Microinjection of living adherent cells by using a semi-automatic microinjection system

Testing in vitro is an alternative to animal experimentation. The capillary pressure microinjection technique is a supporting technology for efficient in vitro testing. The main benefit of the technique is the possibility of injecting large molecules into a single living cell. The ultimate goal of the research discussed in this paper is to increase the cell survival rate in capillary pressure microinjection. A method to reliably evaluate cell survival rate is therefore needed. A three-phase evaluation process is presented in this paper. The first phase determines the success rate of the injection capillary to penetrate the cell membrane. The second phase studies the success rate of delivering the injection substance inside the cell, while the third phase studies cell survival after the microinjection. In addition to the three-phase evaluation process, this paper describes the initial results of penetration and injection tests performed by using a semi-automatic capillary pressure microinjection system developed by the research group. Three adherent cell lines, namely, retinal pigment epithelial cells, MCF-7 human breast cancer cells and SH-SY5Y neuroblastoma cells, were used in the experiments. The results of the penetration tests show that the average success rate of penetrating the cell membrane using the micromanipulator was 87%. The goal of the injection tests was to demonstrate the successful microinjection of living cells and to study the injection success rate. Fluorescein dextran was injected into MCF-7 cells, and preliminary results showed an injection success rate of 49%. In the survival tests, the neuronal cells were microinjected with KCl. During long-term observation after the microinjection, the microinjected cells first decreased their adhesion to the plate, but later adhered to the bottom of the plate and even grew some dendrites. In the next phase of the study, more tests will be performed in order to obtain a statistically reliable value for the survival rate.     

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.     

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     

Erythrocyte ghost-mediated microinjection into cells in monolayer cultures: a highly efficient and low toxic technique

We describe a technique by which macromolecules can be microinjected into mammalian cells in monolayer cultures. This technique employs erythrocyte ghosts as the vehicle for microinjection, calcium as attachment agent and polyethylene glycol as fusogen. The use of calcium allows a reduction of the time of exposure to polyethylene glycol, and results in a high injection efficiency and a high cell viability when followed by incubation in a buffer free of divalent cations. Injecting over 90% of the cells, a reduction of cell viability is not observed and the mitotic index is never lower than 2.3%. Light and electron microscopy suggest that erythrocyte ghost-cell fusion is only a short event.     

Determination of the mitotic index by microinjection of fluorescently labelled tubulin

The microneedle injection technique is one of the most established procedures for the introduction of proteins into living cells. To analyse injected proteins which are important in cell cycle progression it is often necessary to determine the mitotic index. Measuring the mitotic index after microinjection is complicated because only a limited number of cells of the whole cell population is microinjected. Therefore, we attempted to establish a new method to determine the mitotic index using microinjection of fluorescently labelled alpha/beta-tubulin into mammalian cells which allows to monitor the injected cells simultaneously with the determination of the mitotic index. We demonstrated that fluorescently labelled tubulin incorporates efficiently into the mitotic spindle apparatus. Fluorescence remains stable for several hours which is sufficient to observe the progression of cells through the M-phase of the cell cycle. The determination of the mitotic index with the method presented here gave similar results to those determined using other methods. With this method also different stages of mitosis can be visualized by analysing various steps of spindle formation. Thus, this rapid method allows the monitoring of the injected cells after microneedle injection and simultaneously the determination of the mitotic index.     

Performance of an automated system for capillary microinjection into living cells

An automated capillary microinjection system for nuclear and cytoplasmic injections into cells is described. The system has been tested with samples of DNA, RNA and proteins. Movements of the capillary with precise cell positioning and time of injections are controlled by a computer. This first automated microinjection system allows injection of more than 1500 cells per hour with a minimum of practical training, volumes injected are more reproducible and cells are less damaged when compared with the standard manual injection technique. Retrieval of the injected cells is accurate to within 1% without complicated and laborious produced orientation marks on the cell support. The number of successfully injected cells is easily determined with great accuracy and the error of the statistical evaluation of the results is reduced to a minimum. Standardized procedures for pulling, handling and storage of the injection capillaries were developed.     

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.     

Single cell assay with an automated capillary microinjection system

An automated capillary microinjection system with computer-controlled positioning of the cells and of the capillary, and its applications and advantages, is described. The system is easy in handling and manipulation. About 1500 injections are possible in 1 h, with high reproducibility. In cytoplasmic and nuclear injections more than 90 and 85% of the cells are successfully injected. Using FITC-dextran at a concentration of 0.5% as a fluorescently labeled coinjection marker, 99% of the cells can be retrieved in culture medium even 48 h after injection. The coordinates of the cells are stored in the computer and accuracy in statistical evaluation of experiments is improved in comparison to the manual techniques. Methods for preparation and handling of glass capillaries were developed resulting in reproducible form and significantly reduced clogging rate. The improved characteristics offered by this system are demonstrated in studies leading to the confirmation of existence of an mRNA inhibiting DNA synthesis in cells. Functional screening by cell injections of cDNA libraries and of size-fractionated mRNA molecules can be performed efficiently with the automated microinjection system.     

