- Email: [email protected]
The catalytic demethylation of N,N-dimethylaniline-N-oxide by liver microsomes
BI~~~MICAL
Vol. 13, No. 3, 1963
Flora Clayton
Foundation
Received
the oxidative first
described
LaDu,
et al.
present
by Mueller
and Miller
demonstrated fraction
supplemented
with
appears
to be of the
oxidase.
first
part
a&y1
N-oxide
cated
by the
MPH
of Chemistry
and oxygen
(Gillette
type
classified
the U-methyl
and the intermedf.ate last
i)
two steps
in the
"W%)2
to the
1957).
The enzyme
Drodie
1958)
then
micro-
CQmpQUndS
(1957)
is
by
the Qxidative
by Mason
compound
following
NAIIPR3
catalyzed
fcf.
N-oxide
studies
The isolated
et al. cm
was
compounds
system was localized
N-alkyl
suggested
catalyzing
Subsequent
the enzyme
amine
It has been
of the reaction
(1953).
soluble
tlssua
N-methyl
homogenates.
of lipid
and corresponding
soluble
that
of liver
of a variety
function
Department Texas
in mammalianliver
of lipid
(1955)
dealkylation
system
M. Ziegler’
Institute and the of Texas, Austin,
demethylation
the microsome
aldehyde
and Daniel
RESEARCH CO~UNICATIONS
23, 1963
August
somes when
Ii, Pettit
Biochemical The University
The enzyme system
in
AND BIOPHYSICAL
as a mixed that
in the
is oxidized
to the
degraded
as indi-
sequence
of
reactions:
0 R-B(ai3)2
02
Supported fn part G&09044-02. +Work American
by a grant
out during
carried Heart.
ASSOciatiQn,
from National
tenure
Institutes
as an Established
Inc.
193
of ffealth,
Investigator,
BIOC~~ICAL
Vol. 13, No. 3, 1963
AND BIOP~SI~L
RESEARCH CO~UN{CATiONS
While there was someevidence to support this reaction mechanism (Fish et al.
1955,1956), an earlier
N,N-dimethylaniline-N-oxide intermediate livar
this
microsomes catalyze
of N,N-dimethylaniline-N-oxide
reaction
methylation
gation from liver
by the liver
The oxtdative
de-
microsomes.
were isolated by differential
centrifu-
(1948).
demethylation assays were
erlenmeyer flasks at 38' in a Dubnoff
carried
out
shaker.
metabolic
in
10 ml
open
The complete
mediumcontained per ml: potassium phosphate, pff 7.5, 200
nmoles; magnesiumchloride,
citric
oxidative
homogenatesprepared in 0.25 g sucrose according to
the method of HogebooPl-et al.
moles;
and form-
The maximumrate of
is several fold greater than the overall
The microsoma fractions
reaction
the rapid de-
to methylaniline
of both WPH and oxygen.
of dimethylaniltne
by
The data presented in this report
Drodie 1938).
aldehyde in the absence
to be an
damethylation of N,N-dimethylaniline
damonstrate that rat and pig liver
qethylation
that the rate of
demethylatioa was too slow for it
in the oxfdative
mierosomss (cf.
report indicated
MDP+, 0.1 vole;
5 wales;
isocitrate,
5 poles;
semicarbazide, 1 mole;
h&D+, 5
and sufficient
iso-
dehydrogenase to reduce 0.5 Crmoleof NsDP+per minute per ml,
Tha concentration
of N,~dimethylaniline,
and of microsomal protein
N,N-di~thyla~line-~oxide
are given in the Table and Figure.
After
preincubating
with shaking for 4 minutes the react&on was started by
adding either
the microsomas or the substrate.
action mixture were withdrawn at intervals containing
sufficient
concentration
6.0 p! trichloroacetit
of 0.6 &
The deproteinized
Aliquots
and pipetted
of the re-
into tubes
acid to give a final supernatant solutions were
assayed for formaldehyde by the method of Nash (1953).
The rates of
formsldehyde formation reported in this paper are corrected small
amount
for the
of formaldehyde produced in the absence of substrate.
