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Molecular aspects of debrisoquine metabolism studied by gas chromatography mass spectrometry with electron capture negative ion chemical ionisation
Journal of Mass Spectrometry and fan Physics, 48 (1983) 89-92 Elsevier Scientific Publishing Company, Amsterdam - Printed in The NetherIands
89
International
MOLECULAR MASS
ASPECTS
OF DEBRISOQUINE
SPECTROMETRY
S.MURRAY,
G-C-KAHN,
Department Ducane
WITH
ELECTROH
Road,
CAPTURE
A.R.BOOBIS
of Clinical London
METABOLISM
NEGATIVE
BY GAS CHROMATOGRAPHY
ION CHEMICAL
IONISATION
and D.S.DAVIES Royal
Pharmacology,
W12 OHS
STUDIED
Postgraduate
Medical
School,
(UK)
ABSTRACT A gas chromatographic mass spectrometric assay using electron capture negative ion chemical ionisation has been developed for the analysis of 4-hydroxydebrisoquine in human liver microsomal incubations. The assay has been guanoxan and phenformin are competitive inhibitors used to show that sparteine, of human liver debrisoquine 4-hydroxylase activity in vitro.
INTRODUCTION Debrisoquine treatment
of hypertension.
4-hydroxydebrisoquine exhibits
a genetic
graphic vitro
mass
by human
(ref.3,4). enzyme
ment
P-450
limit
has been
used
of
liver
human
oxidation
that
that
We have
this
in man
impact
that the defect
to a deficiency activity,
is reaction
a gas chromato-
(ET)
produced
present,
in
ionisation
in oxidation
or absence
when
in the
hydroxylation
developed
uses electron
this
used
for 4-hydroxydebrisoquine
shown
is due
agent
of
of hepatic
is catalysed
by
(ref.4). assay
ion chemical
in the
which
we have
in vivo and
assay
blocking
of debrisoquine
has shown
(ref.l,2).
microsomes
(ref.3)
metabolite
work
(GC-MS)
this assay,
published
negative
recent
polymorphism
observed
activity
The
and
liver
With
cytochrome
A major
spectrometric
debrisoquine
sympathetic
is a post-ganglionic,
has now
been
ionisation
of detection
to investigate in vitro
polymorphism
modified
to incorporate resulting
{ECNICI),
the effect
on debrisoquine
reportedly
capture
in a substantial
of 4-hydroxydebrisoquine.
of drugs
electron
associated
The modified 4-hydroxylase with
improveassay activity
the debrisoquine
in vivo.
METHODS Sample
Preparation
This
was as described
the final GC-MS
extracts
analysis.
altered
were
for the assay not
Incubations
treated were
the pH to approximately
OOZO-7381/83/000~0000/$03.00
D
using
with
terminated 13.5.
EI ionisation
trifluoroacetic
(ref.4) anhydride
by the addition
A deuterated
analogue
of
except prior
that to
1M NaOH which
of 4-hydroxy-
1983 Elsevier Scientific Publishing Company
90 debrisoquine, After
the internalstandard
a triple
extraction
debrisoquine, debrisoquine converted with
for the assay,
chloroform
the pH of the aqueous and the deuterated
which
phase
analogue
to the corresponding
was
was
then
removed
adjusted
added
most
to 8.5.
in the aqueous
to each
sample.
of the unreacted
phase
4-Hydroxywere
pyrimidinyltetrahydroisoquinolines
then by reaction
hexafluoroacetylacetone.
GC-MS
Conditions
A Finnigan negative
4000
transfer
equipped
with
(100-120
mesh)
gas.
quadrupole
ion chemical
all glass
Under
in the negative tuned
molecular
glass
with
a pulsed
was
used,
gas chromatograph.
column
packed
C with
with
helium
positive
three
minutes.
ionisation
negative
mode with
ions at m/z
(M-) of the derivatives
The mass
The
3% OV-1
methane
via an
latter
of 4-hydroxydebrisoquine
9
as carrier
derivatives was operated
as reagent
371 which
was
on Gas-Chrom
(15 ml/min)
spectrometer
363 and m/z
ion/
interfaced
the pyrimidinyltetrahydroisoquinoline
ion chemical
analogue
9610
at 200 degrees
of about
to monitor ions
deuterated
x 2mm i.d.
conditions,
times
spectrometer
(PPIIdICI) module
to a Finnigan
and operated
these
mass
ionisation
line
a 1.8m
had retention was
with
gas.
were
It
the
and its
respectively.
DISCUSSION 4-Hydroxydebrisoquine problem solved
of extraction by previous
Pnolecule with
(I) is a polar, from an aqueous
workers
(ref.5)
who
hexafluoroacetylacetone
water
soluble
environment
compound.
into an organic
condensed
the amidine
in a two phase
reaction
The consequent solvent
was
sidechain
in the
mixture
(Fig.1).
