Steroselectivity of the glutathione S-transferase catalyzed conjugation of aralkyl halides

Steroselectivity of the glutathione S-transferase catalyzed conjugation of aralkyl halides

Vol. 96, No. September 1, 1980 BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS 333-340 Pages 16, 1980 STEREOSELECTIVITY OF THE GLUTATH...

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Vol.

96, No.

September

1, 1980

BIOCHEMICAL

AND

BIOPHYSICAL

RESEARCH

COMMUNICATIONS

333-340

Pages

16, 1980

STEREOSELECTIVITY OF THE GLUTATHIONE S-TRANSFERASE CATALYZED CONJUGATION OF ARALKYL HALIDES James B. Mangold University Received

July

and Mahmoud M. Abdel-Monem*

Department of Medicinal Chemistry of Minnesota, Minneapolis, MN 55455

29,198O

SUMMARY: Ratcytosolicglutathione Siransferases catalyzed the conjugation of phenethyl chloride and phenethyl bromide with glutathione. The reaction proceeded with a high degree of stereoselectivity. The glutathione conjugate possessing the (R,S,S)absolute configuration was formed in major quantities from the racemic substrates. The use of the enantiomers of the phenethyl chloride substrates indicated that the (S)-phenethyl chloride was conjugated in preference to the (R)-enantiomer. The conjugation proceeded with inversion of configuration at the benzylic carbon consistent with an SN2-type mechanism. The stereoselectivity was greater for phenethyl chloride than for phenethyl bromide. Varying the substrate or enzyme concentration had no effect upon the observed stereoselectivity. The diastereomeric glutathione conjugates were separated by high performance liquid chromatography. These findings represent the first demonstration of the substrate stereoselectivity of the glutathione S-transferases. INTRODUCTION: glutathione

with

substrates to have group

The glutathione an extremely

including no rigid

of the

conjugation

hydrophobic

of glutathione

(3.4).

However,

to involve at the

it

intermediate

displacement

reaction

*

xenobiotics

(1,Z).

the

(2).

direct

the occurance

To whom correspondence

attack

that

substrate should

or the for

chiral

the

substrates, provides

a single

between would

substrate concentrations,

mechanism

center,

the produce

involving

an

in which

the

a straightforward

or double

chiral

leaving

of the sulfhydryl

at low glutathione

of either

reaction

appears

atom on the hydrophobic

The use of chiral the

Catalysis

mechanism

nucleophilic

of

hydrophobic

skeleton

a double-displacement

involves

and a racemic

carbon

The normal

electrophilic

via

the conjugation

of electrophilic,

either

(3).

The conjugation

catalyze

variety

has been suggested

may proceed

means of determining

for substrate

enzyme-bound

glutathione,

toxic

specificity

group

mechanism.

broad

certain

appears

the catalysis

S-transferases

displacement

tripeptide,

two diastereomers

displaying

be addressed.

0006-291X/80/170333-08$01.00/0 333

Copyright 0 1980 by Academic Press, Inc. AN rights of reproduction in any fwm reserved.

Vol.

96, No.

different

physical

of the if

BIOCHEMICAL

1, 1980

substrate

whether

is the

not

center,

thereby

chiral

substrate unusual that

substrates,

can undergo

catalysis

produce

only

retention

of glutathione

with

one of these

between

of glutathione

This

at the

the very these

then

the

catalysis a high

is

particularly

variety

indicate

two mechanisms.

encountered

large

center.

of configuration

S-transferase

stereoselectivity

one

diastereomers,

chiral

would

or inversion

we have unexpectedly

with

COMMUNICATIONS

of the product

distinguishing

considering

RESEARCH

by racemization

with

studies

stereoselectivity. and unexpected

BIOPHYSICAL

reaction

configuration

proceeded

In our mechanistic using

should

accompanied

absolute

the reaction

at the chiral

Further,

enantiomers

the reaction

Establishing

properties.

AND

degree

of

of substrates

isozymes.