N-methylaniline
was estimated by vapor phase chromatography using a
194
BIOCHEMICAL
Vol. 13, No. 3, 1963
AND BIOPHYSICAL
column packed with 5 per cent polyethylene
RESEARCH COMMUNICATIONS
glycol
succinate on chromo-
was distilled
under vacuum. Analy-
sorb P at 182". Commercial N,N-dimethylaniline
sis by vapor phase chromatography indicated
that it was free from con-
taminants other than traces of N-methylaniline. aniline-N-oxide ment.
was synthesized by Dr. Rowland Pettit
The melting point of the recrystallized
ported,
The N,N-dimethylof our Depart-
N-oxide was 150" [re-
152" (Belov and Savich 1947)]. The data summarized in Table I demonstrate that pig liver
somescatalyze
the demethylation of N,N-dimethylaniline-N-oxide
rate greater than the oxidative
proximately
that N-methylaniline
(at pR 9.0)
is produced at ap-
the samerate as formaldehyde during the catalytic
ation of the N-oxide. component catalyzing non-dializable
at a
demethylation of the corresponding di-
methyl amine. Vapor phase chromatography of ether extracts of the reaction mediumindicate
micro-
Recent experiments indicate
demethyl-
that the microsomal
the demethylation of the N-oxide is heat labile,
and appears to be an enzyme. The rate of formaldehyde
production is a linear over a relatively
function
of microsomal protein concentration
wide range (0.2 to 4.0 mg per ml) and the reaction
is also linear with time for at least the first
ten minutes.
A graphical determination of the Michaelis constant for N,N-dimethylaniline
in rat liver
q icrosomes gave a Kmof 1.42 x 10-3 g. The
Michaelis constant for the N-oxide was determined in both rat and pig liver
microsomes from the Lineweaver-Burke plot shown in Figure I.
The high Kmvalue (139 x 10e3 kl) observed with both rat and pig liver microsomesmay be due to the very limited polar N-oxide (cf.
lipid
solubility
of the
Brodie 1958).
The data presented in this report demonstrates that the rate of N,N-dimethylaniline-N-oxide ficiently
demethylation by liver
microsomes is suf-
high for the N-oxide to be considered as an intermediate
the oxidative
demethylation of N,N-dimethylaniline. 195
in
BIOCHEMICAL
Vol. 13, No. 3, 1963
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Table I Demethylation Activity
of Pig Liver Microsomes Substrates N,N-dimethylN,N-dimethylaniline aniline-Noxide mumolesformaldehyde per q in per
Additions
Complete system II
5.4
15
minus KADP+and NADPKgenerating system
0
14
minus NADPHgenerating system and oxygen
0
17
minus WDPB generating system, NbIIt and p&C12
0
17
1)
minus q icrosomes
0
0
II
minus microsomes plus boiled microsomes
0
0
II 0
II
II
Concentration of substrates, protein, 2.6-3.3 mg per ml.
3 pies
per ml; concentration
0.20-
0.16-
0.12I 7
/
0.08-
I
0.02
/
/ ?'
0.04
/I
//
/
//
0.06
/
//
/
/
//
0.08
of microsomal
P/'
0.10
[+ x lo-3 Figure I.
mg
Lineweaver-Burke plot of the effect of substrate concentration on the rate of demethylation of N,N-dimethylaniline-Noxide.
[Sl = Mcdarity v - qmoles formaldehyde produced per min. per mg q icrosomal protein per - Pig liver microsomes Km = 139 x 10-3M Vmax = 175.4 voles min per mg --- - Bat liver microsomes Km- 139 x 10-3K Vmex - 71.4 qusoles per mia per mg
Vol. 13, No. 3, 1963
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
References 1.
Belov, V. N., and Savich, 257
K.
K., J. Gen. them. (U.S.S.R.),
17,
(1947).
2.
Brodie, B. B., Ann. Kev. Biochem., 57, 427 (1958).
3.
Fish, M. S., Johnson, N. Pi., Lawrence, E. R., Horning, g. c., Biochim. et Biophys. acta, l8, 564 (1955).
4.
Fish, H. s., Sweeley, C. C., Johnson, N. M., Lawrence, E. P., and Kerning, E. c., Biochim. et Biophys. acta, 2l, 196 (1956).
5.
Gillette, J. B., Brodie, B. B., and LaDu, B. N., J. Pharmacol. Exptl. Therap., 119, 532 (1957).
6.
Eogeboom, G. Ii., Schneider, W. C., and Palade, G. P., J. Biol. Chem., 172, 619 (1948).
7.
LaDu, B. N., Gaudette, L., Trousof, N., and Brodie, B. B., J. Biol. Chem., 214, 741 (1955).
8.
Mason, Ii. S., Science, 125, 1185 (1957).
9.
Mueller,
10.
G. C., and Miller,
J. A.,
J. ~i01. Chem., 202, 579 (1953).
Nash, T., Biochem. J., 55, 416 (1953).
