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An NADH dependent cleavage of DTNB by the α-ketoglutarate dehydrogenase complex
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 32, No. 3, 1968
AN NADH DEPENDENT CLEAVAGE OF DTNB BY THE a-KETOGLUTARATE
DEHYDROGENASE COMPLEX1
J. D. Erfle Animal
Research
Research
Institute,
Ottawa
Received
Branch,
Canada Department
3, Ontario,
of Agriculture,
Canada
July 10, 1968
In the complex
titration
of sulfhydryl
by the DTNB2 method
contribution lipoic
and F. Sauer
to the total
acid.
groups
of Ellman sulfhydryl
The mechanism
in
(1959) groups
+ LipS2-E2
Reduced
-
+ E3-FAD
that
what
enzyme bound
NADH would
reduce
all
CRCH(OH)-TPP!-~1
+ co2
(1)
-f
[RCO-S-LipSHI-E2
+ TPP-El
(2)
[Lip(SH)2]-E2
2
E3-FAD + NAD+ i!
RCOCOOH + NAD+ + CoASH
to determine
+
+ CoASH 5!
[Lip(SH)2]-E2
was of interest
predicted
RCOCOOH + TPP-El
[RCO-S-LipSH]-E2
it
dehydrogenase
was made by reduced,
of the reaction
[RCH(OH)-TPP]-~~
the a-ketoglutarate
+
LipS2-E2
+ R-CO-S-CoA + reduced
(3)
E3FAD
(4)
E3FAD + NADH + H+ RCO-S-CoA
(5)
--
+ CO2 + NADH + H+
(6)
R = HOOC(CH2)2 the lipoic
sulfhydryl
and these
should
in the complex metric.
then
by reversal
be titratable.
in the presence
The nature
' Contribution
groups
of this
No. 317 from
of reactions The reaction
of NADH proved reaction
the Animal
4 and 5 (Sanadi of DTNB with
to be catalytic
has been studied
Research
et al.
sulfhydryl rather
and evidence
than
1952) groups
stoichio
is presented
Institute.
DTNB, 5,5'-dithio-bis(2-nitrobenzoic acid); TNB, 5-thio, 2 Abbreviations: 2-nitrobenzoic acid; TPP, thiamine pyrophosphate; Lips2 and Lip(SH)2, FAD, flavin adenine dinucleotide. oxidized and reduced lipoate (or lipoamide); E2 is dihydrolipoyl transuccinylase and El is a-ketoglutarate decarboxylase; E3 is lipoamide dehydrogenase (E.C. 1.6.4.3).
562
to
Vol. 32, No. 3, 1968
BIOCHEMICAL
demonstrate
of DTNB with
the reaction
succinylat:ion is
during
reduced
by lipoamide
the internal this
catalysis
is
the
of the
of lipoic
acid
taining
0.5
density
centrifugation
overall
G-200
and elution
Traces
study
additions
DTNB, 1 umole;
given
dehydrogenase
complex
optima
and 9.2.
of the reaction
of
by
was to replace
the
on a 2.5 x 40 cm (pH 7.0)
removed
(1966).
con-
by sucrose
The enzyme prepara-
2 to 4 units
per mg in
the
Boehringer
Biochemical
Mannheim
from
Corp.
N-ethyl
Corporation.
the increase potassium
NADH and iodoacetamide
in absorbancy
phosphate,
at 412 mu in a
(pH 7.0),
dehydrogenase,
5 ug;
of preincubation
50 umoles;
and purified
and the
order
CL-
of
and tables.
and Discussion
catalytic
illustrated The Km for
was 1 umole
dehydrogenase
Co., from
lipoamide
figure
of the is
from
Chemical
The details
in the
The NADH dependence
Lipoamide
of
heart
phosphate
were
--et al.
activities
Results -
metry
to that
from bovine
M potassium
by Ishikawa
dehydrogenase
contained
dehydrogenase.
at 7.6
formed
The significance
chromatography
dehydrogenase
of assay was to follow
umoles;
are
4).
modification
with
0.05
of pyruvate
of Nutritional
Incubations
ketoglutarate
thus
fashion
was isolated
The only
with
from Aldrich
was a product
NADH, 0.15
undergoes
6).
