posted on 2019-04-12, 00:00authored byPatrick
N. Blank, Stephen A. Shinsky, David W. Christianson
The
natural product sesquisabinene is a key component of the fragrant
essential oil of the sandalwood tree, currently valued at $5,000/L.
Sesquisabinene contains a highly strained [3.1.0] bicyclic ring system
and is generated from farnesyl diphosphate in a reaction catalyzed
by a class I terpenoid cyclase. To understand how the enzyme directs
the formation of a strained hydrocarbon ring system, we now report
the X-ray crystal structure of sesquisabinene synthase 1 (SQS1) from
the Indian sandalwood tree (Santalum album). Specifically,
we report the structure of unliganded SQS1 at 1.90 Å resolution
and the structure of its complex with three Mg2+ ions and
the inhibitor ibandronate at 2.10 Å resolution. The bisphosphonate
group of ibandronate coordinates to all three metal ions and makes
hydrogen bond interactions with basic residues at the mouth of the
active site. These interactions are similarly required for activation
of the substrate diphosphate group to initiate catalysis, although
partial occupancy binding of the Mg2+B ion suggests
that this structure represents the penultimate metal coordination
complex just prior to substrate activation. The structure of the liganded
enzyme enables a precise definition of the enclosed active site contour
that serves as a template for the cyclization reaction. This contour
is very product-like in shape and readily fits an extended conformation
of sesquisabinene and its precursor, the homobisabolyl cation. Structural
comparisons of SQS1 with epi-isozizaene synthase
mutants that also generate sesquisabinene suggest that [3.1.0] ring
formation is not dependent on the isoprenoid tail conformation of
the homobisabolyl cation.