197
Vol. 13, No. 3, 1963
Flora Clayton
Foundation
Received
the oxidative first
described
LaDu,
et al.
present
by Mueller
and Miller
demonstrated fraction
supplemented
with
appears
to be of the
oxidase.
first
part
a&y1
N-oxide
cated
by the
MPH
of Chemistry
and oxygen
(Gillette
type
classified
the U-methyl
and the intermedf.ate last
i)
two steps
in the
"W%)2
to the
1957).
The enzyme
Drodie
1958)
then
micro-
CQmpQUndS
(1957)
is
by
the Qxidative
by Mason
compound
following
NAIIPR3
catalyzed
fcf.
N-oxide
studies
The isolated
et al. cm
was
compounds
system was localized
N-alkyl
suggested
catalyzing
Subsequent
the enzyme
amine
It has been
of the reaction
(1953).
soluble
tlssua
N-methyl
homogenates.
of lipid
and corresponding
soluble
that
of liver
of a variety
function
Department Texas
in mammalianliver
of lipid
(1955)
dealkylation
system
M. Ziegler’
Institute and the of Texas, Austin,
demethylation
the microsome
aldehyde
and Daniel
RESEARCH CO~UNICATIONS
23, 1963
August
somes when
Ii, Pettit
Biochemical The University
The enzyme system
in
AND BIOPHYSICAL
as a mixed that
in the
is oxidized
to the
degraded
as indi-
sequence
of
reactions:
0 R-B(ai3)2
02
Supported fn part G&09044-02. +Work American
by a grant
out during
carried Heart.
ASSOciatiQn,
from National
tenure
Institutes
as an Established
Inc.
193
of ffealth,
Investigator,
BIOC~~ICAL
Vol. 13, No. 3, 1963
AND BIOP~SI~L
RESEARCH CO~UN{CATiONS
While there was someevidence to support this reaction mechanism (Fish et al.
1955,1956), an earlier
N,N-dimethylaniline-N-oxide intermediate livar
this
microsomes catalyze
of N,N-dimethylaniline-N-oxide
reaction
methylation
gation from liver
by the liver
The oxtdative
de-
microsomes.
were isolated by differential
centrifu-
(1948).
demethylation assays were
erlenmeyer flasks at 38' in a Dubnoff
carried
out
shaker.
metabolic
in
10 ml
open
The complete
mediumcontained per ml: potassium phosphate, pff 7.5, 200
nmoles; magnesiumchloride,
citric
oxidative
homogenatesprepared in 0.25 g sucrose according to
the method of HogebooPl-et al.
moles;
and form-
The maximumrate of
is several fold greater than the overall
The microsoma fractions
reaction
the rapid de-
to methylaniline
of both WPH and oxygen.
of dimethylaniltne
by
The data presented in this report
Drodie 1938).
aldehyde in the absence
to be an
damethylation of N,N-dimethylaniline
damonstrate that rat and pig liver
qethylation
that the rate of
demethylatioa was too slow for it
in the oxfdative
mierosomss (cf.
report indicated
MDP+, 0.1 vole;
5 wales;
isocitrate,
5 poles;
semicarbazide, 1 mole;
h&D+, 5
and sufficient
iso-
dehydrogenase to reduce 0.5 Crmoleof NsDP+per minute per ml,
Tha concentration
of N,~dimethylaniline,
and of microsomal protein
N,N-di~thyla~line-~oxide
are given in the Table and Figure.
After
preincubating
with shaking for 4 minutes the react&on was started by
adding either
the microsomas or the substrate.
action mixture were withdrawn at intervals containing
sufficient
concentration
6.0 p! trichloroacetit
of 0.6 &
The deproteinized
Aliquots
and pipetted
of the re-
into tubes
acid to give a final supernatant solutions were
assayed for formaldehyde by the method of Nash (1953).
The rates of
formsldehyde formation reported in this paper are corrected small
amount
for the
of formaldehyde produced in the absence of substrate.