Sigma Chem. Co. and lipoamide
1 cm cuvette.
complex
had specific
(reaction
DTNB was purchased
The method
The dithiol
of reaction
chromatography
as described
this
reaction
maleimide
which
and Methods
(1967).
gel
mM EDTA.
in
--et al.
phosphate
of Sephadex
used
reaction.
(reverse
dehydrogenase
of Hirashima
cellulose-calcium
tions
sulfhydryl
discussed.
The o-ketoglutarate
column
acid
and NADH in an analogous
Materials
the method
lipoic
overall
dehydrogenase
dithiol
react-ion
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
alone
cleavage
in Figure
of DTNB by the a-ketoglutarate
1 (curve
DTNB was 1 mM at both of NADH oxidized was unable
563
1).
This
pH values.
per mole
to catalyze
reaction
has pH
The stoichio-
of DTNB reduced.
this
reaction
(Figure
1,
Vol. 32, No. 3, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TIME (MN)
cleavage of DTNB by the a-ketoglutarate dehydrogenase Figure 1. The enzymatic complex, The assay system is described in the Methods. Curve 1 - a-ketoglutarate dehydrogenase, 53 pg, (SQ. Act. 4 units/mg); curve 2 - same as 1 but preincubated 2 min. with NADH and succinyl-CoA (0.098 umoles/ml); curve 3 - same as 1 but preincubated 2 min. with a-ketoglutarate (0.1 umolefml); curve 4 - lipoamide dehydroAt the point indicated by the arrow the reaction was started by genase (25 ug). the addition of NADH (curves 1 and 4) or DTNB (curves 2 and 3). Table
I.
Properties cleavage
of the a-ketoglutarate of DTNB. Other
Enzyme additions*
dehydrogenase
additions
catalyzed
Activity
a-KGDH (native)
none
100
Lip.DH
none
0
Lip.DH o-KGDH (denatured)**
lipoamide + Lip.DH
(0.01 none
umole)
780 78
o-KGDH (denatured)
+ Lip.DH
Succinyl-CoA
78
a-KGDH (denatured)
+ Lip.DH
a-ketoglutarate
100
The reaction was run at pH 7.0, * The complete system is described in Methods. dehydrogenase complex. and initiated with DTNB. a-KGDH is a-ketoglutarate Lip.DH is lipoamide dehydrogenase. ** a-KGDH was denatured by a 10 min. incubation in 2.5 N KOH of 30°. paration was neutralized to pH 7.0 and buffered before assaying. 564
The pre-
Vol. 32, No. 3, 1968
curve
4),
unless
requirement
for
resides
with
8lOCHEMlCAL
catalytic
succinylase).
protein That
promotes
dehydrogenase
complex.
The participation in DTNB cleavage results
from
succinyl-CoA in the
tional
bound
evidence
Table
II.
the
case is
NADH.
demonstrated
moieties
demonstrated
results
was inhibitory the role
of lipoic
I where
complex
acid
tran-
lipoamide
2 and 3) by the inhibition
with
a-ketoglutarate of the
or lipoic
acid
and by reversal
Neither
cleavage
probably
transuccinylase
a-ketoglutarate
was denatured
in the
the
a-ketoglutarate
succinylation
and NADH.
Thus
the dihydrolipoyl
the case of a-ketoglutarate
when the
I). complex
of denatured
1, curves
in enzymatic
1 and 2 in
in
in Table
of the enzyme complex
This
(Table
of dihydrolipoyl
(Figure
the case of succinyl-CoA
for
(i.e.
acid
lipoic
(Table of DTNB is
I).
