On the role of water density fluctuations in the inhibition of a proton channel

Hv1 is a transmembrane four-helix bundle that transports protons in a voltage-controlled manner. Its crucial role in many pathological conditions, including cancer and ischemic brain damage, makes Hv1 a promising drug target. Starting from the recently solved crystal structure of Hv1, we used structural modeling and molecular dynamics simulations to characterize the channel's most relevant conformations along the activation cycle. We then performed computational docking of known Hv1 inhibitors, 2-guanidinobenzimidazole (2GBI) and analogs. Although salt-bridge patterns and electrostatic potential profiles are well-defined and distinctive features of activated versus nonactivated states, the water distribution along the channel lumen is dynamic and reflects a conformational heterogeneity inherent to each state. In fact, pore waters assemble into intermittent hydrogen-bonded clusters that are replaced by the inhibitor moieties upon ligand binding. The entropic gain resulting from releasing these conformationally restrained waters to the bulk solvent is likely a major contributor to the binding free energy. Accordingly, we mapped the water density fluctuations inside the pore of the channel and identified the regions of maximum fluctuation within putative binding sites. Two sites appear as outstanding: One is the already known binding pocket of 2GBI, which is accessible to ligands from the intracellular side; the other is a site located at the exit of the proton permeation pathway. Our analysis of the waters confined in the hydrophobic cavities of Hv1 suggests a general strategy for drug discovery that can be applied to any ion channel.

In silico DNA-binding and rational design of ruthenium-arene anticancer drugs

Christian Gossens

Organometallic ruthenium(II)-arene (RA) antitumour compounds of the general type [Ru(II)(η6-arene)(X)2(pta)], RA-pta, and [Ru(II)(η6-arene)X(en)], RA-en, (X=leaving group; pta=1,3,5-triaza-7-phosphaadamantane, en=ethylenediamine) have been investigated computationally. The main focus has been i.e. the hydrolysis properties, ligand exchange reactions, binding to DNA and the analysis of the resulting structural perturbations. The goal of this thesis was to elucidate key steps in the reactivity of the above drugs that are not readily accessible by experimental techniques. The methodologies employed cover tailor made force fields in classical molecular dynamics (MD), density functional theory (DFT) MD simulations in implicit and explicit solvent as well as combined classical/quantum (QM/MM) MD simulations. For RA-pta compounds, binding energies between the metal centres and the surrounding ligands were calculated. The calculated energies rationalize the experimentally observed tendencies for arene loss, and show that the pta ligands are relatively strongly bound. Exchange of metal centre, methylation or protonation of the pta-ligand, or change of the arene result in significant differences in the metal-arene binding energies while leaving the metalphosphine bond strength essentially unchanged. Significantly lower binding energies and reduced hapticity are predicted for the exchange of arene by nucleobases. The latter show higher binding energies for nitrogen π-bonding than for p-bonding. No influence on the ruthenium-arene interaction was observed for RA-pta complexes bearing arenes with functionalized side chains. A combined DFT/continuum electrostatics approach has been used to estimate the protonation states and absolute pKa values of a series of RA-pta compounds and their hydrolysis products. Our results suggest that the selective in vivo activity towards cancer cells and the observed pH dependent DNA damage is due to a pH dependent activation/deactivation mechanism. In the context of rational drug design, it is hypothesised that analogues with fluorinated arene rings should result in improved selectivity towards hypoxic cancer cells. For RA-en complexes, we rationalized the chemoselectivity towards guanine. The calculated DFT binding energies for the three investigated nucleobases (G, A, C) decreases in the order G(N7) >> C(O2) ∼ C(N3) > A(N7) > G(O6) > OH2. The G(N7) complex is the most stable product due to a C6=O-HNen hydrogen bond while the corresponding C6-NH2-HNen interaction in adenine is repulsive. A study of the reaction of [(η6-benzene)Ru(en)(OH2)]2+ (1) towards the nucleobases G, A and C reveals a strong preference for a formation of an H-bonded cis vs. trans reactant adduct. Only guanine can form a thermally stable trans reactant adduct. The potential reaction sites of adenine and cytosine might loose their nucleophilicity by protonation while simultaneously the aqua leaving group of 1 is converted into an unreactive hydroxo ligand. For the reaction of 1 with guanine three different reaction pathways were identified, however, a "direct trans" reaction pathway is probably the most biologically relevant. Using classical and QM/MM MD we showed that both investigated ruthenium compounds, RA-pta and RA-en, can bind to the major groove of duplex DNA and are stable in this position. The DNA is highly flexible, adapts very fast and widens the major groove to accommodate the ruthenium complex. The local and global structural changes of the DNA (e.g. bending towards the major groove) observed for the RA-pta series are similar to those reported for cisplatin. A severe perturbation of the Watson-Crick base pairing adjacent to the binding site of RA-en was observed that can be linked to recent experimental results. Finally, a tailor made force field for RA-en was derived from our QM/MM trajectories using a force matching approach.

