Integration of foreign DNA following microinjection of tobacco mesophyll protoplasts

Summary DNA from a bacterial plasmid containing the T-DNA border sequences of Agrobacterium tumefaciens was transferred into the nucleus or the cytoplasm of tobacco mesophyll protoplasts by microinjection. Following culture in hanging drops, some of these protoplasts produced calli containing the foreign DNA sequences. Evidence for the presence of the injected plasmid DNA in these calli was provided by Southern hybridization analysis. The results demonstrated that random portions of the bacterial plasmid were linked to plant DNA and that integration did not occur at the T-DNA borders present on the injected plasmid. The average number of integrated copies ranged from less than one to 1–2 per tobacco genome. The frequency of integration averaged 14% with intranuclear injections compared to 6% with cytoplasmic injections. With further refinement, the use of microinjection may allow the introduction of many different types of genetic elements into plants.     

High efficiency transient and stable transformation by optimized DNA microinjection into Nicotiana tabacum protoplasts

An efficient system has been established that allows well controlledDNA microinjection into tobacco (Nicotiana tabacum) mesophyllprotoplasts with partially regenerated cell walls and subsequentanalysis of transient as well as stable expression of injectedreporter genes in particular targeted cells or derived clones.The system represents an effective tool to study parametersimportant for the successful transformation of plant cells bymicroinjection and other techniques. Protoplasts were immobilizedin a very thin layer of medium solidified with agarose or alginate.DNA microinjection was routinely monitored by coinjecting FITC-dextranand aimed at the cytoplasm of target cells. The injection procedurewas optimized for efficient delivery of injection solution intothis compartment. Cells were found to be at the optimal stagefor microinjection about 24 h after immobilization in solidmedium. Embedded cells could be kept at this stage for up to4 d by incubating them at 4 C in the dark. Within 1 h successfuldelivery of injection, solution was routinely possible into20–40 cells. Following cytoplasmic coinjection of FITC-dextran and pSHI913,a plasmid containing the neo (neomycin phosphotransferase II)gene, stably transformed, paromomycin-resistant clones couldbe recovered through selection. Transgenic tobacco lines havebeen established from such clones. Injection solutions containingpSHI913 at a concentration of either 50 µg ml^–1or 1 mg ml^–1 have been tested. With 1 mg ml^–1 plasmidDNA the percentage of resistant clones per successfully injectedcell was determined to be about 3.5 times higher. Incubationof embedded protoplasts at 4C before microinjection was foundto reduce the percentage of resistant clones obtained per injectedcell Protoplasts were immobilized above a grid pattern and the locationof injected cells was recorded by Polaroid photography. Thefate of particular targeted cells could be observed. Isolationand individual culture of clones derived from injected cellswas possible. Following cytoplasmic coinjection of FITC-dextranand 1 mg ml^–1 plasmid DNA on average about 20% of thetargeted cells developed into microcalli and roughly 50% ofthese calli were stably transformed. Transient expression ofthe firefly luciferase gene (Luc) was nondestructively analysed24 h after injection of pAMLuc. Approximately 50% of the injectedcells that were alive at this time point expressed the Luc genetransiently. Apparently, stable integration of the injectedgenes occurred in essentially all transiently expressing cellsthat developed into clones. Key words: DNA microinjection, firefly luciferase, FITCdextran, Nicotiana tabacum, protoplast transformation     

Cloned mice derived from somatic cell nuclei

In 1997, a cloned sheep "Dolly" was produced by nuclear transfer of somatic cell. The first birth of cloned mice derived from some somatic cells were succeeded in 1998. At present, it is shown that somatic cells, cumulus cells, fibroblasts and Sertoli cells can be used to the study of cloned animal as nuclear donor. In this study investigation was designed to compare with efficiency on the production of cloned embryos by using the microinjection and the electrofusion methods for nuclear transfer. Oocyte enucleation was performed with a micromanipulator. The oocyte was held by holding pipette, and was enucleated using a beveled pipette. Microinjection method: Cell's nucleus injection was carried out by piezo-micromanipulator. Cytochalasin B treated cumulus cell was aspirated into a injection pipette, and was broken its plasma membrane using the injection pipette. Then, the cumulus cell was injected into the enucleated ooplasm directly. Electrofusion method: The cell was aspirated into a beveled pipette, and then an aspirated cell was inserted into perivitelline space. Then, the pair of enucleated oocyte and cell was fused using electrical cell fusion apparatus. The reconstituted embryos were activated after nuclear transfer using St2+. Reconstituted embryos had been produced by the microinjection showed the embryonic development to over 8-cell stages. But, the rate of fragmentation of reconstituted embryos by the microinjection showed a little high rate in comparison with the electrofusion. When some reconstituted embryos by the microinjection were transplanted to pseudopregnant females' oviduct, 9 fetuses were observed at 14 days post coitum.     

