration of 7.6 ms in A. orientalis. Plasmid pRL1 is the first hybrid plasmid which could be used successfully for the transformation of A. mediterranei. The plasmid has a rather high copy number, is genetically stable, and can be easily reisolated from A. mediterranei. Plasmid pRL1 will be useful for further construction of a shuttle vector for E. coli and A. mediterranei and becomes the basis for the development of gene cloning techniques in Amycolatopsis spp.     

Construction of a hybrid plasmid capable of replication in Amycolatopsis mediterranei.

A new plasmid, pA387, has been isolated from "Amycolatopsis sp." (DSM 43387). This plasmid could be isolated from liquid culture as well as mycelium from agar plates by a modified procedure. Plasmid pA387 is about 29.6 kb and can be cured at low frequency by protoplasting and ethidium bromide and heat treatment. Hybridization experiments showed that this plasmid is present in free form and does not integrate into the chromosome. A hybrid plasmid was constructed by cloning a 5.1-kb fragment of pA387 into the Escherichia coli vector pDM10. This hybrid plasmid, termed pRL1, could be transformed into Amycolatopsis mediterranei and A. orientalis by electroporation. A transformation frequency of 2.2 x 10(3) transformants per micrograms of DNA at 12.5 kV/cm and a pulse duration of 10.8 ms was obtained in A. mediterranei, whereas 1.1 x 10(5) transformants per microgram of DNA were obtained at a field strength of 7.5 kV/cm and a pulse duration of 7.6 ms in A. orientalis. Plasmid pRL1 is the first hybrid plasmid which could be used successfully for the transformation of A. mediterranei. The plasmid has a rather high copy number, is genetically stable, and can be easily reisolated from A. mediterranei. Plasmid pRL1 will be useful for further construction of a shuttle vector for E. coli and A. mediterranei and becomes the basis for the development of gene cloning techniques in Amycolatopsis spp.     

Isolation of a human X chromosome-linked gene essential for progression from G1 to S phase of the cell cycle

The tsBN462 cell line, a temperature-sensitive (ts) mutant isolated from the hamster cell line, BHK21/13, cannot progress into S phase at 39.5 degrees C, following the release from isoleucine deprivation. The mutant cells were transfected with high molecular weight (HMW) DNA from human KB cells, and several human DNA bands were found to be conserved through three cycles of ts+ transformation. Conserved human DNA was isolated from the cosmid library of the secondary ts+ transformant (K-1-1), using 32P-labelled total human DNA as a probe. The isolated human DNA covers about 70 kb of human DNA flanked with hamster DNA, and originates from the human X chromosome. The middle part (56 kb) of the isolated human DNA was conserved through the primary, secondary and tertiary ts+ transformation, without gross rearrangement.     

High-efficiency gene transfection by in situ electroporation of cultured cells

It is demonstrated in this study that high-efficiency gene transfection can be obtained by directly electroporating cultured mammalian cells in their attached state using a pulsed radio-frequency (RF) electric field. A plasmid DNA containing the reporter gene beta-gal was introduced into COS-M6 cells and CV-1 cells using this in situ electroporation method. At the optimal electric field strength (1.2 kV/cm), we found that over 80% of the M6 cells took up and expressed the beta-gal gene with a cell survival rate of about 50%. In contrast, the transfection efficiency was less than 20% when the M6 cells were electroporated in suspension. It was shown that CV-1 cells could also be electroporated highly efficiently using the in situ method. Furthermore, we have measured the time required to express the beta-gal gene after the plasmid DNA was introduced. We found that the percentage of cells expressing beta-gal reached a peak value about 10 h after electroporation. This time-course was the same for both attached and suspended cells, suggesting that the observed difference in transfection efficiency was mainly the result of effects of the detachment treatment on the electroporation process rather than on the gene expression.     

