Biophysical aspects of reconstruction of a single cell by the methods of cell engineering

The problems of a low efficiency of mammalian cloning are discussed with emphasis on the necessity of the expertise of each step of single cell reconstruction, beginning with microsurgical manipulations. The fact of cell content leakage when the cell is held during microsurgery or microinjections with the help of the conventional method using negative pressure in the holding micropipette was demonstrated in experiments on murine embryos. It was shown that the rate of cell content efflux depends on the value of negative pressure generated in the holding micropipette, and is directly proportional to the dimensions of its orifice and the duration of micromanipulations. An alternative method of cell fixation using the capillary forces of the holding micropipette was proposed. The method optimizes the process of cell fixation, reducing the holding effort by two orders of magnitude. As a result, 92% of embryos remain viable after fixation of embryo, as compared with 39% in the conventional technique. In order to diminish the cell damage produced by the tip of a microinstrument, a new technique of fabricating micropipettes was proposed. The improved method of filling the micropipette with viscous liquids, including DNA, which is described in details in the paper, enabled constant (non-stop) microinjection of more than 1000 cells by hand, without any special automatic device.     

An application of the micropipette technique to the measurement of the mechanical properties of cultured bovine aortic endothelial cells

The mechanical properties of endothelial cells were measured using the micropipette technique. The cells employed were collected from bovine aortic endothelium and cultured in our laboratory. Endothelial cells from confluent monolayers under no-flow conditions were detached from their substrate by trypsin or by a mechanical method and suspended in modified Dulbecco medium (MDM). In the micropipette technique, a part of the cell is aspirated into the tip of the micropipette under a microscope, and the deformation measured from a photograph. In this study, the data obtained were analyzed using a model where the cytoskeletal elements, which are considered to be the primary stress bearing components, are assumed to reside in a submembranous, cortical layer. Detached cells were found to have almost homogeneous mechanical properties based on measurements from different regions of the surface of a single cell. However, a hysteresis loop was observed in the relation between pressure and cell deformation during the loading and unloading processes. The calculated elastic shear moduli obtained for the trypsin-detached cells were as much as 10-20 times larger than those of a red blood cell. Mechanically-detached cells had moduli approximately twice that of the trypsin detached cells. Passage time, i.e., cell culture age, had no influence on the mechanical properties of the trypsin-detached cells, but did have an effect on the mechanically-detached cells, with both the younger and older cells being somewhat stiffer.     

A method for microinjection into subpleural alveoli of rat lung in situ

A new technique is described for the micropuncture of rat lung in the intact thorax. Under pentobarbital sodium anesthesia a glass micropipette is passed through a small area of the parietal pleura, which has been cleared of overlying intercostal muscle. The micropipette is passed into the lung parenchyma and withdrawn again without collapsing the lung. The current application of this technique is in the microinjection of fluid into subpleural alveoli, which is illustrated using a suspension of colloidal gold. The gold particles are immediately dispersed over the surface of many alveoli, a small proportion spreading laterally as far as 4-6 mm. There is no evidence of alveolar flooding.     

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.     

A simple microinjection technique not employing a micromanipulator

A new microinjection method is presented in which a modified condenser is used instead of a conventional micromanipulator. The micropipette is located in a hole through the optical axis of the condenser lens of a normal microscope. The three-dimensional movement of the micropipette is simply controlled by manipulation of the adjusting screws controlling the movement of the condenser. In comparison with conventional microinjection instruments, the simplicity of this new instrument is outstanding.     

Transfer of macromolecules into living adult cardiomyocytes by microinjection

Among techniques commonly used to deliver bioactive molecules into living cells, microinjection is a very efficient method. Microinjection has been used extensively for gene transfer into different cell types. We applied the microinjection technique to the adult rat ventricular cardiac muscle cells (AVC) in primary culture and optimized microinjection parameters and the appropriate cell culture conditions. We also optimized the use of particular agents (i.e. 2,3-butanedione monoxime, verapamil) for the prevention of the cell damage caused by the micropuncture. We obtained the expression of a CMV--galactosidase reporter gene in up to 20% of the injected cells with efficient maintenance of long term cell viability. Under our experimental conditions direct microinjection is a very advantageous technique to transfer macromolecules into living adult cardiac muscle cells and a powerful system to study and manipulate the biochemistry and molecular biology of the cardiac myocyte.     

