Enzymatic resolution of chiral phosphinate esters

Article abstract of DOI:10.1021/ja048457m

The bacterial phosphotriesterase has been shown to catalyze the stereoselective hydrolysis of phosphinate esters. The wild-type enzyme preferentially hydrolyzes the S_P-enantiomers of methyl phenyl p-X-phenylphosphinate esters by 3 orders of mag

Full text of DOI:10.1021/ja048457m

Published on Web 07/01/2004
Enzymatic Resolution of Chiral Phosphinate Esters
Yingchun Li, Sarah D. Aubert, Eugene G. Maes, and Frank M. Raushel*
Departments of Chemistry and of Biochemistry and Biophysics, Texas A&M UniVersity, P.O. Box 30012,
College Station, Texas 77842-3012
Received March 17, 2004; E-mail: raushel@tamu.edu
Phosphotriesterase (PTE) catalyzes the hydrolysis of a wide
spectrum of organophosphorus compounds including agricultural
insecticides and military nerve agents.¹ High-resolution X-ray
structures of PTE have shown that the active site consists of two
Zn²⁺ ions which are bridged by hydroxide.² The asymmetry of the
active site has been exploited for the kinetic resolution of racemic
phosphate (A) and phosphonate (B) esters in high enantiomeric and
chemical yield where L represents a leaving-group phenol.³
Manipulation of the active-site structure has enabled mutants of
the wild-type enzyme to be prepared with altered stereoselective
Figure 1. (a) Brønsted plots for the hydrolysis of S_P-(b) and R_P-(9)
properties.⁴ With organophosphate triesters, variants of PTE were
enantiomers of compounds 1-8 with wild-type PTE. (b) Stereoselectivity
prepared that exhibited enhancement, relaxation, or reVersal of the
inherent stereoselectivity of the wild-type enzyme.⁵ With as few
as five amino acid changes the stereoselectivity was altered by
nearly 7 orders of magnitude.⁵ In this communication we report
the synthesis and stereoselective hydrolysis of a series of phosphi-
nate (C) esters by PTE. To the best of our knowledge this represents
the first time that phosphinate esters have been demonstrated to be
substrates for any enzyme. Chiral phosphinate esters can serve as
the entry point for the chemoenzymatic preparation of P-chiral
phosphines and phosphine oxides.⁶
for the enzymatic hydrolysis of compounds 1-5 plotted as the ratio of k_cat
K_m as a function of the pK_a of the leaving group phenol.
/
Scheme 1
(0.65 mg) was added to a 3 L solution of racemic 5 (1.00 g) in
aqueous MeOH (20%) buffered with 50 mM HEPES, pH 8.0. The
hydrolysis reaction was monitored by following the change in
absorbance at 297 nm until the first phase of the reaction was
complete after 20 min. The reaction was quenched, and the
unreacted enantiomer of 5 was extracted from the reaction mixture
by the addition of 200 mL of CH₂Cl₂. A general workup followed
by silica gel chromatography gave a crystalline solid (0.38 g). The
enantiomeric excess (ee) was quantified by chiral electrophoresis
and found to be greater than 99.8%.
The chiral preference for the PTE-catalyzed hydrolysis of the
phosphinate esters synthesized for this communication was estab-
lished through a combination of X-ray crystallography and ³¹P NMR
spectroscopy as summarized in Scheme 2. The diastereomeric
mixture of (S_P)-11 and (R_P)-11 in a ratio ∼1:1 was prepared by
the reaction of racemic methyl phenyl phosphinic chloride (9) with
(S)-2-tert-butoxycarbonylamino-3-hydroxypropionic acid tert-butyl
ester (10) in the presence of triethylamine. Chromatography of the
crude reaction product on silica gel yielded a crystalline sample of
the (R_P)-11 diastereomer.
A series of racemic phosphinate esters was synthesized as
potential substrates for PTE. Methyl and phenyl substituents were
attached directly to the phosphorus center, while the leaving group
consisted of a para-substituted phenol. The specific set of com-
pounds is presented in Scheme 1. These compounds are excellent
substrates for PTE, comparable to the turnover rates observed for
the analogous phosphate and phosphonate derivatives.^5,7 The time
courses for the enzymatic hydrolysis (pH 8.0) at low substrate
concentrations for each pair of enantiomers were biphasic, a direct
indication that one enantiomer was preferentially hydrolyzed relative
to its mirror image. The values of k_cat/K_m for the preferred
enantiomers and five of the more slowly hydrolyzed enantiomers
were measured and plotted vs the pK_a of the leaving-group phenol
(Figure 1). For the more rapidly hydrolyzed enantiomers a nonlinear
Brønsted plot was obtained, indicative of a change in the rate-
limiting step that breaks at a pK_a of approximately 8.5. There was
a linear dependence of k_cat/K_m with the pK_a of the leaving group
for the slower enantiomers with a â-value of -0.75.
The experimental results of these exploratory studies demonstrate
that there is a substantial difference in the rate of enzymatic
hydrolysis between pairs of phosphinate ester enantiomers and that
in the most favorable cases, the differential exceeds 3 orders of
magnitude. Therefore, it should be practical to use PTE to kinetically
resolve phosphinate esters on a preparative scale. Wild-type PTE
The structure and stereochemistry of (R_P)-11 at the phosphorus
center was established unambiguously by X-ray crystallography.
The ³¹P NMR spectrum of the mixture of diastereomers (R_P)-11
and (S_P)-11 shows resonances at 45.03 and 45.65 ppm of equal
intensity (Figure 2a). The resonance at 45.03 ppm was assigned to
9
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J. AM. CHEM. SOC. 2004, 126, 8888-8889
10.1021/ja048457m CCC: $27.50 © 2004 American Chemical Society

