Coulombic Surface Coloring

Coulombic Surface Coloring calculates electrostatic potential according to Coulomb's law:

φ = Σ [q_i / (εd_i)]

φ is the potential (which varies in space), q are the atomic partial charges, d are the distances from the atoms, and ε is the dielectric, representing screening by the medium or solvent. A distance-dependent dielectric (ε = Cd where C is some constant) is sometimes used to approximate screening by implicit solvent.

Coulombic Surface Coloring colors molecular surfaces by the potential values and can handle structures with or without explicit hydrogens. It can also generate a grid of the potential values.

Whereas Coulombic Surface Coloring can only color molecular surfaces based on the charges of the residues they enclose, the coulombic command has an option to use the charges of an arbitrary set of atoms. This allows coloring the surface of one molecule by the potential from another, for example, or coloring nonmolecular surfaces such as density isosurfaces.

The Electrostatic Surface Coloring tool is similar, but uses a previously computed electrostatic potential grid. The grid could be from Coulombic Surface Coloring or from any of several separate (not included with Chimera) programs that solve the Poisson-Boltzmann equation. Chimera does include interfaces to such programs: DelPhiController requires a local (user-installed) copy of DelPhi, and the APBS tool can use either a web service or a locally installed copy of APBS (Adaptive Poisson-Boltzmann Solver).

Poisson-Boltzmann calculations are more complex and, if done correctly, more accurate than simple Coulomb's law approaches. However, a Coulombic potential may suffice for visualization. (See https://tinyurl.com/mzopva for an informal comparison of images made in Chimera using Coulombic Surface Coloring with published figures of Poisson-Boltzmann electrostatic potential.)

There are several ways to start Coulombic Surface Coloring, a tool in the Surface/Binding Analysis category. It is also implemented as the command coulombic.

The molecular surface(s) should first be displayed (using Actions... Surface... show or the command surface) and then chosen from the list of Surfaces to color by ESP. Only the residues enclosed by a surface will be used to calculate the potential on that surface. For example, nearby ions, solvent, or ligand molecules will not affect the results for a surface that encloses only protein. Coulombic Surface Coloring does not show the potential from one molecule on the surface of another, although that can be done in an additional step after generating a grid.

Parameters:

Number of colors/values (default 3: red, white, and blue) - up to 11 pairs can be used. Each color can be adjusted by clicking its color well and using the Color Editor. The values can be edited directly, and are in units of kcal/(mol·e) at 298 K.
The specified color/value pairs or thresholds define a color mapping. The value calculated for each surface vertex will be compared to the thresholds. Surface vertices with values lower than any threshold will be assigned the color of the lowest-value threshold, while vertices with values higher than any threshold will be assigned the color of the highest-value threshold. The colors of the remaining vertices will be obtained by linear interpolation between the nearest lower and higher thresholds. Finally, each surface triangle will be colored by linearly interpolating its vertex colors. Colors are defined by red, green, blue, and opacity/transparency components.
Distance-dependent dielectric (true/false) - whether ε should vary in proportion to the distance from each charge
Dielectric constant (default 4.0) - value of C, where ε = Cd if distance-dependent, ε = C if not distance-dependent
Distance from surface (default 1.4 Å) - how far out from each surface vertex, along its normal, to evaluate the electrostatic potential. The rationale for looking outward is that the values at the centers of any interacting atoms are more relevant than those at their surfaces. A molecular surface is solvent-excluded; it shows where the surface of a spherical probe (typically of radius 1.4 Å) can lie. Thus, 1.4 Å out from the molecular surface is about as close as the probe center can get, the solvent-accessible surface.

The Implicit Histidine Protonation section controls the charge states of histidines in structures without hydrogens. Although hydrogens will not be added explicitly, the implicit protonation states will affect the results because the charges differ throughout the residue for different protonation states, and the charges of the implicit hydrogens will be merged with those of the attached heavy atoms.