OH
OH
-
CFa
NH,
I
Fiq.1.
The
The reaction of 4-hydroxydebrisoquine (I) with hexafluoroacetylacetone to give a pyrimidinyltetrahydroisoquinoline (II)
resulting
to partition basis
pyrimidinyltetrahydroisoquinoline readily
into
of an EI ionisation
(II) is sufficiently
the organic
phase.
GC-MS
for 4-hydroxydebrisoquine
assay
This
reaction
has been
non polar used as the
produced
in
9-l vitro
by human
We have
methane
liver
recently
as
microsomes recorded
gas
reagent
(ref.3,4). mass
the ECNICI
spectrum
of compound
II using
(Fig.2).
* ZI
.Z
KY
100
a3
.-c
100 1
200
300
k-7
400
ECNICI
75 I-
^_^
jbj
01 > .-
se
( M- 1
c m
-
I
I 200
I
I 100
L
1 300
I
,I 4Ocl
m I t
Fig.2.
The EI
Besides
possessing this
ion current, the EI
mass
detection
ion
These
(ref.10).
metabolism
liver
as those sparteine of these
microsowes.
of these
drugs
as competitive
II
363 which
as intense
constitutes
as m/z
modifying
in a substantial
344
(the base
the published
improvement
By monitoring
80% of the total peak)
GC-MS
in the limit
negative
ions at m/z
in
assay
of 363, an
to 500 femtograms4-hydroxydebrisoquine
to noise
other
the modified
the effects
of human in vitro
include
Using
a signal
of several
pair of alleles
studied
times
II corresponding
with
of compound
Consequently,
of 4-hydroxydebrisoquine.
of compound
The oxidation quine.
results
spectra
ion at m/z
twenty
is
(ref.6).
ECNICI
can be detected same
mass
a molecular
spectrum
to incorporate
amount
and ECNICI
ratio
drugs
of one
appears
regulating
(ref.6).
to be under
the alicyclic
(ref.7,8),
guanoxan
the control
hydroxylation
(ref.9)
assay
for 4-hydroxydebrisoquine,
three
drugs
on debrisoquine
enzyme
as well
as debrisoquine, of debrisoquine
we
4-hydroxylase
is responsible
inhibitors
of debriso-
and phenfarmin
GC-MS
If the same
of the
then these
have activity
for the oxidative compounds
4-hydroxylation.The
shouldact results
92 we obtained
TABLE
are given
in Table
1.
1
The effects activity
of sparteine,
of human
Drug
guanoxan
and phenformin
on debrisoquine
liver microsomes
Concentration
Debrisoquine
4-hydroxylatioh
Vmax(pmol/mg/min)
(mM)
Phenformin
I I
In
all three
increased remains
rl?sponsible
l?cl 3267 67.33
87 83
0 0.1 0.3
61 63 61
116 434 1554
36 24
1U7 105 113
125 550 1737
220 190
cases,
the Km for debrisoquine
increasing
unchanged.
inhibitors
;Zl 71
2.5
with
(PM)
205 5.0
0 0.75
~
Ki
Km(uM)
Sparteine
Guanoxan
4-hydroxylase
These
of debrisoquine
drug
concentration,
dat a indicate
that
4-hydroxylation
for the oxidative
4-hydroxylation
metabolism
while these
Vmax
three
and suggest of all four
is markedly
for the compounds
reaction are competitive
that the same
enzyme
is
compounds.
REFERENCES R.Lancaster and R.L.Smith, Lancet, ii (1977) A.Mahgoub, J-R-Idle, L.G.Uring, 584-586 M.S.Lennard and A.J.Smith, Lancet, ii (1977) 2 G-T-Tucker, J.H.Silas, A.O.Iyun, 718 3 D-S-Davies, G-C-Kahn, S.Murray, M.J.Brodie and A.R.Boobis, Br.J.clin-Pharmac., 11 (1981) 89-91 4 G-C-Kahn, A.R.Buobis, S.Murray, M.J.Brodie and D.S.Davies, Br.J.clin.Pharmac., 13 (1982) 637-645 5 S.L.Malcotm and T.R.Marten, Anal.Chem., 48 (1976) 807-809 6 S-Murray and K.A.Waddell, Biomed.Mass Spectrom., in press 7 T.Inaba, S.V.Otton arid W.Kalow, Clin.Pharmac.Ther., 27 (1980) 547-549 M.Eichelbaum and H.-U.Schulz, Eur.J.clin.Pharmac., 8 L.Bertilsson, H.J.Dengler, 17 (1980) 153-155 9 T.P_Sloan, A.Mahgoub, R-Lancaster, J.R.Idle and R.L.Smith, Br.med.J.,Z (1978) 655-657 10 R.R.Shah, N.S.Oates, J.R.Idle and R.L.Smith, Lancet, i (1980) 1147 1
89
International
MOLECULAR MASS
ASPECTS
OF DEBRISOQUINE
SPECTROMETRY
S.MURRAY,
G-C-KAHN,
Department Ducane
WITH
ELECTROH
Road,
CAPTURE
A.R.BOOBIS
of Clinical London
METABOLISM
NEGATIVE
BY GAS CHROMATOGRAPHY
ION CHEMICAL
IONISATION
and D.S.DAVIES Royal
Pharmacology,
W12 OHS
STUDIED
Postgraduate
Medical
School,
(UK)
ABSTRACT A gas chromatographic mass spectrometric assay using electron capture negative ion chemical ionisation has been developed for the analysis of 4-hydroxydebrisoquine in human liver microsomal incubations. The assay has been guanoxan and phenformin are competitive inhibitors used to show that sparteine, of human liver debrisoquine 4-hydroxylase activity in vitro.