C O M M U N I C A T I O N S
Scheme 2
Figure 3. (a) Brønsted plot for the hydrolysis of R_p-(b) And S_p-(O)
enantiomers of compounds 1-8 with mutant TAGW. (b) Stereoselectivity
for the enzymatic hydrolysis of compounds 1-8, plotted as the ratio of k_cat
K_m as a function of the pK_a of the leaving group phenol.
/
that of (R_P)-11 based on an increase in the intensity of the signal
after addition of authentic (R_P)-11 to the diastereomeric mixture
of 11 (Figure 2b). Reaction of racemic 5 with 10 catalyzed by
triethylamine gives a diastereomeric mixture of (R_P)- and (S_P)-11.
Under the same conditions, the chiral product isolated after the
enzymatic resolution of racemic 5 reacts with 10 to give initially
only (S_P)-11 (Figure 2c). Since the reaction of 5 with 10 is expected
to occur with an inversion of configuration at phosphorus,⁸ the
absolute stereochemistry of the product isolated from the PTE-
catalyzed hydrolysis of racemic 5 is that of the (R_P)-configuration.
Therefore, wild-type PTE preferentially hydrolyzes the series of
phosphinate esters prepared for this investigation of the (S_P)-
configuration. This observation is consistent with the known
stereochemical preferences for the hydrolysis of homologous
phosphate and phosphonate esters.³
The mutant TAGW was used for the isolation of the (S_P)-
enantiomer of 5. TAGW (1.2 mg) was added to a solution (600
mL) of racemic 5 (200 mg) in aqueous MeOH (20%) buffered with
50 mM HEPES, pH 8.0. The hydrolysis reaction was monitored
by following the change in absorbance at 270 nm. The reaction
was quenched, and the unreacted enantiomer of 5 was extracted
from the reaction mixture by the addition of 200 mL of CH₂Cl₂. A
general workup followed by silica gel chromatography gave (S_p)-5
as a crystalline solid (44 mg) with an ee > 90%.
PTE catalyzes the hydrolysis of phosphinate esters. For methyl
phenyl phosphinates, the (S_P)-enantiomers are preferred by the wild-
type PTE. Racemic phosphinate esters can be resolved enzymati-
cally on a preparative scale to give a chiral product with high
enantiomeric excess. Structural variants of PTE have been identified
that possess the opposite stereoselectivity. The chiral phosphinate
esters may function in the chemoenzymatic preparation of P-chiral
phosphines and phosphine oxides.
Acknowledgment. We thank Dr. Joseph Ribenspies, for the
X-ray structural analysis, and thank Brent Busby and Professor
Gyula Vigh for their assistance with the chiral electrophoresis. This
work was supported in part by the NIH (GM 33894 and GM 68550)
and the Texas Advanced Research Program.
Supporting Information Available: Preparation and characteriza-
tion of the substrates, coordinates for the crystal structure, and ee
determinations by CE. X-ray crystallographic data in CIF format. This
material is available free of charge via the Internet at http://pubs.acs.org.
Figure 2. (a) ³¹P NMR spectrum of (S_P)- and (R_P)-11 from reaction of
racemic 9 with 10. (b) NMR spectrum of racemic 11 after additon of
authentic (R_P)-11. (c) NMR spectrum of product isolated from the kinetic
resolution of racemic 5 with the wild-type PTE after reaction with 10.
References
Prior investigations have demonstrated that alterations in the
inherent substrate specificity of wild-type PTE can be obtained by
mutation of those amino acids that come in close contact with the
substrate in the active site. A series of mutants was screened in an
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as possessed by the wild-type PTE. For the kinetic resolution of
compound 5, the mutant I106T/F132A/H254G/H257W (TAGW)
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hydrolyzed the (R_P)-enantiomer of 5 over the (S_P)-enantiomer by
a factor of 17. The catalytic properties of TAGW were quantified
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and the results are presented in Figure 3. The stereoselectivity of
the mutant TAGW is not as dramatic as that of the wild-type
enzyme, but this variant of PTE shows a clear preference for the
hydrolysis of the (R_P)-enantiomer over that for the corresponding
mirror image.
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