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Enzymatic synthesis of malonaldehyde
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Moy 30,1978
Pages
547-552
ENZYMATIC SYNTHESIS OF MALONALDEHYDE Frank
W. Summerfield
Department University
'Received
April
and Al L. Tappel
of Food Science and Technology of California, Davis, CA 95616
4,1978
SUMMARY Malonaldehyde was prepared from 1,3-propanediol by alcohol dehydrogenase. The Km for 1,3-propanediol was about 1.7 mM. The reaction proceeded best at low ionic strength and at pH 9. The reaction was unaffected bY2pyro$psE;;y, phosphate, bicarbonate, or N-ethylmorpholine buffers, or by Mg , Ca or citrate. However, the reaction was inhibited 50% by 1.5 mM borate, 1 mM ' cyanide, and 5 mM azide. Thiols, such as dithioerythritol, inhibited the reaction 50% at 50-100 PM, while others, such as mercaptoacetate, inhibited 50% at concentrations over 1 ti. Malonaldehyde was removed from the reaction mixture by evaporation at pH 3 and condensation at -78°C. No other products associated with lipid peroxidation were produced. The method was useful for preparation of radiolabeled malonaldehyde. INTRODUCTION Malonaldehyde radiation
damage
lipids
(4),
actions Until acidic
it
concentration radiolabeled
in aging
and nucleic
malonaldehyde
was necessary
hydrolysis
protonated
(5),
involve
implicated
(l),
acids
(6).
to prepare
(8).
In either
of malonaldehyde tetraalkoxypropanes
For these
reasons,
a new synthesis
MATERIALS
AND METHODS
are
rapid
(Z),
groups
the study
by the (7)
a few millimolar. available,
tracer
occurs Also,
studies
of reareas.
high-temperature,
or by shaking
polymerization
and
on phospho-
in many biochemical
malonaldehyde
case, exceeds
amino Therefore,
is of interest
of a 1,1,3,3-tetraalkoxypropane
resins
carcinogenesis
It has been shown to crosslink
(3).
proteins
that now,
has been
since cannot
with if
the no be done.
was developed.
Equine liver alcohol dehydrogenase (EC l.l.l.l), rabbit muscle lactic dehydrogenase (EC 1.1.1.271, and NAD were obtained from Sigma Chemical Co.; and citrate from Mallinckrodt sodium phosphate, pyrophosphate, bicarbonate, Chemical Works; sodium pyruvate and N-ethylmorpholine from Nutritional Biochemicals Corp.; and 1,3-propanediol and 1,1,3,3-tetramethoxypropane from Eastman Organic Chemicals. The 1,3-propanediol was distilled twice, and only the fraction boiling above 200°C was used.
0006-291X/78/0822-0547$01.00/0 547
Copyright All rights
0 1978 by Academic of reproduction in any
Press, Inc.
form reserved
BIOCHEMICAL
Vol. 82, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
01 FIGURE 1. Time
course
for
FIGURE 2. Hanes-Woolf centration.
production
plot
of malonaldehyde.
of enzyme activity
as a function
of substrate
con-
Unless otherwise stated, all reactions were carried out at 25'C in 50 mM pyrophosphate buffer, pH 9, with 0.0015 unit (1 unit is equivalent to 1 pmole product/min) of alcohol dehydrogenase, 0.005 unit of lactic dehydrogenase, 50 M NAD, 1 mM 1,3-propanediol, and 20 r&l pyru te in a final volume of 1 ml. [l- Y4C]-1,3-Propanediol for the preparation of Y3C-malonaldehyde was obtained from ICN Chemical and Radioisotope Division. Malonaldehyde was determined by a modification of the thiobarbituric acid reaction (9). The reaction mixture, or an appropriate aliquot thereof diluted to 1 ml, was mixed with 1 ml of glacial acetic acid and 3 ml of 10 mM thiobarbituric acid and the mixture was heated in a covered test tube in a boiling water bath for 1 hr. Tetramethoxypropane was used as a standard, and the absorbance was read at 532 nm. RESULTS The time lag rate not
of about
increase
20 min,
beyond
mM 1,3-propanediol. nase for
by higher
about
was the
The reaction of the
at about
After
an initial
50 nanomoles/hr.
