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Irreversible inactivation of pig brain γ-aminobutyric acid-α-ketoglutarate transaminase by 4-amino-5-halopentanoic acids
Vol.
95. No.
July
16, 1980
1, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
250-255
Pages
IRREVERSIBLE INACTIVATION OF PIG BRAIN y-AMINOBUTYRIC c+KETOGLUTARATE TRANSAMINASE BY 4-AMINO-5-HALOPENTANOIC ACIDS
ACID-
Richard B. Silverman and Mark A. Levy Department of Chemistry, Northwestern University Evanston, Illinois 60201 Received
May
29,198O
SUMMARY y-Aminobutyric acid-ar-ketoglutarate transaminase from pig brain is irreversibly inactivated by 4-amino-5-halopentanoic acids. Protection from inactivation by the natural substrates, the pH dependence of inactivation and the incorporation of 1.7 moles of radioactive inhibitor per mole of enzyme from (S)-[UJ*C]-4-amino-5-chloropentanoic acid suggest a covalent adduct at the active site of the enzyme. A mechanism-based inactivation. is proposed. INTRODUCTION It is well established Its concentration converts
in the brain
glutamate
of GABA to succinic a coenzyme vulsions
to GABA,
may result
(2).
(1).
diseases,
been to block the degradation used epilepsy reversibly
(4).
drug,
sodium
Several
neurotransmitter
by two enzymes,
and GABA-T,
GAD, which
which catalyzes
Both of these enzymes
When brain
levels
(1).
the degradation require
of GABA diminish,
PLP
(3), a chemotherapeutic e.g.,
epilepsy
and Huntington’s
of GABA by inhibiting valproate,
compounds,
approach
GABA-T
barrier
to the treatchorea, (1).
has been shown to inhibit 4-aminohex-5-ynoic
as
con-
Since GABA does not cross the blood-brain
circumstances
ment of convulsive
is regulated
semialdehyde.
for activity
under normal
that GABA is an inhibitory
has
The widely GABA-T
acid (6), 4-amino-
Abbreviations: GABA: y-aminobutyric acid; GABA-T : Y-aminobutyric acid -a-ketoglutarate transaminase, E.C. 2.6.1.19; GAD: glutamate decarboxylase, E .C. 4.1.1.14; PLP : pyridoxal phosphate; a-KG: a-ketoglutaric acid; SSADH : succinic semialdehyde - NADP : oxidoreductase, E .C D 1.2.1.16; NADP : nicotinamide adenosine triphosphate; Pyr in Scheme 1 represents the substituted pyridine nucleus in PLP . 0006-291X/80/130250-06$01.00/0 Copyright IG 1980 by Academic F’ress, Inc. A II righrs oJ reproducilon in an.vJorm rererved.
250
Vol.
95. No.
1, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
hex-5-enoic
acid (7), gabaculine
(8), isogabaculine
sulfate
(lo),
have been proven
to be mechanism-based
vators
(5) of GABA-T.
