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.     

Analysis of BHK cell growth kinetics after microinjection of catalytic subunit of cyclic AMP-dependent protein kinase.

The effect of catalytic subunit (C) of cyclic AMP-dependent protein kinase on cell growth kinetics of BHK cells was assessed by microinjection with chicken erythrocyte ghosts as vehicles for introduction of the protein into the cytosol of large populations of cells. The advantage in using chicken erythrocytes for microinjection is that the inactive erythrocyte nuclei serve as a probe for identifying and analyzing microinjection events. By utilizing this procedure, BHK cells were microinjected with an amount of C that was 5- to 10-fold greater than their endogenous levels. Growth kinetics were analyzed by [3H]thymidine incorporation and autoradiography. Cells were stained after autoradiography to more clearly reveal the chicken nuclei, and at each time point, cells were categorized into four groups: (i) not microinjected, not in S phase, (ii) not microinjected, in S phase, (iii) microinjected, not in S phase, (iv) microinjected, in S phase. Those cells not microinjected served as internal controls. Two experimental protocols were used to test the notion that C is involved in blocking cell progression through G1 phase of the cell cycle. First, cells were arrested in G0 phase by serum deprivation, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum or purified growth factors. Second, cells were collected in mitosis, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum. The results of these studies indicate that a 5- to 10-fold increase in the intracellular concentration of C is not a sufficient signal to arrest cell growth in G1 phase. Thus, growth-inhibitory effects of cyclic AMP on BHK cells are unlikely to be the result of activation of cyclic AMP-dependent protein kinase.     

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.     

Capillary Microinjection into Protoplasts and Intranuclear Localization of Injected Materials

By a direct microinjection through pressurized glass micropipettes,we injected fluorescent Lucifer Yellow, berberine and berberine-boundDNA into protoplasts isolated from cultured Euphorbia milliicells and from tobacco mesophyll cells. The protoplasts to beinjected were held by a holding pipette with which the cytoplasmor nucleus of the protoplasts could be oriented with referenceto the tip of the injection pipette. Upon microinjection ofa berberine-bound DNA, the nucleus and intranuclear organelles,possibly including nucleolus, specifically exhibited yellowfluorescence due to berberine. This provides a direct evidencethat DNA molecules can be microinjected into the intranuclearcompartment of the protoplasts. The injected protoplasts survivedthe capillary microinjection. (Received August 6, 1984; Accepted November 12, 1984)     

Microinjection as a tool of mechanical delivery

Microinjection to single cells has been widely used in the studies of transduction-challenged cells, transgenic animal production, and in vitro fertilization to mechanically transfer DNAs, RNA interferences, sperms, proteins, peptides, and drugs. The advantages of microinjection include the precision of delivery dosage and timing, high efficiency of transduction as well as low cytotoxicity. However, manual microinjection is labor intensive and time consuming, which limits the application of this technique to large number of cells in a sample. New cell culture matrix ensuring all cells grow in a desired position and orientation is needed for application of high throughput automatic injection systems, which will significantly increase injection speed, cell survival, and success rates.     

Embryogenesis from microinjected single cells in a carrot cell suspension culture

A micrroinjection method was established for intact single cells with cell walls using a carrot suspension culture system in which selected single cells differentiate to embryos at high frequency. A solution of a fluorescent dye, Lucifer Yellow CH, was microinjected into those single cells, using an inverted microscope and a hydraulic micro-manipulator. In order to hold cells with cell walls and to overcome their turgor pressure, certain modification to conventional microinjection methods for protoplasts were necessary. The microinjected cells could divide and differentiate to embryos at a frequency of about 50%.     

Efficiency of transgenic rat production is independent of transgene-construct and overnight embryo culture

The aim of the present work was to study factors affecting the efficiency of transgenic technology in rats. We investigated the possible effects of pronuclear microinjection of buffer or different DNA-constructs on survival and development of rat zygotes in vitro and in vivo as well as the influence of overnight culture of these embryos before transfer into pseudopregnant foster mothers. The survival rate of zygotes and their development to the two-cell and morula stage was not affected by pronuclear microinjection with different DNA-constructs or buffer. However, the development to the blastocyst stage was impaired. Nevertheless, there was no difference in blastocyst development between zygotes injected with DNA-constructs or with buffer. Neither was there a difference in cell number in in vitro cultured blastocysts resulting from pronuclear microinjection of a transgene compared with non-injected controls. The survival rate to term was about 30% irrespective of whether microinjected embryos were transferred immediately after microinjection or after overnight culture in vitro. However, a reduction in the survival to term was observed for non-injected zygotes when they were developed in vitro to the two-cell stage before transfer to a pseudopregnant female. The percentage of transgenic rats that resulted from microinjected zygotes was similar in all groups regardless of the DNA-construct used (2.7-10.0%). In conclusion, the main detrimental factor in the microinjection of rat zygotes is the introduction of solution in the pronucleus. Overnight culture of zygotes between microinjection and oviduct transfer does not decrease the efficiency of transgenic rat generation.     

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.     

