Skinny and fat DNA
Texto Completo
Compartir
DNA is where all the genetic information necessary for the functioning, development,
growth and reproduction of living things is stored. It is responsible for transmitting the
instructions required to create other components of cells, such as proteins. It is composed
of two long polymers placed antiparallelly that intertwine to form a double helix. These
two chains are composed of nucleotides. The nitrogenous bases of nucleotides can be:
adenine (A), cytosine (C), guanine (G), and thymine (T). They always are linked, by
hydrogen bonds, adenines with thymines and cytosines with guanines, i.e., a purine with
a pyrimidine. These base pairs alternate with each other at an angle of 35 º and are
stabilized by π-π stacking interactions.
Recent studies start to investigate with artificial bases in order to introduce them into
DNA so that it can store more information and build different proteins. This would allow,
among other things, a benefit in medicine. One of these recent studies has created two
groups of artificial bases: skinny and fat. The skinny are pairs of pyrimidines and the fat
pairs of purines; therefore, the size complementarity of natural nitrogenous bases (AT and
GC) is not followed.
In this project, a computational study of the systems formed for the different artificial
pairs and natural pairs is made in order to check if the artificial bases are stable enough
to introduce them into the DNA. The parameters investigated are the optimal twist angle,
the π-π stacking interactions in the gas and water phases and the effect caused by different
substituents on this interaction.
The results obtained show that, despite having a wide range of angles, they differ very
little between optimal angle energy and the energy at 35 º, the original DNA, which would
allow the artificial bases to be they adapted to it correctly. In addition, π-π stacking
interactions are similar or superior to those produced by natural bases, implying greater
system stability. The base pairs CV and BP have been selected to check the effect of the
substituents, because they have been the ones that have obtained a more favourable
interaction energy. In the case of the CV, there has been an improvement with EWG
substitutes, but EDG do not affect it. In contrast, in the case of BP, there has been a lot of
variability, although in general, better results have also been obtained with an EWG
substituent. In this way, it can be concluded that the results obtained show that the
artificial bases are stable and open up a world of possibilities