posted on 2015-09-18, 00:00authored byFengbin Wang, Shanteri Singh, Weijun Xu, Kate E. Helmich, Mitchell
D. Miller, Hongnan Cao, Craig A. Bingman, Jon S. Thorson, George N. Phillips
Sugar
aminotransferases (SATs) are an important class of tailoring
enzymes that catalyze the 5′-pyridoxal phosphate (PLP)-dependent
stereo- and regiospecific installation of an amino group from an amino
acid donor (typically l-Glu or l-Gln) to a corresponding
ketosugar nucleotide acceptor. Herein we report the strategic structural
study of two homologous C4 SATs (Micromonospora echinospora CalS13 and Escherichia coli WecE) that utilize
identical substrates but differ in their stereochemistry of aminotransfer.
This study reveals for the first time a new mode of SAT sugar nucleotide
binding and, in conjunction with previously reported SAT structural
studies, provides the basis from which to propose a universal model
for SAT stereo- and regiochemical control of amine installation. Specifically,
the universal model put forth highlights catalytic divergence to derive
solely from distinctions within nucleotide sugar orientation upon
binding within a relatively fixed SAT active site where the available
ligand bound structures of the three out of four representative C3
and C4 SAT examples provide a basis for the overall model. Importantly,
this study presents a new predictive model to support SAT functional
annotation, biochemical study and rational engineering.