posted on 2024-05-27, 08:13authored byStefano Bosio, Mattia Bernetti, Walter Rocchia, Matteo Masetti
It is nowadays clear that RNA molecules
can play active roles in
several biological processes. As a result, an increasing number of
RNAs are gradually being identified as potentially druggable targets.
In particular, noncoding RNAs can adopt highly organized conformations
that are suitable for drug binding. However, RNAs are still considered
challenging targets due to their complex structural dynamics and high
charge density. Thus, elucidating relevant features of drug-RNA binding
is fundamental for advancing drug discovery. Here, by using Molecular
Dynamics simulations, we compare key features of ligand binding to
proteins with those observed in RNA. Specifically, we explore similarities
and differences in terms of (i) conformational flexibility of the
target, (ii) electrostatic contribution to binding free energy, and
(iii) water and ligand dynamics. As a test case, we examine binding
of the same ligand, namely riboflavin, to protein and RNA targets,
specifically the riboflavin (RF) kinase and flavin mononucleotide
(FMN) riboswitch. The FMN riboswitch exhibited enhanced fluctuations
and explored a wider conformational space, compared to the protein
target, underscoring the importance of RNA flexibility in ligand binding.
Conversely, a similar electrostatic contribution to the binding free
energy of riboflavin was found. Finally, greater stability of water
molecules was observed in the FMN riboswitch compared to the RF kinase,
possibly due to the different shape and polarity of the pockets.