Comparison of aggregation and injection techniques in producing chimeras with embryonic stem cells in mice

We analyzed embryonic stem cell lines for their capacity to produce aggregation chimeras with diploid or developmentally compromised tetraploid embryos. Descendants of embryonic stem cells which contributed to midgestation fetuses at high levels were capable of supporting fetal development also with tetraploid partners. Different numbers of embryonic stem cells were introduced into diploid and tetraploid morulae as well as into blastocysts by microinjection. There were no differences in the frequency of embryonic stem cell-containing fetuses when comparing aggregation or injection into morulae versus blastocysts. However, the distribution pattern of embryonic stem cell derivatives in chimeric fetuses suggested that pre-compaction embryos are more suitable for generating fetuses with high embryonic stem cell contribution. Injection of embryonic stem cells into tetraploid embryos showed that completely embryonic stem cell-derived fetuses can also be produced by this technique. Totally embryonic stem cell derived fetuses were observed in each group, when embryonic stem cells were injected into diploid embryos. However, the rate of chimeras and chimerism was lower when 1 or 3 embryonic stem cells were used versus 8 or 15 cells. This suggests that the number of embryonic stem cells introduced might play a role in the colonization ability.     

利用雄性生殖细胞建立转基因动物

追溯了用雄性生殖细胞建立转基因动物的发展历程 ,系统阐述了本领域理论和实践的最新进展 ,围绕方法学逐渐改进和完善的过程 ,从利用精子和精原干细胞携带外源DNA两个方向展开 ,分析和评价了DNA转移方法与精子载体法结合、胞浆内单精子注射、蛋白连接的精子介导的基因转移、输精管注射法以及曲细精管显微注射法和精原干细胞移植法 6种实验设计方法。     

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。     

Microinjection of monoclonal antibodies specific for one intermediate filament protein in cells containing multiple keratins allow insight into the composition of particular 10 nm filaments

Monoclonal antibodies specific for vimentin (V9), keratin 7 (CK 7) and keratin 18 (CK5) have been microinjected into three human epithelial cell lines: HeLa, MCF-7 and RT-4. The effect of the injection on other keratin polypeptides and vimentin filaments has been observed by double label immunofluorescence and in some instances by immunoelectron microscopy using gold labels of different sizes. Microinjection of V9 into HeLa cells causes the vimentin to collapse into a perinuclear cap leaving the keratin filaments unaffected. Injection of CK5 does not affect the vimentin filaments but disrupts the keratin filaments revealing keratin aggregates similar to those seen in some epithelial cell lines during mitosis. The keratin aggregates obtained after microinjection in HeLa contain the keratins 8 and 18 and probably also other keratins, as no residual keratin filaments are observed with a keratin polyclonal antibody of broad specificity. Aggregates in mitotic HeLa cells contain at least the keratins 7, 8, and 18. In MCF-7 cells keratins 8, 18, and 19 are observed in the aggregates seen 3 h after microinjection which, however, show a different morphology from those seen in HeLa cells. In MCF-7 cells a new keratin filament is built within 6 h after the injection which is composed mainly of keratin 8 and 19. The antibody-complexed keratin 18 remains in spherical aggregates of different size. The results suggest that in HeLa cells vimentin and keratin form independent networks, and that individual 10 nm filaments in epithelial cell lines can contain more than two keratins.     

Stable and unstable transformation by microinjection of macronucleoplasm in Paramecium.

Transformation by microinjection of macronucleoplasm in Paramecium caudatum was investigated. Macronucleoplasm with three genetic markers (behavior, trichocyst, and mating type) was injected into the macronucleus. To facilitate microinjection, in most cases, paramecia were immobilized in a gelatin (7.5%) solution. The injected cells began to express a dominant gene (cnrA+ or cnrB+) of the donor 9-24 hr after injection. Expression did not require cell division suggesting injected macronucleoplasm was capable of expressing a phenotype. The amount of injected macronucleoplasm appears to correlate with the frequency of successful expression but not to correlate with the time required for expression. After a number of fissions, the injected cells produced clones which had cells expressing the phenotype of the donor. This suggests that injected macronucleoplasm was replicated and expressed in the recipient cell lines. The transformed clones were classified into two groups. In one group, transformation was stable. All cell lines derived from the injected cells expressed a phenotype similar to the heterozygote of donor and recipient cells. In the other group, transformation was unstable. During the first five to seven fissions after injection, at each division, cells produced one daughter cell which later reverted to the recipient phenotype. After this unstable period, cells no longer produced the recipient phenotype but produced the donor phenotype exclusively. Donor and recipient phenotypes were, thus, segregated in different cell lines. Observation of genetic markers and analysis by computer simulation shed light on the mode of transmission of injected macronucleoplasm. In stable transformation, injected macronucleoplasm appears to be distributed equally to daughter cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Disruption of the in vivo distribution of the intermediate filaments in fibroblasts through the microinjection of a specific monoclonal antibody

