81 research outputs found
Automated Docking Screens: A Feasibility Study
Molecular docking is themost practical approach to leverage protein structure for ligand discovery, but the technique retains important liabilities that make it challenging to deploy on a large scale. We have therefore created an expert system, DOCKBlaster, to investigate the feasibility of full automation. The method requires a PDB code, sometimes with a ligand structure, and from that alone can launch a full screen of large libraries. A critical feature is self-assessment, which estimates the anticipated reliability of the automated screening results using pose fidelity and enrichment. Against common benchmarks, DOCKBlaster recapitulates the crystal ligand pose within 2 A ̊ rmsd 50-60 % of the time; inferior to an expert, but respectrable. Half the time the ligand also ranked among the top 5 % of 100 physically matched decoys chosen on the fly. Further tests were undertaken culminating in a study of 7755 eligible PDB structures. In 1398 cases, the redocked ligand ranked in the top 5 % of 100 property-matched decoys while also posing within 2 A ̊ rmsd, suggesting that unsupervised prospective docking is viable. DOCK Blaster is available a
CSAR Benchmark Exercise of 2010: Selection of the Protein–Ligand Complexes
ABSTRACT: A major goal in drug design is the improvement of computational methods for docking and scoring. The Community Structure Activity Resource (CSAR) aims to collect available data from industry and academia which may be used for this purpose (www.csardock.org). Also, CSAR is charged with organizing community-wide exercises based on the collected data. The first of these exercises was aimed to gauge the overall state of docking and scoring, using a large and diverse data set of protein ligand complexes. Participants were asked to calculate the affinity of the complexes as provided and then recalculate with changes which may improve their specific method. This first data set was selected from existing PDB entries which had binding data (Kd or Ki) in Binding MOAD, augmented with entries from PDBbind. The final data set contains 343 diverse protein ligand complexes and spans 14 pKd. Sixteen proteins have three or more complexes in the data set, from which a user could start an inspection of congeneric series. Inherent experimental error limits the possible correlation between scores and measured affinity; R 2 is limited to ∼0.9 when fitting to the data set without over parametrizing. R 2 is limited to ∼0.8 when scoring the data set with a method trained on outside data. The details of how the data set was initially selected, and the process by which it matured t
Cellular Active N-Hydroxyurea FEN1 Inhibitors Block Substrate Entry to the Active Site
The structure-specific nuclease human flap endonuclease-1 (hFEN1) plays a key role in DNA replication and repair and may be of interest as an oncology target. We present the first crystal structure of inhibitor-bound hFEN1 and show a cyclic N-hydroxyurea bound in the active site coordinated to two magnesium ions. Three such compounds had similar IC50 values but differed subtly in mode of action. One had comparable affinity for protein and protein– substrate complex and prevented reaction by binding to active site catalytic metal ions, blocking the unpairing of substrate DNA necessary for reaction. Other compounds were more competitive with substrate. Cellular thermal shift data showed engagement of both inhibitor types with hFEN1 in cells with activation of the DNA damage response evident upon treatment. However, cellular EC50s were significantly higher than in vitro inhibition constants and the implications of this for exploitation of hFEN1 as a drug target are discussed
Molecular dynamics simulations and in silico peptide ligand screening of the Elk-1 ETS domain
Background: The Elk-1 transcription factor is a member of a group of proteins called ternary complex factors, which serve as a paradigm for gene regulation in response to extracellular signals. Its deregulation has been linked
to multiple human diseases including the development of tumours. The work herein aims to inform the design of
potential peptidomimetic compounds that can inhibit the formation of the Elk-1 dimer, which is key to Elk-1
stability. We have conducted molecular dynamics simulations of the Elk-1 ETS domain followed by virtual screening.
Results: We show the ETS dimerisation site undergoes conformational reorganisation at the a1b1 loop. Through
exhaustive screening of di- and tri-peptide libraries against a collection of ETS domain conformations representing the dynamics of the loop, we identified a series of potential binders for the Elk-1 dimer interface. The di-peptides showed no particular preference toward the binding site; however, the tri-peptides made specific interactions with residues: Glu17, Gln18 and Arg49 that are pivotal to the dimer interface.