Plant transformation by microinjection techniques

Several techniques have been developed for introducing cloned genes into plant cells. Vectorless delivery systems such as PEG-mediated direct DNA uptake (e.g. Pasz-kowski et al. 1984), electroporation (e.g. Shillito et al. 1985), and fusion of protoplasts with liposomes (Deshayes et al. 1985) are routinely used in many experiments (see several chapters of this issue). A wide range of plant species, dicotyledonous as well as monocotyledonous, has been transformed by these vectorless DNA transfer systems. However, the availability of an efficient protoplast regeneration system is a prerequisite for the application of these techniques. For cells with intact cell walls and tissue explants the biological delivery system of virulent Agrobacterium species has been routinely used (for review see Fraley et al. 1986). However, the host range of Agrobacterium restricts the plant species, which can be transformed using this vector system. In addition, all these methods depend on selection systems for recovery of transformants. Therefore a selection system has to be established first for plant species to be transformed. The microinjection technique is a direct physical approach, and therefore host-range independent, for introducing substances under microscopical control into defined cells without damaging them. These two facts differentiate this technique from other physical approaches, such as biolistic transformation and macroinjection (see chapters in this issue). In these other techniques, damaging of cells and random manipulation of cells without optical control cannot be avoided so far. In recent years microinjection technology found its application in plant sciences, whereas this technique has earlier been well established for transformation of animal tissue culture cells (Capecchi 1980) and the production of transgenic animals (Brin-ster et al. 1981, Rusconi and Schaffner 1981). Furthermore, different parameters affecting the DNA transfer via microinjection, such as the nature of microinjected DNA, and cell cycle stage, etc, have been investigated extensively in animal cells (Folger et al. 1982, Wong and Capecchi 1985), while analogous experiments on plant cells are still lacking.     

Cytological studies on mitochondria-induced cytoplasmic transformation in yeasts

In Saccharomyces cerevisiae, protoplasts from respiratory-deficient(rho^–) cytoplasmic mutant cells were transformed intorespiratory-sufficient (rho⁺) cells by incubation with mitochondriaprepared from rho⁺ cells in the presence of polyethylene glycoland CaCl₂. Mitochondria prepared from different species, Hansenulawingei and Schizosaccharomyces pombe, also caused the transformationof S. cerevisiae rho^– protoplasts into the rho⁺ cellsas previously reported (14) The obtained transformants wereconfirmed to contain one nucleus and several mitochondrial DNAsby fluorescent staining of DNA. The transformants clearly restoredcytochromes a and b while untransformed recipient cells lackedthe cytochromes. In order to know the mechanism of the transformation,physiological measurement of endocytotic activity of protoplastsand cytological examination of mitochondria-protoplast aggregatesunder the transforming condition were performed. Protoplastshad significant endocytotic activity under this condition. Onthe other hand, fluorescence and electron microscopic observationsindicated that mitochondria forming aggregates with protoplastswere subsequently integrated into recipient protoplasts throughfusion rather than endocytosis. However, the possibility ofendocytosis could not be completely excluded when the low frequencyof the transformation (about 10^–6 to 10^–7) was takeninto account. This is discussed in this paper. A new convenientmethod for measuring endocytosis is also presented. (Received September 27, 1979; )     

Optimisation of introducing foreign genes into egg cells and zygotes of wheat (Triticum aestivum L.) via microinjection