GABA-T
(ll),
pentanoic results
Based on the accepted
we have synthesized
acids (9 as potential of our inhibition
NH+
L
anticonvulsant
studies with purified
irreversible
inacti-
of action of
of 5-substituted-4-amino-
agents and report pig brain la,
X
here the
GABA-T. X=F
,b, x = Cl coo-
2, X=Br
3
MATERIALS
(9), and ethanolamine-o-
mechanism
(12) a series
COMMUNICATIONS
cl, X=OH
AND METHODS
Pig brain GABA-T was purified by the method of John and Fowler for the rabbit brain enzyme (13). The enzyme showed one band on SDS gel electrophoresis and had a specific activity of 7.5 units per mg protein. One unit is defined as the amount of enzyme which catalyzes the transamination of 1 clmole of GABA per min at 25’ C . GABA-T activity was determined using a modification of the method of Scott and Jakoby (11). The final concentrations in the assay solution were 10 mM GABA, 5 mM a-KG, 1 mM NADP, 5 mM .R-mercaptoethanol, and excess SSADH in 50 mM potassium pyrophosphate buffer, pH 8.5. Enzyme activity was determined by observing the change in absorbance at 340 nm at 25’ C after several minutes of incubation. SSADH was prepared from GABASE (Sigma Chemical Co. or Boehringer Mannheim) by inactivating the GABA-T with (S)-4-amino5-fluoropentanoic acid followed by exhaustive dialysis at 4’ C against 37.5 mM potassium phosphate, pH 7.2 containing 12.5% glycerol. This preparation could be stored for several months at -80’ C with no loss of SSADH activity and no gain of GABA-T activity. (S)-[U-14C]-4-Amino-5chloropentanoic acid (specific activity 1.02 mCifhnmo1) was prepared in an overall 32% yield from [U-14C]-L-glutamic acid (Research Products International) diluted with 0.25 mmol of unlabeled L -glutamic acid by carrying out the synthesis of & as previously reported (12). The purity was determined to be greater than 99% by TLC (cellulose, n-butanol-H,O-acetic acid, 12:5:3 and n-butanol-pyridine-water, 1:l:l) and by high voltage electrophoresis (pH 1.9). Radioactivity was determined on a Beckman LS-3100 scintillation counter using 3a 70B scintillation fluid (Research Products International) with [U-14C] toluene (New England Nuclear) as an internal standard. All other materials and methods have been reported previously (12) or are commercially available.
251
Vol.
95. No.
1. 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
50
I.01 5
IO
I5
20
TIME
Figure 1.
Inactivation
of GABA-T
(min.
25
30
35
)
by (S)-4-Amino-5-fluoropentanoic
acid.
Pig brain GABA -T (0.13 8 units) was incubated at 25’ C in 0.4 ml of 50 mM buffer containing 5 mM mercaptoethanol and different concentrations of inhibitor and substrates. The incubation was stopped by diluting a 40 d aliquot of this mixture to 1 ml in a U. V. cuvette with buffer containing all of the necessary reagents for the assay. The inhibitor concentrations and the substrates depicted are: A , control; X, 0.100 mM inhibitor, pH 7.5; A , 0.200 mM inhibitor, pH 8.5; 0 , 0.100 mM inhibitor, pH 8.5; 0.100 mM inhibitor, pH 8.5, 0 , plus 1.0 mM cr-KG and Cl , plus 1.0 mM (u-KG and 1 .O mM GABA.
RJ3SULTS
AND DISCUSSION
The 4-amino-5-halopentanoic irreversible with
inactivators
of pig brain
b or a led to a pseudo
activity (PI-I 8.5,
(Figure
1).
(A3
GABA-T.
first-order
The KI and kc&
25’ C) and for*
It is noteworthy
acids
k, cJ were
Incubation
time-dependent (6) for&
252
of GABA-T loss
of enzyme
are 395 @I and 0.50 min -1
are 13.1 mM and 0.55 min-‘,
that the I$ for & is 12 times
found to be
lower
respectively.
than the KM (4.8 mM)
Vol.
95. No.
1, 1980
BIOCHEMICAL
for GABA (14).
Incubation
loss of enzyme vation
activity
gradually
AND
BIOPHYSICAL
of GABA-T
with & showed a time-dependent
In a separate
with time.
that preincubation
of & in pH 8.5 buffer
minutes
a solution
High voltage
amino-5-hydroxypentanoic
GABA-T
inhibitor
by 2 and l& is slower for the enzyme activity
(14).
dependent.
Since the rate of inactivation
strate,
The enzyme was protected
a-KG,
was dependent
and by GABA with a-KB on substrate
site-directed.
ethanol,
suggesting
that a reactive
Treatment followed
by exhaustive
ation of the labeled radioactivity inactivator
may be enzymeby its second sub-
The degree of protection
was unaffected
dialysis
does not escape from the active Exhaustive
enzyme
led to incorporation
This is consistent
two moles
of PLP
dialysis
of the inacti-
any enzyme activity.
thus confirming
to the protein. 253
acid
of 1.7 moles
of inacti-
with the fact that the enzyme
per mole of enzyme
in 8 M urea resulted
from the enzyme,
is
by B-mercapto-
with (S)-[U-14C]-4-amino-5-chloropentanoic
vator per mole of enzyme. containing
with the
that the inactivation
at pH 5.4 to pH 8.5 did not regenerate
of GABA-T
is a dimer
species
to effect inactivation.