Addi-
provided
by
Effect of NADH on NEM and iodoacetamide inhibition of DTNB cleavage by the a-ketoglutarate dehydrogenase complex *
conditions:
NADH --
Iodoacetamide
+
residues
of the
Preincubation
+
acid
added
dehydrogenase
in the presence
further
3-5 in
were
DTNB cleavage
enzyme by reactions
succinyl-CoA
lipoic
preincubation
plus
of reactions nor
is
of lipoamide
of the a-ketoglutarate
such is
dehydrogenase
which
quantities
the remainder
its
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
NEM
Enzyme activity** G> 100
+
95
+
0 +
78
+
0
* Preincubations contained in 1 ml: pmoles; NADH, 1.2 umoles; NEM, 1 A 10 min. preincubation of enzyme after the addition of sulfhydryl of the last four incubations was to titrate sulfhydryl reagents. ** The enzyme preparations were hydrogenase (5 pg) was added addition of NADH.
Tris-Cl (pH 7.0), 50 umoles; EDTA, 0.2 pmole; iodoacetamide, 2 umoles; oKGDH, 3.6 mg. and NADH was followed by a 15 min. incubation reagents. After the incubation a 0.25 ml aliquot mixed with a stoichiometric amount of cysteine
assayed as described in Methods. Lipoamide The reactions were started to each assay.
565
deby the
Vol. 32, No. 3, 1968
the
inhibition
mide
(Table
studies II).
the reversal
by both
cleaves
These
complex
mechanism
bond
dependent also
is
and iodoaceta-
on NADH and hence
show that
oxidized
lipoic
the native acid
shown as one in which
between
6 of lipoic
Lipoamide E2-NHCO(CH2)4-CH
is
only
of DTNB cleavage
at carbon
N-ethylmaleimide
results
contains
the disulfide
sulfhydryl
reagents
compounds
4 and 5.
dehydrogenase
dehydrogenase
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the sulfhydryl
Inhibition
The proposed
the
with
of reactions
ketoglutarate
Since
BIOCHEMICAL
acid
lipoic is
acid
the
on o-
residues. lipoamide
and thionitrobenzoate.
one reported
to undergo
dehydrogenase
- CH2 - CH2 1 S
:
+q
E2-NHCO(CH2)4-jH
- CH2 - iH2 SH
NAD+
SH
TNB + NAD+
succinylation reaction.
(Gunsalus This
is
et al.,
consistent
1958) with
it
is depicted
inhibition
caused
as the one involved by conditions
in
the
favouring
succinylation.
Conclusions The results acid-TNB
disulfide
to succinylation
presented
demonstrate
by lipoamide have
led
the NADH dependent
dehydrogenase.
to the proposed
Inhibition
mechanism.
566
cleavage
of the
by conditions This
model
reaction
lipoic conducive has been
Vol. 32, No. 3, 1968
used to study all
for other This
is
this
caution
chain
as well.
demonstrating
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of lipoic acyl-CoA
of inhibition
acid
esters
moieties
in
and may have
The reaction
catalytic
involvement
cleavage
of a dithiol
the inhibition application
in studies
may in addition of protein
of the over-
provide
bound
of
a useful
lipoic
acid
enzymes. enzyme-catalyzed
to the best
that
the
by long
types
tool in
the involvement
reaction
other
BIOCHEMICAL
of our knowledge
reaction
is
of a more general
to investigators
presence
a hitherto
who attempt
formed
unreported
reaction
reaction.
or non-specific the titration
from
with
DTNB
The possibility
nature
should
serve
of enzyme sulfhydryl
as a
groups
in
of substrate.
References Ellman, G. L., (1959), Archives Biochem. Biophys., 82, 70. Gunsalus, I. C., and Smith, R. A., (1958), in Proceedings of Symposium on Enzyme Chemistry, p. 77. Maruzen, Tokyo, Hirashima, M., Hayakawa, T., and Koike, M., (1967), J. Biol. Ishikawa, E., Oliver, R. M., and Reed, L. J., (1966), Proc. 2, 534. Sanadi, D. K., Littlefield, J. W., and Bock, R. M., (1952),
567
the
International
Chem. a, Natl. Acad. J. Biol.
