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Dopamine agonists used in the treatment of Parkinson's disease and their selectivity for the D1, D2, and D3 dopamine receptors in human striatum
Prqq.Nrllro-Psychopharmacol. Pergamon
& Bid. Psychiat. 1995. Vol 19. pp. I 147-I 154 Copyright 0 1995 Elsevier Srienre Inc. Printed
in Great
Britain.
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DOPAMINE AGONISTS USED IN THE TREATMENT OF PARKINSON’S DISEASE AND THEIR SELECTMTY FOR THE D1, D,, AND D3 DOPAMINE RECEPTORS IN HUMAN STRIATUM JACQUES DE KEYSER*, JEAN-PAUL Department
of Neurology,
Academisch
DE BACKER, NADINE WILCZAK Ziekenhuis Vrije Universiteit
and Luc HERROELEN
Brussel, Brussels, Belgium
(Final form, June 1995)
De Keyser, Jacques, Jean-Paul De Backer, Nadine Wilczak and Luc Herroelen: Dopamine agonists used in the treatment of Parkinson’s disease and their selectivity for the DT , D2, and D3 dopamine receptors in human striatum. Prog. Neuro-Psychopharmacol. & Biol. Psychiat. 1995, 1 g(7): 1147-l 154.
1.
2.
3.
4.
It has been suggested that an ideal antiparkinsonian treatment requires stimulation of both D1 and D2 dopamine receptors. Bromocriptine and lisuride are regarded as pure D2 receptor agonists, whereas pergolide and apomorphine are thought to stimulate both DT and D2 receptors. The aim of this study was to compare the affinities of bromocriptine, lisuride, pergolide, and apomorphine for the DT , D2, and D3 receptors in postmortem human striatum. The dissociation constants (Ki values) of the dopamine agonists were determined from competition binding experiments with selective radioligands. The Ki values of the orally administered agonists - bromocriptine, pergolide, and lisuride - for the D2 receptors were proportional to their optimal doses against parkinsonism. Ki(DT )/Ki(D2) ratios were 23 for lisuride, 67 for pergolide, 60 for bromocriptine, and 2.6 for apomorphine. Ki(D3)/Ki(D2) ratios were 0.4 for lisuride, 1 for pergolide, 5.4 for bromocriptine, and 21 for apomorphine. The present results support the hypothesis that the antiparkinsonian effect of dopamine agonists is mediated primarily by D2 receptors. Apomorphine is a mixed DT /D2 agonist, but pergolide has no more 01 agonist properties than bromocriptine and lisuride. The role of the D3 receptors is unknown, but their activation might either be associated with the generation of psychiatric sideeffects or dyskinesias, or alternatively add to antiparkinsonian activity.
Kevwoa
: dopamine
:
Abbrevlatlons ([3H]SCH
agonists,
dopamine receptors,
human striatum,
Parkinson’s
5-(+)-8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-l
23390),7-hydroxy-N,N-di-n-propyl-Z-aminotetralin
disease -N-3-benzazepine
([3H]7-OH-DPAT).
Introduction
Striatal Parkinson’s
dopamine
receptors
are the primary targets
disease. Bromocriptine
is only marketed
and pergolide
in European countries
agonists
used in the treatment
are the most widely used dopamine
(Calne, 1993).
* Present address: Janssen Research Foundation,
for dopamine
Apomorphine
Beerse, Belgium
1147
is administered
agonists;
subcutaneously
of
lisuride or
1148
intranasally,
and
Parkinson’s
its
use is currently
disease (Montastruc
Based on a synergistic and non-human combined
to
overcome
sudden
“off’‘-periods
in advanced
et al., 1993).
effect
primates,
stimulation
restricted
c1 al.
of DT and D2 dopamine
it has been proposed
of both DT and D2
that
dopamine
receptor
agonism on locomotor
an ideal antiparkinsonian
receptors
(Walters
activity
treatment
et al., 1987;
in rats
requires
Gomez-Mancilla
a et
al., 1992). Traditionally, pergolide
bromocriptine
and lisuride
and apomorphine
Montastruc
et al.,1 993;
provide
a better
versus
DT /D2
are considered Beaulieu,
therapeutic receptor
are regarded
1987;
response
stimulation
to stimulate Ahlskog
as pure both
than bromocriptine
is based on measurements binding
receptors
in tissue culture
cells (Goldstein
et al., 1980;
agonist-induced
dyskinesias
have also suggested
receptors
(Ahlskog
localized
within
Landwehrmeyer
that
et al., 1992; the
limbic
et al., 1993;
Rosengarten
et al.,
on receptors
1983).