1).
implying
The rate of inactivation
site and then return vated enzyme
concentration,
l), the pH optimum
inactivation
(Figure
of
of GABA-T
corresponds
of inactivation from
4-
is slower than the
The rate of inactivation
the mechanism
the enzyme.
the rate of inactivation
at pH ‘7.5 than at pH 8.5 (Figure
of the enzyme,
for 20
which we have found to be
of the experiment
hydrolysis.
we found
showed that it may contain
Presumably,
by g under the conditions
experiment
did not inactivate
a compound
of GABA-T.
rate of its non-enzymatic
active
of this solution acid (l&),
the rate of inacti-
in the absence of enzyme
whose components
electrophoresis
a reversible
COMMUNICATIONS
which was not pseudo first-order;
diminished
produced
RESEARCH
(14).
Denatur-
in little
or no release
covalent
attachment
of
of the
Vol.
95, No.
1, 1980
BIOCHEMICAL
Scheme 1. Proposed Mechanism 5 -halopentanoic Acids. These results inactivators
are currently
BIOPHYSICAL
of Inactivation
RESEARCH
. We believe
inactivators investigating
acids are irreversible
that these compounds
of this enzyme this proposed
COMMUNICATIONS
of GABA-T by 4-Amino-
show that 4-amino-5-halopentanoic
of GABA-T
based (suicide)
AND
as described mechanism
are mechanism-
in Scheme 1, and
of inactivation.
ACKNOWLEDGMENT The authors Institutes
are grateful
of Health
for support
of this research
by the National
(Grant NS 15703).
REFERENCES 1.
Roberts, Nervous
E., Chase, T. N., and Tower, System Function, Raven Press,
D. B. (1976) GABA in N. Y.
2.
Beeler, 371.
T . and Churchich,
3.
Meldrnn, B. S. and Horton, R. W. in Harris, (Edit.) (1974) Epilepsy, Churchill Livingstone,
J. E. (1977) Eur.
254
J. Biochem.
85, 365-
P . and Mawdsley , C . Edinburgh, p. 55.
Vol.
95, No.
1, 1980
BIOCHEMICAL
AND
4.
Godin, them.
Y., Heiner, L., 16, 869 -873.
5.
Walsh,
C. (1977) Horiz.
6.
Jung, M. J. and Metcalf, Comm. 67, 301-306.
7.
B. W., Jung, Lippert, B., Metcalf, Eur. J. Biochem. 74, 441-445.
8.
Rando, Comm.
9.
Metcalf, B. W. and Jung, 539 -545.
Mark,
Fowler,
11.
Scott,
12,
Silverman, 818.
13.
John,
14.
Bloch-Tardy, 56, 823 -832.
L. J. and John, E. M. and Jakoby,
R. A. and Fowler, Rolland,
RESEARCH
and Mandel, Biophys.
M. J.,
COMMUNICATIONS
P . (1969) J. Neuro-
3, 36-81.
B. W. (1975) Biochem.
Biophys.
and Casara,
F. W. (1977) Biochem. M. J. (1979) Molecular
R. A. (1972) Biochem. B. (1958) J. Biol.
R. B. and Levy,
M.,
J.,
Biochem.
R. R. and Bangerter, 76, 1276-1281.
10.
BIOPHYSICAL
255
and Gonnard,
Biophys.
Res. 16,
J. 130, 569-573.
M. A. (1980) J. Org.
B.,
P. (1977)
Pharmacol.
Chem.
L. J. (1976) Biochem.
Res.
234, 932-936. Chem.