temperatures,
of 1,3-propanediol was allowed
initial this
lag. value
alcohols
is
but
The
the yield
The plot large,
dehydrogenase
548
concentration
to proceed
the
is much greater
the NAD requirement
Kd of alcohol
1.
did
65%. the effect
Though
3 displays
shown in Figure
was increased
many non-biological
Figure
is
was formed
2 illustrates
the effect
reaction
malonaldehyde
of the reaction.
minimizing
factor
of the
of the reaction
Figure rate
course
reveals
4 hr,
than
NAD, about
thus
a Km of about
Km of alcohol
of the reaction. for
for
on the
for
1.7
dehydroge-
ethanol
(10).
The determining 30 uM (11).
Vol. 82, No. 2, 1978
BIOCHEMICAL
LOG NAD,
FIGURE 3. Dependency
of reaction
ity
4 depicts
was observed
The left
side
optimum
activity
Figure pyruvate ionic
be increased
0.1.
activity
because
lactic
activ-
at pH 8 or 10.
dehydrogenase
has
pH 7.5. of ionic
strength Thus,
of the
N-ethylmorpholine,
strength
on the reaction.
Here,
the
was used so that
could
be used.
The results
showed
no maximum
above
0.02,
substantial
activity
at ionic
for
reaction
phosphate,
50% inhibition
a 50% inhibition EIITA had little erythritol
optimum
but
good activity,
the
ionic
strength
should
not
unnecessarily.
The rate
caused
significant
may be steeper
as low as 0.02
below
Though
was 10 mM, and 10 mM N-ethylmorpholine
at any ionic
strengths
was still
the effect
concentration
activity
others,
curve
of pH.
of pH on the reaction.
at pH 9, there
5 shows
on NAD concentration.
as a function
at about
strengths
rate
the effect
of the
RESEARCH COMMUNICATIONS
pM
FIGURE 4. Enzyme activity
Figure
AND BIOPHYSICAL
was not
or bicarbonate
by affecting by 1 n$l cyanide
effect.
Thiols
and mercaptoethanol, such as cysteine,
significantly
required
the
changed
buffers;
lactic
caused
50% inhibition
2-5 mM concentration
549
groups,
use of
1.5 mM borate There
but Ca +2, Mgt2,
hydroxyl
tion.
however,
dehydrogenase.
and 5 mM azide, containing
by the
was also
citrate,
such as dithio-
at 50-100 to cause
PM, while 50% inhibi-
and
Vol. 82, No.2,
1978
05
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
06
LOG IONIC STRENGTH
FIGURE 5. Effect
of ionic
FIGURE 6. Effect hyde.
of pH on the
Kwon and Watts of malonaldehyde affected
(7)
proceeded 5O'C.
from for
with
spectral
a pK of about
malonaldehyde
4.5.
24 h, the
By this
obtained.
pH.
absorption
the
Since
changes With
were
this
The solution
its
When the
removal
reaction
stream
and then
of had to
condensed
by evaporation
of up to 40 tnM malonaldehyde stored
Figure
to pH 3 and heated
to pH 7 and concentrated
if
is
pK.
a scheme for
was adjusted
concentrations
spectrum
of malonaldehyde
used to determine
by an air
was adjusted
was stable
volatility
was devised.
mixture
of malonalde-
absorption
information,
was volatilized
method,
spectrum
ultraviolet
the
mixture
reaction
The condensate
at 35°C.
ultraviolet
the reaction
The malonaldehyde
at -78'C.
on enzyme activity.
have shown that
changes
by pH, these
6 reveals
strength
PH
were
at pH 7 and 4°C.
