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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This protocol describes a method for the temporary permeabilization of adherent cells using an inert gas jet. This technique facilitates the transfer of genetic material and biomolecules into adherent mammalian cells by the utilization of mechanical forces to disrupt the plasma membrane.

Abstract

Various cell transfection techniques exist and these can be broken down to three broad categories: viral, chemical and mechanical. This protocol describes a mechanical method to temporally permeabilize adherent cells using an inert gas jet that can facilitate the transfer of normally non-permeable macromolecules into cells. We believe this technique works by imparting shear forces on the plasma membrane of adherent cells, resulting in the temporary formation of micropores. Once these pores are created, the cells are then permeable to genetic material and other biomolecules. The mechanical forces involved do run the risk of permanently damaging or detaching cells from their substrate. There is, therefore, a narrow range of inert gas dynamics where the technique is effective. An inert gas jet has proven efficient at permeabilizing various adherent cell lines including HeLa, HEK293 and human abdominal aortic endothelial cells. This protocol is appropriate for the permeabilization of adherent cells both in vitro and, as we have demonstrated, in vivo, showing it may be used for research and potentially in future clinical applications. It also has the advantage of permeabilizing cells in a spatially restrictive manner, which could prove to be a valuable research tool.

Introduction

With the evolution of biomedicine and the understanding of cell mechanics, the delivery of biomolecules into cells has become vital to many research fields and medical therapies. Different techniques have been developed to introduce foreign molecules through the plasma membrane and into the cell cytosol. These can be generally classified as either: viral, chemical or mechanical techniques. Viral techniques can transfect genetic material such as RNA and DNA using viral vectors1. Viral techniques tend to have high efficiencies in certain cell lines, however they do have the potential for immune and inflammatory reactions2. Common chemical transfection methods include precipitation with calcium phosphate3, bacterial exotoxins4 and lipofection5. These techniques have proven to be effective; however, certain problems arise such as cell toxicity and non-specificity. Furthermore, techniques such as calcium phosphate precipitation have been found to have transfection efficiencies up to 70% but only in certain cell lines, rarely in primary cells6. This is of note as increasing research efforts are being put into primary cells, especially in the case of designing various treatments for clinical use and the study of DNA functioning.

Temporal disruption of the cell membrane through mechanical stimuli is an alternative for introducing foreign molecules into cells. Techniques include: microinjection of molecules7, electroporation using an electric field to disrupt the membrane8,9, sonoporation using ultrasound waves to disrupt the cell membrane10-12, particle bombardment as demonstrated by the "gene gun", which shoots particles bound with genes into the cell13, and more recently, the application of fluid shear stress that has been shown to temporally permeabilize mammalian cells14,15. Although mechanical methods avoid some of the aforementioned issues, they are typically accompanied by lower efficiencies and very complex and specialized setups. An atmospheric pressure glow discharge torch (APGD-t) was developed at McGill with the initial goal of functionalizing surfaces and detaching adherent cells in vitro16. Serendipitously, it was discovered that a live/dead stain being used was somehow being taken in by cells without a permeabilizing agent being added. Furthermore, this seemed to have occurred only in restricted areas of the wells which happened to match up with the torch path. Investigation into the permeabilization capabilities of the APGD-t continued and in control studies, it was found that the carrier inert gas jet of the plasma without excitation was also able to permeabilize cells. This contradicted the initial hypothesis that the reactive species created by the plasma jet temporarily impaired the membrane function and suggested that simply the mechanical forces were sufficient to cause cell permeabilization. From here, studies continued in our lab to try and quantify and characterize the permeabilization efficiency of an inert gas jet as well as look at its transfection capabilities16.

Through these studies, it has been found that micropores do in fact form in the plasma membrane, and these pores tend to reseal within approximately 5 sec15. We have demonstrated the technique's utility in vitro and in vivo in the chorioallantoic membrane of a chick embryo.

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Protocol

1. Development of LabView Program

  1. A mass flow controller (MKS M100B Mass-Flo Controller) is attached to the helium gas line to ensure a precise gas flow rate. This unit is controlled by an input voltage, ranging between 0 and 5 V. A control loop in the LabView program determines the required voltage at any given time. Interfacing between the computer and the mass flow controller is performed by a data acquisition device (NI USB-6009), and a 12 V power supply provides power to the mass flow controller.
  2. Two positioning linear slides are used to control the movement of the 6-well plate, one for each direction. Each assembly consists of a MA15-series Velmex Unislide Assembly coupled with a stepping motor, and both assemblies are controlled by a single Velmex VXM Stepping Motor Controller. The controller allows for manual jogging of each motor or accepts a string of external serial commands, the combination of which allow for specific movement patterns. Several patterns can be programmed into the LabView program, requiring the user to provide only the desired torch speed as well as the path dimensions.

