Aaron Jacob
Aug 18, 2025, 2:22:38 PMAug 18
to gmx_MMPBSA
Greetings,
I have been trying to calculate delta G of binding of a antibody, antigen complex. But the dG values i get are extremely overestimated (-50 kcal/mol). Realistically speaking it should be around 10. how can i correct the estimation.
Below is the input file:
sys_name = ""
startframe = 1 # First frame to analyze
endframe = 9999999 # Last frame to analyze
interval = 10 # Number of frames between adjacent frames analyzed
forcefields = "oldff/leaprc.ff99SB,leaprc.gaff" # Define the force field to build the Amber topology
ions_parameters = 1 # Define ions parameters to build the Amber topology
PBRadii = 7 # Define PBRadii to build amber topology from GROMACS files
temperature = 298.15 # Temperature
qh_entropy = 0 # Do quasi-harmonic calculation
interaction_entropy = 0 # Do Interaction Entropy calculation
ie_segment = 25 # Trajectory segment to calculate interaction entropy
c2_entropy = 0 # Do C2 Entropy calculation
assign_chainID = 0 # Assign chains ID
exp_ki = 0.0 # Experimental Ki in nM
full_traj = 0 # Print a full traj. AND the thread trajectories
gmx_path = "" # Force to use this path to get GROMACS executable
keep_files = 0 # How many files to keep after successful completion
netcdf = 0 # Use NetCDF intermediate trajectories
solvated_trajectory = 0 # Define if it is necessary to cleanup the trajectories
verbose = 1 # How many energy terms to print in the final output
/
# (AMBER) Possion-Boltzmann namelist variables
&pb
ipb = 2 # Dielectric model for PB
inp = 1 # Nonpolar solvation method
sander_apbs = 0 # Use sander.APBS?
indi = 1.0 # Internal dielectric constant
exdi = 80.0 # External dielectric constant
emem = 4.0 # Membrane dielectric constant
smoothopt = 1 # Set up dielectric values for finite-difference grid edges that are located across the solute/solvent dielectric boundary
istrng = 0.15 # Ionic strength (M)
radiopt = 0 # Use optimized radii?
prbrad = 1.4 # Probe radius
iprob = 2.0 # Mobile ion probe radius (Angstroms) for ion accessible surface used to define the Stern layer
sasopt = 0 # Molecular surface in PB implict model
arcres = 0.25 # The resolution (Å) to compute solvent accessible arcs
memopt = 0 # Use PB optimization for membrane
mprob = 2.7 # Membrane probe radius in Å
mthick = 40.0 # Membrane thickness
mctrdz = 0.0 # Distance to offset membrane in Z direction
poretype = 1 # Use exclusion region for channel proteins
npbopt = 0 # Use NonLinear PB solver?
solvopt = 1 # Select iterative solver
accept = 0.001 # Sets the iteration convergence criterion (relative to the initial residue)
linit = 1000 # Number of SCF iterations
fillratio = 4.0 # Ratio between the longest dimension of the rectangular finite-difference grid and that of the solute
scale = 2.0 # 1/scale = grid spacing for the finite difference solver (default = 1/2 Å)
nbuffer = 0.0 # Sets how far away (in grid units) the boundary of the finite difference grid is away from the solute surface
nfocus = 2 # Electrostatic focusing calculation
fscale = 8 # Set the ratio between the coarse and fine grid spacings in an electrostatic focussing calculation
npbgrid = 1 # Sets how often the finite-difference grid is regenerated
bcopt = 5 # Boundary condition option
eneopt = 2 # Compute electrostatic energy and forces
frcopt = 0 # Output for computing electrostatic forces
scalec = 0 # Option to compute reaction field energy and forces
cutfd = 5.0 # Cutoff for finite-difference interactions
cutnb = 0.0 # Cutoff for nonbonded interations
nsnba = 1 # Sets how often atom-based pairlist is generated
decompopt = 2 # Option to select different decomposition schemes when INP = 2
use_rmin = 1 # The option to set up van der Waals radii
sprob = 0.557 # Solvent probe radius for SASA used to compute the dispersion term
vprob = 1.3 # Solvent probe radius for molecular volume (the volume enclosed by SASA)
rhow_effect = 1.129 # Effective water density used in the non-polar dispersion term calculation
use_sav = 1 # Use molecular volume (the volume enclosed by SASA) for cavity term calculation
cavity_surften = 0.0378 # Surface tension
cavity_offset = -0.5692 # Offset for nonpolar solvation calc
maxsph = 400 # Approximate number of dots to represent the maximum atomic solvent accessible surface
maxarcdot = 1500 # Number of dots used to store arc dots per atom
npbverb = 0 # Option to turn on verbose mode
/
startframe = 1 # First frame to analyze
endframe = 9999999 # Last frame to analyze
interval = 10 # Number of frames between adjacent frames analyzed
forcefields = "oldff/leaprc.ff99SB,leaprc.gaff" # Define the force field to build the Amber topology
ions_parameters = 1 # Define ions parameters to build the Amber topology
PBRadii = 7 # Define PBRadii to build amber topology from GROMACS files
temperature = 298.15 # Temperature
qh_entropy = 0 # Do quasi-harmonic calculation
interaction_entropy = 0 # Do Interaction Entropy calculation
ie_segment = 25 # Trajectory segment to calculate interaction entropy
c2_entropy = 0 # Do C2 Entropy calculation
assign_chainID = 0 # Assign chains ID
exp_ki = 0.0 # Experimental Ki in nM
full_traj = 0 # Print a full traj. AND the thread trajectories
gmx_path = "" # Force to use this path to get GROMACS executable
keep_files = 0 # How many files to keep after successful completion
netcdf = 0 # Use NetCDF intermediate trajectories
solvated_trajectory = 0 # Define if it is necessary to cleanup the trajectories
verbose = 1 # How many energy terms to print in the final output
/
# (AMBER) Possion-Boltzmann namelist variables
&pb
ipb = 2 # Dielectric model for PB
inp = 1 # Nonpolar solvation method
sander_apbs = 0 # Use sander.APBS?