Monoclonal antibodies (JLB1 and JLB7) that recognize minor components of the intermediate filament system of cultured cells were introduced into living fibroblasts by microinjection. Several minutes after injection of the JLB7 antibody virtually all of the intermediate filaments of the cells were found to be aggregated into tight bundles near or around the nucleus. In contrast, injection of the JLB1 antibody caused little or no aggregation of the intermediate filaments. Electron microscopy showed that the perinuclear bundles that formed after injection of the JLB7 antibody each consisted of ten or more intermediate filaments apparently crosslinked together. Double-label immunofluorescence microscopy showed that virtually all of the vimentin-containing intermediate filaments in the JLB7 antibody-injected cells were redistributed to the perinuclear region and remained there for at least 24 hr. The distributions of actin microfilaments and microtubules were seemingly undisturbed following microinjection. No obvious changes in cell morphology or behavior were apparent in the cells injected with JLB7 antibody; the cells displayed a flat appearance, showed a polarity, were able to ruffle and bleb and even appeared to show the normal saltatory movements of intracellular vesicles, granules and mitochondria, suggesting that intermediate filaments are not involved in these activities. The microinjection of highly specific monoclonal antibodies that recognize and alter components of the cell provides an additional approach to determine the in vivo functions of intracellular elements.     

Gene transfer: DNA microinjection compared with DNA transfection with a very high efficiency.

We have developed a procedure that gives a very high efficiency of transfection in mammalian cells with low-molecular-weight DNA (approximately 10(4) base pairs). The procedure uses cells in suspension that are shocked with polyethylene glycol 4 h after replating. We compared this transfection technique to the standard technique involving manual microinjection of DNA into the nuclei of mammalian cells, using recombinant plasmids containing the simian virus 40 A gene or the herpes simplex virus thymidine kinase gene or both. The efficiency of transfection depends on a number of variables, the most important of which is the difference in transfectability of different cell lines. In our laboratory, the cell line that had the highest efficiency of transfection was tk-ts13, which is derived from baby hamster kidney cells that are deficient in thymidine kinase and temperature sensitive for growth. Under the appropriate conditions, as many as 70% of these cells can be transfected so that transient gene expression can be detected. With the manual microinjection technique, gene expression is independent of the cell line used and occurs faster than after transfection. The results suggest that the critical stage in transfection is the delivery of DNA molecules to the nucleus. Our experiments also indicate that an enzymatic function, in our case, thymidine kinase activity, gives a higher percentage of positive transfectants than when proteins are visualized only by indirect immunofluorescence. The transfection procedure described in this paper is simple and reproducible and, although less efficient than microinjection, ought to be useful in phenotypic and genotypic studies in which transfer of genes to a large number of cells is desirable.     

Stable and unstable transformation by microinjection of macronucleoplasm in Paramecium

Transformation by microinjection of macronucleoplasm in Paramecium caudatum was investigated. Macronucleoplasm with three genetic markers (behavior, trichocyst, and mating type) was injected into the macronucleus. To facilitate microinjection, in most cases, paramecia were immobilized in a gelatin (7.5%) solution. The injected cells began to express a dominant gene (cnrA⁺ or cnrB⁺) of the donor 9–24 hr after injection. Expression did not require cell division suggesting injected macronucleoplasm was capable of expressing a phenotype. The amount of injected macronucleoplasm appears to correlate with the frequency of successful expression but not to correlate with the time required for expression. After a number of fissions, the injected cells produced clones which had cells expressing the phenotype of the donor. This suggests that injected macronucleoplasm was replicated and expressed in the recipient cell lines. The transformed clones were classified into two groups. In one group, transformation was stable. All cell lines derived from the injected cells expressed a phenotype similar to the heterozygote of donor and recipient cells. In the other group, transformation was unstable. During the first five to seven fissions after injection, at each division, cells produced one daughter cell which later reverted to the recipient phenotype. After this unstable period, cells no longer produced the recipient phenotype but produced the donor phenotype exclusively. Donor and recipient phenotypes were, thus, segregated in different cell lines. Observation of genetic markers and analysis by computer simulation shed light on the mode of transmission of injected macronucleoplasm. In stable transformation, injected macronucleoplasm appears to be distributed equally to daughter cells. In unstable transformation, injected macronucleoplasm is distributed only to one of the daughter cells at every division until about the fifth to seventh fission after injection and then begins to assort equally to daughter cells. The cell cycle stage at injection may influence the mode of transformation. Interspecific microinjection of macronucleoplasm from P. multimicronucleatum and P. tetraurelia to P. caudatum. resulted in the expression of foreign genes in P. caudatum. In one case, injection of macronucleoplasm of P. tetraurelia produced a stable transformant indicating replication of foreign macronucleoplasm in P. caudatum. This work reveals the mode of transformation by injected macronucleoplasm and shows the possibility of transformation among Paramecium species, which is significant in the study of the conservation of gene products and the mechanism of gene expression in different species. © 1992 Wiley-Liss, Inc.     

