Hello. I have a question regarding thermodynamic integration schemes based on a linear coupling parameter and subsequent integration over the potential energy gradient to determine free energies of binding or free energies of solvation. I know that there are a bunch of papers that demonstrate the feasibility of this approach in unrestrained or unconstrained MD, where experimental values are matched with a good accuracy. However, if there are restraints or constraints applied in the system, the Hamiltonian of the system is affected and the free energy as well. Are there coupling schemes which adaptively can incorporate the restraint or constraint energies so that equilibrium free energies will be obtained ? Another issue is given by the fact that the fluctuations in the system are affected if constraints or restraints are applied. How is it possible to predict free energies based on thermodynamic integration if there are restraints or constraints are applied ? (I know that the alternative way would be umbrella sampling and subsequent weighted histogram analysis, but what if I would like to predict a binding free energy and I do not know the reaction coordinate and restrain the center of mass in the binding cavity ?). Is there a way to compensate the harmonic restraint energy so that my result will be as accurate as in an extensively long MD-run ? Thanks for any suggestions.
Hi Emanuel,
check this guide out. It explains how to remove the contribution of the restraint in your result.
http://www.alchemistry.org/wiki/Example:_Absolute_Binding_Affinity
What you ask is likely to be system specific. In principle it should be possible to dig out equilibrium free energies from geometrically restrained simulations. You may wish to check the following paper, where they kept water molecules inside a protein cavity by positional restraints, and disappear them eventually. http://dx.doi.org/10.1021/ja0377908
http://dx.doi.org/10.1021/ja0377908
i think for a truely rigorous calculation of free energies with constraints you need sometyhing like this ... http://pubs.acs.org/doi/abs/10.1021/jp0217839 ... (McCammons approach referenced by Michal might work for small, rigid, and close to spherical molecules like water, but to me it is not clear how rigorous this method is if you are dealing with anything more complex than that)
You only need these corrections though if you are interested in ABSOLUTE free energies, if you want to calculate a DeltaDeltaG ... e.g. the difference in binding free energies between two different ligands in a binding site you should get away doing a simple alchemical mutation ... to give you a more precise answer it'd be helpful to know what type of ystem you consider here ...
Michael
Find attached paper it helps you to calculate binding free energy for macromolecules.
Thanks for your replies. Now, as far as I understand it, restraints or constraints affect the system, but I still get e.g. binding free energies, if I am considering everything based on thermodynamic cycles, and I will obtain the finite differences in the free energy when the same constraints are applied in all states of the thermodynamic cycle.
I think that sounds consistent to me. Maybe probabilistic approaches combined with enhanced sampling are more rigorous, with F = -kT ln P, or the PMF = -kT ln g(r). But that's another discussion. Thanks again.
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