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     

Single Cell Adhesion Assay Using Computer Controlled Micropipette

Cell adhesion is a fundamental phenomenon vital for all multicellular organisms. Recognition of and adhesion to specific macromolecules is a crucial task of leukocytes to initiate the immune response. To gain statistically reliable information of cell adhesion, large numbers of cells should be measured. However, direct measurement of the adhesion force of single cells is still challenging and today’s techniques typically have an extremely low throughput (5–10 cells per day). Here, we introduce a computer controlled micropipette mounted onto a normal inverted microscope for probing single cell interactions with specific macromolecules. We calculated the estimated hydrodynamic lifting force acting on target cells by the numerical simulation of the flow at the micropipette tip. The adhesion force of surface attached cells could be accurately probed by repeating the pick-up process with increasing vacuum applied in the pipette positioned above the cell under investigation. Using the introduced methodology hundreds of cells adhered to specific macromolecules were measured one by one in a relatively short period of time (∼30 min). We blocked nonspecific cell adhesion by the protein non-adhesive PLL-g-PEG polymer. We found that human primary monocytes are less adherent to fibrinogen than their in vitro differentiated descendants: macrophages and dendritic cells, the latter producing the highest average adhesion force. Validation of the here introduced method was achieved by the hydrostatic step-pressure micropipette manipulation technique. Additionally the result was reinforced in standard microfluidic shear stress channels. Nevertheless, automated micropipette gave higher sensitivity and less side-effect than the shear stress channel. Using our technique, the probed single cells can be easily picked up and further investigated by other techniques; a definite advantage of the computer controlled micropipette. Our experiments revealed the existence of a sub-population of strongly fibrinogen adherent cells appearing in macrophages and highly represented in dendritic cells, but not observed in monocytes.     

In vivo single-cell electroporation for transfer of DNA and macromolecules

Single-cell electroporation allows transfection of plasmid DNA or macromolecules into individual living cells using modified patch electrodes and common electrophysiological equipment. This protocol is optimized for rapid in vivo electroporation of Xenopus laevis tadpole brains with DNA, dextrans, morpholinos and combinations thereof. Experienced users can electroporate roughly 40 tadpoles per hour. The technique can be adapted for use with other charged transfer materials and in other systems and tissues where cells can be targeted with a micropipette. Under visual guidance, an electrode filled with transfer material is placed in a cell body-rich area of the tadpole brain and a train of voltage pulses applied, which electroporates a nearby cell. We show examples of successfully electroporated single cells, instances of common problems and troubleshooting suggestions. Single-cell electroporation is an affordable method to fluorescently label and genetically manipulate individual cells. This powerful technique enables observation of single cells in an otherwise normal environment.     

Genetic transformation of animals by the insertion of foreign genes into the zygotes

A review of literature on genetic transformation of animal (mouse and Drosophila) germ cells by microinjection of the cloned genes into the pronuclei or into the early embryos. The fate of foreign genes and mechanisms of their integration into the recipient genome are considered in detail, as well as genetic consequences of the exogenic DNA insertion. Expression of the donor genes in transgenic animals is analyzed, its irregular and unusual pattern is noted in transgenic mice. An attempt has been undertaken not only to stress obvious advances in genetic transformation of animals, but also to outline unsolved problems related to inheritance of exogenous genes, insertion mutagenesis and irregular expression of the donor genes.     

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.     

Viscoelastic properties of transformed cells: role in tumor cell progression and metastasis formation

The micropipette aspiration technique was used to investigate the deformation properties of a panel of nontransformed and transformed rat fibroblasts derived from the same normal cell line. In this method, a step negative pressure is applied to the cell via a micropipette and the aspiration distance into the pipette as a function of time is determined using video techniques. A standard solid viscoelastic model was then used to analyze the viscoelastic properties of the cell. From these results, it is concluded that a direct correlation exists between an increase in deformability and progression of the transformed phenotype from a nontumorigenic cell line into a tumorigenic, metastatic cell line.     

Chemically facilitated microinjection of proteins into intact monolayers of tissue culture cells

Microinjection of physiologic quantities of macromolecules into tissue culture cells can facilitate the study of the biological effects of such macromolecules. In this communication, we describe a chemical technique which can be used to microinject proteins into monolayers of intact cells. Protein is loaded into erthrocyte ghosts, and the ghosts are then fused to the monolayer with polyethylene glycol 1000. Receipient cells can be injected with an efficiency of greater than 90% and contain an average of 3.8 X 10(6) microinjected molecules per cell. This technique circumvents certain problems encountered in virus-induced microinjection.     

