Nucleated cells response to protein electroinsertion

Application of an electrical pulse field at a strength slightly below the value required for electroporation to a suspension of red blood cells in the presence of membrane xenoproteins leads to the insertion of those proteins in the erythrocyte plasma membrane. This observation is extended to nucleated cells. In the presence of glycophorin A, application of such pulses leads to the insertion of 10(4)-10(5) molecules of glycophorin A per cell in CEM-CM3, Hela S3, and bovine CD8+ T cells. Electroinserted glycophorin A is detected by flow cytometry using anti-glycophorin monoclonal antibodies. The survival of the cells subjected to electroinsertion was 55% for CEM-CM3 cells, 69% for Hela S3 cells, and 65% for CD8+ T cells. Cells cultured after electroinsertion lost the electroinserted glycophorin A, with two different rates, by a temperature and cell type-dependent mechanism. During the first 2 h after electroinsertion, the CD8+ T cells lost 12.5% of the inserted glycophorin A per h, the CEM-CM3 cells lost 7.7% per h, whereas the Hela S3 cells lost only 0.8% of the inserted protein per h. After 2 h, the rate increased substantially, to 41.7% per h for the CD8+ T cells, 13.5% for the CEM-CM3 cells, and 8.9% for the Hela S3 cells. Cytochalasin D efficiently inhibited the disappearance of electroinserted glycophorin A during the first 2 h after electroinsertion only.

Gene replacement in Lactobacillus helveticus

An efficient method for gene replacement in Lactobacillus helveticus CNRZ32 was developed by utilizing pSA3 as an integration vector. This plasmid is stably maintained in CNRZ32 at 37 degrees C but is unstable at 45 degrees C. This method consisted of a two-step gene-targeting technique: (i) chromosomal integration of a plasmid carrying an internal deletion in the gene of interest via homologous recombination and (ii) excision of the vector and the wild-type gene via homologous recombination, resulting in gene replacement. By using this procedure, the chromosomal X-prolyl dipeptidyl aminopeptidase gene (pepXP) of CNRZ32 was successfully inactivated.

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.

Study of mechanisms of electric field-induced DNA transfection. V. Effects of DNA topology on surface binding, cell uptake, expression, and integration into host chromosomes of DNA in the mammalian cell

Neumann and coworkers (Neumann, E., M. Schaefer-Ridder, Y. Wang, and P. H. Hofschneider. 1982. EMBO J. 1:841-845) have shown that the efficiency of pulsed electric field (PEF)-induced DNA transfection of mouse L-cells by the thymidine kinase gene is several times higher for the linear DNA than for the closed circular DNA. Transfection of Escherichia coli bacteria by several plasmids indicates that the transfection efficiency was much higher for the closed circular/supercoiled (sc-) and circular/relaxed (cr-) DNA than for the linearized (In-) DNA (Xie, T. D., L. Sun, H. G. Zhao, J. A. Fuchs, and T. Y. Tsong. 1992. Biophys. J. 63:1026-1031). To resolve these conflicting observations, we have systematically examined electrotransfection of NIH3T3 mouse fibroblast by the plasmids, pRSVcat, pRSVneo, and pRSVgpt. Mg(2+)-facilitated surface binding of DNA before, and DNA uptake by 3T3 cells after treatment with PEF, were monitored by 3H-labeled plasmids. Transfection efficiency was evaluated by both the transient expression of chloramphenicol acetyltransferase (cat) activity 2-3 days after, and the permanent expression of neomycin phosphotransferase (neo) and xanthine-guanine phosphoribosyltransferase (gpt) genes in the transformants 2 weeks after the PEF treatment. Our results indicate that cell surface binding and PEF-induced cell uptake of DNA did not depend on the topology of DNA. However, both the transient and the permanent expression of the plasmids were three to five times more efficient for the cr-DNA and the sc-DNA than for the in-DNA. These results indicate that electrotransfection of cells involves several steps: the cation-dependent binding of DNA to the cell surface, the electric field-driven DNA entry into the cells, the transient expression of DNA, and the integration of DNA into the host chromosomes. For understanding mechanisms of electrotransfection, only the DNA binding to the cell surface and the electric field assisted membrane-crossing of DNA are relevant. Both the expression of the loaded DNA and the DNA integration into the host chromosomes depend more on the properties of the cell and its interactions with a foreign gene. Since these properties and interactions will be similar irrespective of the method chosen to facilitate DNA transfer, they are not relevant for the study of mechanisms of electrotransfection. Our results also support the idea that the PEF-induced cellular uptake of DNA is mainly by the electrophoresis of the surface bound DNA across the plasma membrane.