pure (R) and (S)-mandelic acids were MATERIALS AND METHODS: Optically purchased from Aldrich Chemical Company. Reduced glutathione was obtained from Sigma Chemical Company. Racemic phenethyl chloride was prepared from 1-phenylethanol using PoC13 by the method of Siegel and Graefe (5). Racemic phenethyl bromide was obtained from 1-phenylethanol using PBr3 by the method of Rupe and Tomi (6). Synthesis of Optically Active Substrates from Optically Pure Mandelic Acids (8). Mandelic acid was reduced with borane-THk+%cmplex to the corresponding phenylethylene glycol using the procedure of Yoon et al. (7). Phenylethylene glycol was converted to 1-phenylethanol by the procedure of Maylin et (8). The chiral 1-phenylethanol was converted to the -- al. corresponding chloro compound using POC13 by the method of Siegel and Graefe (S)-isomer, 52% yield (cr]g4 -99.3" (neat), 78.8% e.e., Anal. (C8HgC1); (5). Calcd: C 68.34, H 6.45, Cl 25.21; Found: C 68.20, H 6.86, Cl 24.74; (R)isomer, 46% yield, (~16~ + 99.6O(neat), 79.0% e.e., Anal. (C8HgC1); C 68.34, H, 6.45, Cl 25.21; Found: C 69.02, H 6.78, Cl 23.96. The optical purity of the chiral phenethyl chlorides was verified by reaction with glutathione (as described below) to form the corresponding S-(1-phenylethyl)-glutathiones. The diasteriomeric purities of the conjugates obtained from the (S)-chloro and (R)-chloro compounds were 76.2% and 81.4%, respectively. S-(1-Phenylethyl)-glutathione. Glutathione (10 nnnol, 3.07 g) was dissolved in 1.2 M KOH (25 mL). Ethanol (25 mL) was added followed by (R,S)-phenethyl chloride (10 mmol, 1.40 g) and a catalytic amount of 18Crown-6 (1 mmol, 264 mg) (Aldrich Chemical Company). The reaction was stirred (3 h) and then adjusted to pH 3.2 (cont. HCl), concentrated and extracted with diethyl ether. Solids formed during concentration or extraction were isolated by filtration. The aqueous layer was evaporated to dryness. The combined solids were recrystallized from hot water. Product enriched in the (S,S,S)-diastereomer crystallized first; Anal. (C18H26N306S); Calcd; C 52.54, H, 6.12, S 7.93; Found: 52.62, H 6.08, s 8.05. The mother liquor provided product enriched in the (R,S,S)-diastereomer ** Abbreviations: HPLC, high performance liquid chromatography; tetrahydrofuran, TCA, trichloroacetic acid; e-e., enantiomeric EDTA, ethylenediaminetetraacetic acid; and GSH, glutathione.

334

THF, excess;

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upon concentration; Anal. (ClSH26N306S); Calcd: c 52.54, H 6.12, S 7.93; Found: C 52.36, H 6.16, S 7.94. Isolated yields were generally about 60%. Enzyme Preparation. A 20% liver homogenate in 0.1 M potassium phosphate buffer (pH 7.0) containing 1 mM EDTA was obtained from male Sprague-Dawley rats (150-200 g). The 105,000 g supernatant was used as the source of the glutathione S-transferase activity. Protein was measured by a dye-binding assay (Bio-Rad Protein Assay Kit; Bio-Rad Laboratories), using bovine serum albumin as the standard. Enzyme Incubations. Enzyme incubations were performed at pH 7.5 in 0.1 M potassium phosphate buffer at 25O C for 5 minutes. Standard incubation mixtures contained 15.2 mg of protein (as 105,000 g liver supernatant), 5 mM glutathione, 2 mM substrate, 1 mM EDTA and 4% (v/v) ethanol in a total volume of 10 mL. The incubations were terminated by the addition of 20% TCA (2 mL). The precipitated protein was removed by centrifugation and the supernatant was extracted with methylene chloride. The methylene chloride layer was discarded and the aqueous layer was adjusted to pH 5 by the dropwise addition of 4.6 M sodium acetate. The aqueous solution was extracted with methylene chloride and a 9 mL aliquot of the aqueous layer was passed through a 1 x 4 cm AmberliteR XAD-4 resin column. A stepwise methanol-water gradient was used to elute the glutathione conjugates. The 20-40% fractions were combined and concentrated to dryness under reduced pressure. The resulting residue was reconstituted with 100 uL of distilled water and an aliquot was analyzed by HPLC. Quantitation of the conjugates was carried out by measuring chromatographic peak heights. The concentrations of the conjugates in the original incubation mixtures were calculated by comparing their chromatographic peak heights with those obtained from known amounts of authentic samples of the conjugates added to the incubation mixtures. Recoveries of the two diastereomers from the incubation mixture were determined using synthetically prepared glutathione conjugates. At the concentrations tested, the two diastereomers were recovered equally from the incubation mixture. RESULTS AND DISCUSSION: pure

mandelic

of the

acids

carboxyl

carbon.

of known

group

chiral

benzylic of configuration

phenethyl

halides

proceed

with

10).

inversion

starting

adducts halides.

illustrated

of configuration

1 represents

from the

reaction

were

which

of the benzylic

converted

proceed (5,

reduction

to the

primarily

9).

with

The reaction

has been demonstrated

consistent absolute

upon the known course

optically

with

absolute

to

an SN2-type

configuration

of the

configuration

of a typical

of

mechanism resulting of the

synthetic

sequence

Scheme I.

