Practical Fragments has previously written about the concept
of hot spots – regions on a protein where fragments are particularly prone to
bind. It’s always nice to have one of these when starting a program, since it’s
a good indication that the protein is ligandable.
But there’s another type of hot spot too. When two proteins
interact, they often do so through very large interfaces comprising dozens of
amino acid residues. This is daunting from a molecular recognition perspective,
but it turns out that most of these residues contribute very little
energetically to the binding affinity, as assessed by alanine scanning mutagenesis. The few residues that do matter often cluster into hot spots,
which are generally much smaller than the entire interface.
In a new paper in J.
Chem. Inf. Model., Sandor Vajda, Adrian Whitty, Dima Kozakov, and
colleagues at Boston
University ask how these
two types of hot spots are related.
The researchers used the program FTMap to look for
fragment-binding hot spots on the protein ribonuclease A (RNase A). They found
four in the vicinity of the binding site for the protein ribonuclease inhibitor
(RNI), three of which had also been shown experimentally to bind small organic
(solvent) molecules.
Having shown that FTMap can find fragment hot spots, they
next turned to a set of 15 protein-protein complexes for which alanine scanning
data were available; amino acid side chains were considered hot spots if
mutation to alanine decreased binding by more than 2 kcal/mol. Applying FTMap
to the receptor of each protein-protein pair showed that 92% of alanine-scanning
hot spot residues map onto FTMap hot spots. Moreover, there were very few false
negatives: 92% of “unimportant” residues did not map onto FTMap hot spots. In
other words, the two types of hot spots seem to overlap considerably.
Although these results may make sense intuitively, the
researchers discuss several reasons why this was not a foregone conclusion.
First, a residue identified as a hot spot by alanine scanning might not be
important for binding per se, but may instead be important for imposing
long-range structure on the protein. Second, alanine scanning only identifies
important side chains; backbone atoms
are not considered, so a fragment may bind to a hot spot that is invisible by
alanine scanning. Finally, hot spots identified by alanine scanning reflect the
interactions between two proteins, whereas hot spots identified by fragments
(or their virtual equivalents) look at only a single protein. This is important
because if a residue protrudes from one protein into a cavity on the other, the
protruding residue may be a hot spot for interactions but, because of its geometry, not be a
good binding site for small molecules. As the authors put it:
A convex surface site
on a protein typically will not bind small molecules strongly no matter how much
binding energy the region generates in an interaction with a complementary
concave site on its protein binding partner. Thus, observation of a hot spot by
alanine scanning mutagenesis does not necessarily imply the existence of a
small molecule fragment consensus site at that region.
And of course, as we’ve noted before, proteins can be
wriggly little things, with new pockets opening up where you least expect them.
So despite all these caveats, it’s reassuring to see that, for the most part,
there is some constancy in the hotness of spots.
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5 comments:
So does the alanine scan measure the hotness of the spot or the size and/or polarity of the residue being mutated?
Ultimately it measures hotness, but if size and/or polarity are important for binding to the partner protein, then these would certainly play a role.
I'm far from convinced that alanine-scanning measures the hotness of the spot. It can be argued that mutating tryptophan or arginine to alanine represents a larger perturbation than mutating phenylalanine or leucine to alanine. It's difficult to mutate protein side chains isosterically which means that it's difficult to determine the importance of specific protein-ligand contacts in binding. In many cases mutating the ligand would provide more relevant information. However, it's worth remembering that the contribution that a particular intermolecular contact makes to affinity is not strictly and experimental observable.
Alanine scanning certainly has limits, several of which are noted in the main text. It's also true that mutating a Trp to an Ala is a larger perturbation than mutating a Phe to an Ala. On the other hand, if mutation of a Trp to an Ala causes, on average, more loss in affinity than mutation of a Phe to an Ala, this could be interpreted as Trp residues being generally hotter than Phe residues.
Ultimately the concept of hotness is operational, and while it reflects the underlying energetics, it does so coarsely and through the lens of the experiment (and the experimenter!)
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