Disrupting protein-protein interactions (PPIs) tends to be
challenging: interfaces are often large and flat, with few deep pockets in
which small molecules can bind. Also, much like unhappy families, PPIs are
usually dissimilar, meaning that HTS collections yield fewer, less attractive
hits. Both of these challenges are well-addressed by fragments, and indeed last
year saw the approval of venetoclax, which targets a PPI. Two new papers in J. Med. Chem. report inhibitors of
another PPI.
B-Cell lymphoma 6 (BCL6) binds to other proteins to regulate
gene expression. As its name suggests, it was identified in diffuse large
B-cell lymphoma (DLBCL), and is thus an interesting anticancer target. Also,
structures of the protein in complex with a peptide suggested that it may not be
impossible to find small molecule inhibitors. Yusuke Kamada and colleagues at
Takeda set out to do just this.
An SPR-based screen of 1494 fragments, each at 1 mM,
identified 64 hits which confirmed in dose-response titrations. However, only
seven compounds confirmed in an STD-NMR experiment. Of these, compound 1 was
characterized crystallographically bound in the peptide groove.
A few tweaks to the fragment led to compound 4, with
improved potency. Meanwhile, an HTS screen had identified the very weak
compound 5, and crystallography showed that it bound at the same site as
compound 4. Merging the two molecules led to compound 7, with mid-nanomolar
biochemical potency and low micromolar activity in a cell-based assay. This is
a classic case of fragment-assisted drug discovery (FADD), and a good
illustration of how FBLD and HTS can be complementary.
The second paper, by William McCoull and a large team of
collaborators from AstraZeneca and Pharmaron, goes somewhat further. The
researchers conducted an SPR-based screen of 3500 fragments along with a
virtual screen. Both found hits, and led to molecules with the same core as
compound A2. Crystallography revealed that these also bind in the peptide
groove, and combining elements of both molecules while tweaking the properties
led to compound A5, with improved affinity.
The next step was growing compound A5 to try to make a
hydrogen bond interaction with the protein. That led to compound A8, with
submicromolar affinity. A crystal structure of a related compound bound to BCL6
revealed that two chemically distant portions of the molecule were in close
proximity, suggesting a macrocyclization strategy similar to what we described
last week. This proved highly successful, improving the affinity by more than
two orders of magnitude for compound A11. NMR studies of the linear and
cyclized compounds revealed that the conformation of the latter was indeed
closer to that seen in the crystal structure.
The medicinal chemistry continues extensively from here. In
particular, compound A11 showed some activity against the kinase CK2, but this
could be engineered out. Multiple additional changes were explored, with many
compounds showing low nanomolar activity in a biochemical assay and some
showing high nanomolar activity in a cell-based assay. Unfortunately, none were
very effective at inhibiting the proliferation of lymphoma cell lines. The
authors state, “we conclude that the BCL6 hypothesis as a means of treatment
for DLBCL is still unproven and we have elected not to progress this series of
BCL6 inhibitors further into development.”
This makes sense, though I wouldn’t abandon all hope. For
two other PPIs, BCL2 and MCL1, robust cell activity required picomolar affinity in a biochemical
assay. Whether this level of potency is achievable for BCL6 remains an open
question.
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