INTRODUCTION Debrisoquine treatment
of hypertension.
4-hydroxydebrisoquine exhibits
a genetic
graphic vitro
mass
by human
(ref.3,4). enzyme
ment
P-450
limit
has been
used
of
liver
human
oxidation
that
that
We have
this
in man
impact
that the defect
to a deficiency activity,
is reaction
a gas chromato-
(ET)
produced
present,
in
ionisation
in oxidation
or absence
when
in the
hydroxylation
developed
uses electron
this
used
for 4-hydroxydebrisoquine
shown
is due
agent
of
of hepatic
is catalysed
by
(ref.4). assay
ion chemical
in the
which
we have
in vivo and
assay
blocking
of debrisoquine
has shown
(ref.l,2).
microsomes
(ref.3)
metabolite
work
(GC-MS)
this assay,
published
negative
recent
polymorphism
observed
activity
The
and
liver
With
cytochrome
A major
spectrometric
debrisoquine
sympathetic
is a post-ganglionic,
has now
been
ionisation
of detection
to investigate in vitro
polymorphism
modified
to incorporate resulting
{ECNICI),
the effect
on debrisoquine
reportedly
capture
in a substantial
of 4-hydroxydebrisoquine.
of drugs
electron
associated
The modified 4-hydroxylase with
improveassay activity
the debrisoquine
in vivo.
METHODS Sample
Preparation
This
was as described
the final GC-MS
extracts
analysis.
altered
were
for the assay not
Incubations
treated were
the pH to approximately
OOZO-7381/83/000~0000/$03.00
D
using
with
terminated 13.5.
EI ionisation
trifluoroacetic
(ref.4) anhydride
by the addition
A deuterated
analogue
of
except prior
that to
1M NaOH which
of 4-hydroxy-
1983 Elsevier Scientific Publishing Company
90 debrisoquine, After
the internalstandard
a triple
extraction
debrisoquine, debrisoquine converted with
for the assay,
chloroform
the pH of the aqueous and the deuterated
which
phase
analogue
to the corresponding
was
was
then
removed
adjusted
added
most
to 8.5.
in the aqueous
to each
sample.
of the unreacted
phase
4-Hydroxywere
pyrimidinyltetrahydroisoquinolines
then by reaction
hexafluoroacetylacetone.
GC-MS
Conditions
A Finnigan negative
4000
transfer
equipped
with
(100-120
mesh)
gas.
quadrupole
ion chemical
all glass
Under
in the negative tuned
molecular
glass
with
a pulsed
was
used,
gas chromatograph.
column
packed
C with
with
helium
positive
three
minutes.
ionisation
negative
mode with
ions at m/z
(M-) of the derivatives
The mass
The
3% OV-1
methane
via an
latter
of 4-hydroxydebrisoquine
9
as carrier
derivatives was operated
as reagent
371 which
was
on Gas-Chrom
(15 ml/min)
spectrometer
363 and m/z
ion/
interfaced
the pyrimidinyltetrahydroisoquinoline
ion chemical
analogue
9610
at 200 degrees
of about
to monitor ions
deuterated
x 2mm i.d.
conditions,
times
spectrometer
(PPIIdICI) module
to a Finnigan
and operated
these
mass
ionisation
line
a 1.8m
had retention was
with
gas.
were
It
the
and its
respectively.
DISCUSSION 4-Hydroxydebrisoquine problem solved
of extraction by previous
Pnolecule with
(I) is a polar, from an aqueous
workers
(ref.5)
who
hexafluoroacetylacetone
water
soluble
environment
compound.
into an organic
condensed
the amidine
in a two phase
reaction
The consequent solvent
was
sidechain
in the
mixture
(Fig.1).
OH
OH
-
CFa
NH,
I
Fiq.1.