Summary An expeditious and highly efficient technique of microinjection has been developed with the aim of introducing exogenous DNA into egg cells and zygotes of wheat. Using a mechanical-dissection method and a novel immobilisation approach enabled us to microinject around 15 egg cells of wheat per hour. Exposing the protoplasts to a high-frequency alternating-current field for immobilisation, a significantly higher transient expression rate of the injected genes (46% and 52% for egg cells and zygotes, respectively) could be achieved than reported thus far for plant protoplasts. Whether this high transformation efficiency is due to the highfrequency electrical field applied for immobilising the protoplasts is not known. The transformation rate appeared to be a factor depending upon the time of egg cell isolation. According to the ultrastructural observations this seems to reflect a variation in competence of the egg cells during in situ development. In order to conduct studies directed towards establishing the optimal timewindow for DNA delivery into the fertilised egg cell, the time course of DNA dynamics during zygotic development has been quantified via quantitative microspectrofluorometry.Abbreviations AC alternating current - DAE days after emasculation - FDA fluorescein diacetate - HAP hours after pollination     

Generation of Recombinant Chinese Hamster Ovary Cell Lines by Microinjection

Microinjection is a gene transfer technique enabling partial control of plasmid delivery into the nucleus or cytoplasm of cultured animal cells. Here this method was used to establish various recombinant mammalian cell lines. The injection volume was estimated by fluorescence quantification of injected fluorescein isothyocynate (FITC)-dextran. The DNA concentration and injection pressure were then optimized for microinjection into the nucleus or cytoplasm using a reporter plasmid encoding the green fluorescent protein (GFP). Nuclear microinjection was more sensitive to changes in these two parameters than was cytoplasmic microinjection. Under optimal conditions, 80–90% of the cells were GFP-positive 1 day after microinjection into the nucleus or the cytoplasm. Recombinant cell lines were recovered following microinjection or calcium phosphate transfection and analyzed for the level and stability of recombinant protein production. In general, the efficiency of recovery of recombinant cell lines and the stability of reporter protein expression over time were higher following microinjection as compared to CaPi transfection. The results demonstrate the feasibility of using microinjection as a method to generate recombinant cell lines. Revisions requested 27 October 2005; Revisions received 12 December 2005     

Nanoinjection: pronuclear DNA delivery using a charged lance

We present a non-fluidic pronuclear injection method using a silicon microchip ??nanoinjector?? composed of a microelectromechanical system with a solid, electrically conductive lance. Unlike microinjection which uses fluid delivery of DNA, nanoinjection electrically accumulates DNA on the lance, the DNA-coated lance is inserted into the pronucleus, and DNA is electrically released. We compared nanoinjection and microinjection side-by-side over the course of 4?days, injecting 1,013 eggs between the two groups. Nanoinjected zygotes had significantly higher rates of integration per injected embryo, with 6.2?% integration for nanoinjected embryos compared to 1.6?% integration for microinjected embryos. This advantage is explained by nanoinjected zygotes?? significantly higher viability in two stages of development: zygote progress to two-cell stage, and progress from two-cell stage embryos to birth. We observed that 77.6?% of nanoinjected zygotes proceeded to two-cell stage compared to 54.7?% of microinjected zygotes. Of the healthy two-cell stage embryos, 52.4?% from the nanoinjection group and 23.9?% from the microinjected group developed into pups. Structural advantages of the nanoinjector are likely to contribute to the high viability observed. For instance, because charge is used to retain and release DNA, extracellular fluid is not injected into the pronucleus and the cross-sectional area of the nanoinjection lance (0.06???m²) is smaller than that of a microinjection pipette tip (0.78???m²). According to results from the comparative nanoinjection versus microinjection study, we conclude that nanoinjection is a viable method of pronuclear DNA transfer which presents viability advantages over microinjection.     

A Comparison of Methods for Plasmid Delivery into Plant Protoplasts

Three methods of plasmid delivery to mesophyll protoplasts ofNicotiana tabacum cv. Xanthi have been evaluated. Specifically;a) chemically stimulated uptake of isolated plasmid, b) deliveryof plasmid encapsulated in liposomes, and c) fusion of plasmid-containingspheroplasts, were combined with divalent cation (Ca²⁺ and Mg²⁺)or polyalcohol [polyethylene glycol (PEG) and polyvinyl alcohol(PVA)] treatments. The quantity and quality of plasmid associatedwith intact protoplasts, was assessed by DNA-DNA blot hybridisationanalysis, following stringent washing to separate intact protoplastsfrom non-viable protoplasts and debris. Treatments which increasedassociation of plasmid with protoplasts decreased protoplastviability. Optimum association of plasmid with protoplasts,in the context of acceptable loss of viability, was achievedwhen protoplasts were interacted with either naked plasmid orliposomeencapsulated DNA in the presence of 15% w/v PEG 6000,or with Escherichia coli spheroplasts containing chloramphenicol-amplifiedplasmid in the presence of 25% w/v PEG 6000. Divalent cationsdid not stimulate significant plasmid delivery without unacceptableloss of protoplast viability. Strategies to further increasethe efficiency of plasmid delivery are discussed. (Received June 21, 1984; Accepted August 20, 1984)     

