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<div class="container text_header"><h1>Mutation</h1></div> | <div class="container text_header"><h1>Mutation</h1></div> | ||
<div class="container text_header"><h2>Power through diversity</h2></div> | <div class="container text_header"><h2>Power through diversity</h2></div> | ||
− | + | <div class="container text_header"><h3>Motivation</h3></div> | |
+ | <div class="container text"> | ||
+ | Without mutation our would look very different to how we see it today. The evolutionary process, as we know it, | ||
+ | is mainly based | ||
+ | on the principles of mutagenesis and recombination. While recombination redistributes already existing features in nature, | ||
+ | mutagenesis may vary existing and create completely new ones. In nature the process of mutagenesis is random which means | ||
+ | quite a lot of unsuccessful variants reagarding survival. A successful mutation, on the other hand, may be the first step to a new and better | ||
+ | adapted species. But an advantageous mutation in one species may mean chaos for another. A predator for example may profit | ||
+ | from a mutation but its prey could quickly become endangered. In this race more mutations in a shorter period of time | ||
+ | could make the difference in survival or extinction. In a way this, so called mutation rate, could be seen as | ||
+ | the speed of evolution. One of the highest mutation rates kown to man is present in the family of <i>Flaviviridae</i>. | ||
+ | This group of viruses contains popular members like Dengue and Zika virus. Not 150 years | ||
+ | ago, in the blink of an evolutionary eye, Dengue was only able to infect | ||
+ | apes. Mutations enabled it to use humans as a host. But not only the hostrange but also the mortality of a virus | ||
+ | could be changed by only a few mutations. <br> | ||
+ | That is why fight fire with fire. By applying a special mutagenesis system, we are able to strongly | ||
+ | enhance mutation rate compared to the numbers present in nature. To create an effective evolutionary system we don't | ||
+ | only need a efficient mutagenesis system, but also need to use it during growth of the mutating organism. This is why | ||
+ | we use <i>in vivo</i> mutagenesis. It may seem less efficient than conventional laboratory mutagenesis but it provides | ||
+ | an advantage which can not be bestowed by <i>in vitro</i> techniques: <u>Evolution</u>. | ||
+ | </div> | ||
+ | |||
<div class="container text_header"><h3>Overview</h3></div> | <div class="container text_header"><h3>Overview</h3></div> | ||
<div class="container text"> | <div class="container text"> | ||
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<div class="container text"> | <div class="container text"> | ||
− | A more specific approach is the two plasmid mutagenesis system (Camps, 2003). It is | + | A more specific approach is the two plasmid mutagenesis system (Camps <i>et al.</i>, 2003). It is |
based on a modified DNA polymerase I, which replicates the first part of plasmids belonging | based on a modified DNA polymerase I, which replicates the first part of plasmids belonging | ||
to the ColE1-family, like pSB1C3. | to the ColE1-family, like pSB1C3. | ||
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<br> | <br> | ||
</div> | </div> | ||
+ | |||
</div> | </div> | ||
</body> | </body> | ||
</html> | </html> |
Revision as of 17:11, 17 October 2016
Mutation
Power through diversity
Motivation
Without mutation our would look very different to how we see it today. The evolutionary process, as we know it,
is mainly based
on the principles of mutagenesis and recombination. While recombination redistributes already existing features in nature,
mutagenesis may vary existing and create completely new ones. In nature the process of mutagenesis is random which means
quite a lot of unsuccessful variants reagarding survival. A successful mutation, on the other hand, may be the first step to a new and better
adapted species. But an advantageous mutation in one species may mean chaos for another. A predator for example may profit
from a mutation but its prey could quickly become endangered. In this race more mutations in a shorter period of time
could make the difference in survival or extinction. In a way this, so called mutation rate, could be seen as
the speed of evolution. One of the highest mutation rates kown to man is present in the family of Flaviviridae.
This group of viruses contains popular members like Dengue and Zika virus. Not 150 years
ago, in the blink of an evolutionary eye, Dengue was only able to infect
apes. Mutations enabled it to use humans as a host. But not only the hostrange but also the mortality of a virus
could be changed by only a few mutations.
That is why fight fire with fire. By applying a special mutagenesis system, we are able to strongly enhance mutation rate compared to the numbers present in nature. To create an effective evolutionary system we don't only need a efficient mutagenesis system, but also need to use it during growth of the mutating organism. This is why we use in vivo mutagenesis. It may seem less efficient than conventional laboratory mutagenesis but it provides an advantage which can not be bestowed by in vitro techniques: Evolution.
That is why fight fire with fire. By applying a special mutagenesis system, we are able to strongly enhance mutation rate compared to the numbers present in nature. To create an effective evolutionary system we don't only need a efficient mutagenesis system, but also need to use it during growth of the mutating organism. This is why we use in vivo mutagenesis. It may seem less efficient than conventional laboratory mutagenesis but it provides an advantage which can not be bestowed by in vitro techniques: Evolution.
Overview
One of the elementary requirements of every evolutionary process is variability, which can be achieved by
mutagenesis.
The alteration of existing genotypes is the only way to discover new features and abilities
of proteins and organisms. The aim of our mutagenesis system is to create a diversity of
binding proteins during the course of fermentation to gain as much different Evobodies
as possible. Building on the library approach and leading to the selection system, the
mutagenesis represents the central part of our project. After transformation of the library and an initial selection round
the mutagenesis has to take over. That is why we are using a system that is capable of in vivo
DNA alteration. Two different approaches were applied to reach this aim.
The mutagenesis plasmid is rather unspecific and leads to a general
raise of mutations in the DNA of host organisms. This system was used to get a manifold
increase of base pair exchanges and a strong repression of bacterial DNA repair mechanisms. Six
different proteins build this mutation system.
A more specific approach is the two plasmid mutagenesis system (Camps et al., 2003). It is
based on a modified DNA polymerase I, which replicates the first part of plasmids belonging
to the ColE1-family, like pSB1C3.
In the following, we will elaborate on why and how we implemented these two systems in detail in our project.