Towards a MIP‐based alignment and docking in computer‐aided drug design

Barbany, Montserrat; Gutiérrez‐de‐Terán, Hugo; Sanz, Ferrán; Villà­-Freixa, Jordi

doi:10.1002/prot.20153

Cited by 6 publications

(4 citation statements)

References 35 publications

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“…The contents of this review suggest that both approaches are going to be successful in the upcoming years, and we predict that the convergence of powerful machines and simulation algorithms, smart protocols for multiscaling and, although sometimes obscure by the technology but especially important, a deep understanding of the physico-chemical properties of protein and peptide interfaces [91] are going to produce accurate predictions of complex formation. In this direction, computational tools that are able to integrate different algorithms and facilitate the researcher's work are going to become central, as well as formats and protocols to share methods, systems and simulations.…”

Section: Resultsmentioning

confidence: 99%

Multiscale Molecular Dynamics of Protein Aggregation

Ávila

Drechsel²,

Alcantara³

et al. 2011

CPPS

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The 60's gave birth to the practical implementation of classical mechanics to unravel the dynamics and energetics of biomolecules. In the 70's the use of generalized force fields and more advanced integrative solutions to the microscopic understanding of nature (like hybrid QM/MM) were introduced. During the 80's, algorithms to obtain free energy values were further developed and in the 90's practical integration schemes of molecular mechanics force fields with other levels of detail (QM on one extreme and advances in implicit solvation on the other) were implemented in widely spread software. In the first decade of the XXIst century a considerable effort has been put in two seemingly discordant models for the simulation of biomolecules. On the one hand, extraordinary advances in computing technologies (both in terms of processor power and of new efficient parallel and distributed computing schemas) have allowed researchers to deal with bigger systems and longer simulations, reaching molecular processes including millions of particles or lying in the microsecond scale. On the other hand, the realization that the relevant answers to many biomolecular problems are not homogeneously distributed through the molecular structure, something already envisioned by the QM/MM pioneers more than three decades ago, has led researchers to find smart ways of putting different emphases on different ranges of the spatial or system time scale. In this context, e.g., molecular aggregation represents a paradigm for multiscalability, as molecular recognition can be understood with simple (semi-)macroscopic terms when the two fragments are far apart, while the atomic interactions need to be considered in full detail upon close distances. In this manuscript the current status of the techniques that use multiple scale representations of biomolecules are reviewed, and the findings are synthesized in a modular schema that can be extensively used when studying aggregation processes. It is shown that a smart alternative to brute force and massive computation of uninteresting regions in the all atom potential energy surface is the consideration of a simplified reference potential, explored thoroughly in the relevant regions, combined with a free energy perturbation approach that transforms this simple representation to a full atom representation.

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Section: Resultsmentioning

confidence: 99%

Multiscale Molecular Dynamics of Protein Aggregation

Ávila

Drechsel²,

Alcantara³

et al. 2011

CPPS

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“…In BRUTUS, the shape match is favored over the electrostatic fit, and a value of five is assigned to grid points inside the van der Waals radius. However, the importance of shape and electrostatic fit may depend on the target [29], and this value might not be optimal for all targets.…”

Section: Energy Fieldsmentioning

confidence: 96%

BRUTUS: Optimization of a grid-based similarity function for rigid-body molecular superposition. II. Description and characterization

Rönkkö

Tervo

Parkkinen

et al. 2006

J Comput Aided Mol Des

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Finding novel lead molecules is one of the primary goals in early phases of drug discovery projects. However, structurally dissimilar compounds may exhibit similar biological activity, and finding new and structurally diverse lead compounds is difficult for computer algorithms. Molecular energy fields are appropriate for finding structurally novel molecules, but they are demanding to calculate and this limits their usefulness in virtual screening of large chemical databases. In our approach, energy fields are computed only once per superposition and a simple interpolation scheme is devised to allow coarse energy field lattices having fewer grid points to be used without any significant loss of accuracy. The resulting processing speed of about 0.25 s per conformation on a 2.4 GHz Intel Pentium processor allows the method to be used for virtual screening on commonly available desktop machines. Moreover, the results indicate that grid-based superposition methods could be efficiently used for the virtual screening of compound libraries.

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“…Considering the fact, that MIMIC only operates The Similarity Principle -New Trends and Applications … 9 with steric and electrostatic fields and that H-bonds and π-π interactions play a dominant role in drug receptor interactions, a further improvement of using this 3D-SIBAR approach should be obtained when shape similarities are calculated on basis of molecular interaction fields utilising the full panel of probe atoms (H-bond acceptor, H-bond donor, hydrophobic, aromatic,…). This method is utilised in the software package MIPSIM, which compares 3D distribution of both molecular electrostatic potentials derived from quantum chemical calculations and molecular interaction fields of series of biomolecules [12,13]. Obviously, the computational costs are by far higher than those for MIMIC and require front-end computational tools.…”

Section: D-shape Similaritymentioning

confidence: 99%

The Similarity Principle – New Trends and Applications in Ligand-Based Drug Discovery and ADMET Profiling

Schwaha¹,

Ecker

2008

Sci Pharm

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Structural similarity is one of the basic underlying principles in drug discovery and development. Numerous algorithms and concepts are known to search compound libraries for analogous compounds assuming that similar compounds show similar biological activity. In recent years the focus shifted towards more complex methods using 3D-shape similarities on one side and highly reductionistic approaches such as smiles substrings on the other side. Furthermore, pharmacological activity profiling becomes increasingly important. Within this review we will highlight selected new concepts and methods applying similarity metrics in the drug discovery and development process.

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Towards a MIP‐based alignment and docking in computer‐aided drug design

Cited by 6 publications

References 35 publications

Multiscale Molecular Dynamics of Protein Aggregation

Multiscale Molecular Dynamics of Protein Aggregation

BRUTUS: Optimization of a grid-based similarity function for rigid-body molecular superposition. II. Description and characterization

The Similarity Principle – New Trends and Applications in Ligand-Based Drug Discovery and ADMET Profiling

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