Direct Transfer of Plasmid DNA from Intact Yeast Spheroplasts into Plant Protoplasts

We developed a polyethylene glycol (PEG)-mediated direct DNAtransfer method from intact Saccharomyces cerevisiae spheroplastsinto Arabidopsis thaliana protoplasts. To monitor the DNA transferfrom yeast to plant cells, ß-glucuronidase (GUS) reportergene in which a plant intron was inserted was used as a reporter.This intron-GUS reporter gene on a 2µm-based plasmid vectorwas not expressed in yeast transformants, while it expressedGUS activity when the plasmid DNA was introduced into plantcells. When a mixture of 1 x 10⁸ of S. cerevisiae spheroplastsharboring the plasmid and 2 x 10⁶ of A. thaliana protoplastswas treated with PEG and high pH-high Ca²⁺ solution (0.4 M mannitol,50 mM CaCl₂, 50 mM glycine-NaOH pH 10.5), GUS activity was detectedin the extract of the plant cells after a three-day culture.The GUS activity was higher than that of a reconstitution experimentin which the mixture of 1 x 10⁸ of S. cerevisiae spheroplastswhich did not carry the reporter gene, 2 x 10⁶ of A. thalianaprotoplasts and the same amount of the reporter plasmid DNAas that contained in 1 x 10⁸ of S. cerevisiae spheroplasts,was treated with PEG and high pH-high Ca²⁺ solution. Moreover,the GUS gene expression was resistant to micrococcal nucleasetreatment before and during PEG treatment. From these results,we concluded that plasmid DNA can be directly transferred fromintact yeast spheroplasts to plant protoplasts by a nuclease-resistantprocess, possibly by the cell fusion. ²Deceased on September 15, 1992.     

Intranuclear microinjection for transformation of tomato callus cells

An efficient method, called the culture plate method, was devised for microinjection of foreign materials into nuclei of tomato callus cells. The culture plate method, used in this study, is advantageous because cells suitable for microinjection can be selected microscopically and the injected cells subsequently cultured in the same plate. With this microinjection system, some foreign materials were injected into nuclei of callus cells without causing detrimental effects. Kanamycin-resistant callus clones were obtained 1 month after injection from single cells whose nuclei were microinjected with a NPT II DNA fragment of the pE2KX plasmid.     

完整的供体细胞膜及供体胞质对小鼠体细胞克隆胚发育的影响

利用显微注射和电融合的方法都可以成功地获得体细胞克隆小鼠, 由于电融合法操作耗时, 融合率低, 因而大多数克隆小鼠是采用注射方法。而注射法需要将供体细胞核从细胞中分离出来, 此分离操作有可能导致对DNA的损伤, 曾有人使用直径较粗的注射管进行完整的供体细胞注射, 这种方法操作相对简单而且对供体核没有损伤。为了研究这种方法在小鼠核移植中是否适用, 本实验使用完整的小鼠卵丘细胞作供体, 进行显微注射, 结果显示, 完整的卵丘细胞注入卵母细胞后, 无论在1小时或者6小时激活, 大部分的重构胚在2细胞期碎裂, 而去掉细胞膜的供体体细胞核注入卵母细胞后, 重构胚可以卵裂并进一步发育。卵母细胞去核后不注射供体也发生碎裂, 大部分的孤雌胚(不去核)在完整的卵丘细胞被注入后同样发生碎裂。在供体卵丘细胞刚破膜后即被注入卵胞质和供核被充分剥离后注入两种情况下获得的重构胚的体外发育中, 前者发育各期的比率显著低于后者。这些结果说明完整的卵丘细胞膜阻碍了卵胞质对体细胞核的重编程作用, 造成碎裂; 注入卵胞质的供体质膜和胞质成分影响了克隆胚的体外发育。     

Regeneration of Triticum aestivum apical explants after microinjection of germ line progenitor cells with DNA