DISCUSSION Alcohol
dehydrogenase
corresponding since
only
(10).
malonaldehyde
steady-state reaction
aldehydes
converts
thermodynamic the malonaldehyde
variety
study,
the
an initial
of alcohols
However,
was reacting
over it with
90% conversion is quite itself
550
to their
substrate
was a diol,
and
lag
be expected
for
of hydroxypropionaldehyde
equilibrium,
basis.
In this
was detected,
concentration reached
a wide
would
to be reached. would
possible as rapidly
If the
be expected
that
at this
as it
a
on a
concentration,
was formed.
Since
Vol. 82, No. 2, 1978
higher
substrate
is
likely
not
concentrations that
The study system with in
for
most
it
is
buffers,
salt
system
described
micelles
hydrogen
must be used, products
useful
peroxide
described
no peroxides
or biochemical
commercially thus
Therefore,
polyunsaturated
low,
the
Malonaldefatty
However, very
do
bacteri-
of investigations.
is
than
different
times.
or lipoxygenase.
acid
oxygen
or per-
and many other
available
possible
[l-
to prepare
Thus,
products
Finally, 1
necessary,
or ultraviolet
secondary
damage
if
products.
ac d reaction
can be used to prepare
is
present,
or thiols;
reaction
a variety
reactive
or other
and also
it
resembles
may require
can be used anaerobically
as a thiobarbituric
from
long
by a
the molecule
is
chelators,
of malonaldehyde
prepared
toxicity,
contains
concentration
by treating
(6)
the yield
for
be facilitated
more closely
cations,
for
in situ
would
molecules
it
[l-l4
malonaldehyde absorption
related
rancidity, was prepared
by the methods malonaldehyde
for
can be standard
to food
Cl-malonaldehyde
4C]-1,3-propanediol
radiolabelled
and it
described;
tracer
studies. ACKNOWLEDGMENT This National
re-
can be formed.
The system generates
low
target
may be necessary
be generated
active
a constant,
concentrations,
enzyme.
that
of system
divalent
may prove
with
type
Different
hyde can also
oxide
mixture
concentrations,
such as azide
the
in a reaction This
RESEARCH COMMUNICATIONS
product
was inactivating malonaldehyde
in which
systems.
in higher
involving
to react.
conditions,
in vitro
tides
malonaldehyde
generation
AND BIOPHYSICAL
resulted
of reactions
its
which vivo
BIOCHEMICAL
research Institute
was supported
by NIH research
of Arthritis,
Metabolism
grant
AM 09933
and Digestive
from the
Diseases.
REFERENCES 1.
Munkres,
K. D.
(1976)
2.
Kubinski, (1973)
3.
Packer, L., Deamer, Res. 2, 23-64.
Mech.
Aging
M. A., H., Strangstalin, Can. Res. 33, 3103-3107.
Devel. Baird,
D. W., and Heath,
551
5, 171-191. W. M.,
R. L.
and Bountwell,
(1967)
Advan.
R. K. Gerontol.
Vol. 82, No. 2, 1978
8lOCHEMlCAL
4.
Bidlack,
W. R.,
5.
Chio,
6.
Reiss, U., Chio, K. S., Commun. 48, 921-925.
7.
Kwon,
8.
Brooks,
9.
Wills,
K. S.,
T.,
10.
Dickinson,
11.
Theorell, 1114.
and Tappel,
and Tappel,
and Watts, R. B.,
E. D.
F. M., H.,
A. L. A. L.
(1973)
(1969)
and Tappel,
8. M.
and Klamerth, (1966)
AND BIOPHYSICAL
Biochem.
and Dalziel,
and Bonnichsen,
Biochemistry
R. K.
552
8, 2827-2832.
(1972)
Biochem. 28,
(1968)
J. Biochem.
99,
K.
8, 203-207.
J. Food Sci.
0. L. J.
Lipids
A. L.
(1963)
RESEARCH COMMUNICATIONS
Eur.
Biophys.
Res.
627-630. 5, 178-182.
667-676.
(1967) (1951)
Biochem. Acta
J.
104,
165-172.
Chem. Stand.