Genetic manipulation of Campylobacter: evaluation of natural transformation and electro-transformation

Two methods, natural transformation and electro-transformation, for the introduction of DNA into nine strains of Campylobacter jejuni were compared. Both methods were successful with a limited number of strains. Natural transformation was efficient only for the introduction of C. jejuni chromosomal DNA, while electro-transformation was also applicable for the introduction of Escherichia coli-derived vector DNA into at least one C. jejuni strain. The efficiency of DNA recombination after entry was determined using C. jejuni chromosomal DNA containing disrupted flagellin genes of C. jejuni or suicide vectors containing a portion of these genes. In the latter case, DNA recombination occurred with as little as 200-bp homology present, indicating that only short homologous DNA segments are required.

Characterisation of two identical independent non-homologous integration sites in mouse embryonic stem cells

On analysis of 46 Geneticin-resistant (GtR) cell lines, derived by electroporation of mouse embryonic stem (ES) cells with a promoterless neo vector, we observed that in two independently derived cell lines, the vector had integrated into the same locus. The sequence flanking the vector integration site in both cell lines was cloned and sequenced. The vector had integrated into a 3 to 6-bp region in both cell lines. No homology is observed between the integration site sequence and the vector sequence.

Protein phosphatase activity is required for light-inducible gene expression in maize

Chlorophyll accumulation and photosynthetic gene activation are two hallmarks of greening process in etiolated maize leaves in response to light signals. However, very little is known about the relevant signal transduction pathways mediating these essential processes that lead to photosynthetic competence. It is shown here that a potent and specific protein phosphatase 1 (PP1) and PP2A inhibitor, okadaic acid, efficiently blocks chlorophyll accumulation induced by light in etiolated maize leaves. In addition, the light-inducible expression of two photosynthetic fusion genes can be specifically suppressed by the structurally unrelated PP1 and PP2A inhibitors, okadaic acid and calyculin A, using a sensitive and physiological maize protoplast transient assay. The specificity and effective concentration of the inhibitors in vivo and in vitro strongly suggest that PP1 is required for transmitting light signals. Intriguingly, several partial cDNAs encoding novel as well as conserved PP1 can be identified in maize leaves using the polymerase chain reaction. Studies of chimeric promoters indicate that PP1 activity is essential for the interaction of multiple regulatory elements. Although PP1 and PP2A have been implicated in the suppression of gene activity in yeast and animals, the present data indicate that PP1 appears to be essential for light-dependent gene activation in plants.

Transformation of Mycoplasma pneumoniae with Tn4001 by electroporation

Mycoplasma pneumoniae was transformed with the Staphylococcus aureus transposon Tn4001 by electroporation. A transformation frequency of 10(-3) to 10(-5)/colony-forming unit was observed using 30.0 microgram plasmid DNA and 10(7)-10(8) M. pneumoniae colony-forming units. DNA hybridization analyses using standard and pulsed field agarose gel electrophoresis confirmed chromosomal insertion of the transposon, apparently by a transpositional mechanism into random sites. These studies demonstrate the functionality of Tn4001 in M. pneumoniae and suggest its potential as a genetic tool in this mycoplasma.

Characterization of a restriction barrier and electrotransformation of the cyanobacterium Nostoc PCC 7121