A simple, rapid, aseptic method for filling micropipettes by centrifugation

A centrifugation method for sterilizing, storing, and filling micropipettes is described. Each micropipette is held in a centrifuge tube by a rubber stopper which clamps the butt end of the micropipette. The pipettes are sterilized and aseptically stored. A pipette is filled by injecting solution into the butt end of the micropipette. The micropipette is returned to a suspended position in the centrifuge tube and the liquid is rapidly forced into the micropipette tip by centrifugation. The technique is simpler and more rapid than presently used centrifugation methods.     

The effect on butyryl-CoA dehydrogenase of reagents specific for nucleophilic sulphur.

The technique of erythrocyte-mediated microinjection has been successfully adapted for use with cultured muscle cells. Erythrocytes were fused with primary chick myotube cultures with poly(ethylene glycol), and fluorescent antibodies to haemoglobin demonstrated that this protein was injected into the sarcoplasm of myotubes. The microinjection treatment did not significantly alter protein metabolism in the muscle cells as monitored by rates of synthesis and degradation of muscle proteins. 125I-labelled ribonuclease A and bovine serum albumin were degraded with the expected exponential decay kinetics after microinjection into muscle cells, and the half-life of ribonuclease A (40 h) was approximately twice that of bovine serum albumin (17 h). The degradation of ribonuclease A in the muscle cells was enhanced 1.6-fold in the absence of horse serum and chick-embryo extract, whereas the degradation of bovine serum albumin was not altered during deprivation. These results are characteristic of the breakdown of microinjected ribonuclease A and bovine serum albumin in other cell types. Therefore, our experiments indicate the erythrocyte-mediated microinjection is a valid technique to study protein degradation in primary chick muscle cultures.     

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.     

Red blood cell-mediated microinjection: methodological considerations

Red blood cell-mediated microinjection is a powerful approach to introducing proteins into the cytoplasm of cultured cells. In the course of our microinjection studies of intracellular protein degradation, we have encountered several potential problems with certain proteins. The microinjection procedure may be accompanied by denaturation of protein by radiolabeling procedures, binding of protein to red cell ghosts during loading, degradation of protein by the red cell ghost prior to microinjection, and adsorption of protein that leaks from red cell ghosts in the presence of fusogen to the fibroblast monolayer. We conclude with a list of points that must be considered prior to use of red cell-mediated microinjection to study a particular protein.     

The application of a homogeneous half-space model in the analysis of endothelial cell micropipette measurements

Experimental studies have shown that endothelial cells which have been exposed to shear stress maintain a flattened and elongated shape after detachment. Their mechanical properties, which are studied using the micropipette experiments, are influenced by the level as well as the duration of the shear stress. In the present paper, we analyze these mechanical properties with the aid of two mathematical models suggested by the micropipette technique and by the geometry peculiar to these cells in their detached post-exposure state. The two models differ in their treatment of the contact zone between the cell and the micropipette. The main results are expressions for an effective Young's modulus for the cells, which are used in conjunction with the micropipette data to determine an effective Young's modulus for bovine endothelial cells, and to discuss the dependence of this modulus upon exposure to shear stress.     

Intracellular delivery can be achieved by bombarding cells or tissues with accelerated molecules or bacteria without the need for carrier particles

To deliver non-permeable molecules into cells, one can utilize protocols such as microinjection, electroporation, liposome-mediated transfection or virus-mediated transfection. However, each method has its own limitations. Here we have developed a new molecular delivery technique where live cells or tissues are bombarded with highly accelerated molecules directly and without the need to conjugate the molecules onto carrier particles, which is essential in conventional "gene gun" experiments. Gene bombardments can be applied to well-differentiated cells, primary cultured cells/neurons or tissue explants, all of which are notoriously difficult to transfect. Exogenously made proteins and even bacteria can be effectively introduced into cells where they can execute their function or replicate. Our experimental results and physical model support the notion that accelerated chemicals, proteins, or microorganisms carry enough momentum to penetrate the plasma membrane. The bombardment process is associated with a transient (approximately 10 min) increase in cell permeability, but such membrane leakage has a minimal adverse effect on cell survival.     

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.