A highly efficient method of regenerating fertile, phenotypically normal plants from shoot apex cultures of T. aestivum was developed. The hypodermal layer (L2) of the vegetative apex containing germ line precursor cells could be located with bright field microscopy and targeted for microinjection. Fluorescently labelled dextrans were used as markers to develop a microinjection procedure which did not disrupt nuclear or cytoplasmic structure. This procedure was used to inject plasmid DNA into L2 cells. Capillary microinjection did not shear the plasmid DNA and delivery of DNA was confirmed by polymerase chain reaction analysis of DNA isolated from injected apices. The significance of these findings in relation to the development of cereal transformation systems will be discussed.     

Transferring isolated mitochondria into tissue culture cells

We have developed a new method for introducing large numbers of isolated mitochondria into tissue culture cells. Direct microinjection of mitochondria into typical mammalian cells has been found to be impractical due to the large size of mitochondria relative to microinjection needles. To circumvent this problem, we inject isolated mitochondria through appropriately sized microinjection needles into rodent oocytes or single-cell embryos, which are much larger than tissue culture cells, and then withdraw a ‘mitocytoplast’ cell fragment containing the injected mitochondria using a modified holding needle. These mitocytoplasts are then fused to recipient cells through viral-mediated membrane fusion and the injected mitochondria are transferred into the cytoplasm of the tissue culture cell. Since mouse oocytes contain large numbers of mouse mitochondria that repopulate recipient mouse cells along with the injected mitochondria, we used either gerbil single-cell embryos or rat oocytes to package injected mouse mitochondria. We found that the gerbil mitochondrial DNA (mtDNA) is not maintained in recipient rho0 mouse cells and that rat mtDNA initially replicated but was soon completely replaced by the injected mouse mtDNA, and so with both procedures mouse cells homoplasmic for the mouse mtDNA in the injected mitochondria were obtained.     

Intracellular oligonucleotide hybridization detected by fluorescence resonance energy transfer (FRET).

Fluorescence resonance energy transfer (FRET) was used to study hybrid formation and dissociation after microinjection of oligonucleotides (ODNs) into living cells. A 28-mer phosphodiester ODN (+PD) was synthesized and labeled with a 3' rhodamine (+PD-R). The complementary, antisense 5'-fluorescein labeled phosphorothioate ODN (-PT-F) was specifically quenched by addition of the +PD-R. In solution, the -PT-F/+PD-R hybrid had a denaturation temperature of 65 +/- 3 degrees C detected by both absorbance and FRET. Hybridization between the ODNs occurred within 1 minute at 17 microM and was not appreciably affected by the presence of non-specific DNA. The pre-formed hybrid slowly dissociated (T1/2 approximately 3 h) in the presence of a 300-fold excess of the unlabeled complementary ODN and could be degraded by DNAse I. Upon microinjection into the cytoplasm of cells, pre-formed fluorescent hybrids dissociated with a half-time of 15 minutes, which is attributed to the degradation of the phosphodiester. Formation of the hybrid from sequentially injected ODNs was detected by FRET transiently in the cytoplasm and later in the cell nucleus, where nearly all injected ODNs accumulate. This suggests that antisense ODNs can hybridize to an intracellular target, of exogenous origin in these studies, in both the cytoplasm and the nucleus.     

Regulatory mechanism of simian virus 40 gene expression in permissive and in nonpermissive cells.

Primary or continuous lines of mouse cells (3T3) are nonpermissive for simian virus 40 (SV40). Abortively infected cells synthesize tumor antigen (T antigen but not viral DNA and virus capsid protein (V antigen). V antigen, however, was obtained when SV40 DNA was injected into 3T3 cells. This late gene expression also appears to be correlated with the quantity of injected DNA molecules per 3T3 cell. T antigen formation can be detected after microinjection of only 1 to 2 DNA molecules, but the intensity of intranuclear T antigen fluorescence is significantly brighter with injection of higher concentrations of viral DNA. In permissive cells (TC7), early and late SV40 gene expression is directly related to the number of injected molecules. Microinjection of 1DNA molecule induced T and V antigen formation with the same efficiency as microinjection of 2,000 to 4,000 molecules. The question of weather late SV40 gene expression is directly related to the quantity of an early virus-specific product was approached by microinjection of early SV40 complementary RNA together with small amounts of viral DNA. V antigen was obtained in a high proportion of recipient 3T3 cells at conditions where microinjection of viral DNA alone induced T but not V antigen synthesis.     

