Chapter 7 – Complementary Experimental Tools 275
in the cell membrane to pump DNA from the outside to the inside). This natural phenom
enon in bacteria occurs in a process called “horizontal gene transfer,” which results in genetic
diversity through the transfer of plasmid DNA between different cells, and is, for example, a
mechanism for propagating antibiotic resistance in a cell population. It may also have evolved
as a mechanism to assist in the repair of damaged DNA, that is, to enable the internaliza
tion of nondamaged DNA that can then be used as a template from which to repair native
damaged DNA.
Artificial methods can improve the rate of transformation. These can include treating cells
first with enzymes to strip away outer cells walls, adding divalent metal ions such as mag
nesium or calcium to increase binding of DNA (which has a net negative charge in solution
due to the presence of the backbone of negatively charged phosphate groups), or increasing
cell membrane fluidity. These also include methods that involve a combination of cold and
heat shocking cells to increase internalization of recombinant by undetermined mechanisms
as well as using ultrasound (sonication) to increase the collision frequency of recombinant
DNA with host cells. The most effective method, however, is electroporation. This involves
placing the aqueous suspension of host cells and recombinant DNA into an electrostatic
field of strength 10–20 kV cm−1 for a few milliseconds that increases the cell membrane
permeability dramatically through creating transient holes in the membrane through which
plasmid DNA may enter.
Transfection can be accomplished using an extensive range of techniques, some of which
are similar to those used for transformation, for example, the use of electroporation. Other
more involved methods have been optimized specifically for host animal cell transfection,
however. These include biochemical-based methods such as packaging recombinant DNA
into modified liposomes that then empty their contents into a cell upon impact on, and mer
ging with, the cell membrane. A related method is protoplast fusion, which involves chem
ically or enzymatically stripping away the cell wall from a bacterial cell to enable it to fuse in
suspension with a host animal cell. This delivers the vector that may be inside the bacterial
cell, but with the disadvantage of delivery of the entire bacterial cell contents, which may
potentially be detrimental to the host cell.
But there are also several biophysical techniques for transfection. These include
sonoporation (using ultrasound to generate transient pores in cell membranes), cell squeezing
(gently massaging cells through narrow flow channels to increase the membrane perme
ability), impalefection (introducing DNA bound to a surface of a nanofiber by stabbing the
cell), gene guns (similar to impalefection but using DNA bound to nanoparticles that are fired
into the host cell), and magnet-assisted transfection or magnetofection (similar to the gene
gun approach, though here DNA is bound to a magnetic nanoparticle with an external B-field
used to force the particles into the host cells).
The biophysical transfection tool with the most finesse involves optical transfection, also
known as photoporation. Here, a laser beam is controllably focused onto the cell membrane
generating localized heating sufficient to form a pore in the cell membrane and allow recom
binant DNA outside the cell to enter by diffusion. Single-photon absorption processes in
the lipid bilayer can be used here, centered on short wavelength visible light lasers; how
ever, better spatial precision is enabled by using a high-power near-infrared (IR) femtosecond
pulsed laser that relies on two-photon absorption in the cell membrane, resulting in smaller
pores and less potential cell damage.
Viruses undergoing transfection (i.e., viral transduction) are valuable because they can
transfer genes into a wide variety of human cells in particular with very high transfer rates.
However, this method can also be used for other cell types, including bacteria. Here, the
recombinant DNA is packaged into an empty virus capsid protein coat (see Chapter 2). The
virus then performs its normal roles of attaching to host cell and then injecting the DNA into
the cell very efficiently, compared to the other transfection/transformation methods.
The process of inserting recombinant DNA into a host cell has normally low efficiency,
with only a small proportion of host cells successfully taking up the external DNA. This
presents a technical challenge in knowing which cells have done so, since these are the ones
that need to be selectively cultivated from a population. This selection is achieved by engin
eering one or more selectable markers into the vector. A selectable marker is usually a gene