45,
815-
J. 155, 645-651. P. (1974) Biochimie
95. No.
July
16, 1980
1, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
250-255
Pages
IRREVERSIBLE INACTIVATION OF PIG BRAIN y-AMINOBUTYRIC c+KETOGLUTARATE TRANSAMINASE BY 4-AMINO-5-HALOPENTANOIC ACIDS
ACID-
Richard B. Silverman and Mark A. Levy Department of Chemistry, Northwestern University Evanston, Illinois 60201 Received
May
29,198O
SUMMARY y-Aminobutyric acid-ar-ketoglutarate transaminase from pig brain is irreversibly inactivated by 4-amino-5-halopentanoic acids. Protection from inactivation by the natural substrates, the pH dependence of inactivation and the incorporation of 1.7 moles of radioactive inhibitor per mole of enzyme from (S)-[UJ*C]-4-amino-5-chloropentanoic acid suggest a covalent adduct at the active site of the enzyme. A mechanism-based inactivation. is proposed. INTRODUCTION It is well established Its concentration converts
in the brain
glutamate
of GABA to succinic a coenzyme vulsions
to GABA,
may result
(2).
(1).
diseases,
been to block the degradation used epilepsy reversibly
(4).
drug,
sodium
Several
neurotransmitter
by two enzymes,
and GABA-T,
GAD, which
which catalyzes
Both of these enzymes
When brain
levels
(1).
the degradation require
of GABA diminish,
PLP
(3), a chemotherapeutic e.g.,
epilepsy
and Huntington’s
of GABA by inhibiting valproate,
compounds,
approach
GABA-T
barrier
to the treatchorea, (1).
has been shown to inhibit 4-aminohex-5-ynoic
as
con-
Since GABA does not cross the blood-brain
circumstances
ment of convulsive
is regulated
semialdehyde.
for activity
under normal
that GABA is an inhibitory
has
The widely GABA-T
acid (6), 4-amino-
Abbreviations: GABA: y-aminobutyric acid; GABA-T : Y-aminobutyric acid -a-ketoglutarate transaminase, E.C. 2.6.1.19; GAD: glutamate decarboxylase, E .C. 4.1.1.14; PLP : pyridoxal phosphate; a-KG: a-ketoglutaric acid; SSADH : succinic semialdehyde - NADP : oxidoreductase, E .C D 1.2.1.16; NADP : nicotinamide adenosine triphosphate; Pyr in Scheme 1 represents the substituted pyridine nucleus in PLP . 0006-291X/80/130250-06$01.00/0 Copyright IG 1980 by Academic F’ress, Inc. A II righrs oJ reproducilon in an.vJorm rererved.
250
Vol.
95. No.
1, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
hex-5-enoic
acid (7), gabaculine
(8), isogabaculine
sulfate
(lo),
have been proven
to be mechanism-based
vators
(5) of GABA-T.
