posted on 2016-09-26, 00:00authored byNikolay Simakov, David A. Leonard, Jeremy C. Smith, Troy Wymore, Agnieszka Szarecka
Widespread
antibiotic resistance, particularly when mediated by
broad-spectrum β-lactamases, has major implications for public
health. Substitutions in the active site often allow broad-spectrum
enzymes to accommodate diverse types of β-lactams. Substitutions
observed outside the active site are thought to compensate for the
loss of thermal stability. The OXA-1 clade of class D β-lactamases
contains a pair of conserved cysteines located outside the active
site that forms a disulfide bond in the periplasm. Here, the effect
of the distal disulfide bond on the structure and dynamics of OXA-1
was investigated via 4 μs molecular dynamics simulations. The
results reveal that the disulfide promotes the preorganized orientation
of the catalytic residues and affects the conformation of the functionally
important Ω loop. Furthermore, principal component analysis
reveals differences in the global dynamics between the oxidized and
reduced forms, especially in the motions involving the Ω loop.
A dynamical network analysis indicates that, in the oxidized form,
in addition to its role in ligand binding, the KTG family motif is
a central hub of the global dynamics. As activity of OXA-1 has been
measured only in the reduced form, we suggest that accurate assessment
of its functional profile would require oxidative conditions mimicking
periplasm.