indi = 1.0 # Internal dielectric constant
exdi = 80.0 # External dielectric constant
emem = 4.0 # Membrane dielectric constant
smoothopt = 1 # Set up dielectric values for finite-difference grid edges that are located across the solute/solvent dielectric boundary
istrng = 0.15 # Ionic strength (M)
radiopt = 0 # Use optimized radii?
prbrad = 1.4 # Probe radius
iprob = 2.0 # Mobile ion probe radius (Angstroms) for ion accessible surface used to define the Stern layer
sasopt = 0 # Molecular surface in PB implict model
arcres = 0.25 # The resolution (Å) to compute solvent accessible arcs
memopt = 0 # Use PB optimization for membrane
mprob = 2.7 # Membrane probe radius in Å
mthick = 40.0 # Membrane thickness
mctrdz = 0.0 # Distance to offset membrane in Z direction
poretype = 1 # Use exclusion region for channel proteins
npbopt = 0 # Use NonLinear PB solver?
solvopt = 1 # Select iterative solver
accept = 0.001 # Sets the iteration convergence criterion (relative to the initial residue)
linit = 1000 # Number of SCF iterations
fillratio = 4.0 # Ratio between the longest dimension of the rectangular finite-difference grid and that of the solute
scale = 2.0 # 1/scale = grid spacing for the finite difference solver (default = 1/2 Å)
nbuffer = 0.0 # Sets how far away (in grid units) the boundary of the finite difference grid is away from the solute surface
nfocus = 2 # Electrostatic focusing calculation
fscale = 8 # Set the ratio between the coarse and fine grid spacings in an electrostatic focussing calculation
npbgrid = 1 # Sets how often the finite-difference grid is regenerated
bcopt = 5 # Boundary condition option
eneopt = 2 # Compute electrostatic energy and forces
frcopt = 0 # Output for computing electrostatic forces
scalec = 0 # Option to compute reaction field energy and forces
cutfd = 5.0 # Cutoff for finite-difference interactions
cutnb = 0.0 # Cutoff for nonbonded interations
nsnba = 1 # Sets how often atom-based pairlist is generated
decompopt = 2 # Option to select different decomposition schemes when INP = 2
use_rmin = 1 # The option to set up van der Waals radii
sprob = 0.557 # Solvent probe radius for SASA used to compute the dispersion term
vprob = 1.3 # Solvent probe radius for molecular volume (the volume enclosed by SASA)
rhow_effect = 1.129 # Effective water density used in the non-polar dispersion term calculation
use_sav = 1 # Use molecular volume (the volume enclosed by SASA) for cavity term calculation
cavity_surften = 0.0378 # Surface tension
cavity_offset = -0.5692 # Offset for nonpolar solvation calc
maxsph = 400 # Approximate number of dots to represent the maximum atomic solvent accessible surface
maxarcdot = 1500 # Number of dots used to store arc dots per atom
npbverb = 0 # Option to turn on verbose mode
/
marioe911116
Aug 18, 2025, 2:31:06 PMAug 18
to gmx_MMPBSA
Implicit solvent-based methods tend to overestimate the binding free energy significantly; it is a well-described fact in the literature. It's better to use them for relative comparisons rather than absolute ones
Aaron Jacob
Aug 18, 2025, 2:47:10 PMAug 18
to gmx_MMPBSA
Oh, I see.
Thank you for your kind reply
Deepak Thakur
Aug 19, 2025, 3:54:27 PMAug 19
to Aaron Jacob, gmx_MMPBSA
First check the convergence of simulation (rmsd, rg, com distance......) and then try to apply mmpbsa on converged trajectory length.
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