Influence of combined microinjection of gene engineering construct and endonuclease on preimplantation development of mouse embryos in vitro

We studied the influence of combined microinjection of a gene engineering construct and site-specific endonuclease Sal in the pronucleus on preimplantation development of (CBA x C57BL)F1 mouse embryos in vitro. The rate of survival of the embryos was estimated according to their capacity to develop until the blastocyst stage and hatch from zona pellucida. The results obtained suggest that the microinjection of exogenous DNA jointly with endonuclease SalI at concentrations from 0.1 to 0.01 U/microl decreased reliably the rate of survival, as compared to the control (p < 0.05 and p < 0.01, respectively). However, a decrease of endonuclease SalI concentration in the injection mixture to 0.01 U/microl enhanced the capacity of mouse embryos to develop until the blastocyst stage and hatch from zona pellucida, as compared to the embryos microinjected with exogenous DNA and endonuclease SalI at a higher concentration.     

Expression of thermotolerance following microinjection of glutathione disulfide

Asynchronous Chinese hamster ovary cells were microinjected with glutathione disulfide (GSSG). Successfully injected cells were scored by coinjecting FITC-dextran with GSSG, followed by fluorescent microscopy. After microinjection, cells were incubated for 2.5 h at 37 degrees C to permit thermotolerance development and then heated at 45 degrees C for 40 min. Cellular heat sensitivity was quantitated by counting the number of grains per cell after labeling heated cells with tritiated amino acids and processing for autoradiography. The data show that microinjection of GSSG induced thermotolerance which increased the number of grains per cell up to 500% of controls. Cells that were exposed to similar concentrations of GSSG in culture medium without microinjection or microinjected without GSSG did not develop thermotolerance.     

The synthesis and intracellular localization of adenovirus hexon protein studied by microinjection of mRNA into human cells

Polyadenylated RNA isolated 18 h after infection of HeLa cells with adenovirus type 2 was both translated in vitro and microinjected into the cytoplasm of human transformed amnion cells. The hexon polypeptide could be specifically immunoprecipitated from the products of cell-free translation with a rabbit-anti-hexon serum. The same serum when used in immunofluorescence assays of microinjected cells revealed hexon protein synthesized 6 h after microinjection. The intensity of the staining persisted up to 16 h after injection of messenger RNA (mRNA). Newly-synthesized hexon protein was characteristically located mainly in the nucleus. Essentially the same results were obtained when normal amnion cells were microinjected.     

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.     

Mechanisms of intracellular protein catabolism. Intracellular fate of microinjected polypeptides translated in vitro.

Erythrocyte-mediated microinjection was used to introduce [35S]polypeptides translated in vitro into 3T3-L1 cells. Such [35S]polypeptides are not degraded after loading into erythrocytes and are stable for the first 2 h after microinjection into growing 3T3-L1 cells. Similarly, little or no degradation of microinjected [35S]polypeptides is observed in either growing or confluent 3T3-L1 cells over a 70 h period. Microinjection of reticulocyte lysate alone does not affect the rate of degradation of long-lived endogenous protein. Reductively [3H]methylated lysate haemoglobin is degraded after microinjection by a cytosolic mechanism. Microinjected 125I-labelled bovine serum albumin is rapidly degraded by a cytosolic mechanism at the same rate in the absence or presence of reticulocyte lysate. The data do not support the notion that the observed lack of degradation of microinjected [35S]polypeptides translated in vitro is due to the presence of proteolytic inhibitors in reticulocyte lysates which can inhibit the degradation of microinjected or cellular proteins.     

Factors related to successful sperm microinjection of hamster eggs: The effect of sperm species, technical experience, needle dimensions, and incubation medium on egg viability and sperm decondensation following microinjection

A series of experiments was designed to identify factors in a sperm microinjection system that could influence egg viability and decondensation of sperm nuclei after microinjection. Egg viability and sperm decondensation rates were not different among eggs microinjected with rodent sperm. The microinjection of ram sperm required a larger diameter needle for injection, which resulted in low egg viability and sperm decondensation in the first 3 mo of the study but improved greatly after 9 mo of technical experience. The degree of technical experience (3 vs 9 mo) also improved (P<0.05) egg viability after microinjection with rodent sperm; however, the rate of sperm decondensation remained unaffected. Altering the dimensions of the injection needle from a tapered needle barrel to a more uniform needle barrel increased egg viability from 61 to 96% and sperm decondensation from 3 to 27%. The use of medium 199 for incubating microinjected eggs further increased (P<0.05) the percentage of eggs containing decondensed sperm nuclei (52%) compared to eggs incubated in Holmes defined medium (28%). By altering the dimensions of the injection needle, by selecting an appropriate incubation medium, and by gaining technical experience in microinjection, the efficiency of a sperm microinjection system was improved for both rodents and domestic animals.     

