Circular
Dichroism, Magnetic Circular Dichroism, and
Variable Temperature Variable Field Magnetic Circular Dichroism Studies
of Biferrous and Mixed-Valent myo-Inositol Oxygenase: Insights into Substrate Activation of O2 Reactivity
posted on 2013-10-23, 00:00authored byRae Ana Snyder, Caleb
B. Bell, Yinghui Diao, Carsten Krebs, J. Martin Bollinger, Edward I. Solomon
myo-Inositol oxygenase (MIOX) catalyzes the 4e– oxidation of myo-inositol (MI) to d-glucuronate
using a substrate activated Fe(II)Fe(III) site.
The biferrous and Fe(II)Fe(III) forms of MIOX were studied with circular
dichroism (CD), magnetic circular dichroism (MCD), and variable temperature
variable field (VTVH) MCD spectroscopies. The MCD spectrum of biferrous
MIOX shows two ligand field (LF) transitions near 10000 cm–1, split by ∼2000 cm–1, characteristic of
six coordinate (6C) Fe(II) sites, indicating that the modest reactivity
of the biferrous form toward O2 can be attributed to the
saturated coordination of both irons. Upon oxidation to the Fe(II)Fe(III)
state, MIOX shows two LF transitions in the ∼10000 cm–1 region, again implying a coordinatively saturated Fe(II) site. Upon
MI binding, these split in energy to 5200 and 11200 cm–1, showing that MI binding causes the Fe(II) to become coordinatively
unsaturated. VTVH MCD magnetization curves of unbound and MI-bound
Fe(II)Fe(III) forms show that upon substrate binding, the isotherms
become more nested, requiring that the exchange coupling and ferrous
zero-field splitting (ZFS) both decrease in magnitude. These results
imply that MI binds to the ferric site, weakening the Fe(III)−μ-OH
bond and strengthening the Fe(II)−μ-OH bond. This perturbation
results in the release of a coordinated water from the Fe(II) that
enables its O2 activation.