The
The reaction of 4-hydroxydebrisoquine (I) with hexafluoroacetylacetone to give a pyrimidinyltetrahydroisoquinoline (II)
resulting
to partition basis
pyrimidinyltetrahydroisoquinoline readily
into
of an EI ionisation
(II) is sufficiently
the organic
phase.
GC-MS
for 4-hydroxydebrisoquine
assay
This
reaction
has been
non polar used as the
produced
in
9-l vitro
by human
We have
methane
liver
recently
as
microsomes recorded
gas
reagent
(ref.3,4). mass
the ECNICI
spectrum
of compound
II using
(Fig.2).
* ZI
.Z
KY
100
a3
.-c
100 1
200
300
k-7
400
ECNICI
75 I-
^_^
jbj
01 > .-
se
( M- 1
c m
-
I
I 200
I
I 100
L
1 300
I
,I 4Ocl
m I t
Fig.2.
The EI
Besides
possessing this
ion current, the EI
mass
detection
ion
These
(ref.10).
metabolism
liver
as those sparteine of these
microsowes.
of these
drugs
as competitive
II
363 which
as intense
constitutes
as m/z
modifying
in a substantial
344
(the base
the published
improvement
By monitoring
80% of the total peak)
GC-MS
in the limit
negative
ions at m/z
in
assay
of 363, an
to 500 femtograms4-hydroxydebrisoquine
to noise
other
the modified
the effects
of human in vitro
include
Using
a signal
of several
pair of alleles
studied
times
II corresponding
with
of compound
Consequently,
of 4-hydroxydebrisoquine.
of compound
The oxidation quine.
results
spectra
ion at m/z
twenty
is
(ref.6).
ECNICI
can be detected same
mass
a molecular
spectrum
to incorporate
amount
and ECNICI
ratio
drugs
of one
appears
regulating
(ref.6).
to be under
the alicyclic
(ref.7,8),
guanoxan
the control
hydroxylation
(ref.9)
assay
for 4-hydroxydebrisoquine,
three
drugs
on debrisoquine
enzyme
as well
as debrisoquine, of debrisoquine
we
4-hydroxylase
is responsible
inhibitors
of debriso-
and phenfarmin
GC-MS
If the same
of the
then these
have activity
for the oxidative compounds
4-hydroxylation.The
shouldact results
92 we obtained
TABLE
are given
in Table
1.
1
The effects activity
of sparteine,
of human
Drug
guanoxan
and phenformin
on debrisoquine
liver microsomes
Concentration
Debrisoquine
4-hydroxylatioh
Vmax(pmol/mg/min)
(mM)
Phenformin
I I
In
all three
increased remains
rl?sponsible
l?cl 3267 67.33
87 83
0 0.1 0.3
61 63 61
116 434 1554
36 24
1U7 105 113
125 550 1737
220 190
cases,
the Km for debrisoquine
increasing
unchanged.
inhibitors
;Zl 71
2.5
with
(PM)
205 5.0
0 0.75
~
Ki
Km(uM)
Sparteine
Guanoxan
4-hydroxylase
These
of debrisoquine
drug
concentration,
dat a indicate
that
4-hydroxylation
for the oxidative
4-hydroxylation
metabolism
while these
Vmax
three
and suggest of all four
is markedly
for the compounds
reaction are competitive
that the same
enzyme
is
compounds.
REFERENCES R.Lancaster and R.L.Smith, Lancet, ii (1977) A.Mahgoub, J-R-Idle, L.G.Uring, 584-586 M.S.Lennard and A.J.Smith, Lancet, ii (1977) 2 G-T-Tucker, J.H.Silas, A.O.Iyun, 718 3 D-S-Davies, G-C-Kahn, S.Murray, M.J.Brodie and A.R.Boobis, Br.J.clin-Pharmac., 11 (1981) 89-91 4 G-C-Kahn, A.R.Buobis, S.Murray, M.J.Brodie and D.S.Davies, Br.J.clin.Pharmac., 13 (1982) 637-645 5 S.L.Malcotm and T.R.Marten, Anal.Chem., 48 (1976) 807-809 6 S-Murray and K.A.Waddell, Biomed.Mass Spectrom., in press 7 T.Inaba, S.V.Otton arid W.Kalow, Clin.Pharmac.Ther., 27 (1980) 547-549 M.Eichelbaum and H.-U.Schulz, Eur.J.clin.Pharmac., 8 L.Bertilsson, H.J.Dengler, 17 (1980) 153-155 9 T.P_Sloan, A.Mahgoub, R-Lancaster, J.R.Idle and R.L.Smith, Br.med.J.,Z (1978) 655-657 10 R.R.Shah, N.S.Oates, J.R.Idle and R.L.Smith, Lancet, i (1980) 1147 1