Functional histone antibody fragments traverse the nuclear envelope

Factors important in the translocation process of proteins across the nuclear membrane were studied by microinjecting either fluoresceinated nonimmune IgG and F(ab)2 or the corresponding molecules, prepared from antisera to histones, into the nucleus and cytoplasm of human fibroblasts. Intact IgG from both preparations remained at the site of injection regardless of whether it was injected into the nucleus or the cytoplasm. In contrast, nonimmune F(ab)2 distributed uniformly throughout the cell. The F(ab)2 derived from affinity-pure antihistone moves into the nucleus after cytoplasmic injection and remains in the nucleus after nuclear microinjection. The migration of the antihistone F(ab)2 into the nucleus results in inhibition of uridine incorporation in the nuclei of the microinjected cells. We conclude that non-nuclear proteins, devoid of specific signal sequences, traverse the nuclear membrane and accumulate in the nucleus provided their radius of gyration is less than 55A and the nucleus contains binding sites for these molecules. These findings support the model of "quasibifunctional binding sites" as a driving force for nuclear accumulation of proteins. The results also indicate that active F(ab)2 fragments, microinjected into somatic cells, can bind to their antigenic sites suggesting that microinjection of active antibody fragments can be used to study the location and function of nuclear components in living cells.     

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.     

Cell cycle-related differences in susceptibility of NIH/3T3 cells to ribonucleases

Microinjection of Onconase or RNase A into NIH/3T3 cells was used to study the intracellular actions of these two proteins. Onconase preferentially killed actively growing cells in both microinjection and cell culture experiments. Moreover, agents that increased the number of cells in S phase such as serum or microinjected signal transduction mediators (Ras, protein kinase C, and mitogen-activated protein kinase) enhanced Onconase cytotoxicity. Conversely, agents that decreased these proliferative pathways (dibutyryl cAMP and protein kinase A) correspondingly diminished Onconase cytotoxicity in microinjection experiments. These results were also mimicked in cell culture experiments since log-phase v-ras-transformed NIH/3T3 cells were more sensitive to Onconase (IC50 of 7 microg/ml) than parental NIH/3T3 fibroblasts (IC50 of 40 microg/ml). Based on those data we postulated that Onconase-mediated cell death in NIH/3T3 cells was related to events occurring at two or more points in the cell cycle preferentially associated with late G1/S and S phases. In contrast, quiescent NIH/3T3 cells were more sensitive to microinjected RNase A than log phase cells and positive mediators of proliferative signal transduction did not enhance RNase A-mediated cytotoxicity. Taken together, these results demonstrate that these two RNases use different pathways and/or mechanisms to elicit cytotoxic responses in NIH/3T3 cells. Predictions formulated from these studies can be tested for relevance to RNase actions in different target tumor cells.     

Inhibition of baroreflex vagal bradycardia by activation of the rostral ventrolateral medulla in rats

In stressful conditions, baroreflex vagal bradycardia (BVB) is often suppressed while blood pressure is increased. To address the role of the rostral ventrolateral medulla (RVL), a principal source of sympathetic tone, in inhibition of BVB, we microinjected DL-homocysteic acid (DLH, 6 nmol) into the RVL of chloralose-urethan-anesthetized, sinoaortic-denervated rats to examine the effect on BVB. The BVB was provoked by electrical stimulation of the aortic depressor nerve ipsilateral to the injection sites. DLH microinjection was found to suppress BVB while increasing blood pressure. The inhibition of BVB was observed even during the early phase in which DLH transiently suppressed central inspiratory activity. The inhibition was not affected either by upper spinal cord transection or suprapontine decerebration. Similar results were obtained by microinjection of bicuculline methiodide (160 pmol), a GABA antagonist, into the RVL of carotid sinus nerve-preserved rats due to withdrawal of a tonic GABA-mediated, inhibitory influence including the input from arterial baroreceptors. In conclusion, activation of the RVL inhibits BVB at brain stem level independently of central inspiratory drive.     

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.     

Timing of DNA integration, transgenic mosaicism, and pronuclear microinjection

Selection of transgenic embryos prior to embryo transfer is a means to increase the efficiency of transgenic livestock production. Among transgenic reporters, cytoplasmic expression of green fluorescent protein (GFP) has features that make it ideal for transgenic embryo selection. The primary objective of this study was to assess cytoplasmic expression of a specially designed GFP reporter as a tool for transgenic bovine embryo selection. A second objective was to evaluate this reporter for studying transgenic mosaicism related to timing of integration of pronuclear microinjected DNA. Transgenic embryos produced by pronuclear injection showed a discrete pattern of GFP expression with clusters at 25, 50, and 100% of blastomeres expressing GFP. This pattern of mosaicism is interpreted to indicate that the integration of microinjected DNA occurred, not only at the pronuclear stage, but also in the subsequent cell divisions. Among the GFP-positive transgenic embryos, only in 21% did all the blastomeres show the green fluorescence. Using the fraction of positive blastomeres within an embryo, the timing of integration of microinjected DNA was estimated. The frequency of nonmosaic embryos expressing GFP is consistent with published germline transmission success rates of transgenic cattle derived from pronuclear microinjected embryos. These results indicate the possible application of GFP as a marker of transgenic embryos and graphically illustrate underlying complexities in DNA integration in embryos subjected to pronuclear microinjection.