Liposomes as a carrier of genetic information

Incorporation of genetic material into the bilayer lipid vesicles (liposomes) and the subsequent transfer of liposomal content into cells or protoplasts appear to be a promising technique for transfer of genetic information. The following three methods are most frequently used to incorporate DNA into liposomes lipid microinjection into aqueous phase, multistep treatment of the lipid suspension by ultrasonication, Ca2+ ions and EDTA, reverse phase evaporation. Viral particles, chromosomes, nuclei, viral nucleic acids, plasmids and chromosomal DNA can be successfully transferred into animal and plant protoplasts by the described technique. Successful transformation of a number of microorganisms (Neurospora, E. coli, B. subtilis, Streptomyces, Mycoplasma) with the liposome incorporated DNA has also been reported. Transformation frequency can be considerably increased by optimizing the conditions of liposome formation or of liposome-protoplasts interaction.     

Mitotic protoplasts and their infection with tobacco mosaic virus RNA encapsulated in liposomes

M-phase and S-phase protoplasts were prepared from tobacco cells in suspension culture after a high degree of synchronization using aphidicolin, a specific inhibitor for eukaryotic DNA polymerase. When TMV-RNA was introduced into these protoplasts mediated by REV liposomes, 37% of M-phase and 26% of S-phase protoplasts were infected as determined by the fluorescent antibody technique. After the 24 hr interval between the introduction of TMV-RNA into protoplasts and the determination of infection, half of the infected mitotic protoplasts formed dumbell-shaped daughter cells. The significance of synchronized protoplasts in genetic engineering of plant cells is discussed in reference to the delivery of DNA into the nucleus.Abbreviation LS medium, Linsmaier and Skoog medium - PEG polyethylene glycol - REV reversephase evaporation vesicles - TMV tobacco mosaic virus     

The Effects of Cell Cycle Parameters on Cell Wall Regeneration and Cell Division of Cotton Protoplasts (Gossypium hirsutum L.)

Protoplasts of cotton cotyledons were isolated and culturedto undergo cell wall regeneration and cell division. DNA contentand cell cycle parameters of nuclei from cotyledons and/or protoplastswere determined by flow cytometry. The DNA content of cotton,Gossypium hirsutum L., was estimated to be 4·34±0·12pg DNA per nucleus. There was a strong positive correlation between G₂ or Sand G₂,and cell wall regeneration and cell division and a strong negativecorrelation between G₁, and cell wall regeneration and celldivision of cotton cotyledon protoplasts. The cell cycle statusof cotyledons changes during their development; as the cotyledonsenlarge, the proportion of cells in G₀ and G₁ phases of thecell cycle increases. The implication of these results in relationto protoplast growth and development is discussed. Key words: Cell cycle parameters, cell wall regeneration, cell division, flow cytometry, Gossypium     

Experession and integration of genes introduced into highly synchronized plant protoplasts

Summary Chimaeric genes containing the chloramphenicol acetyltransferase (CAT) coding sequence were introduced into protoplasts of suspension-cultured tobacco cells using improved conditions of electroporation (Okada et al. 1986). CAT activity became detectable in the protoplasts within 3 h, was maximal during a period of 18–36 h after electroporation, and then declined gradually. Alpha-amanitin added to the medium abolished the transient expression of the CAT gene. The closed circular form of input DNA was as effective as the linear form for the transient expression. The suspension culture was treated with aphidicolin, and S, G₂, M and G₁ phases were identified in the highly synchronized cell cycle obtained by releasing the cells from the inhibition of DNA synthesis. When a chimacric CAT gene was introduced into M phase protoplasts prepared from the synchronized culture, the transient expression of the CAT gene was 3–4 times higher than when it was introduced into protoplasts of other cell cycle phases. The frequency of stable transformation with a chimaeric neomycin phosphotransferase II gene was studied using the same system. G-418-resistant transformants were obtained from M phase protoplasts at frequencies 2–8 times those obtained from protoplasts at other cell cycle phases. The results indicate that the absence of the nuclear membrane in mitotic cells favours delivery to the nucleus of exogenous DNA introduced into the cytoplasm.