# How to tell if our ligand-protein docking is good from AutoDock Vina's result

I have perform a ligand-protein docking using Autodock Vina. The result of the docking looks like this:

WARNING: The search space volume > 27000 Angstrom^3 (See FAQ)
Detected 8 CPUs
Setting up the scoring function ... done.
Analyzing the binding site ... done.
Using random seed: -1553787135
Performing search ... done.
Refining results ... done.

mode |   affinity | dist from best mode
| (kcal/mol) | rmsd l.b.| rmsd u.b.
-----+------------+----------+----------
1         -5.9      0.000      0.000.  Pose 1
2         -5.7     22.945     25.492.  Pose 2
3         -5.5      1.426      2.046.  Pose 3
4         -5.5     23.669     25.616
5         -5.4     25.783     29.152.  .....
6         -5.3     21.146     23.357
7         -5.2     20.323     22.545
8         -5.2     23.864     26.064
9         -5.1     23.422     26.585.  Pose 9


As far as I understand from these statistics Mode 1(Pose 1) is the best. However when I actually visualize them in Pymol, Pose 1 has no hydrogen bonding at all but Pose 2 has.

My question is how can we judge if which of those two Pose is the best to use?

Note in figure below Pose 2 has dashed line (Hydrogen bond).

It is best to contextualise the numbers. -1 kcal/mol is about the potential energy gained from a hydrogen bond —technically described in the r^6 part of the Lenard–Jones term, it is also the average collision energy of a water molecule at 37°C as that is RT ($$\frac{k_b\cdot T}{N_A}$$, wiki)under a Maxwell–Boltzmann distribution. A salt bridge –2 kcal/mol (Columbic force term). So your scores are not very low, hence why you are counting two hydrogen bonds. Although you can also see a lovely sulfur-pi interaction which is –1 to –2 kcal/mol, so those bonds alone are probably making a –4 kcal/mol contribution, so I am guessing that some terms may be horrendous, such as repulsion forces etc. A nice metric is doing a conversion to ligand efficiency, which weeds out affinities driven by size of the molecule... in this case most of the molecule is doing nothing. Also, most programs have an accuracy of 1 kcal/mol or higher.
• Thanks. By  ∆∆G Do you mean  affinity (kcal/mol)? Then what do you consider ideal score range for ∆∆G. Since you said that my score above is not low enough? Jun 14 at 0:08
• I did and it generally is fine, but variations of definitions and calculation come into play. Gibbs free energy is ∆G (so one delta to start with), although some tools refer to ∆G_bind as ∆∆G, and generally it's intended as ∆∆G = ∆G_holo - (∆G_apo + ∆G_aq), where ∆G_aq is the free energy in aqueous solvent, but this is not always true as there may be fancy stuff correcting for ∆G_aq (which makes little sense for a high partition coefficient compound), Vina is one of them. Jun 14 at 16:13