High throughput easy microinjection with a single-cell manipulation supporting robot

A single-cell manipulation supporting robot (SMSR) has been developed for the high throughput and easy microinjection. Its concept is to let an experimenter concentrate his/her attention only on the microinjection by facilitating other associated works. SMSR was applied to the microinjection into rice protoplasts and mouse embryonic stem (ES) cells. The microinjection into these cells is exceptionally difficult than usual animal cells such as fibroblasts. In the case of rice protoplast, for example, non-stop microinjection into 100 cells could be done within 1h that was 17-times faster than that of the robot-less work. The success rate was 7-8% that was same level obtained by the robot-less work. The present results indicate that SMSR is a useful machine for the microinjection of specific genes and proteins in living cells to analyze their respective functions, which is an urgent and important subject in the post-genome era.     

Direct introduction of cloned DNA into the sea urchin zygote nucleus, and fate of injected DNA

A method is described for microinjection of cloned DNA into the zygote nucleus of Lytechinus variegatus. Eggs of this species are unusually transparent, facilitating visual monitoring of the injection process. The initial fate of injected DNA fragments appears similar to that observed earlier for exogenous DNA injected into unfertilized egg cytoplasm. Thus after end-to-end ligation, it is replicated after a lag of several hours to an extent indicating that it probably participates in most of the later rounds of DNA synthesis undergone by the host cell genomes during cleavage. The different consequences of nuclear versus cytoplasmic injection are evident at advanced larval stages. Larvae descendant from eggs in which exogenous DNA was injected into the nuclei are four times more likely (32% versus 8%) to retain this DNA in cell lineages that replicate very extensively during larval growth, i.e. the lineages contributing to the imaginal rudiment, and thus to display greatly enhanced contents of the exogenous DNA. Similarly, 36% of postmetamorphic juveniles from a nuclear injection sample retained the exogenous DNA sequences, compared to 12% of juveniles from a cytoplasmic injection sample. However, the number of copies of the exogenous DNA sequences retained per average genome in postmetamorphic juveniles was usually less than 0.1 (range 0.05-50), and genome blot hybridizations indicate that these sequences are organized as integrated, randomly oriented, end-to-end molecular concatenates. It follows that only a small fraction of the cells of the average juvenile usually retains the exogenous sequences. Thus, even when introduced by nuclear microinjection, the stable incorporation of exogenous DNA in the embryo occurs in a mosaic fashion, although in many recipients the DNA enters a wider range of cell lineages than is typical after cytoplasmic injection. Nuclear injection would probably be the route of choice for studies of exogenous DNA function in the postembryonic larval rudiment.     

Influence of microfilament and microtubule inhibitors applied by immersion and microinjection on circulation streaming in the staminal hairs ofTradescantia blossfeldiana

Summary Reaction of cytoplasmic streaming inTradescantia staminal hairs to microfilament and microtubule specific inhibitors, applied either by conventional immersion or by microinjection, indicates that both the actin-myosin and the microtubule system may be involved in driving the particle stream. Cytoplasmic streaming was stopped at relatively high drug concentrations when the cells were immersed in the inhibitor solution. Microinjection of defined concentrations of inhibitor into single, selected cells were effective at concentrations at least two orders of magnitude lower. Further reduction of inhibitor concentrations, however, enhanced streaming up to 100%. When a mixture of cytochalasin D and oryzalin were injected at concentrations that had previously been shown to enhance particle movement, very efficient inhibition occurred and streaming rapidly stopped. Adjacent cells on both sides of the injected cell were also affected: within a few minutes of the injection of microfilament inhibitors the basal cell reacted, followed slightly later by the apical one; microtubule inhibitors caused a reaction in the apical cell earlier than in the basal cell. The results are discussed with respect to the involvement of actin and myosin microfilaments, as well as microtubules, as force generating systems of particle movement.Abbreviations CB cytochalasin B - CD cytochalasin D - Cys cysteine - DMSO dimethylsulfoxid - DTT dithiothreitol - MI microinjection - NBD 7-nitrobenz-2-oxa-1,3-diazole - NEM N-ethylmaleimide Nocodazole methyl [5-(2-thienylcarbonyl)-1 H-benzimidazol-2-yl]carbamate