Implicit solvation
Implicit solvation is a method to represent solvent as a continuous medium instead of individual "explicit" solvent molecules, most often used in molecular dynamics simulations and in other applications of molecular mechanics. The method is often applied to estimate free energy of solute-solvent interactions in structural and chemical processes, such as folding or conformational transitions of proteins, DNA, RNA, and polysaccharides, association of biological macromolecules with ligands, or transport of drugs across biological membranes.
The implicit solvation model is justified in liquids, where the potential of mean force can be applied to approximate the averaged behavior of many highly dynamic solvent molecules. However, the interfaces and the interiors of biological membranes or proteins can also be considered as media with specific solvation or dielectric properties. These media are not necessarily uniform, since their properties can be described by different analytical functions, such as "polarity profiles" of lipid bilayers.
There are two basic types of implicit solvent methods: models based on accessible surface areas that were historically the first, and more recent continuum electrostatics models, although various modifications and combinations of the different methods are possible.
The accessible surface area method is based on experimental linear relations between Gibbs free energy of transfer and the surface area of a solute molecule. This method operates directly with free energy of solvation, unlike molecular mechanics or electrostatic methods that include only the enthalpic component of free energy. The continuum representation of solvent also significantly improves the computational speed and reduces errors in statistical averaging that arise from incomplete sampling of solvent conformations, so that the energy landscapes obtained with implicit and explicit solvent are different. Although the implicit solvent model is useful for simulations of biomolecules, this is an approximate method with certain limitations and problems related to parameterization and treatment of ionization effects.
Accessible surface area-based method
The free energy of solvation of a solute molecule in the simplest ASA-based method is given by:where is the accessible surface area of atom i, and
is solvation parameter of atom i, i.e., a contribution to the free energy of solvation of the particular atom i per surface unit area. The needed solvation parameters for different types of atoms, nitrogen, oxygen, sulfur are usually determined by a least squares fit of the calculated and experimental transfer free energies for a series of organic compounds. The experimental energies are determined from partition coefficients of these compounds between different solutions or media using standard mole concentrations of the solutes.
Notably, solvation energy is the free energy needed to transfer a solute molecule from a solvent to vacuum. This energy can supplement the intramolecular energy in vacuum calculated in molecular mechanics. Thus, the needed atomic solvation parameters were initially derived from water-gas partition data. However, the dielectric properties of proteins and lipid bilayers are much more similar to those of nonpolar solvents than to vacuum. Newer parameters have thus been derived from octanol-water partition coefficients or other similar data. Such parameters actually describe transfer energy between two condensed media or the difference of two solvation energies.
Poisson-Boltzmann
The Poisson-Boltzmann equation describes the electrostatic environment of a solute in a solvent containing ions. It can be written in cgs units as:or :
where represents the position-dependent dielectric, represents the electrostatic potential, represents the charge density of the solute, represents the concentration of the ion i at a distance of infinity from the solute, is the valence of the ion, q is the charge of a proton, k is the Boltzmann constant, T is the temperature, and is a factor for the position-dependent accessibility of position r to the ions in solution. If the potential is not large, the equation can be linearized to be solved more efficiently.
Although this equation has solid theoretical justification, it is computationally expensive to calculate without approximations. A number of numerical Poisson-Boltzmann equation solvers of varying generality and efficiency have been developed, including one application with a specialized computer hardware platform. However, performance from PB solvers does not yet equal that from the more commonly used generalized Born approximation.
Generalized Born model
The Generalized Born model is an approximation to the exact Poisson-Boltzmann equation. It is based on modeling the solute as a set of spheres whose internal dielectric constant differs from the external solvent. The model has the following functional form:where
and
where is the permittivity of free space, is the dielectric constant of the solvent being modeled, is the electrostatic charge on particle i, is the distance between particles i and j, and is a quantity termed the effective Born radius. The effective Born radius of an atom characterizes its degree of burial inside the solute; qualitatively it can be thought of as the distance from the atom to the molecular surface. Accurate estimation of the effective Born radii is critical for the GB model.
With accessible surface area
The Generalized Born model augmented with the hydrophobic solvent accessible surface area term is GBSA. It is among the most commonly used implicit solvent model combinations. The use of this model in the context of molecular mechanics is termed MM/GBSA. Although this formulation has been shown to successfully identify the native states of short peptides with well-defined tertiary structure, the conformational ensembles produced by GBSA models in other studies differ significantly from those produced by explicit solvent and do not identify the protein's native state. In particular, salt bridges are overstabilized, possibly due to insufficient electrostatic screening, and a higher-than-native alpha helix population was observed. Variants of the GB model have also been developed to approximate the electrostatic environment of membranes, which have had some success in folding the transmembrane helixes of integral membrane proteins.Ad hoc fast solvation models
Another possibility is to use ad hoc quick strategies to estimate solvation free energy. A first generation of fast implicit solvents is based on the calculation of a per-atom solvent accessible surface area. For each of group of atom types, a different parameter scales its contribution to solvation.Another strategy is implemented for the CHARMM19 force-field and is called EEF1. EEF1 is based on a Gaussian-shaped solvent exclusion. The solvation free energy is
The reference solvation free energy of i corresponds to a suitably chosen small molecule in which group i is essentially fully solvent-exposed. The integral is over the volume Vj of group j and the summation is over all groups j around i. EEF1 additionally uses a distance-dependent dielectric, and ionic side-chains of proteins are simply neutralized. It is only 50% slower than a vacuum simulation. This model was later augmented with the hydrophobic effect and called Charmm19/SASA.
Hybrid implicit-explicit solvation models
It is possible to include a layer or sphere of water molecules around the solute, and model the bulk with an implicit solvent. Such an approach is proposed by M. J. Frisch and coworkers and by other authors. For instance in Ref. the bulk solvent is modeled with a Generalized Born approach and the multi-grid method used for Coulombic pairwise particle interactions. It is reported to be faster than a full explicit solvent simulation with the particle mesh Ewald summation method of electrostatic calculation. There are a range of hybrid methods available capable of accessing and acquiring information on solvation.Effects unaccounted for
The hydrophobic effect
Models like PB and GB allow estimation of the mean electrostatic free energy but do not account for the entropic effects arising from solute-imposed constraints on the organization of the water or solvent molecules. This is termed the hydrophobic effect and is a major factor in the folding process of globular proteins with hydrophobic cores. Implicit solvation models may be augmented with a term that accounts for the hydrophobic effect. The most popular way to do this is by taking the solvent accessible surface area as a proxy of the extent of the hydrophobic effect. Most authors place the extent of this effect between 5 and 45 cal/. Note that this surface area pertains to the solute, while the hydrophobic effect is mostly entropic in nature at physiological temperatures and occurs on the side of the solvent.Viscosity
Implicit solvent models such as PB, GB, and SASA lack the viscosity that water molecules impart by randomly colliding and impeding the motion of solutes through their van der Waals repulsion. In many cases, this is desirable because it makes sampling of configurations and phase space much faster. This acceleration means that more configurations are visited per simulated time unit, on top of whatever CPU acceleration is achieved in comparison to explicit solvent. It can, however, lead to misleading results when kinetics are of interest.Viscosity may be added back by using Langevin dynamics instead of Hamiltonian mechanics and choosing an appropriate damping constant for the particular solvent. In practical bimolecular simulations one can often speed-up conformational search significantly by using much lower collision frequency. Recent work has also been done developing thermostats based on fluctuating hydrodynamics to account for momentum transfer through the solvent and related thermal fluctuations. One should keep in mind, though, that the folding rate of proteins does not depend linearly on viscosity for all regimes.