Abstract
BackgroundMolecular dynamics (MD) simulations provide valuable insight into biomolecular systems at the atomic level. Notwithstanding the ever-increasing power of high performance computers current MD simulations face several challenges: the fastest atomic movements require time steps of a few femtoseconds which are small compared to biomolecular relevant timescales of milliseconds or even seconds for large conformational motions. At the same time, scalability to a large number of cores is limited mostly due to long-range interactions. An appealing alternative to atomic-level simulations is coarse-graining the resolution of the system or reducing the complexity of the Hamiltonian to improve sampling while decreasing computational costs. Native structure-based models, also called Gō-type models, are based on energy landscape theory and the principle of minimal frustration. They have been tremendously successful in explaining fundamental questions of, e.g., protein folding, RNA folding or protein function. At the same time, they are computationally sufficiently inexpensive to run complex simulations on smaller computing systems or even commodity hardware. Still, their setup and evaluation is quite complex even though sophisticated software packages support their realization.ResultsHere, we establish an efficient infrastructure for native structure-based models to support the community and enable high-throughput simulations on remote computing resources via GridBeans and UNICORE middleware. This infrastructure organizes the setup of such simulations resulting in increased comparability of simulation results. At the same time, complete workflows for advanced simulation protocols can be established and managed on remote resources by a graphical interface which increases reusability of protocols and additionally lowers the entry barrier into such simulations for, e.g., experimental scientists who want to compare their results against simulations. We demonstrate the power of this approach by illustrating it for protein folding simulations for a range of proteins.ConclusionsWe present software enhancing the entire workflow for native structure-based simulations including exception-handling and evaluations. Extending the capability and improving the accessibility of existing simulation packages the software goes beyond the state of the art in the domain of biomolecular simulations. Thus we expect that it will stimulate more individuals from the community to employ more confidently modeling in their research.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2105-15-292) contains supplementary material, which is available to authorized users.
Highlights
Molecular dynamics (MD) simulations provide valuable insight into biomolecular systems at the atomic level
The structure-based modeling (SBM) GridBean Based on the SBM Python script we have developed an SBM GridBean that allows users to configure and run SBM simulations
The laborious working steps and protocols, as well as security mechanisms are hidden in the inner logic of the UNICORE Rich Client (URC), the SBM GridBean and the UNICORE service and only properties and functions relevant for modeling and execution of workflows are exposed through the user interface so that end-users can focus on solving domain-specific challenges in biophysics, biochemistry or bioinformatics
Summary
Great progress in experimental techniques, such as Xray diffraction analysis and nuclear magnetic resonance spectroscopy, has led to a vastly increased diversity and quality of biomolecular structure data presented in the Protein Data Bank [1]. To enable regular use by the community of, in particular, experimental scientists or other researchers who do not possess specialized programming and/or modeling experience, it seems senseful to establish a research infrastructure (similar to the PDB service) standardizing and simplifying the simulation setup and submission, as well as the evaluation of these simulations. Providing a modeling and simulation service for SBM solves several challenging issues which we outline in the following: i) The simulations require use of computing resources which are usually unavailable locally and the scientist has to face the high technical complexity of distributed computing infrastructure. The middleware ARC (Advanced Resource Connector) [43] has been developed and included in the software stack of the European Middleware Initiative It implements web services standards for serverclient communication and provides a GUI client. The contact map is a two-dimensional representation of the residue-residue contacts present in the native conformation and the Q value trajectory is the temporal evolution of the number of formed native contacts along the simulated trajectory
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