system,
including
the
Herroelen
et al., 1994),
whereas
(Came,
thus
activity
may result
from
receptors
in rodent
Studies
activation
of DT
are preferentially
(Sokoloff
and their activation
in D2
animal brain and cloned
Seeman & Van Tol, 1993).
striatum,
1993;
theoretically
the distinction
cyclase
from
D3 dopamine
ventral
could
However,
of adenylate
and radioligand
expressed
Pergolide
and lisuride.
experiments
agonists,
DT and D2 receptors
et al., 1992).
brain homogenates,
in animals
D2 receptor
et
al.,
1990;
might contribute
to drug-
of bromocriptine,
lisuride,
induced psychosis. In this study pergolide,
the authors
have compared
the pharmacological
specificity
for the D1 , D2, and D3 dopamine receptors
and apomorphine,
in postmortem
human striatum.
by the ethical committee
of the University
l&sue Preoar~ The use of postmortem
human brain tissue was approved
Hospital of the ‘Vrije Universiteit brains obtained
at autopsy
or psychiatric dopamine
disease,
agonists.
and stored
Postmortem
4°C in 50 mM Hepes/NaOH
were determined
[3H]SCH benzazepine)
23390
nucleus and putamen)
None of the patients
containing
had received
1 mM EDTA, and centrifuged
and centrifuged
containing
twice at 30,000
10% glycerol
(vol/vol),
were dissected
years) without
from
neurologic
antipsychotics
were homogenised
at 30,000
or at
g for 20 min.
g for 15 min. The final pellet and stored
at -80°C.
Protein
by the method of Lowry et al. (1951).
(5-(+)-8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-l-N-3-
and [3H]7-OH-DPAT
from Amersham.
at -80°C.
in buffer
in the same buffer
concentrations
(caudate
(5 men and 3 women; aged 46-82
delay was less than 12 hours. The pooled striata
(pH 7.5)
The pellets were resuspended was suspended
Brussel’. Striata
from 8 patients
[3H]spiperone
(7-hydroxy-N,N-di-n-propyl-2-aminotetralin)
was obtained
from New England Nuclear. Bromocriptine
were
obtained
was a gift from
Dopamine agonists and human striatal dopaminr Sandoz,
pergolide
the Janssen
from
Research
Eli Lilly, lisuride from Schering, Foundation.
Apomorphine,
mianserin
(+)butaclamol,
1149
receptors
from
Organon,
and dopamine
and spiperone
from
were purchased
from
Sigma.
The DT receptors
were studied
with [3H]spiperone
with
[3H]SCH
23390
(De Keyser et al., 1989b),
(De Keyser
et al.,1 989a),
and the D3 receptors
the D2
receptors
with [3H]7-OH-DPAT
(Herroelen
et al., 1994). The striatal 23390
(87
membranes CVmmol)
at a final concentration
or [3H]spiperone
mM MgCl2 for 20 min at 30°C 7.5), containing Saturation
experiments
between
1 nM. For competition
[3H]SCH
23390,
0.5
and that
samples
were rapidly
filtered
a Beckman (LS 6000)
the following
0.3 mM was added to prevent
were
performed
6 concentrations
concentrations
(pH
adrenergic
receptors
6
with
of
[3H]SCH
(De Keyser et
0.3 I.IM mianserin
of 4 ml of ice-cold
GF/B glass fibre
with between
were used: 2 nM for Binding
of 100 nM spiperone
by the addition
over Whatman
filters.
buffer.