GABA-T
(ll),
pentanoic results
Based on the accepted
we have synthesized
acids (9 as potential of our inhibition
NH+
L
anticonvulsant
studies with purified
irreversible
inacti-
of action of
of 5-substituted-4-amino-
agents and report pig brain la,
X
here the
GABA-T. X=F
,b, x = Cl coo-
2, X=Br
3
MATERIALS
(9), and ethanolamine-o-
mechanism
(12) a series
COMMUNICATIONS
cl, X=OH
AND METHODS
Pig brain GABA-T was purified by the method of John and Fowler for the rabbit brain enzyme (13). The enzyme showed one band on SDS gel electrophoresis and had a specific activity of 7.5 units per mg protein. One unit is defined as the amount of enzyme which catalyzes the transamination of 1 clmole of GABA per min at 25’ C . GABA-T activity was determined using a modification of the method of Scott and Jakoby (11). The final concentrations in the assay solution were 10 mM GABA, 5 mM a-KG, 1 mM NADP, 5 mM .R-mercaptoethanol, and excess SSADH in 50 mM potassium pyrophosphate buffer, pH 8.5. Enzyme activity was determined by observing the change in absorbance at 340 nm at 25’ C after several minutes of incubation. SSADH was prepared from GABASE (Sigma Chemical Co. or Boehringer Mannheim) by inactivating the GABA-T with (S)-4-amino5-fluoropentanoic acid followed by exhaustive dialysis at 4’ C against 37.5 mM potassium phosphate, pH 7.2 containing 12.5% glycerol. This preparation could be stored for several months at -80’ C with no loss of SSADH activity and no gain of GABA-T activity. (S)-[U-14C]-4-Amino-5chloropentanoic acid (specific activity 1.02 mCifhnmo1) was prepared in an overall 32% yield from [U-14C]-L-glutamic acid (Research Products International) diluted with 0.25 mmol of unlabeled L -glutamic acid by carrying out the synthesis of & as previously reported (12). The purity was determined to be greater than 99% by TLC (cellulose, n-butanol-H,O-acetic acid, 12:5:3 and n-butanol-pyridine-water, 1:l:l) and by high voltage electrophoresis (pH 1.9). Radioactivity was determined on a Beckman LS-3100 scintillation counter using 3a 70B scintillation fluid (Research Products International) with [U-14C] toluene (New England Nuclear) as an internal standard. All other materials and methods have been reported previously (12) or are commercially available.
251
Vol.
95. No.
1. 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
50
I.01 5
IO
I5
20
TIME
Figure 1.
Inactivation
of GABA-T
(min.
25
30
35
)
by (S)-4-Amino-5-fluoropentanoic
acid.
Pig brain GABA -T (0.13 8 units) was incubated at 25’ C in 0.4 ml of 50 mM buffer containing 5 mM mercaptoethanol and different concentrations of inhibitor and substrates. The incubation was stopped by diluting a 40 d aliquot of this mixture to 1 ml in a U. V. cuvette with buffer containing all of the necessary reagents for the assay. The inhibitor concentrations and the substrates depicted are: A , control; X, 0.100 mM inhibitor, pH 7.5; A , 0.200 mM inhibitor, pH 8.5; 0 , 0.100 mM inhibitor, pH 8.5; 0.100 mM inhibitor, pH 8.5, 0 , plus 1.0 mM cr-KG and Cl , plus 1.0 mM (u-KG and 1 .O mM GABA.
RJ3SULTS
AND DISCUSSION
The 4-amino-5-halopentanoic irreversible with
inactivators
of pig brain
b or a led to a pseudo
activity (PI-I 8.5,
(Figure
1).
(A3
GABA-T.
first-order
The KI and kc&
25’ C) and for*
It is noteworthy
acids
k, cJ were
Incubation
time-dependent (6) for&
252
of GABA-T loss
of enzyme
are 395 @I and 0.50 min -1
are 13.1 mM and 0.55 min-‘,
that the I$ for & is 12 times
found to be
lower
respectively.
than the KM (4.8 mM)
Vol.
95. No.
1, 1980
BIOCHEMICAL
for GABA (14).
Incubation
loss of enzyme vation
activity
gradually
AND
BIOPHYSICAL
of GABA-T
with & showed a time-dependent
In a separate
with time.
that preincubation
of & in pH 8.5 buffer
minutes
a solution
High voltage
amino-5-hydroxypentanoic
GABA-T
inhibitor
by 2 and l& is slower for the enzyme activity
(14).
dependent.
Since the rate of inactivation
strate,
The enzyme was protected
a-KG,
was dependent
and by GABA with a-KB on substrate
site-directed.
ethanol,
suggesting
that a reactive
Treatment followed
by exhaustive
ation of the labeled radioactivity inactivator
may be enzymeby its second sub-
The degree of protection
was unaffected
dialysis
does not escape from the active Exhaustive
enzyme
led to incorporation
This is consistent
two moles
of PLP
dialysis
of the inacti-
any enzyme activity.
thus confirming
to the protein. 253
acid
of 1.7 moles
of inacti-
with the fact that the enzyme
per mole of enzyme
in 8 M urea resulted
from the enzyme,
is
by B-mercapto-
with (S)-[U-14C]-4-amino-5-chloropentanoic
vator per mole of enzyme. containing
with the
that the inactivation
at pH 5.4 to pH 8.5 did not regenerate
of GABA-T
is a dimer
species
to effect inactivation.