The diasteriomeric Figure

of the

The stereochemical in

integrity

alcohols

nucleophiles

from

The sequential

some racemization

sulfhydryl

was based

synthesized

configuration.

by reactions

with

the assignment

Thus,

glutathione

is

with

were

the configurational benzylic

halides

inversion

substrates

absolute

conserved

The resulting

corresponding

(5,

The chiral

glutathione the

conjugates

HPLC separation

of glutathione

with

of the the

335

were

separated

two diastereomers

different

substrates.

using

HPLC.

obtained

Vol.

96, No.

BIOCHEMICAL

1. 1980

AND

BIOPHYSICAL

w-2

(Sk4a

RESEARCH

COMMUNICATIONS

(R)-3

(RTS,S)-5a

(RF4b Scheme I. glutathione configurations below the

Stereochemical conjugates of the structures.

course of the formation of the diastereomeric from optically active mandelic acids. The absolute are designated in parentheses specific intermediates

RPL& separation of the diastereomeric glutathione conjugates formed 1. bv react ion of glutathione with: (a) (R,S)-phenethyl bromide, (b) (R,S)(c) (R)-phenethyl chloride and (d) (S)-phenethyl chloride. pienethyl chloride, Peak A corresponds to the diastereomer having the (R,S,S)-configuration The analysis and peak B to the diastercomer of the (S,S,S)-configuration. was performed on a u-Bondapak C-18 column (Waters Associates; Milford, Mass.) using 12% isopropyl alcohol in 0.01 M acetic acid as the mobile phase at a flow rate of 1.5 mL/min and a W detector set at 254 Nn.

Fig.

336

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96, No.

1, 1980

BIOCHEMICAL

AND

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RESEARCH

COMMUNICATIONS

1

Fig. 2. Enzymatic formation of glutathione conjugates from phenethyl bromide, phenethyl chloride and its enantiomers. The open bars represent the product having the (R,S,S)-configuration and the cross-hatched bars correspond to the product with the (S,S,S)-configuration. Each point represents the average of two separate experiments.

Incubation

of

of rat

liver

of the

glutathione

in equal

(R,S)-phenethyl

in the presence

-5a and -5b.

as expected.

to that

of the

of the

(R,S)-phenethyl in the

was only

3.

under

of a mixture

the origin

of the preferential

Incubation

of phenethyl

in higher

yields

of the glutathione

equimolar

amount

of the racemate.

approximately

8.

the

(R)-enantiomer

ratio

(5a/5b) --

In contrast, resultedin

in the

product

enriched

with

the

conjugates The ratio the

incubation

a much lower was about

337

1.4.

not produced

than

also

the ratio

established

the racemic

substrates.

(S)-enantiomer

resulted

obtained

substrate

experiments

from an was

enriched

of the conjugates

These

(5a/5b) --

in the product

of the yield

Incubation

conditions

those

(5a/5b) --

(5a) -

2).

substrates

of -5a from

enriched

the formation

were

of -5a and -5b. but

formation

chloride

in

5 (Fig.

same reaction

The use of enantiomerically

g supernatant

(R,S,S)-diastereomer

was about

the

105,000

thioethers

of the

(5b) -

bromide

formation

the

resulted

These

The ratio

(S,S,S)-diastereomer

resulted

with

of 5 mM glutathione

conjugates

amounts

chloride

andthe suggested

in

Vol.

96, No.

BIOCHEMICAL

1, 1980

AND

8USSTRATE

Fig. 3. conjugation designate represent

Effect the the

these

having

the (R,S,S)-configuration

of

(S,S,S)-configuration.

The

enantiomer more,

for

the

an examination between

indicated

that

at the with

benzylic

the

of high

the

reaction

carbon

verify

the effect

and the protein relative

the total

proceeded

conjugate

enzymatic The triangles

enriched

of the

substrate.

proposed

for

as well

ratio

of the diasteriomers

and glutathione

of configuration

observation

is

consistent

reactions

phenomenon

substrate

concentration

4) on the amount

of the diastereomers formation

conjugation

in the presence

(3).

the (Fig.

(RIFurther-

(S)-enantiomer

stereoselectivity

of varying

the

activities.

an inversion This

of stereo-

than

of the

the conjugation

of glutathione the

in the with

degree

substrate

course

concentration (Sa/Sb) --

a high

stereochemical

concentration ratios

with

S-transferase

proceeded

that

the

and the circles point represents

glutathione

substrate

concentrations

in nature,

and the

of the the

on

Each

was a better

liver

SN2 mechanism

To further

that

reactions

rat

COMMUNICATIONS

experiments.