The filters
The were
remaining on the filters was counted
in
counter. was determined
for [3H]spiperone
pargyline
with
[3H]7-OH-DPAT.
and the radioactivity
23390
and for [3H]7-OH-DPAT
and al
were terminated
buffer,
1989b),
[3H]SCH
in 50 mM Hepes/NaOH
and [3H]7-OH-DPAT [3H]spiperone
and 1 nM for
under vacuum
of [3H]SCH
(De Keyser et al., 1989a),
Pata
23390
to 5-HTz
liquid scintillation
binding
CVmmol)
was masked by the addition
Incubations
washed 3 times with 4 ml ice-cold
Non-specific
[3H]SCH
of [3H]spiperone
(De Keyser et al., 1989b).
(100
with
20 mM NaCI-2
ascorbic acid, for 60 min at 20°C.
[3H]spiperone,
receptors
were incubated
in 20 ml Tris HCI (pH 7.4)-l
[3H]7-OH-DPAT
binding experiments,
nM for
to 5-HTz serotonin
al.,1989a),
with
of 0.3 mg protein/ml
Ci/mmol)
0.2 and 6 nM, and those with
0.05 and
23390
and with
2 mM MgCl2 and 0.005%
binding
concentrations
(81
in the presence
of 10 PM (+)butaclamol
in the presence of 1 PM (+)butaclamol
in the presence of 10 PM dopamine dopamine metabolism)
(De Keyser et al.,
(the monoamine
(Herroelen
oxidase inhibitor
et al., 1994).
Analvsis
Specific binding
binding
studies
was obtained
were analyzed
by subtracting by computerized
non-specific non-linear
constants
(Ki values) of the dopamine agonists were obtained
following
formula:
equilibrium
constant
Ki=ICSO/(
1 +L/Kd),
of the radioligand.
where
binding
from total
least-square
binding.
curve fitting.
from the corresponding
L corresponds
to the
Kd values were obtained
IC50 values by the
concentration
from Scatchard
Competition
The dissociation
and Kd to the
analysis of saturation
binding experiments.
The D3 receptor display
similar
belongs to the DE family of dopamine
affinity
for
cloned
DZ and D3 receptor
receptors, subtypes
and spiperone expressed
has been reported in tissue
culture
to
cells
J. Lk Kryser- (‘I ril.
1150
(Sokoloff
et al., 1990).
To examine
labels D2 receptors,
we performed
spiperone.
displaced
Spiperone
in human striatal concentration
membranes
whether
[3H]spiperone
[3H]7-OH-DPAT
[3H]7-OH-DPAT
agonist competition
only labels D3 receptors, binding experiments,
inhibition of [3H].SCH 23390 Representative competition
[3H]SCH
23390
and [3H]spiperone
a low affinity represents
mediated
et al., 1989b).
presumption (KH=KL)
(Ki=KL).
the receptors
least partially Keyser
state
that
competition
two different
affinity
Only the
that
through
guanine
The monophasic
high- and low-affinity
(Seeman and Van Tol, 1993).
a high affinity
state (Levesque
Ki values of the dopamine Ki(D1 )/Ki(Dz) apomorphine.
ratio
was
23390
curves
state
coupled
nucleotide
with
(Log M)
and of [3H]spiperone (V), pergolide (0))
(2 nM) and [3H]spiperone
pergolide
and apomorphine
a high affinity
state
is pharmacologically
binding
proteins)
for bromocriptine
states
for these
[3H]7-OH-DPAT
agonist,
and
since
it
mechanisms
(at
et al., 1989a;
De
are explained
are identical
is a D3 receptor
(Ki=KH)
relevant,
(De Keyser
and lisuride
agonists
at the
are shown in Fig 1,
to cellular signal transduction
curves
that
or nearly
by the identical
and thus only labels
et al., 1992). agonists
23
The Ki(D3)/Ki(D2)
and 21 for apomorphine.
[3H]SCH
for the agonist:
high affinity
are functionally
unlabbeled
and that [3H]spiperone
binding to DI receptors, curves of bromocriptine
binding
states
selectively
with
only labels D2 receptors.