Diverse effects of nanosecond pulsed electric fields on cells and tissues

The application of pulsed electric fields to cells is extended to include nonthermal pulses with shorter durations (10-300 ns), higher electric fields (< or =350 kV/cm), higher power (gigawatts), and distinct effects (nsPEF) compared to classical electroporation. Here we define effects and explore potential application for nsPEF in biology and medicine. As the pulse duration is decreased below the plasma membrane charging time constant, plasma membrane effects decrease and intracellular effects predominate. NsPEFs induced apoptosis and caspase activation that was calcium-dependent (Jurkat cells) and calcium-independent (HL-60 and Jurkat cells). In mouse B10-2 fibrosarcoma tumors, nsPEFs induced caspase activation and DNA fragmentation ex vivo, and reduced tumor size in vivo. With conditions below thresholds for classical electroporation and apoptosis, nsPEF induced calcium release from intracellular stores and subsequent calcium influx through store-operated channels in the plasma membrane that mimicked purinergic receptor-mediated calcium mobilization. When nsPEF were applied after classical electroporation pulses, GFP reporter gene expression was enhanced above that observed for classical electroporation. These findings indicate that nsPEF extend classical electroporation to include events that primarily affect intracellular structures and functions. Potential applications for nsPEF include inducing apoptosis in cells and tumors, probing signal transduction mechanisms that determine cell fate, and enhancing gene expression.     

Electroporation of extraneous proteins into CHO cells: Increased efficacy by utilizing centrifugal force and microsecond electrical pulses

A novel electroporation system employing an oscillating electric pulse and centrifugal force was used to introduce extraneous proteins into CHO cells. Following the electrical pulse, the compression and subsequent rebound induced by the centrifugal acceleration and deceleration, respectively, enhanced protein uptake, presumably by a hydrodynamic pumping of extracellular solutions through the permeabilized membrane. Protein uptake was quantitated by measuring the amount of radiolabeled, extraneous, CHO proteins introduced into unlabeled CHO cells. The amount of protein introduced into electroporated CHO cells was enhanced up to four-fold by a combination of electric pulse and centrifugal force compared to that introduced by electric pulse only. The optimum gradient of centrifugal force (GCF, temporal change of centrifugal force) was 590 and -470 g/s during acceleration and deceleration, respectively. The optimum electric field was 5 kV/cm with a 30-microsecond pulse length. At this optimum electroporation condition, approximately 5 pg of proteins (up to 200 kDa molecular weight) were introduced per CHO cell. These same settings also permitted electroporation of other membrane impermeable substances including propidium iodide and ethidium bromide. Introduction of extraneous materials into the cytoplasm during electroporation was confirmed by the ability of anti alpha-tubulin to stain the microtubules and propidium iodide and ethidium bromide to stain the nuclei. Cells electroporated with optimum device settings exhibited no significant decrease in clonogenic survival.     

A multi-channel electroporation microchip for gene transfection in mammalian cells

We developed a multi-channel electroporation microchip made of polydimethylsiloxane (PDMS) and glass for gene transfer in mammalian cells. This chip produces multiple electric field gradients in a single microchip by varying the lengths of the microchannels from 2 to 4 cm. Electric fields of 0.65, 0.57, 0.49, 0.41, and 0.33 kV/cm were simultaneously produced in a single chip when the voltage of 1.3 kV was applied. We transferred enhanced green fluorescent protein genes (pEGFP) into HEK-293 and CHO cells, which were cultured within the microchannels. The feasibility of our device was demonstrated because it was able to produce five different transfection rates and survival rates at different electric fields produced in a single microchip. This system is expected to optimize the experimental conditions in gene transfection research more easily and faster than conventional electroporation methods.     

Quantitative study of electroporation-mediated molecular uptake and cell viability

Electroporation's use for laboratory transfection and clinical chemotherapy is limited by an incomplete understanding of the effects of electroporation parameters on molecular uptake and cell viability. To address this need, uptake of calcein and viability of DU 145 prostate cancer cells were quantified using flow cytometry for more than 200 different combinations of experimental conditions. The experimental parameters included field strength (0.1-3.3 kV/cm), pulse length (0.05-20 ms), number of pulses (1-10), calcein concentration (10-100 microM), and cell concentration (0.6-23% by volume). These data indicate that neither electrical charge nor energy was a good predictor of electroporation's effects. Instead, both uptake and viability showed a complex dependence on field strength, pulse length, and number of pulses. The effect of cell concentration was explained quantitatively by electric field perturbations caused by neighboring cells. Uptake was shown to vary linearly with external calcein concentration. This large quantitative data set may be used to optimize electroporation protocols, test theoretical models, and guide mechanistic interpretations.     