5, 1105-
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Moy 30,1978
Pages
547-552
ENZYMATIC SYNTHESIS OF MALONALDEHYDE Frank
W. Summerfield
Department University
'Received
April
and Al L. Tappel
of Food Science and Technology of California, Davis, CA 95616
4,1978
SUMMARY Malonaldehyde was prepared from 1,3-propanediol by alcohol dehydrogenase. The Km for 1,3-propanediol was about 1.7 mM. The reaction proceeded best at low ionic strength and at pH 9. The reaction was unaffected bY2pyro$psE;;y, phosphate, bicarbonate, or N-ethylmorpholine buffers, or by Mg , Ca or citrate. However, the reaction was inhibited 50% by 1.5 mM borate, 1 mM ' cyanide, and 5 mM azide. Thiols, such as dithioerythritol, inhibited the reaction 50% at 50-100 PM, while others, such as mercaptoacetate, inhibited 50% at concentrations over 1 ti. Malonaldehyde was removed from the reaction mixture by evaporation at pH 3 and condensation at -78°C. No other products associated with lipid peroxidation were produced. The method was useful for preparation of radiolabeled malonaldehyde. INTRODUCTION Malonaldehyde radiation
damage
lipids
(4),
actions Until acidic
it
concentration radiolabeled
in aging
and nucleic
malonaldehyde
was necessary
hydrolysis
protonated
(5),
involve
implicated
(l),
acids
(6).
to prepare
(8).
In either
of malonaldehyde tetraalkoxypropanes
For these
reasons,
a new synthesis
MATERIALS
AND METHODS
are
rapid
(Z),
groups
the study
by the (7)
a few millimolar. available,
tracer
occurs Also,
studies
of reareas.
high-temperature,
or by shaking
polymerization
and
on phospho-
in many biochemical
malonaldehyde
case, exceeds
amino Therefore,
is of interest
of a 1,1,3,3-tetraalkoxypropane
resins
carcinogenesis
It has been shown to crosslink
(3).
proteins
that now,
has been
since cannot
with if
the no be done.
was developed.
Equine liver alcohol dehydrogenase (EC l.l.l.l), rabbit muscle lactic dehydrogenase (EC 1.1.1.271, and NAD were obtained from Sigma Chemical Co.; and citrate from Mallinckrodt sodium phosphate, pyrophosphate, bicarbonate, Chemical Works; sodium pyruvate and N-ethylmorpholine from Nutritional Biochemicals Corp.; and 1,3-propanediol and 1,1,3,3-tetramethoxypropane from Eastman Organic Chemicals. The 1,3-propanediol was distilled twice, and only the fraction boiling above 200°C was used.
0006-291X/78/0822-0547$01.00/0 547
Copyright All rights
0 1978 by Academic of reproduction in any
Press, Inc.
form reserved
BIOCHEMICAL
Vol. 82, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
01 FIGURE 1. Time
course
for
FIGURE 2. Hanes-Woolf centration.
production
plot
of malonaldehyde.
of enzyme activity
as a function
of substrate
con-
Unless otherwise stated, all reactions were carried out at 25'C in 50 mM pyrophosphate buffer, pH 9, with 0.0015 unit (1 unit is equivalent to 1 pmole product/min) of alcohol dehydrogenase, 0.005 unit of lactic dehydrogenase, 50 M NAD, 1 mM 1,3-propanediol, and 20 r&l pyru te in a final volume of 1 ml. [l- Y4C]-1,3-Propanediol for the preparation of Y3C-malonaldehyde was obtained from ICN Chemical and Radioisotope Division. Malonaldehyde was determined by a modification of the thiobarbituric acid reaction (9). The reaction mixture, or an appropriate aliquot thereof diluted to 1 ml, was mixed with 1 ml of glacial acetic acid and 3 ml of 10 mM thiobarbituric acid and the mixture was heated in a covered test tube in a boiling water bath for 1 hr. Tetramethoxypropane was used as a standard, and the absorbance was read at 532 nm. RESULTS The time lag rate not
of about
increase
20 min,
beyond
mM 1,3-propanediol. nase for
by higher
about
was the
The reaction of the
at about
After
an initial
50 nanomoles/hr.