1).
implying
The rate of inactivation
site and then return vated enzyme
concentration,
l), the pH optimum
inactivation
(Figure
of
of GABA-T
corresponds
of inactivation from
4-
is slower than the
The rate of inactivation
the mechanism
the enzyme.
the rate of inactivation
at pH ‘7.5 than at pH 8.5 (Figure
of the enzyme,
for 20
which we have found to be
of the experiment
hydrolysis.
we found
showed that it may contain
Presumably,
by g under the conditions
experiment
did not inactivate
a compound
of GABA-T.
rate of its non-enzymatic
active
of this solution acid (l&),
the rate of inacti-
in the absence of enzyme
whose components
electrophoresis
a reversible
COMMUNICATIONS
which was not pseudo first-order;
diminished
produced
RESEARCH
(14).
Denatur-
in little
or no release
covalent
attachment
of
of the
Vol.
95, No.
1, 1980
BIOCHEMICAL
Scheme 1. Proposed Mechanism 5 -halopentanoic Acids. These results inactivators
are currently
BIOPHYSICAL
of Inactivation
RESEARCH
. We believe
inactivators investigating
acids are irreversible
that these compounds
of this enzyme this proposed
COMMUNICATIONS
of GABA-T by 4-Amino-
show that 4-amino-5-halopentanoic
of GABA-T
based (suicide)
AND
as described mechanism
are mechanism-
in Scheme 1, and
of inactivation.
ACKNOWLEDGMENT The authors Institutes
are grateful
of Health
for support
of this research
by the National
(Grant NS 15703).
REFERENCES 1.
Roberts, Nervous
E., Chase, T. N., and Tower, System Function, Raven Press,
D. B. (1976) GABA in N. Y.
2.
Beeler, 371.
T . and Churchich,
3.
Meldrnn, B. S. and Horton, R. W. in Harris, (Edit.) (1974) Epilepsy, Churchill Livingstone,
J. E. (1977) Eur.
254
J. Biochem.
85, 365-
P . and Mawdsley , C . Edinburgh, p. 55.
Vol.
95, No.
1, 1980
BIOCHEMICAL
AND
4.
Godin, them.
Y., Heiner, L., 16, 869 -873.
5.
Walsh,
C. (1977) Horiz.
6.
Jung, M. J. and Metcalf, Comm. 67, 301-306.
7.
B. W., Jung, Lippert, B., Metcalf, Eur. J. Biochem. 74, 441-445.
8.
Rando, Comm.
9.
Metcalf, B. W. and Jung, 539 -545.
Mark,
Fowler,
11.
Scott,
12,
Silverman, 818.
13.
John,
14.
Bloch-Tardy, 56, 823 -832.
L. J. and John, E. M. and Jakoby,
R. A. and Fowler, Rolland,
RESEARCH
and Mandel, Biophys.
M. J.,
COMMUNICATIONS
P . (1969) J. Neuro-
3, 36-81.
B. W. (1975) Biochem.
Biophys.
and Casara,
F. W. (1977) Biochem. M. J. (1979) Molecular
R. A. (1972) Biochem. B. (1958) J. Biol.
R. B. and Levy,
M.,
J.,
Biochem.
R. R. and Bangerter, 76, 1276-1281.
10.
BIOPHYSICAL
255
and Gonnard,
Biophys.
Res. 16,
J. 130, 569-573.
M. A. (1980) J. Org.
B.,
P. (1977)
Pharmacol.
Chem.
L. J. (1976) Biochem.
Res.
234, 932-936. Chem.
45,
815-
J. 155, 645-651. P. (1974) Biochimie