Dopamine agon~a co~ralion
lisuride (A), and apomorphine (0) for the binding of (0.5 nM) in human striatal membranes are shown.
were biphasic, indicating
membranes
experiments
binding curves for DI and D2 receptors
Oopamine agonistmncantratiin(Log M)
Fig 1. Dopamine agonist binding to D2 receptors.
binding
with a Ki value of 1 PM, indicating
the binding of [3H]7-OH-DPAT
of 0.5 nM, used in the competition
Representative
in human striatal
competition
for
for the 3 dopamine lisuride,
ratio
67
for
receptor
pergolide,
was 0.4 for lisuride,
subtypes 60 for
are listed in Table 1. The
bromocriptine,
1 for pergolide,
and
2.6
for
5.4 for bromocriptine,
Dopamine
agonists
and hl.mxm
striatal
dopaminr
1151
receptors
Table 1. Dissociation
(Ki values) of Dopamine Agonists for DT , Human Striatal Membranes
Constants
D2 receptors (nM)
D1 receptors (nM) bromocriptine lisuride pergolide
2170?416** 83? 9 ** 230 + 26 (43 f 2) 3130+ 91 48 f 4 (45 f 3) 1620f 76
KH (46/?/f) KL KH (%RH) KL
apomorphine
D2 and D3 Dopamine Receptors in
36 3.5 3.4 113 18 480
f 3** ?r 0.6 ** * 0.5 (52_+ 2) rt 26 f 3(49_+2) f 30
Values are the means + SD of 4 experiments
carried out in duplicate.
respectively
state
the high and low affinity
agonist
D3 receptors (nM)
of the receptor.
*
197 f20 1.6 + 0.1 3.4 t 0.2 389
+
4
KH and KL are the Ki values of *
[3H]7-OH-DPAT
only
labels
a
high affinity state of the D3 receptor;** KH = KL. (Ki values (dissociation constants) are the reciprocal of the affinity of a compound for a receptor. The lower the Ki value, the higher the affinity or potency. RH is the number of high affinity sites.
Bromocriptine lisuride
displayed
had a lo-fold
a higher affinity
higher
affinity
keeping with the clinical experience than
bromocriptine
receptor
(Calne,
is the primary
agreement
with
a previous
agonist/antagonist clinical potency
An important
receptors
(lower
Ki value)
et al., 1993;
in which
in human
cannot
brain.
motor
comparable
Gomez-Mancilla
affinities
and bromocriptine traditional appears adenylate 1980).
respectively
incorrect. cyclase
et al., 1992).
The relevance
(Dl
patients
agonists.
responses
(Schachter
to general thoughts, Very
the antiparkinsonian
In our study,
of such findings
that
is known
pergolide,
is doubtful,
efficacy
a 23-fold
lower affinity
stimulation)
models
apomorphine
Lisuride displayed
a 60 and 67-fold
receptor
little
in rats and primate
provides a more balanced D1 /D2
It has been reported activity
contrary
experiments
at DT and D2 receptors.
view that pergolide
it is likely that
to dopamine
endocrine
bromocriptine.
In
10 times more potent
to
the D2
This is in
D1
and D2
et al., 1980).
with the other three dopamine
and lisuride.
suggest that selective D1 agonism may potentiate et al. , 1987;
and
1987),
than
Pergolide and
agonists,
The
because
or intranasally.
bromocriptine
However,
Beaulieu,
response
in parkinsonian
be compared
from this study is that,
than
D2 receptors
Montastruc
of the antiparkinsonian
subcutaneously
conclusion
for these
and lisuride being approximately
drugs were investigated
properties
than at DT and D3 receptors.
of pergolide
study
of apomorphine
this drug is administered
D1 agonist
1993;
mediator
at D2 receptors
pergolide about
has no more
the
role of D1
of Parkinson’s
disease
of D2 agonists
(Walters
was the only agonist
showing
lower affinity,
and pergolide
at D1 than at D2 receptors. agonism than bromocriptine
unlike bromocriptine
in rat striatal since striatal
and lisuride,
homogenates homogenates
Thus the or lisuride
(Goldstein contain
enhances et al.,
a mixture
of
.J. DC Kqser
1152
receptors
which may influence
adenylate
cyclase
<'Icd
activity,
including
binding studies in animal tissue and cloned human dopamine pergolide for the high affinity
states of the D1 and DZ receptors
Van Tol, 1993).
there
(Creese
However,
et al., 1979),
for the corresponding results
is that
disease both
receptors
pergolide
(LeWitt
agonists,
and that
patients
(Sokoloff
in the way that
long-term
et al., 1990).