We have investigated host restriction as a barrier to transformation and developed a method for gene transfer into the previously untransformable, heterotrophic cyanobacterium Nostoc PCC 7121. A restriction endonuclease, designated Nsp 7121I, has been partially purified by phosphocellulose chromatography of Nostoc cell extracts. Comparisons of Nsp 7121I digests of bacteriophage lambda and plasmid DNAs with computer-generated restriction fragment profiles showed that Nsp 7121I is an isoschizomer of restriction endonucleases, such as Asu I, Nsp 7524IV, Sau 96I, and Eco 47II, that recognize the sequence GGNCC. Cleavage by Nsp 7121I within this sequence was confirmed by sequence analysis of DNA fragments cleaved at a unique Nsp 7121I site. These data further suggested that cleavage occurs after the first G (5'-G/GNCC-3') in this site to generate a three base 5' overhang. Nsp 7121I degraded all plasmids used in previous transformation attempts but modification of these DNA molecules by Eco 47II methylase effectively prevented digestion by Nsp 7121I. Plasmids premethylated by passage through Escherichia coli carrying a plasmid encoded Eco 47II methylase have now been used in an electroporation procedure to transform Nostoc PCC 7121 to neomycin resistance at frequencies as high as one transformant per 10(3) viable cells. Transformation, and stable replication within Nostoc of one of the transforming plasmids (pRL25), was confirmed by recovery of pRL25, in its original form, from transformants. Conjugal transfer of pRL25 from E. coli into Nostoc was also possible but at much lower efficiency than by electroporation. These findings establish the basis for genetic analysis of Nostoc PCC 7121, from which genes for photosynthetic electron transport have been cloned.

The contribution of lactococcal starter proteinases to proteolysis in cheddar cheese

The contribution of the lactococcal proteinase to proteolysis and flavor development in Cheddar cheese was investigated using the starter strains Lactococcus lactis ssp. lactis UC317, its proteinase-negative derivative FH041, and variants of UC317 modified in proteinase production, location, and specificity. Lactococcus lactis ssp. lactis FH041 was transformed by electroporation with plasmids pCI3601, pCI3602, or pNZ521. Plasmids pCI3601 and pCI3602 harbor the cloned proteinase genes of L. lactis ssp. lactis UC317 on a high copy number vector and, as such, encode an increased concentration of cell wall-associated and secreted enzymes, respectively. Plasmid pNZ521 contains the cloned proteinase genes from Lactococcus lactis ssp. cremoris SK11. Assessment of proteolysis and flavor development in Cheddar cheese made with these strains revealed that starter proteinases are required for the accumulation of small peptides and free amino acids in Cheddar cheese. Proteolysis was not enhanced by an approximately threefold increase in concentration of the lactococcal proteinase. The strain in which the proteinase remained attached to the cell wall appeared to contribute more to proteolysis than the strain that secreted the enzyme. Water-soluble peptides unique to Lactococcus lactis ssp. cremoris SK11 and L. lactis ssp. lactis UC317 were detected by PAGE and HPLC, respectively. Sensory evaluation showed that the flavors of all cheeses made with proteinase-positive starters were similar, but cheeses made with proteinase-negative starters lacked flavor.

Genetic transformation of Porphyromonas gingivalis by electroporation

Porphyromonas gingivalis was transformed by electroporation using the DNA of plasmid pE5-2, or its derivative, pYT7. Prior to transformation, pE5-2 was transferred from Escherichia coli to P. gingivalis strains by conjugation (mobilization with R751), and the plasmid DNA was purified from the P. gingivalis transconjugants. Transformation occurred when the recipient strain and the donor strain from which the plasmid DNA was purified were homologous. If they were heterologous, transformation did not take place or did so at a very low frequency. This suggested that a restriction-modification system is present in P. gingivalis strains. Plasmid pYT7 was derived by removing an 8.0 kb AvaI fragment from pE5-2 that was purified from P. gingivalis cells. It has several single-cutting restriction sites such as EcoRI, AvaI and ClaI usable for gene cloning, though it was not stable enough in P. gingivalis cells, probably because the rep gene was derived from a relatively distant species, Bacteroides eggerthii.

A ribozyme that enhances gene suppression in tobacco protoplasts

Site-directed mutagenesis has been used to produce two hammerhead ribozyme molecules targeting the chloramphenicol acetyltransferase gene (CAT). One ribozyme has a single catalytic domain between two 12-nucleotide arms that can hybridize 5' and 3' of the GUC target site of the CAT RNA transcript. The second ribozyme is a full-length antisense RNA with four catalytic domains inserted along the length, each targeting a specific GUC site within the CAT mRNA. Our results show that both ribozymes can produce almost equivalent rates of cleavage of the CAT mRNA in vitro (T1/2 of 18 or 15 min, respectively). In tobacco protoplasts we show consistently greater gene suppression in the presence of the long ribozyme molecule, compared with the equivalent antisense (22% gene reduction for antisense compared with 44% with the long ribozyme). These results suggest that hammerhead ribozymes may be developed for the inactivation of gene activity in plant cells.

