276 7.4 Molecular Cloning
conferring resistance against a specific antibiotic that would otherwise be lethal to the cell.
For example, in bacteria, there are several resistance genes available that are effective against
broad-spectrum antibiotics such as ampicillin, chloramphenicol, and kanamycin. Those host
cells that have successfully taken up a plasmid vector during transformation will survive cul
turing conditions that include the appropriate antibiotic, whereas those that have not taken
up the plasmid vector will die. Using host animal cells, such as human cells, involves a similar
strategy to engineer a stable transfection such that the recombinant DNA is incorporated
ultimately into the genomic DNA using a marker gene that is encoded into the genomic DNA
conferring resistance against the antibiotic Geneticin. Unstable or transient transfection does
not utilize marker genes on the host cell genome but instead retains the recombinant DNA as
plasmids. These ultimately become diluted after multiple cell generations and so the recom
binant DNA is lost.
7.4.2 �SITE-DIRECTED MUTAGENESIS
SDM is a molecular biology tool that uses the techniques of molecular cloning described
earlier to make controlled, spatially localized mutations to a DNA sequence, at the level of
just a few, or sometimes one, nucleotide base pairs. The types of mutations include a single
base change (point mutation), deletion or insertion, as well as multiple base pair changes. The
basic method of SDM uses a short DNA primer sequence that contains the desired mutations
and is complementary to the template DNA around the mutation site and can therefore
displace the native DNA by hybridizing with the DNA in forming stable Watson–Crick
base pairs. This recombinant DNA is then cloned using the same procedure as described in
section 7.4.
SDM has been used in particular to generate specific cysteine point mutations. These have
been applied for bioconjugation of proteins as already discussed in the chapter and also for a
technique called cysteine scanning (or cys-scanning) mutagenesis. In cys-canning mutagen
esis, multiple point mutations are made to generate several foreign cysteine sites, typically in
pairs. The purpose here is that if a pair of such nonnative cysteine amino acids is biochem
ically detected as forming a disulfide bond in the resultant protein, then this indicates that
these native residue sites that were mutated must be within ~0.2 nm distance. In other words,
it enables 3D mapping of the location of different key residues in a protein. This was used,
for example, in determining key residues used in the rotation of the F1Fo-ATP synthase that
generates the universal cellular fuel of ATP (see Chapter 2).
A similar SDM technique is that of alanine scanning. Here, the DNA sequence is point
mutated to replace specific amino acid residues in a protein with the amino acid alanine.
Alanine consists of just a methyl (–CH3) substituent group and so exhibits relatively little
steric hindrance effects, as well as minimal chemical reactivity. Substituting individual native
amino acid residues with alanine, and then performing a function test on that protein, can
generate insight into the importance of specific amino acid side groups on the protein’s bio
logical function.
7.4.3 �CONTROLLING GENE EXPRESSION
There are several molecular biology tools that allow control of the level of protein expres
sion from a gene. The ultimate control is to delete the entire gene from the genome of a
specific population of cells under investigation. These deletion mutants, also known as gene
knockouts, are often invaluable in determining the biological function of a given gene, since
the mutated cells can be subjected to a range of functionality tests and compares against the
native cell (referred to as the wild type).
A more finely tuned, reversible method to modify gene expression is to use RNA silen
cing. RNA silencing is a natural and ubiquitous phenomenon in all eukaryote cells in which