posted on 2016-10-17, 00:00authored bySang Joon Won, Dahvid Davda, Kristin J. Labby, Sin Ye Hwang, Rachel Pricer, Jaimeen D. Majmudar, Kira A. Armacost, Laura A. Rodriguez, Christina L. Rodriguez, Fei San Chong, Kristopher
A. Torossian, Jasmine Palakurthi, Edward S. Hur, Jennifer L. Meagher, Charles
L. Brooks, Jeanne A. Stuckey, Brent R. Martin
Post-translational S-palmitoylation directs the
trafficking and membrane localization of hundreds of cellular proteins,
often involving a coordinated palmitoylation cycle that requires both
protein acyl transferases (PATs) and acyl protein thioesterases (APTs)
to actively redistribute S-palmitoylated proteins
toward different cellular membrane compartments. This process is necessary
for the trafficking and oncogenic signaling of S-palmitoylated
Ras isoforms, and potentially many peripheral membrane proteins. The
depalmitoylating enzymes APT1 and APT2 are separately conserved in
all vertebrates, suggesting unique functional roles for each enzyme.
The recent discovery of the APT isoform-selective inhibitors ML348
and ML349 has opened new possibilities to probe the function of each
enzyme, yet it remains unclear how each inhibitor achieves orthogonal
inhibition. Herein, we report the high-resolution structure of human
APT2 in complex with ML349 (1.64 Å), as well as the complementary
structure of human APT1 bound to ML348 (1.55 Å). Although the
overall peptide backbone structures are nearly identical, each inhibitor
adopts a distinct conformation within each active site. In APT1, the
trifluoromethyl group of ML348 is positioned above the catalytic triad,
but in APT2, the sulfonyl group of ML349 forms hydrogen bonds with
active site resident waters to indirectly engage the catalytic triad
and oxyanion hole. Reciprocal mutagenesis and activity profiling revealed
several differing residues surrounding the active site that serve
as critical gatekeepers for isoform accessibility and dynamics. Structural
and biochemical analysis suggests the inhibitors occupy a putative
acyl-binding region, establishing the mechanism for isoform-specific
inhibition, hydrolysis of acyl substrates, and structural orthogonality
important for future probe development.