902. Sci.
(U.S.)
Chem. 197,
851.
Vol. 32, No. 3, 1968
AN NADH DEPENDENT CLEAVAGE OF DTNB BY THE a-KETOGLUTARATE
DEHYDROGENASE COMPLEX1
J. D. Erfle Animal
Research
Research
Institute,
Ottawa
Received
Branch,
Canada Department
3, Ontario,
of Agriculture,
Canada
July 10, 1968
In the complex
titration
of sulfhydryl
by the DTNB2 method
contribution lipoic
and F. Sauer
to the total
acid.
groups
of Ellman sulfhydryl
The mechanism
in
(1959) groups
+ LipS2-E2
Reduced
-
+ E3-FAD
that
what
enzyme bound
NADH would
reduce
all
CRCH(OH)-TPP!-~1
+ co2
(1)
-f
[RCO-S-LipSHI-E2
+ TPP-El
(2)
[Lip(SH)2]-E2
2
E3-FAD + NAD+ i!
RCOCOOH + NAD+ + CoASH
to determine
+
+ CoASH 5!
[Lip(SH)2]-E2
was of interest
predicted
RCOCOOH + TPP-El
[RCO-S-LipSH]-E2
it
dehydrogenase
was made by reduced,
of the reaction
[RCH(OH)-TPP]-~~
the a-ketoglutarate
+
LipS2-E2
+ R-CO-S-CoA + reduced
(3)
E3FAD
(4)
E3FAD + NADH + H+ RCO-S-CoA
(5)
--
+ CO2 + NADH + H+
(6)
R = HOOC(CH2)2 the lipoic
sulfhydryl
and these
should
in the complex metric.
then
by reversal
be titratable.
in the presence
The nature
' Contribution
groups
of this
No. 317 from
of reactions The reaction
of NADH proved reaction
the Animal
4 and 5 (Sanadi of DTNB with
to be catalytic
has been studied
Research
et al.
sulfhydryl rather
and evidence
than
1952) groups
stoichio
is presented
Institute.
DTNB, 5,5'-dithio-bis(2-nitrobenzoic acid); TNB, 5-thio, 2 Abbreviations: 2-nitrobenzoic acid; TPP, thiamine pyrophosphate; Lips2 and Lip(SH)2, FAD, flavin adenine dinucleotide. oxidized and reduced lipoate (or lipoamide); E2 is dihydrolipoyl transuccinylase and El is a-ketoglutarate decarboxylase; E3 is lipoamide dehydrogenase (E.C. 1.6.4.3).
562
to
Vol. 32, No. 3, 1968
BIOCHEMICAL
demonstrate
of DTNB with
the reaction
succinylat:ion is
during
reduced
by lipoamide
the internal this
catalysis
is
the
of the
of lipoic
acid
taining
0.5
density
centrifugation
overall
G-200
and elution
Traces
study
additions
DTNB, 1 umole;
given
dehydrogenase
complex
optima
and 9.2.
of the reaction
of
by
was to replace
the
on a 2.5 x 40 cm (pH 7.0)
removed
(1966).
con-
by sucrose
The enzyme prepara-
2 to 4 units
per mg in
the
Boehringer
Biochemical
Mannheim
from
Corp.
N-ethyl
Corporation.
the increase potassium
NADH and iodoacetamide
in absorbancy
phosphate,
at 412 mu in a
(pH 7.0),
dehydrogenase,
5 ug;
of preincubation
50 umoles;
and purified
and the
order
CL-
of
and tables.
and Discussion
catalytic
illustrated The Km for
was 1 umole
dehydrogenase
Co., from
lipoamide
figure
of the is
from
Chemical
The details
in the
The NADH dependence
Lipoamide
of
heart
phosphate
were
--et al.
activities
Results -
metry
to that
from bovine
M potassium
by Ishikawa
dehydrogenase
contained
dehydrogenase.
at 7.6
formed
The significance
chromatography
dehydrogenase
of assay was to follow
umoles;
are
4).
modification
with
0.05
of pyruvate
of Nutritional
Incubations
ketoglutarate
thus
fashion
was isolated
The only
with
from Aldrich
was a product
NADH, 0.15
undergoes
6).