2. Preparation of Equipment

  1. Open both the helium cylinder and regulator.
  2. Turn on the motor controller.
  3. Open the LabView program and verify all conditions.
  4. Make sure the platform is centered. To check, look at each motor stage and verify that each carriage is not near either stage end. Either have the program center the carriages or manually adjust by using the jogging controls on the front of the motor controller.
  5. If this is the first run of the day, it is recommended to run the program once without cells, to ensure the setup is working correctly.

3. Preparation of the Gas Jet Capillary Nozzle Height

  1. Remove the capillary from the holder and zero the height dial.
  2. Place the 6-well plate on the platform.
  3. Replace and lower the gas jet capillary to the bottom of the well until it hits the cover slip. Secure the capillary in the holder.
  4. Using the height dial, raise the capillary 3 mm. Mark this height on the capillary base.
  5. Raise the capillary to a safe height and then remove the 6-well plate.

4. Cell Permeabilization Protocol

  1. Culture adherent cell line to confluence on glass cover slips in a 6-well plate using standard culturing techniques. For HeLa cells, seed 6-well plates with 2 x 105 cells per well and incubate for 48 hr before treatment.
  2. Prepare appropriate volume of solution containing the desired vector. For hrGFPII-1, a concentration of 50 ng/μl in 1x PBS provides a strong fluorescent signal in HeLa cells 24 hr after transfection. For dextran studies, 80 μg/ml of 10 kDa green fluorescent dextran is recommended. Henceforth, this solution will be referred to as "vector solution".
  3. Remove cell culture media from well and rinse three times with 1x PBS.
  4. Pipette 1,370 μl of vector solution prepared in step 4.2 into well. This should result in a liquid depth of approximately 1.3 mm.
  5. Place the well containing the vector solution in the center of the platform. Lower the gas jet nozzle to the previously marked level indicating a nozzle height of 3 mm above the slide.
  6. Set helium flow rate in the LabView program and select the desired movement pattern to be used. Select "Run" when ready to begin the permeabilization protocol. There will be an initial lag period during which the mass flow controller is preparing to provide the necessary flow rate. Once the appropriate flow rate has been reached, the LabView program will activate the stepper motors to move the well in the desired permeabilization pattern. Once the platform has stopped, wait approximately 30 sec and remove the vector solution. Note: Optimal permeabilization occurs near a dynamic pressure of 100 to 200 Pa at the nozzle outlet, depending on the capillary diameter.
  7. Wash well three times with 1x PBS.
  8. Fill well with fresh culture media.
  9. Repeat steps 4.3 - 4.6 for desired number of experiments. Note: Be sure to include control samples which consist of wells being filled with the vector solution without the gas jet being run over them. Leave the solution in the control wells for approximately 1 min then proceed to steps 4.5 and 4.6.
  10. If running an hrGFP transfection experiment, return 6-well plate to incubator for 24 hr to allow transfected material to be transcribed by the cells. If running a dextran permeabilization experiment, return 6-well plate to incubator for 15 min.

5. Cell Imaging

  1. If desired, immediately before imaging, counterstain with appropriate live/dead stain to evaluate cell death.
  2. Image cells with appropriate microscope to investigate transfection/ permeabilization efficacy.

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Results

Permeabilization of HeLa cells with 10 kDa green fluorescent dextran using a helium gas jet with a 0.86 mm inner diameter capillary is shown in Figure 1. Cells were counterstained immediately after permeabilization with 2 μl/ml EthD-1 solution (LIVE/DEAD Viability/Cytotoxicity Kit) to visualize cell death. Immediately following counterstaining, cover slips were mounted and imaged. This figure shows results of running the helium gas jet at three different outlet pressures compared to a control sample...

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Discussion

Inert gas jet permeabilization is a useful technique for adherent cell transfection. It provides the ability to transfer biomolecules into cells with the use of mechanical forces, which eliminates the need for potentially harmful chemicals or viral vectors. The technique could potentially give researchers and clinicians an efficient and relatively simple way to precisely transfect cells. The selectivity of the permeabilization is also unique allowing researchers to only treat certain cells in a single colony which could ...

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Disclosures

The authors declare they have no competing financial interests.

Acknowledgements

The authors would like to thank the following funding sources: Canadian Institutes of Health Research (CIHR), the Natural Sciences and Engineering Research Council (NSERC).

