posted on 2019-04-09, 00:00authored byMagalie Géraldy, Michael Morgen, Peter Sehr, Raphael R. Steimbach, Davide Moi, Johannes Ridinger, Ina Oehme, Olaf Witt, Mona Malz, Mauro S. Nogueira, Oliver Koch, Nikolas Gunkel, Aubry K. Miller
The discovery of isozyme-selective
histone deacetylase (HDAC) inhibitors
is critical for understanding the biological functions of individual
HDACs and for validating HDACs as drug targets. The isozyme HDAC10
contributes to chemotherapy resistance and has recently been described
to be a polyamine deacetylase, but no studies toward selective HDAC10
inhibitors have been published. Using two complementary assays, we
found Tubastatin A, an HDAC6 inhibitor, to potently bind HDAC10. We
synthesized Tubastatin A derivatives and found that a basic amine
in the cap group was required for strong HDAC10 binding. HDAC10 inhibitors
mimicked knockdown by causing dose-dependent accumulation of acidic
vesicles in a neuroblastoma cell line. Furthermore, docking into human
HDAC10 homology models indicated that a hydrogen bond between a cap
group nitrogen and the gatekeeper residue Glu272 was responsible for
potent HDAC10 binding. Taken together, our data provide an optimal
platform for the development of HDAC10-selective inhibitors, as exemplified
with the Tubastatin A scaffold.