posted on 2022-07-18, 19:14authored byAlexandre
C. Oliveira, Hugo A. L. Filipe, João P.
Prates Ramalho, Armindo Salvador, Carlos F. G. C. Geraldes, Maria João Moreno, Luís M. S. Loura
The correct parametrization of lanthanide complexes is
of the utmost
importance for their characterization using computational tools such
as molecular dynamics simulations. This allows the optimization of
their properties for a wide range of applications, including medical
imaging. Here we present a systematic study to establish the best
strategies for the correct parametrization of lanthanide complexes
using [Gd(DOTA)]− as a reference, which is used
as a contrast agent in MRI. We chose the bonded model to parametrize
the lanthanide complexes, which is especially important when considering
the study of the complex as a whole (e.g., for the study of the dynamics
of its interaction with proteins or membranes). We followed two strategies:
a so-called heuristic approach employing strategies already published
by other authors and another based on the more recent MCPB.py tool.
Adjustment of the Lennard-Jones parameters of the metal was required.
The final topologies obtained with both strategies were able to reproduce
the experimental ion to oxygen distance, vibrational frequencies,
and other structural properties. We report a new strategy to adjust
the Lennard-Jones parameters of the metal ion in order to capture
dynamic properties such as the residence time of the capping water
(τm). For the first time, the correct assessment
of the τm value for Gd-based complexes was possible
by recording the dissociative events over up to 10 μs all-atom
simulations. The MCPB.py tool allowed the accurate parametrization
of [Gd(DOTA)]− in a simpler procedure, and in this
case, the dynamics of the water molecules in the outer hydration sphere
was also characterized. This sphere was divided into the first hydration
layer, an intermediate region, and an outer hydration layer, with
a residence time of 18, 10 and 19 ps, respectively, independent of
the nonbonded parameters chosen for Gd3+. The Lennard-Jones
parameters of Gd3+ obtained here for [Gd(DOTA)]− may be used with similarly structured gadolinium MRI contrast agents.
This allows the use of molecular dynamics simulations to characterize
and optimize the contrast agent properties. The characterization of
their interaction with membranes and proteins will permit the design
of new targeted contrast agents with improved pharmacokinetics.