temperatures,
of 1,3-propanediol was allowed
initial this
lag. value
alcohols
is
but
The
the yield
The plot large,
dehydrogenase
548
concentration
to proceed
the
is much greater
the NAD requirement
Kd of alcohol
1.
did
65%. the effect
Though
3 displays
shown in Figure
was increased
many non-biological
Figure
is
was formed
2 illustrates
the effect
reaction
malonaldehyde
of the reaction.
minimizing
factor
of the
of the reaction
Figure rate
course
reveals
4 hr,
than
NAD, about
thus
a Km of about
Km of alcohol
of the reaction. for
for
on the
for
1.7
dehydroge-
ethanol
(10).
The determining 30 uM (11).
Vol. 82, No. 2, 1978
BIOCHEMICAL
LOG NAD,
FIGURE 3. Dependency
of reaction
ity
4 depicts
was observed
The left
side
optimum
activity
Figure pyruvate ionic
be increased
0.1.
activity
because
lactic
activ-
at pH 8 or 10.
dehydrogenase
has
pH 7.5. of ionic
strength Thus,
of the
N-ethylmorpholine,
strength
on the reaction.
Here,
the
was used so that
could
be used.
The results
showed
no maximum
above
0.02,
substantial
activity
at ionic
for
reaction
phosphate,
50% inhibition
a 50% inhibition EIITA had little erythritol
optimum
but
good activity,
the
ionic
strength
should
not
unnecessarily.
The rate
caused
significant
may be steeper
as low as 0.02
below
Though
was 10 mM, and 10 mM N-ethylmorpholine
at any ionic
strengths
was still
the effect
concentration
activity
others,
curve
of pH.
of pH on the reaction.
at pH 9, there
5 shows
on NAD concentration.
as a function
at about
strengths
rate
the effect
of the
RESEARCH COMMUNICATIONS
pM
FIGURE 4. Enzyme activity
Figure
AND BIOPHYSICAL
was not
or bicarbonate
by affecting by 1 n$l cyanide
effect.
Thiols
and mercaptoethanol, such as cysteine,
significantly
required
the
changed
buffers;
lactic
caused
50% inhibition
2-5 mM concentration
549
groups,
use of
1.5 mM borate There
but Ca +2, Mgt2,
hydroxyl
tion.
however,
dehydrogenase.
and 5 mM azide, containing
by the
was also
citrate,
such as dithio-
at 50-100 to cause
PM, while 50% inhibi-
and
Vol. 82, No.2,
1978
05
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
06
LOG IONIC STRENGTH
FIGURE 5. Effect
of ionic
FIGURE 6. Effect hyde.
of pH on the
Kwon and Watts of malonaldehyde affected
(7)
proceeded 5O'C.
from for
with
spectral
a pK of about
malonaldehyde
4.5.
24 h, the
By this
obtained.
pH.
absorption
the
Since
changes With
were
this
The solution
its
When the
removal
reaction
stream
and then
of had to
condensed
by evaporation
of up to 40 tnM malonaldehyde stored
Figure
to pH 3 and heated
to pH 7 and concentrated
if
is
pK.
a scheme for
was adjusted
concentrations
spectrum
of malonaldehyde
used to determine
by an air
was adjusted
was stable
volatility
was devised.
mixture
of malonalde-
absorption
information,
was volatilized
method,
spectrum
ultraviolet
the
mixture
reaction
The condensate
at 35°C.
ultraviolet
the reaction
The malonaldehyde
at -78'C.
on enzyme activity.
have shown that
changes
by pH, these
6 reveals
strength
PH
were
at pH 7 and 4°C.
