274 7.4 Molecular Cloning
7.4.1 �CLONING BASICS
Molecular cloning describes a suite of tools using a combination of genetic engineering,
cell and molecular biology, and biochemistry to generate modified DNA to enable it to be
replicated within a host organism (“cloning” simply refers to generating a population of cells
all containing the same DNA genetic code). The modified DNA may be derived from the
same or different species as the host organism.
In essence, for cloning of genomic DNA (i.e., DNA obtained from a cell’s nucleus), the
source DNA, which is to be modified and ultimately cloned, is first isolated and purified from
its originator species. Any tissue/cell source can, in principle, be used for this provided the
DNA is mostly intact. This DNA is purified (using a phenol extraction), and the number of
purified DNA molecules present is amplified using polymerase chain reaction (PCR) (see
Chapter 2). To ensure efficient PCR, primers need to be added to the DNA sequence (short
sequences of 10–20 nucleotide base pairs that act as binding sites for initiating DNA repli
cation by the enzyme DNA polymerase). PCR can also be used on RNA sample sources, but
using a modified PCR technique of the reverse transcription polymerase chain reaction that
first converts RNA back into complementary DNA (cDNA), which is then amplified using
conventional PCR. A similar process can also be used on synthetic DNA, that is, artificial
DNA sequences not from a native cell or tissue source.
The amplified, purified DNA is then chemically broken up into fragments by restriction
endonuclease enzymes, which cut the DNA at specific sequence locations. At this stage, add
itional small segments of DNA from other sources may be added that are designed to bind
to specific cut ends of the DNA fragments. These modified fragments are then combined
with vector DNA. In molecular biology, a vector is a DNA molecule that is used to carry
modified (often foreign) DNA into a host cell, where it will ultimately be replicated and the
genes in that recombinant DNA expressed can be replicated and/or expressed. Vectors are
generally variants of either bacterial plasmids or viruses (see Chapter 2). Such a vector that
contains the modified DNA is known as recombinant DNA. Vectors in general are designed
to have multiple specific sequence restriction sites that recognize the corresponding fragment
ends (called “sticky ends”) of the DNA generated by the cutting action of the restriction
endonucleases. Another enzyme called “DNA ligase” catalyzes the binding of the sticky ends
into the vector DNA at the appropriate restriction site in the vector, in a process called liga
tion. It is possible for other ligation products to form at this stage in addition to the desired
recombinant DNA, but these can be isolated at a later stage after the recombinant DNA has
been inserted in the host cell.
KEY POINT 7.4
The major types of vectors are viruses and plasmids, of which the latter is the most
common. Also, hybrid vectors exist such as a “cosmid” constructed from a lambda
phage and a plasmid, and artificial chromosomes that are relatively large modified
chromosome segments of DNA inserted into a plasmid. All vectors possess an origin
of replication, multiple restriction sites (also known as multiple cloning sites), and one
or more selectable marker genes.
Insertion of the recombinant DNA into the target host cell is done through a process
called either “transformation” for bacterial cells, “transfection” for eukaryotic cells, or, if a
virus is used as a vector, “transduction” (the term “transformation” in the context of animal
cells actually refers to changing to a cancerous state, so is avoided here). The recombinant
DNA needs to pass through the cell membrane barrier, and this can be achieved using both
natural and artificial means. For natural transformation to occur, the cell must be in a spe
cific physiological state, termed competent, which requires the expression of typically tens of
different proteins in bacteria to allow the cell to take up and incorporate external DNA from
solution (e.g., filamentous pili structures of the outer member, as well as protein complexes