Sigma Chem. Co. and lipoamide
1 cm cuvette.
complex
had specific
(reaction
DTNB was purchased
The method
The dithiol
of reaction
chromatography
as described
this
reaction
maleimide
which
and Methods
(1967).
gel
mM EDTA.
in
--et al.
phosphate
of Sephadex
used
reaction.
(reverse
dehydrogenase
of Hirashima
cellulose-calcium
tions
sulfhydryl
discussed.
The o-ketoglutarate
column
acid
and NADH in an analogous
Materials
the method
lipoic
overall
dehydrogenase
dithiol
react-ion
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
alone
cleavage
in Figure
of DTNB by the a-ketoglutarate
1 (curve
DTNB was 1 mM at both of NADH oxidized was unable
563
1).
This
pH values.
per mole
to catalyze
reaction
has pH
The stoichio-
of DTNB reduced.
this
reaction
(Figure
1,
Vol. 32, No. 3, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TIME (MN)
cleavage of DTNB by the a-ketoglutarate dehydrogenase Figure 1. The enzymatic complex, The assay system is described in the Methods. Curve 1 - a-ketoglutarate dehydrogenase, 53 pg, (SQ. Act. 4 units/mg); curve 2 - same as 1 but preincubated 2 min. with NADH and succinyl-CoA (0.098 umoles/ml); curve 3 - same as 1 but preincubated 2 min. with a-ketoglutarate (0.1 umolefml); curve 4 - lipoamide dehydroAt the point indicated by the arrow the reaction was started by genase (25 ug). the addition of NADH (curves 1 and 4) or DTNB (curves 2 and 3). Table
I.
Properties cleavage
of the a-ketoglutarate of DTNB. Other
Enzyme additions*
dehydrogenase
additions
catalyzed
Activity
a-KGDH (native)
none
100
Lip.DH
none
0
Lip.DH o-KGDH (denatured)**
lipoamide + Lip.DH
(0.01 none
umole)
780 78
o-KGDH (denatured)
+ Lip.DH
Succinyl-CoA
78
a-KGDH (denatured)
+ Lip.DH
a-ketoglutarate
100
The reaction was run at pH 7.0, * The complete system is described in Methods. dehydrogenase complex. and initiated with DTNB. a-KGDH is a-ketoglutarate Lip.DH is lipoamide dehydrogenase. ** a-KGDH was denatured by a 10 min. incubation in 2.5 N KOH of 30°. paration was neutralized to pH 7.0 and buffered before assaying. 564
The pre-
Vol. 32, No. 3, 1968
curve
4),
unless
requirement
for
resides
with
8lOCHEMlCAL
catalytic
succinylase).
protein That
promotes
dehydrogenase
complex.
The participation in DTNB cleavage results
from
succinyl-CoA in the
tional
bound
evidence
Table
II.
the
case is
NADH.
demonstrated
moieties
demonstrated
results
was inhibitory the role
of lipoic
I where
complex
acid
tran-
lipoamide
2 and 3) by the inhibition
with
a-ketoglutarate of the
or lipoic
acid
and by reversal
Neither
cleavage
probably
transuccinylase
a-ketoglutarate
was denatured
in the
the
a-ketoglutarate
succinylation
and NADH.
Thus
the dihydrolipoyl
the case of a-ketoglutarate
when the
I). complex
of denatured
1, curves
in enzymatic
1 and 2 in
in
in Table
of the enzyme complex
This
(Table
of dihydrolipoyl
(Figure
the case of succinyl-CoA
for
(i.e.
acid
lipoic
(Table of DTNB is
I).