DISCUSSION Alcohol
dehydrogenase
corresponding since
only
(10).
malonaldehyde
steady-state reaction
aldehydes
converts
thermodynamic the malonaldehyde
variety
study,
the
an initial
of alcohols
However,
was reacting
over it with
90% conversion is quite itself
550
to their
substrate
was a diol,
and
lag
be expected
for
of hydroxypropionaldehyde
equilibrium,
basis.
In this
was detected,
concentration reached
a wide
would
to be reached. would
possible as rapidly
If the
be expected
that
at this
as it
a
on a
concentration,
was formed.
Since
Vol. 82, No. 2, 1978
higher
substrate
is
likely
not
concentrations that
The study system with in
for
most
it
is
buffers,
salt
system
described
micelles
hydrogen
must be used, products
useful
peroxide
described
no peroxides
or biochemical
commercially thus
Therefore,
polyunsaturated
low,
the
Malonaldefatty
However, very
do
bacteri-
of investigations.
is
than
different
times.
or lipoxygenase.
acid
oxygen
or per-
and many other
available
possible
[l-
to prepare
Thus,
products
Finally, 1
necessary,
or ultraviolet
secondary
damage
if
products.
ac d reaction
can be used to prepare
is
present,
or thiols;
reaction
a variety
reactive
or other
and also
it
resembles
may require
can be used anaerobically
as a thiobarbituric
from
long
by a
the molecule
is
chelators,
of malonaldehyde
prepared
toxicity,
contains
concentration
by treating
(6)
the yield
for
be facilitated
more closely
cations,
for
in situ
would
molecules
it
[l-l4
malonaldehyde absorption
related
rancidity, was prepared
by the methods malonaldehyde
for
can be standard
to food
Cl-malonaldehyde
4C]-1,3-propanediol
radiolabelled
and it
described;
tracer
studies. ACKNOWLEDGMENT This National
re-
can be formed.
The system generates
low
target
may be necessary
be generated
active
a constant,
concentrations,
enzyme.
that
of system
divalent
may prove
with
type
Different
hyde can also
oxide
mixture
concentrations,
such as azide
the
in a reaction This
RESEARCH COMMUNICATIONS
product
was inactivating malonaldehyde
in which
systems.
in higher
involving
to react.
conditions,
in vitro
tides
malonaldehyde
generation
AND BIOPHYSICAL
resulted
of reactions
its
which vivo
BIOCHEMICAL
research Institute
was supported
by NIH research
of Arthritis,
Metabolism
grant
AM 09933
and Digestive
from the
Diseases.
REFERENCES 1.
Munkres,
K. D.
(1976)
2.
Kubinski, (1973)
3.
Packer, L., Deamer, Res. 2, 23-64.
Mech.
Aging
M. A., H., Strangstalin, Can. Res. 33, 3103-3107.
Devel. Baird,
D. W., and Heath,
551
5, 171-191. W. M.,
R. L.
and Bountwell,
(1967)
Advan.
R. K. Gerontol.
Vol. 82, No. 2, 1978
8lOCHEMlCAL
4.
Bidlack,
W. R.,
5.
Chio,
6.
Reiss, U., Chio, K. S., Commun. 48, 921-925.
7.
Kwon,
8.
Brooks,
9.
Wills,
K. S.,
T.,
10.
Dickinson,
11.
Theorell, 1114.
and Tappel,
and Tappel,
and Watts, R. B.,
E. D.
F. M., H.,
A. L. A. L.
(1973)
(1969)
and Tappel,
8. M.
and Klamerth, (1966)
AND BIOPHYSICAL
Biochem.
and Dalziel,
and Bonnichsen,
Biochemistry
R. K.
552
8, 2827-2832.
(1972)
Biochem. 28,
(1968)
J. Biochem.
99,
K.
8, 203-207.
J. Food Sci.
0. L. J.
Lipids
A. L.
(1963)
RESEARCH COMMUNICATIONS
Eur.
Biophys.
Res.
627-630. 5, 178-182.
667-676.
(1967) (1951)
Biochem. Acta
J.
104,
165-172.
Chem. Stand.
5, 1105-