efficacy
require
of parkinsonian
disability,
&
bind agonists
identical to those
Consistent
in improving
with the present
features
of Parkinson’s
when used in monotherapy
I-dopa as an adjunct
of both D1 and Dz receptors
Previous
nM) (Seeman
receptors
are not necessarily
than bromocriptine
eventually
D2 receptors.
have shown that the Ki values of
were similar (KHxO.8
for cloned receptors
in native tissues
et al.,1 983), as most
improvement
species differences
affinities
is no more effective
Because a balanced stimulation optimal
exist
and agonist
inhibitory
receptors
is limited
for
et al., 1991).
(Caraceni
may be required to achieve and sustain an
the addition
of I-dopa may be necessary
to coactivate
D1 receptors.
0
or the Trnt Bromocriptine
of Parkinson s Dlsea
has a lower incidence of dyskinesias
al., 1993).
The finding
hypothesis
that activation
dyskinesias,
that
both
agonists
of D1 receptors
as has been suggested
is the main mechanism
from animal experiments
In both rat and human brain, D3 receptors and other implicating
limbic areas (Sokoloff a possible
are enriched
et al., 1990;
role in mental
and emotional
than bromocriptine
at D3 receptors
related,
and it may be possible that the activation
effects
of dopamine
agonist treatment.
agonists
the D1 and D2 receptors, 1994).
Bromocriptine,
and D3 receptors, efficacy
D3 receptors
implicating
exposed
Therefore,
genesis of dyskinesia.
functions.
Psychotic
coactivation
showed
side-
are not restricted
D2
to the
similar to that of
as well (Herroelen
et al.,
when given to animals or
has a 5-fold lower affinity activation
of D3 receptors
a higher
are dose-
when more selective
properties
D3 receptor
accumbens)
On the other hand, the authors
function
in view of the similar high affinity
et the
et al., 1994),
to the psychiatric
the whole striatum
role in motor
it may be possible that
(nucleus
manifestations
contributes
throughout
BBdard against
agonist-induced
Herroelen
labelled by [3H]7-OH-DPAT
a possible
we cannot exclude that
striatum
will only be confirmed
to I-dopa (BBdard et al, 1993),
Alternatively,
dopamine
Lisuride and pergolide
of D3 receptors
distribution
argues
et al., 1983).
et al., 1993;
which stands out as having little dyskinetic
humans not previously for DE receptors.
in the ventral
and apomorphine.
This hypothesis
but show a widespread
et al., 1992; ratio
mediating
will become available for studies in humans.
have found that in human striatum, nucleus accumbens,
(Ahlskog
(Rosengarten
Landwehrmeyer
affinity
and D3 receptor
than pergolide
share a similar Ki(D1 )/Ki(DZ)
for D3 than
is associated
of pergolide
with
the
and lisuride for D2
may add to the antiparkinsonian
of these agonists. These questions can only be answered when selective
D3 receptor
agonists will
become available for studies in humans. It is expected properties differences,
that
or with
new agonists very
high
and that agonist
are not necessarily
will be developed
selectivity. affinities
with either combined
It is important
for cloned dopamine
identical to those for the corresponding
to
emphasise
receptors
receptors
dopamine that
expressed
receptor
there
exist
subtype species
in tissue culture
in native tissues.
cells
To obtain a more
1 15.3
Dopamine agonists and human striatal dopamine receptors accurate
insight in the functional
also include research
receptor
binding
aimed at unravelling
will be of great
properties studies
of dopamine agonists,
in
postmortem
the functional
human
pharmacodynamic brain tissue.
roles of the different
help for the design of new dopamine
agonists
receptor
with
better
evaluations
It is likely subtypes efficacy
should
that
future
in human
brain
and less adverse
effects.
Our results support primarily
the hypothesis
by D2 receptors.
properties receptors
than
that the antiparkinsonian
In human striatal
bromocriptine
membranes,
and lisuride.
Pergolide
effect
pergolide
of dopamine
agonists
is mediated
seems to have no more D1 agonist
and lisuride display
a higher
affinity
for the D3
than bromocriptine.