(S)-enantiomer

the

reaction

concentration with glutathione.

product

conjugation

selectivity.

substrate chloride

RESEARCH

(mYI

product

the average of two separate that

CONCENTRATION

of varying the racemic phenethyl

of

BIOPHYSICAL

as to the amount

of added

remained

338

(Fig.

of conjugate

was determined.

was proportional

to both protein

constant

was enzymatic

It the

(enzyme). in all

cases

3) formation was found

substrate The when

Vol.

96, No.

1, 1980

BIOCHEMKAL

AND

BIOPHYSICAL

RESEARCH

COMMUNICATIONS

Fig. 4. Effect of varying the protein concentration on the enzymatic -conjugation of racemic phenethyl chloride with glutathione. The triangles represent the product of the (R,S,S)-configuration and the circles correspond to the product of the (S,S,S)-configuration. Each point represents the average of two separate experiments.

0.3

b-A-A\A~A 2 io.2 2 f a B $0.1 8 E

‘-0-o

0

0

5

10

15 TlYE (ml”.)

0

20

25

30

Fig. 5. Time course of the enzymatic conjugation of racemic phenethyl chloride with glutathione. The triangles represent the product of the (R,S,S)-configuration and the circles correspond to the product of the (S,S,S)-configuration. Each point represents the average of two separate experiments except at 30 set which was a single experiment.

339

Vol.

96, No.

the racemic the

BIOCHEMICAL

1, 1980

phenethyl

enzymatic

proceeding

chloride

reaction maximally

AND

substrate

was studied in about

was not

commonly

five

minutes

demonstrates preference

reagents

(being

to the

observed

rigid

preferences

is

for

National

was found

mixture,

the

of

to be rapid

When either

5).

as an anomoly.

absolute not

boiled

formation

of

of

some

certain

metabolizing

substrates

are

acids).

exhibited a large

enzymes

Generally, the xenobiotic by these variety

few exceptions. essentially the

exceptions

metabolizing enzymes

has

of different

enzymes

do exhibit

by training

grant

stereochemical

(11).

J. B. M. was supported Institutes

since

have been

to metabolize

enzyme catalysis

with

(S)-amino

of specificity

In fact,

stereospecificity

unreasonable

composed

to the need

ACKNOWLEDGEMENTS: from the

be viewed

degree

However,

substrates.

course

time

in the case of the glutathione

stereospecificity

The lesser

been attributed

not

rigidand

chiral

enzymes.

(Fig.

incubation

of stereoselectivity

should

Enantiomeric

The

was tested.

COMMUNICATIONS

detected.

The observation S-transferases

RESEARCH

and the reaction

enzyme or no enzyme was used in the conjugate

BIOPHYSICAL

No. GM-07480

of Health.

REFERENCES 1. 2. 3. 4.

5. 6. 7. 8. 9.

10. 11.

W. H. Habig, M. J. Pabst and W. B. Jakoby (1974) J. Biol. Chem. -'249 7130-7139. L. F. Chasseaud (1976) in Glutathione, Metabolism and Function (I. M. Arias and W. B. Jakoby, eds.) pp. 77-114, Raven Press, New York. M. J. Pabst, W. H. Habig and W. B. Jakoby (1974) J. Biol. Chem. 249, 7140-7150. B. Mannervik, C. Guthenberg, I. Jakobson and M. Warholm (1978) in Conjugation Reactions in Drug Biotransformation, (A. Aitio, Ed.) pp. 101-110, Elsevier/North Holland Biomedical Press, Amsterdam. S. Siegel and A. Graefe (1953) J. Am. Chem. Sot. 75, 4521-4525. H. Rupe and W. Tomi (1914) Ber. 41, 3064-3083. N. M. Yoon, C. S. Pak, H. C. Brown, S. Krishnamurthy and T. P. Stocky (1973) J. Org. Chem. 2, 2786-2792. G. A. Maylin, M. J. Cooper and M. W. Anders (1973) J. Med. Chem. -16, 606-610. R. L. Burwell, Jr., A. D. Shields and H. Hart (1953) J. Am. Chem. Sot. 2, 908-909. E. D. Hughes, C. K. Ingold and A. D. Scott (1937) J. Chem. Sot., 1201-1208. L. K. Low and N. Castignoli, Jr. (1978) in Annual Reports of Medicinal Chemistry, (F. H. Clarke, Ed.), pp. 304-315. Academic Press, New York.

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