Abstract
The organoselenium compound ebselen has recently been investigated as a treatment for COVID-19; however, efforts to model ebselen in silico have been hampered by the lack of an efficient and accurate method to assess its binding to biological macromolecules. We present here a Generalized Amber Force Field modification which incorporates classical parameters for the selenium atom in ebselen, as well as a positively charged pseudoatom to simulate the σ-hole, a quantum mechanical phenomenon that dominates the chemistry of ebselen. Our approach is justified using an energy decomposition analysis of a number of density functional theory–optimized structures, which shows that the σ-hole interaction is primarily electrostatic in origin. Finally, our model is verified by conducting molecular dynamics simulations on a number of simple complexes, as well as the clinically relevant enzyme SOD1 (superoxide dismutase), which is known to bind to ebselen.Graphical Ebselen is an organoselenium drug that has shown promise for the treatment of a number of conditions. Computational modelling of drug-target complexes is commonly performed to determine the likely mechanism of action, however this is difficult in the case of ebselen, as an important mode of interaction is not simulated using current techniques. We present here an extension to common methods, which accurately captures this interaction.
Highlights
Ebselen (1) is a organoselenium compound that is of great interest to many medicinal chemists, in no small part due its unexpectedly low toxicity for an organoselenium species
We develop a parameter set for the selenium atom in ebselen, including a pseudoatom to simulate the σ -hole
We began by deriving the classical bonding parameters involving selenium in ebselen, using the procedure of Torsello [23]
Summary
Ebselen (1) is a organoselenium compound that is of great interest to many medicinal chemists, in no small part due its unexpectedly low toxicity for an organoselenium species. The selenium-containing heterocycle is reductively opened to afford the free selenol, which is the active catalyst. This is rapidly oxidised by ROS to a selenenic acid, which is reduced back to the selenol by glutathione (GSH) via a selenenyl sulfide. There is evidence that ebselen interacts with targets non-covalently [18]. These interactions may include association with aromatic or hydrophobic residues, or Hbonding through the carbonyl. Ebselen can form noncovalent complexes, through the interaction of Lewis bases with an electrophilic σ -hole on the selenium atom, to electron-deficient sulfur-containing molecules [20,21,22]
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