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Materials

NameCompanyCatalog NumberComments
Vitality hrGFPII-1Agilent Technologies Canada240143-57Green fluorescent protein for transfection experiments on HeLa cells
Dextran, AlexaFluor 488; 10,000 MW, Anionic, FixableLife Technologies Inc.D22910dextran for permeabilization experiments
LIVE/DEAD Viability/Cytotoxicity KitLife Technologies Inc.L3224for counterstaining of mammalian cells
Prolong Gold Antifade ReagentInvitrogenP36930for mounting slides when imaging
Ultra High Purity HeliumPraxair Canada Inc.HE 5.0UH-T 
Hyclone DMEM/ High Glucose Media - 500 mlThermo ScientificSH30022.01for HeLa cells
Fetal Bovine SerumInvitrogen26140079For DMEM media
Penicillin-Streptomycin, liquidInvitrogen15140-122For DMEM media
Phosphate-Buffered Saline (PBS) 1xProduced in lab
 Table 1. List of required reagents
6-Well Clear TC-Treated MicroplatesCorning3506 
#1 22 x 22 CoverslipsFisher12-542B 
Glass CapillariesWorld Precision InstrumentsWPI Sizing Information
ID (mm): 1, 0.86, 0.68, 0.5 Order #: 1B200, 1B150, 1B120, 1B100
Mass-Flo ControllerMKSM100B01314CS1BVMass flow controller, Series M100B, requires an external 12 V power supply
USB-6009 DAQ DeviceNational Instruments779026-01 
UniSlide Assembly with stepping motor and controllerVelmexTwo series MA15 UniSlide Assemblies, fitted with Vexta 1.8° stepping motors provided by Velmex, and controlled by a VXM Stepping Motor Controller
 Table 2. List of required equipment

References

  1. Rosenberg, S. A., et al. Gene transfer into humans--immunotherapy of patients with advanced melanoma, using tumor-infiltrating lymphocytes modified by retroviral gene transduction. The New England Journal of Medicine. 323, 570-578 (1990).
  2. Yang, Y., et al. Cellular immunity to viral antigens limits E1-deleted adenoviruses for gene therapy. Proceedings of the National Academy of Sciences of the United States of America. 91, 4407-4411 (1994).
  3. Chen, C., Okayama, H. High-efficiency transformation of mammalian cells by plasmid DNA. Molecular and cellular biology. 7, 2745-2752 (1987).
  4. Walev, I., et al. Delivery of proteins into living cells by reversible membrane permeabilization with streptolysin-O. Proceedings of the National Academy of Sciences of the United States of America. 98, 3185-3190 (2001).
  5. Felgner, P. L., et al. Lipofection: a highly efficient, lipid-mediated DNA-transfection procedure. Proceedings of the National Academy of Sciences of the United States of America. 84, 7413-7417 (1987).
  6. Hamm, A., Krott, N., Breibach, I., Blindt, R., Bosserhoff, A. K. Efficient transfection method for primary cells. Tissue engineering. 8, 235-245 (2002).
  7. Rauth, S., Kucherlapati, R. S. Expression of DNA Transferred into Mammalian-Cells. J. Bioscience. 6, 543-567 (1984).
  8. Spandidos, D. A. Electric field-mediated gene transfer (electroporation) into mouse Friend and human K562 erythroleukemic cells. Gene analysis techniques. 4, 50-56 (1987).
  9. Chu, G., Hayakawa, H., Berg, P. Electroporation for the efficient transfection of mammalian cells with DNA. Nucleic Acids Research. 15, 1311-1326 (1987).
  10. Fechheimer, M., et al. Transfection of mammalian cells with plasmid DNA by scrape loading and sonication loading. Proceedings of the National Academy of Sciences of the United States of America. 84, 8463-8467 (1987).
  11. Koch, S., Pohl, P., Cobet, U., Rainov, N. G. Ultrasound enhancement of liposome-mediated cell transfection is caused by cavitation effects. Ultrasound in Medicine & Biology. 26, 897-903 (2000).
  12. Greenleaf, W. J., Bolander, M. E., Sarkar, G., Goldring, M. B., Greenleaf, J. F. Artificial cavitation nuclei significantly enhance acoustically induced cell transfection. Ultrasound in Medicine & Biology. 24, 587-595 (1998).
  13. Yang, N. S., Burkholder, J., Roberts, B., Martinell, B., McCabe, D. In vivo and in vitro gene transfer to mammalian somatic cells by particle bombardment. Proceedings of the National Academy of Sciences of the United States of America. 87, 9568-9572 (1990).
  14. Hallow, D. M., et al. Shear-induced intracellular loading of cells with molecules by controlled microfluidics. Biotechnology and Bioengineering. 99, 846-854 (2008).
  15. Chouinard-Pelletier, G. L., Guay, M., Coulombe, D., Leask, S., L, R., Jones, E. Use of inert gas jets to measure the forces required for mechanical gene transfection. Biomedical Engineering Online. 11, (2012).
  16. Leduc, M., Coulombe, S., Leask, R. L. Atmospheric Pressure Plasma Jet Deposition of Patterned Polymer Films for Cell Culture Applications. Ieee T. Plasma Sci. 37, 927-933 (2009).
  17. Lu, H., et al. Microfluidic shear devices for quantitative analysis of cell adhesion. Analytical Chemistry. 76, 5257-5264 (2004).
  18. Sankin, G. N., Yuan, F., Zhong, P. Pulsating tandem microbubble for localized and directional single-cell membrane poration. Physical Review Letters. 105, 078101(2010).

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Keywords Cell PermeabilizationInert Gas JetMechanical TransfectionAdherent CellsIn VitroIn VivoShear ForcesMicroporesHeLaHEK293Human Abdominal Aortic Endothelial CellsGenetic MaterialBiomoleculesCell DamageCell Detachment

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