Powerful tool for genetic engineering
Powerful tool for genetic engineering
Posted by:
Deepak Kumar
Viruses
cannot only cause illnesses in humans, they also infect bacteria. Those protect
themselves with a kind of 'immune system' which -- simply put -- consists of
specific sequences in the genetic material of the bacteria and a suitable
enzyme. It detects foreign DNA, which may originate from a virus, cuts it up
and thus makes the invaders harmless.
Scientists
from the Helmholtz Centre for Infection Research (HZI) in Braunschweig have now
shown that the dual-RNA guided enzyme Cas9, which is involved in the process,
has developed independently in various strains of bacteria. This enhances the
potential of exploiting the bacterial immune system for genome engineering.
Even though
it has only been discovered in recent years the immune system with the cryptic
name 'CRISPR-Cas' has been attracting attention of geneticists and
biotechnologists as it is a promising tool for genetic engineering. CRISPR is
short for Clustered Regularly Interspaced Palindromic Repeats, whereas Cas
simply stands for the CRISPR-associated protein. Throughout evolution, this
molecule has developed independently in numerous strains of bacteria. This is
now shown by Prof Emmanuelle Charpentier and her colleagues at the Helmholtz
Centre for Infection Research (HZI) who published their finding in the
international open access journal Nucleic Acids Research.
The
CRISPR-Cas-system is not only valuable for bacteria but also for working in the
laboratory. It detects a specific sequence of letters in the genetic code and
cuts the DNA at this point. Thus, scientists can either remove or add genes at
the interface. By this, for instance, plants can be cultivated which are
resistant against vermins or fungi. Existing technologies doing the same thing
are often expensive, time consuming or less accurate. In contrast to them the
new method is faster, more precise and cheaper, as fewer components are needed
and it can target longer gene sequences.
Additionally,
this makes the system more flexible, as small changes allow the technology to
adapt to different applications. "The CRISPR-Cas-system is a very powerful
tool for genetic engineering," says Emmanuelle Charpentier, who came to
the HZI from Umeå and was awarded with the Humboldt Professorship in 2013.
"We have analyzed and compared the enzyme Cas9 and the
dual-tracrRNAs-crRNAs that guide this enzyme site-specifically to the DNA in
various strains of bacteria." Their findings allow them to classify the
Cas9 proteins originating from different bacteria into groups. Within those the
CRISPR-Cas systems are exchangeable which is not possible between different
groups.
This allows
for new ways of using the technology in the laboratory: The enzymes can be
combined and thereby a variety of changes in the target-DNA can be made at
once. Thus, a new therapy for genetic disorders caused by different mutations
in the DNA of the patient could be on the horizon. Furthermore, the method
could be used to fight the AIDS virus HIV which uses a receptor of the human
immune cells to infect them. Using CRISPR-Cas, the gene for the receptor could
be removed and the patients could become immune to the virus. However, it is
still a long way until this aim will be reached.
Still those
examples show the huge potential of the CRISPR-Cas technology. "Some of my
colleagues already compare it to the PCR," says Charpentier. This method,
developed in the 1980s, allows scientists to 'copy' nucleic acids and therefore
to manifold small amounts of DNA to such an extent that they can be analyzed
biochemically. Without this ground-breaking technology a lot of experiments we
consider to be routine would have never been possible.
Charpentier
was not looking for new molecular methods in the first place. "Originally,
we were looking for new targets for antibiotics. But we found something
completely different," says Charpentier. This is not rare in science. In
fact some of the most significant scientific discoveries have been made
incidentally or accidentally.
Story
Source:
The above
story is based on materials provided by Helmholtz Centre for Infection
Research. Note: Materials may be edited for content and length.
Journal
Reference:
Ines
Fonfara, Anaïs Le Rhun, Krzysztof Chylinski, Kira Makarova, Anne-Laure
Lécrivain, Janek Bzdrenga, Eugene V. Koonin, Emmanuelle Charpentier. Phylogeny
of Cas9 determines functional exchangeability of dual-RNA and Cas9 among
orthologous type II CRISPR-Cas systems. Nucleic Acids Research, November 2013