An Automated Force Field Topology Builder (ATB) and Repository: Version 1.0

Malde, Alpeshkumar K.; Zuo, L.; Breeze, Matthew; Stroet, Martin; Poger, David; Nair, Pramod C.; Oostenbrink, Chris; Mark, Alan E.

doi:10.1021/ct200196m

Cited by 1,484 publications

(1,219 citation statements)

References 65 publications

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“…In this case, the user is responsible for preparing the simulation system. Web portals such as PRODRG, 39 Automated Topology Builder (ATB), 40 SwissParam, 41 and AnteChamber 42 can be used to generate topology and parameter files for nonstandard molecules.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

A Flexible, Grid-Enabled Web Portal for GROMACS Molecular Dynamics Simulations

Dijk

Wassenaar

Bonvin

2012

J. Chem. Theory Comput.

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Molecular dynamics simulations are becoming a standard part of workflows in structural biology. They are used for tasks as diverse as assessing molecular flexibility, probing conformational changes, assessing the impact of mutations, or gaining information about molecular interactions. However, performing a successful simulation requires sufficient computational resources, familiarity with the simulation software, and experience in the setup of a system and the analysis of the resulting trajectories. These considerations become especially critical in large-scale parametric MD simulations. Offering such tools to a wide user community requires a robust and versatile, but user-friendly, facility for molecular dynamics simulations with access to vast computational resources. Here, we present the GROMACS grid-enabled Web portal for the setup and execution of molecular dynamics simulation on the WeNMR grid infrastructure, a distributed network of computational resources within the European Grid Initiative. The Web portal aims at ease-of-use through automated setup of the simulation system using bestpractice protocols, yet allowing for tuning of key parameters. Alternatively, the simulation can be started from preconfigured GROMACS simulation systems. Performing multiple lengthy calculations using multiple processors on the WeNMR grid infrastructure ensures scalability. The combination of analysis routines for quality assurance and automatic recovery in case of failures provides a reliable platform for MD simulations. The GROMACS Web portal is embedded within the services of the WeNMR Virtual Research Community (VRC) accessible from http://www.wenmr.eu/wenmr/nmr-services. It is freely accessible upon registration with a valid X509 personal certificate with the enmr.eu Virtual Organization (VO).

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Section: ■ Results and Discussionmentioning

confidence: 99%

A Flexible, Grid-Enabled Web Portal for GROMACS Molecular Dynamics Simulations

Dijk

Wassenaar

Bonvin

2012

J. Chem. Theory Comput.

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“…The united atom option of GROMOS 54a7 force field (Huang et al 2011;Schmid et al 2011;) was used to calculate the intermolecular and intramolecular interactions for all systems. The DMPC topology was constructed from the Automated Topology Builder (ATB) and repository (Malde et al 2011). The optimized structure of EMH and EM − were obtained though quantum mechanical (QM) calculations with density functional theory (DFT) (Parr and Yang 1994) using the B3LYP exchange-correlation functional (Becke 1993;Imamura et al 2007) and the Pople basis set functions, 6-311++G(d,p) (Ditchfield et al 1971).…”

Section: Computational Details Of the Simulationsmentioning

confidence: 99%

Experimental and theoretical studies of emodin interacting with a lipid bilayer of DMPC

et al. 2017

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Emodin is one of the most abundant anthraquinone derivatives found in nature. It is the active principle of some traditional herbal medicines with known biological activities. In this work, we combined experimental and theoretical studies to reveal information about location, orientation, interaction and perturbing effects of Emodin on lipid bilayers, where we have taken into account the neutral form of the Emodin (EMH) and its anionic/deprotonated form (EM − ). Using both UV/Visible spectrophotometric techniques and molecular dynamics (MD) simulations, we showed that both EMH and EM − are located in a lipid membrane. Additionally, using MD simulations, we revealed that both forms of Emodin are very close to glycerol groups of the lipid molecules, with the EMH inserted more deeply into the bilayer and more disoriented relative to the normal of the membrane when compared with the EM − , which is more exposed to interfacial water. Analysis of several structural properties of acyl chains of the lipids in a hydrated pure DMPC bilayer and in the presence of Emodin revealed that both EMH and EM − affect the lipid bilayer, resulting in a remarkable disorder of the bilayer in the vicinity of the Emodin. However, the disorder caused by EMH is weaker than that caused by EM − . Our results suggest that these disorders caused by Emodin might lead to distinct effects on lipid bilayers including its disruption which are reported in the literature.

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“…edu.au/atb). 13 All of the 12 fragments identified by Drinkwater et al 9 contain at least one 5-or one 6-membered aromatic ring. In the structures of the complexes deposited in the PDB, this ring lies sandwiched between the side chains of Phe182 and Asn39 forming a π−π stacking interaction with the side chain of Phe182.…”

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confidence: 98%

Missing Fragments: Detecting Cooperative Binding in Fragment-Based Drug Design

Nair

Malde

Drinkwater

et al. 2012

ACS Med. Chem. Lett.

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The aim of fragment-based drug design (FBDD) is to identify molecular fragments that bind to alternate subsites within a given binding pocket leading to cooperative binding when linked. In this study, the binding of fragments to human phenylethanolamine N-methyltransferase is used to illustrate how (a) current protocols may fail to detect fragments that bind cooperatively, (b) theoretical approaches can be used to validate potential hits, and (c) apparent false positives obtained when screening against cocktails of fragments may in fact indicate promising leads.

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An Automated Force Field Topology Builder (ATB) and Repository: Version 1.0

Cited by 1,484 publications

References 65 publications

A Flexible, Grid-Enabled Web Portal for GROMACS Molecular Dynamics Simulations

A Flexible, Grid-Enabled Web Portal for GROMACS Molecular Dynamics Simulations

Experimental and theoretical studies of emodin interacting with a lipid bilayer of DMPC

Missing Fragments: Detecting Cooperative Binding in Fragment-Based Drug Design

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