Addi-
provided
by
Effect of NADH on NEM and iodoacetamide inhibition of DTNB cleavage by the a-ketoglutarate dehydrogenase complex *
conditions:
NADH --
Iodoacetamide
+
residues
of the
Preincubation
+
acid
added
dehydrogenase
in the presence
further
3-5 in
were
DTNB cleavage
enzyme by reactions
succinyl-CoA
lipoic
preincubation
plus
of reactions nor
is
of lipoamide
of the a-ketoglutarate
such is
dehydrogenase
which
quantities
the remainder
its
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
NEM
Enzyme activity** G> 100
+
95
+
0 +
78
+
0
* Preincubations contained in 1 ml: pmoles; NADH, 1.2 umoles; NEM, 1 A 10 min. preincubation of enzyme after the addition of sulfhydryl of the last four incubations was to titrate sulfhydryl reagents. ** The enzyme preparations were hydrogenase (5 pg) was added addition of NADH.
Tris-Cl (pH 7.0), 50 umoles; EDTA, 0.2 pmole; iodoacetamide, 2 umoles; oKGDH, 3.6 mg. and NADH was followed by a 15 min. incubation reagents. After the incubation a 0.25 ml aliquot mixed with a stoichiometric amount of cysteine
assayed as described in Methods. Lipoamide The reactions were started to each assay.
565
deby the
Vol. 32, No. 3, 1968
the
inhibition
mide
(Table
studies II).
the reversal
by both
cleaves
These
complex
mechanism
bond
dependent also
is
and iodoaceta-
on NADH and hence
show that
oxidized
lipoic
the native acid
shown as one in which
between
6 of lipoic
Lipoamide E2-NHCO(CH2)4-CH
is
only
of DTNB cleavage
at carbon
N-ethylmaleimide
results
contains
the disulfide
sulfhydryl
reagents
compounds
4 and 5.
dehydrogenase
dehydrogenase
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the sulfhydryl
Inhibition
The proposed
the
with
of reactions
ketoglutarate
Since
BIOCHEMICAL
acid
lipoic is
acid
the
on o-
residues. lipoamide
and thionitrobenzoate.
one reported
to undergo
dehydrogenase
- CH2 - CH2 1 S
:
+q
E2-NHCO(CH2)4-jH
- CH2 - iH2 SH
NAD+
SH
TNB + NAD+
succinylation reaction.
(Gunsalus This
is
et al.,
consistent
1958) with
it
is depicted
inhibition
caused
as the one involved by conditions
in
the
favouring
succinylation.
Conclusions The results acid-TNB
disulfide
to succinylation
presented
demonstrate
by lipoamide have
led
the NADH dependent
dehydrogenase.
to the proposed
Inhibition
mechanism.
566
cleavage
of the
by conditions This
model
reaction
lipoic conducive has been
Vol. 32, No. 3, 1968
used to study all
for other This
is
this
caution
chain
as well.
demonstrating
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of lipoic acyl-CoA
of inhibition
acid
esters
moieties
in
and may have
The reaction
catalytic
involvement
cleavage
of a dithiol
the inhibition application
in studies
may in addition of protein
of the over-
provide
bound
of
a useful
lipoic
acid
enzymes. enzyme-catalyzed
to the best
that
the
by long
types
tool in
the involvement
reaction
other
BIOCHEMICAL
of our knowledge
reaction
is
of a more general
to investigators
presence
a hitherto
who attempt
formed
unreported
reaction
reaction.
or non-specific the titration
from
with
DTNB
The possibility
nature
should
serve
of enzyme sulfhydryl
as a
groups
in
of substrate.
References Ellman, G. L., (1959), Archives Biochem. Biophys., 82, 70. Gunsalus, I. C., and Smith, R. A., (1958), in Proceedings of Symposium on Enzyme Chemistry, p. 77. Maruzen, Tokyo, Hirashima, M., Hayakawa, T., and Koike, M., (1967), J. Biol. Ishikawa, E., Oliver, R. M., and Reed, L. J., (1966), Proc. 2, 534. Sanadi, D. K., Littlefield, J. W., and Bock, R. M., (1952),
567
the
International
Chem. a, Natl. Acad. J. Biol.
902. Sci.
(U.S.)
Chem. 197,
851.