Mutagenic specificity of the (+)anti-diol epoxide of dibenz[a,j]anthracene in the supF gene of an Escherichia coli plasmid

This study was designed to examine the mutagenic specificity of (+)anti-dibenz[a,j]anthracene 3,4-diol-1,2-epoxide ((+)anti-DB[a,j]A-DE) in SOS-induced repair-proficient Escherichia coli ES87 (delta pro-lac, strA)/F' (pro+, lac1Q, lac1am26, lacZ delta M15). The plasmid pUB3, which contains the mutation target gene, supF, was modified with (+)anti-DB[a,j]A-DE in vitro (two to five adducts/plasmid) and then transformed into bacteria by electroporation. The spontaneous mutation frequency for unmodified pUB3 in uninduced cells was about 2 x 10(-6) and for SOS-induced cells, about 8 x 10(-6). The spontaneous supF- mutations were primarily insertions, deletions, and frameshifts. The mutation frequency for (+)anti-DB[a,j]A-DE-modified pUB3 was about 8 x 10(-6) and about 32 x 10(-6) for uninduced cells and SOS-induced cells, respectively. (+)anti-DB[a,j]A-DE induced primarily point mutations in supF in SOS-induced cells. GC-->AT transitions were the major mutations observed in SOS-induced cells (37%). GC-->TA (21%) and GC-->CG (8.6%) transversion mutations were also observed, whereas mutations at AT base pairs were rare (1.9%). Furthermore, a large number of tandem GC/GC-->AT/AT transition mutations were also observed (about 15% of all mutations in SOS-induced cells). Taken together, single and tandem GC-->AT mutations accounted for slightly over half (about 51%) of the mutations observed in SOS-induced cells. These results demonstrated that (+)anti-DB[a,j]A-DE was mutagenic in repair-proficient E. coli; however, unlike other polycyclic aromatic hydrocarbons that induce primarily transversion mutations, (+)anti-DB[a,j]A-DE caused mostly GC-->AT transitions.

Development of pronuclei in pig oocytes activated by a single electric pulse

Pig oocytes were matured in vitro in a modified M-199 medium for 44 h, subjected to electrical stimulation and scored for activation 6 h later. Sham pulsed oocytes, exposed to electroporation medium and an a.c. field, did not develop the female pronucleus any more frequently than occurs spontaneously (8.3% within 50 h of culture). However, a single d.c. pulse proved extremely efficient in activating pig oocytes. Pulses of 0.75-1.65 kV cm-1 lasting 30 or 100 microseconds activated at least 90% of matured oocytes. The developmental pathway taken by the activated oocytes depended on the parameters of the pulse. The lowest effective stimulation (0.45 and 0.60 kV cm-1 for 30 microseconds) frequently produced oocytes that remained in pre-pronuclear stages of activation (29.4 and 42.3%, respectively). Extrusion of the second polar body and creation of one pronucleus was the most frequent type of activation (in up to 88.2% among the activated oocytes). The strongest stimulations used (1.05-1.65 kV cm-1 for 100 microseconds) often yielded oocytes that failed to extrude the second polar body and formed two or more pronuclei (up to 56.3%). Under optimal stimulation (0.75 kV cm-1), the activated oocytes proceed synchronously to interphase of the first mitotic division. Anaphase II is reached within 30 min and telophase Ii at 1 h after application of the pulse. The second polar body is extruded about 2 h after activation. Well-defined swelling pronuclei were found in oocytes 5-6 h after activation. The relationship between the stage of oocyte maturation and susceptibility to activation was investigated. The period of culture in which the oocytes develop the activation competence (32-36 h of culture) overlapped with the period in which the oocytes complete meiosis (28-38 h). This suggests that ageing in meiotic arrest is not essential for pig oocytes to become activated by electric pulses. Activation of pig oocytes was accompanied by release of cortical granules. In sections of control (metaphase II) oocytes, an average of 7.3 intact cortical granules per 10 microns of overlying cytoplasmic membrane was found. This number dropped to 1.5 in 10 microns within 30 min after the pulse.