Conclusions: We have shown molecular dynamics simulations can be combined with virtual peptide screening to obtain an exhaustive docking protocol that incorporates dynamic fluctuations in a receptor. Based on our findings, we suggest experimental binding studies to be performed on the 12 SILE ranked tri-peptides as possible compounds for the design of inhibitors of Elk-1 dimerisation. It would also be reasonable to consider the score ranked tri-peptides as a comparative test to establish whether peptide size is a determinant factor of binding to the ETS domain
Does a machine-learned potential perform better than an optimally tuned traditional force field?: a case study on fluorohydrins
We present a comparative study that evaluates the performance of a machine learning potential (ANI-2x), a conventional force field (GAFF), and an optimally tuned GAFF-like force field in the modeling of a set of 10 γ-fluorohydrins that exhibit a complex interplay between intra- and intermolecular interactions in determining conformer stability. To benchmark the performance of each molecular model, we evaluated their energetic, geometric, and sampling accuracies relative to quantum-mechanical data. This benchmark involved conformational analysis both in the gas phase and chloroform solution. We also assessed the performance of the aforementioned molecular models in estimating nuclear spin–spin coupling constants by comparing their predictions to experimental data available in chloroform. The results and discussion presented in this study demonstrate that ANI-2x tends to predict stronger-than-expected hydrogen bonding and overstabilize global minima and shows problems related to inadequate description of dispersion interactions. Furthermore, while ANI-2x is a viable model for modeling in the gas phase, conventional force fields still play an important role, especially for condensed-phase simulations. Overall, this study highlights the strengths and weaknesses of each model, providing guidelines for the use and future development of force fields and machine learning potentials
Does a Machine-Learned Potential Perform Better Than an Optimally Tuned Traditional Force Field? A Case Study on Fluorohydrins
We present a comparative
study that evaluates the performance of
a machine learning potential (ANI-2x), a conventional force field
(GAFF), and an optimally tuned GAFF-like force field in the modeling
of a set of 10 γ-fluorohydrins that exhibit a complex interplay
between intra- and intermolecular interactions in determining conformer
stability. To benchmark the performance of each molecular model, we
evaluated their energetic, geometric, and sampling accuracies relative
to quantum-mechanical data. This benchmark involved conformational
analysis both in the gas phase and chloroform solution. We also assessed
the performance of the aforementioned molecular models in estimating
nuclear spin–spin coupling constants by comparing their predictions
to experimental data available in chloroform. The results and discussion
presented in this study demonstrate that ANI-2x tends to predict stronger-than-expected
hydrogen bonding and overstabilize global minima and shows problems
related to inadequate description of dispersion interactions. Furthermore,
while ANI-2x is a viable model for modeling in the gas phase, conventional
force fields still play an important role, especially for condensed-phase
simulations. Overall, this study highlights the strengths and weaknesses
of each model, providing guidelines for the use and future development
of force fields and machine learning potentials
Does a Machine-Learned Potential Perform Better Than an Optimally Tuned Traditional Force Field? A Case Study on Fluorohydrins
We present a comparative
study that evaluates the performance of
a machine learning potential (ANI-2x), a conventional force field
(GAFF), and an optimally tuned GAFF-like force field in the modeling
of a set of 10 γ-fluorohydrins that exhibit a complex interplay
between intra- and intermolecular interactions in determining conformer
stability. To benchmark the performance of each molecular model, we
evaluated their energetic, geometric, and sampling accuracies relative
to quantum-mechanical data. This benchmark involved conformational
analysis both in the gas phase and chloroform solution. We also assessed
the performance of the aforementioned molecular models in estimating
nuclear spin–spin coupling constants by comparing their predictions
to experimental data available in chloroform. The results and discussion
presented in this study demonstrate that ANI-2x tends to predict stronger-than-expected
hydrogen bonding and overstabilize global minima and shows problems
related to inadequate description of dispersion interactions. Furthermore,
while ANI-2x is a viable model for modeling in the gas phase, conventional
force fields still play an important role, especially for condensed-phase
simulations. Overall, this study highlights the strengths and weaknesses
of each model, providing guidelines for the use and future development
of force fields and machine learning potentials
Generation of quantum configurational ensembles using approximate potentials
Conformational analysis is of paramount importance in drug design: it is crucial to determine pharmacological properties, understand molecular recognition processes, and characterize the conformations of ligands when unbound. Molecular Mechanics (MM) simulation methods, such as Monte Carlo (MC) and molecular dynamics (MD), are usually employed to generate ensembles of structures due to their ability to extensively sample the conformational space of molecules. The accuracy of these MM-based schemes strongly depends on the functional form of the force field (FF) and its parametrization, components that often hinder their performance. High-level methods, such as ab initio MD, provide reliable structural information but are still too computationally expensive to allow for extensive sampling. Therefore, to overcome these limitations, we present a multilevel MC method that is capable of generating quantum configurational ensembles while keeping the computational cost at a minimum. We show that FF reparametrization is an efficient route to generate FFs that reproduce QM results more closely, which, in turn, can be used as low-cost models to achieve the gold standard QM accuracy. We demonstrate that the MC acceptance rate is strongly correlated with various phase space overlap measurements and that it constitutes a robust metric to evaluate the similarity between the MM and QM levels of theory. As a more advanced application, we present a self-parametrizing version of the algorithm, which combines sampling and FF parametrization in one scheme, and apply the methodology to generate the QM/MM distribution of a ligand in aqueous solution. </p
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