Lamellar, or layered, potassium niobium oxide perovskites are a class of underdeveloped semiconductors in organic photocatalysis that offer the inherent advantages of larger particle size and ease of recoverability as compared to traditional semiconductor materials.
o-Carbonyl arylboronic acids such as 2-formylphenylboronic
acid (2-FPBA) are employed in biocompatible conjugation reactions
with the resulting iminoboronate adduct stabilized by an intramolecular
N–B interaction. However, few studies have utilized these reagents
as active site-directed enzyme inhibitors. We show that 2-FPBA is
a potent reversible, slow-onset inhibitor of mandelate racemase (MR),
an enzyme that has served as a valuable paradigm for understanding
enzyme-catalyzed abstraction of an α-proton from a carbon acid
substrate with a high pK
a. Kinetic analysis
of the progress curves for the slow onset of inhibition of wild-type
MR using a two-step kinetic mechanism gave K
i and K
i* values of 5.1 ±
1.8 and 0.26 ± 0.08 μM, respectively. Hence, wild-type
MR binds 2-FPBA with an affinity that exceeds that for the substrate
by ∼3000-fold. K164R MR was inhibited by 2-FPBA, while K166R
MR was not inhibited, indicating that Lys 166 was essential for inhibition.
Unexpectedly, mass spectrometric analysis of the NaCNBH3-treated enzyme–inhibitor complex did not yield evidence of
an iminoboronate adduct. 11B nuclear magnetic resonance
spectroscopy of the MR·2-FPBA complex indicated that the boron
atom was sp3-hybridized (δ 6.0), consistent with
dative bond formation. Surprisingly, X-ray crystallography revealed
the formation of an Nζ–B dative bond between
Lys 166 and 2-FPBA with intramolecular cyclization to form a benzoxaborole,
rather than the expected iminoboronate. Thus, when o-carbonyl arylboronic acid reagents are employed to modify proteins,
the structure of the resulting product depends on the protein architecture
at the site of modification.
Mandelate racemase (MR) catalyzes the Mg2+-dependent
interconversion of (R)- and (S)-mandelate
by stabilizing the altered substrate in the transition state (TS)
by ∼26 kcal/mol. The enzyme has been employed as a model to
explore the limits to which the free energy of TS stabilization may
be captured by TS analogues to effect strong binding. Herein, we determined
the thermodynamic parameters accompanying binding of a series of bromo-,
chloro-, and fluoro-substituted phenylboronic acids (PBAs) by MR and
found that binding was predominately driven by favorable entropy changes.
3,4-Dichloro-PBA was discovered to be the most potent inhibitor yet
identified for MR, binding with a K
d
app value of 11 ± 2 nM and exceeding the binding of the
substrate by ∼72,000-fold. The ΔC
p value accompanying binding (−488 ± 18 cal·mol–1 K–1) suggested that dispersion
forces contribute significantly to the binding. The pH-dependence
of the inhibition revealed that MR preferentially binds the anionic,
tetrahedral form of 3,4-dichloro-PBA with a pH-independent K
i value of 5.7 ± 0.5 nM, which was consistent
with the observed upfield shift of the 11B NMR signal.
The linear free energy relationship between log(k
cat/K
m) and log(1/K
i) for wild-type and 11 MR variants binding
3,4-dichloro-PBA had a slope of 0.8 ± 0.2, indicating that MR
recognizes the inhibitor as an analogue of the TS. Hence, halogen
substitution may be utilized to capture additional free energy of
TS stabilization arising from dispersion forces to enhance the binding
of boronic acid inhibitors by MR.
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