Residue name-based - residue names will be used to determine which histidine sidechain nitrogens should be implicitly protonated: the δ-nitrogen in residues named HID, the ε-nitrogen in HIE, and both nitrogens in HIP. The HIS = setting specifies how residues with the standard histidine name (HIS) should be treated:
- estimated from H-bonds (default) - choose protonation state based on local H-bonding environment
- delta - neutral sidechain, implicit hydrogen at δ-nitrogen
- epsilon - neutral sidechain, implicit hydrogen at ε-nitrogen
- both - positive sidechain, implicitly protonated at both sidechain nitrogens
Specified individually... the desired protonation state of each histidine residue will be specified with checkboxes in the dialog

Turning on Compute grid... reveals additional options for for generating a three-dimensional grid of the values (see why this might be useful):

Grid spacing (default 1.0 Å) - grid resolution; separation of grid points along X, Y, and Z
Padding (default 5.0 Å) - how far to extend the grid box in every direction from the minimum needed to enclose the atoms
Volume name (default Coulombic ESP) - dataset name

Clicking Apply (or OK, which also dismisses the dialog) calculates the electrostatic potential and applies the coloring.

Create corresponding color key opens the Color Key dialog and populates it with the current colors and values; a color key can then be created interactively with the mouse.

Close simply dismisses the dialog, while Help opens this manual page in a browser window.

GENERATING VOLUME DATA

The Compute grid... option generates a grid of the electrostatic potential values (a volume dataset) and starts the Electrostatic Surface Coloring and Volume Viewer tools. This allows:

showing the Coulombic potential from one molecule on the surface of a different molecule, or on a nonmolecular surface model
coloring planar caps where surfaces are clipped
showing the potential as isosurfaces (however, this is generally less useful for Coulombic than for Poisson-Boltzmann ESP)
saving the grid to a file for later use

The first two of these tasks can be accomplished using Electrostatic Surface Coloring (or scolor), the latter two with Volume Viewer (or volume).

HYDROGENS AND CHARGES

The Coulombic potential calculation requires charge assignments, which in turn require hydrogens. An existing structure lacking hydrogens is not changed, but a copy is created in memory, protonated, and assigned charges (details), which are then transferred to the existing structure. Selenomethionine (MSE) residues are treated as methionines (MET) for purposes of charge assignment. Where hydrogens are missing from the existing structure, their charges are collapsed onto the adjacent heavy atom: such hydrogens are implicit.

A structure may already have explicit hydrogens, or they can be added beforehand in Chimera with AddH. A structure may also have pre-existing charge assignments, from prior use of Add Charge, PDB2PQR, or Coulombic Surface Coloring, or read from a file. If all of the atoms corresponding to the chosen surface already have charges, those values will be used rather than assigned anew the first time Coulombic coloring is applied to that surface. In subsequent applications, the existing charges will be used unless a setting in the Implicit Histidine Protonation section is changed, which forces the charges to be assigned anew. Another way to force reassignment is to remove the charges with the command ~setattr a charge.

While implicit hydrogens are appropriate for most uses, collapsing the hydrogen charges onto the adjacent heavy atoms tends to decrease positive potential magnitudes at the surface. This usually has little effect on the qualitative picture, but if it is of concern, the structure can be protonated beforehand. A disadvantage of explicit hydrogens, however, is that they make surfaces more rugged (bumpier) and complicated to view. To circumvent this problem, one could add first add hydrogens, then generate a grid of the Coulombic potential values, then delete the hydrogens to make the molecular surface less rugged (or show the surface for a separate copy of the structure that does not have hydrogens), and finally, color that surface with Electrostatic Surface Coloring using the Coulombic grid that had been generated in the presence of hydrogens.

LIMITATIONS

Subsequent coloring operations may erase surface custom colors. Unless explicitly limited to non-surface items, subsequent use of Actions... Color or the command color on the molecule model corresponding to a molecular surface will reset the surface's color source to atoms and wipe out the Coulombic potential colors. The custom surface coloring will be erased even when only parts of the molecule model that do not contribute to the molecular surface are recolored.

Subsequent recomputation of the molecular surface erases custom colors. Anything that triggers surface recalculation, such as deleting atoms from the molecule model or changing certain molecular surface parameters, will erase the Coulombic potential colors.

Surface caps not colored. This tool does not color caps on clipped surfaces, but it can be done in an additional step after generating a grid.

UCSF Computer Graphics Laboratory / November 2013