N-methylaniline
was estimated by vapor phase chromatography using a
194
BIOCHEMICAL
Vol. 13, No. 3, 1963
AND BIOPHYSICAL
column packed with 5 per cent polyethylene
RESEARCH COMMUNICATIONS
glycol
succinate on chromo-
was distilled
under vacuum. Analy-
sorb P at 182". Commercial N,N-dimethylaniline
sis by vapor phase chromatography indicated
that it was free from con-
taminants other than traces of N-methylaniline. aniline-N-oxide ment.
was synthesized by Dr. Rowland Pettit
The melting point of the recrystallized
ported,
The N,N-dimethylof our Depart-
N-oxide was 150" [re-
152" (Belov and Savich 1947)]. The data summarized in Table I demonstrate that pig liver
somescatalyze
the demethylation of N,N-dimethylaniline-N-oxide
rate greater than the oxidative
proximately
that N-methylaniline
(at pR 9.0)
is produced at ap-
the samerate as formaldehyde during the catalytic
ation of the N-oxide. component catalyzing non-dializable
at a
demethylation of the corresponding di-
methyl amine. Vapor phase chromatography of ether extracts of the reaction mediumindicate
micro-
Recent experiments indicate
demethyl-
that the microsomal
the demethylation of the N-oxide is heat labile,
and appears to be an enzyme. The rate of formaldehyde
production is a linear over a relatively
function
of microsomal protein concentration
wide range (0.2 to 4.0 mg per ml) and the reaction
is also linear with time for at least the first
ten minutes.
A graphical determination of the Michaelis constant for N,N-dimethylaniline
in rat liver
q icrosomes gave a Kmof 1.42 x 10-3 g. The
Michaelis constant for the N-oxide was determined in both rat and pig liver
microsomes from the Lineweaver-Burke plot shown in Figure I.
The high Kmvalue (139 x 10e3 kl) observed with both rat and pig liver microsomesmay be due to the very limited polar N-oxide (cf.
lipid
solubility
of the
Brodie 1958).
The data presented in this report demonstrates that the rate of N,N-dimethylaniline-N-oxide ficiently
demethylation by liver
microsomes is suf-
high for the N-oxide to be considered as an intermediate
the oxidative
demethylation of N,N-dimethylaniline. 195
in
BIOCHEMICAL
Vol. 13, No. 3, 1963
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Table I Demethylation Activity
of Pig Liver Microsomes Substrates N,N-dimethylN,N-dimethylaniline aniline-Noxide mumolesformaldehyde per q in per
Additions
Complete system II
5.4
15
minus KADP+and NADPKgenerating system
0
14
minus NADPHgenerating system and oxygen
0
17
minus WDPB generating system, NbIIt and p&C12
0
17
1)
minus q icrosomes
0
0
II
minus microsomes plus boiled microsomes
0
0
II 0
II
II
Concentration of substrates, protein, 2.6-3.3 mg per ml.
3 pies
per ml; concentration
0.20-
0.16-
0.12I 7
/
0.08-
I
0.02
/
/ ?'
0.04
/I
//
/
//
0.06
/
//
/
/
//
0.08
of microsomal
P/'
0.10
[+ x lo-3 Figure I.
mg
Lineweaver-Burke plot of the effect of substrate concentration on the rate of demethylation of N,N-dimethylaniline-Noxide.
[Sl = Mcdarity v - qmoles formaldehyde produced per min. per mg q icrosomal protein per - Pig liver microsomes Km = 139 x 10-3M Vmax = 175.4 voles min per mg --- - Bat liver microsomes Km- 139 x 10-3K Vmex - 71.4 qusoles per mia per mg
Vol. 13, No. 3, 1963
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
References 1.
Belov, V. N., and Savich, 257
K.
K., J. Gen. them. (U.S.S.R.),
17,
(1947).
2.
Brodie, B. B., Ann. Kev. Biochem., 57, 427 (1958).
3.
Fish, M. S., Johnson, N. Pi., Lawrence, E. R., Horning, g. c., Biochim. et Biophys. acta, l8, 564 (1955).
4.
Fish, H. s., Sweeley, C. C., Johnson, N. M., Lawrence, E. P., and Kerning, E. c., Biochim. et Biophys. acta, 2l, 196 (1956).
5.
Gillette, J. B., Brodie, B. B., and LaDu, B. N., J. Pharmacol. Exptl. Therap., 119, 532 (1957).
6.
Eogeboom, G. Ii., Schneider, W. C., and Palade, G. P., J. Biol. Chem., 172, 619 (1948).
7.
LaDu, B. N., Gaudette, L., Trousof, N., and Brodie, B. B., J. Biol. Chem., 214, 741 (1955).
8.
Mason, Ii. S., Science, 125, 1185 (1957).
9.
Mueller,
10.
G. C., and Miller,
J. A.,
J. ~i01. Chem., 202, 579 (1953).
Nash, T., Biochem. J., 55, 416 (1953).
197