I'm trying to compare the 3D distance between two AAs with their evolutionary conservation. However, I'm coming across a problem when looking for 3D crystal structures of HIV-1 proteins ... mainly that the majority of crystal structures of proteins are from experiments where the protein of interest is bound with active site inhibitors. Here are some examples for reference:

http://www.pdb.org/pdb/explore/explore.do?structureId=1S6Q

http://www.pdb.org/pdb/explore/explore.do?structureId=1S1X

http://www.pdb.org/pdb/explore/explore.do?structureId=1S1W

I'm not incredibly familiar with 3D structures but I do know that these are small-molecule inhibitors. Can I assume the majority of the structure is unchanged? Should I take many different structures of the protein (with different SMIs) and average them somehow?

I know that all of these methods will add plenty of noise to the distance measurements but I'm just looking for a "back of the envelope" calculation for an initial hypothesis test. Do you think this will add too much noise to the see any signal? If so, can you propose another idea?

To answer your question: 3D structures of proteins are not identical in an inhibitor bound state and unbound state - they will have conformational differences which can be measured using standard Root Mean Square Deviation (RMSD) calculation tools (see: Protein Structural Alignment at Wikipedia).

In your specific case, These structures are co-crystallized with the small molecules and they will definitely have conformational changes due to the binding of the small-molecules. You may check in PDB and try to find a unbound form of your protein of interest and perform an RMSD calculation using SuperPose or similar RMSD calculation tools to measure the distance.

It is not clear to me what you are trying to achieve by averaging the co-crystallized structures.

You can use http://apoholo.projekty.ms.mff.cuni.cz/ to visualize the differences between Apo and Holo protein forms.