EPFL2007

In Silico Design of Three-Dimensional Porous Covalent Organic Frameworks via Known Synthesis Routes and Commercially Available Species

Cory Matthew Simon, Berend Smit

Covalent organic frameworks (COFs) are a class of advanced nanoporous polymeric materials which combine the crystallinity of metalorganic frameworks (MOFs) with the stability and potentially low-cost organic chemistry of porous polymer networks (PPNs). Like other advanced porous materials, COFs can potentially be designed to meet the needs of a variety of applications, from energy, to security, to human health. In this work, we construct in silico a database of hypothetical three-dimensional, crystalline COFs. In constructing this library we generate novel COFs using only established synthetic routes, previously utilized tetrahedral building units, and commercially available bridging linker molecules. This ensures that there are no known chemical barriers to synthesizing all materials in our database. We relaxed all materials in our database through semiempirical electronic structure calculations. In addition, for those structures that allow interpenetration, we designed interpenetrated versions of the basic structure. Then, we characterized the porosity of each of these structures. The final set of 4147 structures (based on 620 unique noninterpenetrated structures) and their computed properties are publicly available and can be screened to identify promising materials for a wide variety of applications. Here, we assess the suitability of our COFs for vehicular methane storage by performing molecular simulations to predict the equilibrium methane uptake.

Amer Chemical Soc2014

Antihypertensive drugs metabolism: an update to pharmacokinetic profiles and computational approaches

Vassily Hatzimanikatis, Ljubisa Miskovic, Aikaterini Zisaki

Drug discovery and development is a high-risk enterprise that requires significant investments in capital, time and scientific expertise. The studies of xenobiotic metabolism remain as one of the main topics in the research and development of drugs, cosmetics and nutritional supplements. Antihypertensive drugs are used for the treatment of high blood pressure, which is one the most frequent symptoms of the patients that undergo cardiovascular diseases such as myocardial infraction and strokes. In current cardiovascular disease pharmacology, four drug clusters - Angiotensin Converting Enzyme Inhibitors, Beta-Blockers, Calcium Channel Blockers and Diuretics - cover the major therapeutic characteristics of the most antihypertensive drugs. The pharmacokinetic and specifically the metabolic profile of the antihypertensive agents are intensively studied because of the broad inter-individual variability on plasma concentrations and the diversity on the efficacy response especially due to the P450 dependent metabolic status they present. Several computational methods have been developed with the aim to: (i) model and better understand the human drug metabolism; and (ii) enhance the experimental investigation of the metabolism of small xenobiotic molecules. The main predictive tools these methods employ are rule-based approaches, quantitative structure metabolism/activity relationships and docking approaches. This review paper provides detailed metabolic profiles of the major clusters of antihypertensive agents, including their metabolites and their metabolizing enzymes, and it also provides specific information concerning the computational approaches that have been used to predict the metabolic profile of several antihypertensive drugs.

Bentham Science Publishers2015

In silico DNA-binding and rational design of ruthenium-arene anticancer drugs

Christian Gossens

EPFL2007