Genetic transformation of intact Lactococcus lactis subsp. lactis by high-voltage electroporation

To apply recombinant DNA techniques for genetic manipulation of the industrially important lactococci, an efficient and reliable high-frequency transformation system must be available. High-voltage electric pulses have been demonstrated to enhance uptake of DNA into protoplasts and intact cells of numerous gram-negative and gram-positive microorganisms. The objective of this study was to develop a system for electroporating intact cells of Lactococcus lactis subsp. lactis LM0230 (previously designated Streptococcus lactis LM0230) with a commercially available electroporation unit (BTX Transfector 100; BTX, Inc., San Diego, Calif.). Parameters which influenced the efficiency of transformation included growth phase and final concentration of cells, ionic strength of the suspending medium, concentration of plasmid DNA, and the amplitude and duration of the pulse. Washed suspensions of intact cells suspended in deionized distilled water were subjected to one high-voltage electric pulse varying in voltage (300 to 900 V corresponding to field strengths of 5 to 17 kV/cm) and duration (100 microseconds to 1 s). Transformation efficiencies of 10(3) transformants per microgram of DNA were obtained when dense suspensions (final concentration, 5 x 10(10) CFU/ml) of stationary-phase cells were subjected to one pulse with a peak voltage of 900 V (field strength, 17 kV/cm) and a pulse duration of 5 ms in the presence of plasmid DNA. Dilution of porated cells in broth medium followed by an expression period of 2 h at 30 degrees C was beneficial in enhancing transformation efficiencies. Plasmids ranging in size from 9.8 to 30.0 kilobase pairs could be transformed by this procedure.     

Genetic transformation of intact Lactococcus lactis subsp. lactis by high-voltage electroporation.

To apply recombinant DNA techniques for genetic manipulation of the industrially important lactococci, an efficient and reliable high-frequency transformation system must be available. High-voltage electric pulses have been demonstrated to enhance uptake of DNA into protoplasts and intact cells of numerous gram-negative and gram-positive microorganisms. The objective of this study was to develop a system for electroporating intact cells of Lactococcus lactis subsp. lactis LM0230 (previously designated Streptococcus lactis LM0230) with a commercially available electroporation unit (BTX Transfector 100; BTX, Inc., San Diego, Calif.). Parameters which influenced the efficiency of transformation included growth phase and final concentration of cells, ionic strength of the suspending medium, concentration of plasmid DNA, and the amplitude and duration of the pulse. Washed suspensions of intact cells suspended in deionized distilled water were subjected to one high-voltage electric pulse varying in voltage (300 to 900 V corresponding to field strengths of 5 to 17 kV/cm) and duration (100 microseconds to 1 s). Transformation efficiencies of 10(3) transformants per microgram of DNA were obtained when dense suspensions (final concentration, 5 x 10(10) CFU/ml) of stationary-phase cells were subjected to one pulse with a peak voltage of 900 V (field strength, 17 kV/cm) and a pulse duration of 5 ms in the presence of plasmid DNA. Dilution of porated cells in broth medium followed by an expression period of 2 h at 30 degrees C was beneficial in enhancing transformation efficiencies. Plasmids ranging in size from 9.8 to 30.0 kilobase pairs could be transformed by this procedure.     

