Recent advances in QM/MM free energy calculations using reference potentials

Duarte, Fernanda; Amrein, Beat Anton; Blaha-Nelson, David; Kamerlin, Shina Caroline Lynn

doi:10.1016/j.bbagen.2014.07.008

Cited by 61 publications

(54 citation statements)

References 144 publications

(278 reference statements)

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“…Another approach is to perform the sampling at the MM level and then evaluate QM/MM energies only for a restricted number of snapshots. Valid QM/MM free energies can be obtained either by a MM→QM/MM FES calculation, employing the thermodynamic cycle in Figure a, or by reweighting of the MM snapshots toward the QM/MM energy function (Figs. b and c) .…”

Section: Introductionmentioning

confidence: 99%

“…b and c) . Such approaches have been used for ligand binding, as well as for solvation free energies and quite extensively for enzyme reactions . The challenge with this approach is to obtain converged results for the MM→QM/MM perturbation, which must be performed in a single step to avoid the need of QM/MM sampling, that is, to ensure that the overlap of the MM and QM/MM potentials is large enough (a few approaches involving QM/MM sampling have been suggested).…”

Section: Introductionmentioning

confidence: 99%

“…The challenge with this approach is to obtain converged results for the MM→QM/MM perturbation, which must be performed in a single step to avoid the need of QM/MM sampling, that is, to ensure that the overlap of the MM and QM/MM potentials is large enough (a few approaches involving QM/MM sampling have been suggested). For enzyme reactions, proper convergence has been obtained by keeping the QM system fixed; without this approximation, very poor convergence has been observed, which could only partly be decreased by employing SQM/MM sampling . For binding affinities, such an approximation seems inappropriate, as the entropy and reorganisation of the ligand is expected to be important for the binding.…”

Section: Introductionmentioning

confidence: 99%

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Converging ligand‐binding free energies obtained with free‐energy perturbations at the quantum mechanical level

2016

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In this article, the convergence of quantum mechanical (QM) free‐energy simulations based on molecular dynamics simulations at the molecular mechanics (MM) level has been investigated. We have estimated relative free energies for the binding of nine cyclic carboxylate ligands to the octa‐acid deep‐cavity host, including the host, the ligand, and all water molecules within 4.5 Å of the ligand in the QM calculations (158–224 atoms). We use single‐step exponential averaging (ssEA) and the non‐Boltzmann Bennett acceptance ratio (NBB) methods to estimate QM/MM free energy with the semi‐empirical PM6‐DH2X method, both based on interaction energies. We show that ssEA with cumulant expansion gives a better convergence and uses half as many QM calculations as NBB, although the two methods give consistent results. With 720,000 QM calculations per transformation, QM/MM free‐energy estimates with a precision of 1 kJ/mol can be obtained for all eight relative energies with ssEA, showing that this approach can be used to calculate converged QM/MM binding free energies for realistic systems and large QM partitions. © 2016 The Authors. Journal of Computational Chemistry Published by Wiley Periodicals, Inc.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Converging ligand‐binding free energies obtained with free‐energy perturbations at the quantum mechanical level

2016

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“…It has attracted renewed interest in recent years, 84,86 in the form of sampling approaches involving either the reweighting or perturbation of MM trajectories to the QM/MM level [185][186][187][188][189][190][191][192][193][194] (including the so-called paradynamics [195][196][197][198] or the continuous switching between MM and QM/MM interactions. 199 The advantage of adjusting the parameters of the MM model to improve the convergence has also been noted in this context.…”

Section: Introductionmentioning

confidence: 99%

Absolute proton hydration free energy, surface potential of water, and redox potential of the hydrogen electrode from first principles: QM/MM MD free-energy simulations of sodium and potassium hydration

Hofer

Hünenberger

2018

The Journal of Chemical Physics

104

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The absolute intrinsic hydration free energy G • H + ,wat of the proton, the surface electric potential jump χ • wat upon entering bulk water, and the absolute redox potential V • H + ,wat of the reference hydrogen electrode are cornerstone quantities for formulating single-ion thermodynamics on absolute scales. They can be easily calculated from each other but remain fundamentally elusive, i.e., they cannot be determined experimentally without invoking some extra-thermodynamic assumption (ETA). The Born model provides a natural framework to formulate such an assumption (Born ETA), as it automatically factors out the contribution of crossing the water surface from the hydration free energy. However, this model describes the short-range solvation inaccurately and relies on the choice of arbitrary ion-size parameters. In the present study, both shortcomings are alleviated by performing first-principle calculations of the hydration free energies of the sodium (Na + ) and potassium (K + ) ions. The calculations rely on thermodynamic integration based on quantum-mechanical molecular-mechanical (QM/MM) molecular dynamics (MD) simulations involving the ion and 2000 water molecules. The ion and its first hydration shell are described using a correlated ab initio method, namely resolution-of-identity second-order Møller-Plesset perturbation (RIMP2). The next hydration shells are described using the extended simple point charge water model (SPC/E). The hydration free energy is first calculated at the MM level and subsequently increased by a quantization term accounting for the transformation to a QM/MM description. It is also corrected for finite-size, approximate-electrostatics, and potentialsummation errors, as well as standard-state definition. These computationally intensive simulations provide accurate first-principle estimates for G • H + ,wat , χ • wat , and V • H + ,wat , reported with statistical errors based on a confidence interval of 99%. The values obtained from the independent Na + and K + simulations are in excellent agreement. In particular, the difference between the two hydration free energies, which is not an elusive quantity, is 73.9 ± 5.4 kJ mol 1 (K + minus Na + ), to be compared with the experimental value of 71.7 ± 2.8 kJ mol 1 . The calculated values of G • H + ,wat , χ • wat , and V • H + ,wat ( 1096.7 ± 6.1 kJ mol 1 , 0.10 ± 0.10 V, and 4.32 ± 0.06 V, respectively, averaging over the two ions) are also in remarkable agreement with the values recommended by Reif and Hünenberger based on a thorough analysis of the experimental literature ( 1100 ± 5 kJ mol 1 , 0.13 ± 0.10 V, and 4.28 ± 0.13 V, respectively). The QM/MM MD simulations are also shown to provide an accurate description of the hydration structure, dynamics, and energetics. Published by AIP Publishing.

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“…The method is validated with suitable benchmarks and its efficiency demonstrated. Kamerlin et al [10] review the concept of QM/MM free energy calculations using reference potentials. The idea behind this approach is that a lower-level potential energy description, that allows extensive sampling and free energy calculations to be carried out, is used to obtain higher-level QM or QM/MM free energies as a perturbation to the reference potential.…”

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confidence: 99%