Simplified cosmid vectors for gene transfer to cultured mammalian cells: isolation of the gene for elongation factor 2 from the mouse

We constructed a series of cosmid vectors that carry two tandemly arranged lambda cos and mammalian selective markers. We achieved cloning efficiencies of 1-3 x 10(7) and greater than 10(6) colony-forming units per microgram of insert, using a cloned 42-kb BamHI fragment and Sau3AI fragments of 40-50 kb from mouse genomic DNA, respectively. The modified Ca.phosphate coprecipitation method [Ishiura et al., Mol. Cell. Biol. 2 (1982) 607-616] considerably improved the efficiency of gene transfer of cosmids into cultured mammalian cells: when genes encoding thymidine kinase from herpes simplex virus type 1 and aminoglycoside 3'-phosphoribosyltransferase from Tn5 were selected, the efficiencies of gene transfer into mouse L cells were about 10(-6). The mouse genome contains one copy of the functional gene for elongation factor 2 (EF2) per haploid genome and multiple copies of the EF2-related gene. We isolated a cosmid that carried functional full-length mouse EF2 from a cosmid library of L-cell genomic DNA, by colony hybridization and subsequent gene transfer of candidate cosmids into human 143B cells.     

Assessment of electroporation by flow cytometry

BACKGROUND: Electroporation accomplishes transient permeabilization of cells and thus aids in the uptake of drugs. The method has been employed clinically in the treatment of dermatological tumors with bleomycin. The conditions of electroporation are still largely empirical and information is lacking as to the interrelationships among voltage pulse height, pulse number and toxicity, cell permeation, drug uptake, and effects on drug toxicity. We used propidium iodide (PI) and flow cytometry to define cell permeation into cytoplasmic and nuclear compartments to determine the improvements of drug toxicity that can be accomplished by electroporation. METHODS: Human squamous carcinoma cells of defined TP53 status and normal human epithelial cells were subjected to electroporation using a square wave pulse generator in the range of 0-5,000 V/cm. Flow cytometry served to establish entry of the drug reporter, PI, into the cytoplasm and nucleus. A dye staining method served to establish cell survival and to determine the toxicity of bleomycin alone, electroporation alone, and electroporation with bleomycin. RESULTS: The electric field intensity (EFI) required to produce 50% permeabilization (EP(50)) is cell type dependent. The EP(50) varied from 1,465 to 2,027 V/cm. An EFI below 900 V/cm is growth stimulatory whereas an EFI in excess of 1,000 V/cm is growth inhibitory. An EFI of 1,000 V/cm is sufficient to increase bleomycin toxicity by a factor of 2-3. A differential electroporation efficiency is observed between normal and tumor cells. CONCLUSIONS: Tumor cells can be targeted preferentially at electroporation voltages where normal cells are less permeable.     

Electroporation-mediated transformation of Aeromonas hydrophila

A strain of Aeromonas hydrophila producing copolyesters of 3-hydroxybutyrate and 3-hydroxyhexanoate, abbreviated as PHBHHx, was successfully transformed by electroporation. The plasmid used was a broad host range plasmid pBBR1MCS. Electroporation conditions were varied systemically to develop an electroporation protocol. The optimal yield of transformant was approximately 4x10(2) CFU/microg DNA at 12.5 kV/cm and 1000 Omega, resulting in a time constant of approximately 5 ms. The A. hydrophila transformants expressed plasmid-encoded resistance to chloromphenicol. Plasmid DNA in the A. hydrophila transformant was stably maintained. This is the first report of transformation of bacteria A. hydrophila.     

Electroporation of lymphoid cells: factors affecting the efficiency of transfection

We have increased the efficiency of electroporation of lymphoid cells over fifty fold by optimising several biological and electrical parameters. Under optimised conditions, the electroporation efficiency was comparable to that reported for other cell types. Actively dividing cells were crucial for high transient transfection signal. The two most important electrical parameters were high capacitance (960 microF) and moderate decay constants in the range of 10-15 ms. The optimal field strength depended on the cell line, but was in the range 0.6-1 kV/cm. Administering the pulse in medium lacking serum gave higher efficiency than when isotonic salt solution was used and the transfection signal was depressed if cells and DNA were allowed to incubate for several minutes either before or after the pulse. Electroporation was carried out at room temperature and there was no advantage in using low temperatures (0-4 degrees C). When electroporated cells were grown in conditioned medium, the signal was enhanced about two fold depending on the source of the conditioned medium.