This study
was supported
by a grant
from
the
Belgian
‘Nationaal
Fonds voor
Wetenschappelijk
Onderzoek’
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Current
ROSENGARTEN, H., SCHWEITZER, J.W. and FRIEDHOFF, A.J. (1983) naive rats by Dl receptor stimulation. Life Sci. 3: 29-35.
Proc.
Protein measurement
status
of dopamine
Induction
with the
agonists
in
of oral dyskinesias
in
SCHACHTER, M., BEDARD, P., DEBONO, A.G., JENNER, P., MARSDEN, CD., PRICE, P., PARKES, J.D., KEEMAN, J., SMITH, B., ROSENTHALER, J., HOROWSKI, R., and DOROW, R. (1980) The role of D-l and D-2 receptors. Nature m: 157-l 58. SEEMAN,
P. and VAN TOL, H.H.M. (1993)
Dopamine
receptor
pharmacology.
Curr.
Opin. Neural.
Neurosurg. 8: 602-608. SOKOLOFF, P., GIROS, B., MARTRES, M.-P., BOUTHENET, M.-L. Molecular cloning and characterization of a novel dopamine neuroleptics. Nature s: 146-l 51.
and SCHWARTZ, J.-C. (1990) receptor (D3) as a target for
WALTERS, J.R., BERGSTROM, D.A., CARLSON, J.H., CHASE, T.N. and BRAUN, A.R. (1987) DT dopamine receptor activation required for postsynaptic expression of D2 agonist effects. Science m: 719722.
Inquiries and reprint
requests
Jacques De Keyser, M.D., Ph.D. Janssen Research Foundation Turnhoutseweg 30 8 2340 Beerse Belgium
should be addressed to:
& Bid. Psychiat. 1995. Vol 19. pp. I 147-I 154 Copyright 0 1995 Elsevier Srienre Inc. Printed
in Great
Britain.
All rights
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027s5846(95)00232-4
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reserwd $29.00
DOPAMINE AGONISTS USED IN THE TREATMENT OF PARKINSON’S DISEASE AND THEIR SELECTMTY FOR THE D1, D,, AND D3 DOPAMINE RECEPTORS IN HUMAN STRIATUM JACQUES DE KEYSER*, JEAN-PAUL Department
of Neurology,
Academisch
DE BACKER, NADINE WILCZAK Ziekenhuis Vrije Universiteit
and Luc HERROELEN
Brussel, Brussels, Belgium
(Final form, June 1995)
De Keyser, Jacques, Jean-Paul De Backer, Nadine Wilczak and Luc Herroelen: Dopamine agonists used in the treatment of Parkinson’s disease and their selectivity for the DT , D2, and D3 dopamine receptors in human striatum. Prog. Neuro-Psychopharmacol. & Biol. Psychiat. 1995, 1 g(7): 1147-l 154.
1.
2.
3.
4.
It has been suggested that an ideal antiparkinsonian treatment requires stimulation of both D1 and D2 dopamine receptors. Bromocriptine and lisuride are regarded as pure D2 receptor agonists, whereas pergolide and apomorphine are thought to stimulate both DT and D2 receptors. The aim of this study was to compare the affinities of bromocriptine, lisuride, pergolide, and apomorphine for the DT , D2, and D3 receptors in postmortem human striatum. The dissociation constants (Ki values) of the dopamine agonists were determined from competition binding experiments with selective radioligands. The Ki values of the orally administered agonists - bromocriptine, pergolide, and lisuride - for the D2 receptors were proportional to their optimal doses against parkinsonism. Ki(DT )/Ki(D2) ratios were 23 for lisuride, 67 for pergolide, 60 for bromocriptine, and 2.6 for apomorphine. Ki(D3)/Ki(D2) ratios were 0.4 for lisuride, 1 for pergolide, 5.4 for bromocriptine, and 21 for apomorphine. The present results support the hypothesis that the antiparkinsonian effect of dopamine agonists is mediated primarily by D2 receptors. Apomorphine is a mixed DT /D2 agonist, but pergolide has no more 01 agonist properties than bromocriptine and lisuride. The role of the D3 receptors is unknown, but their activation might either be associated with the generation of psychiatric sideeffects or dyskinesias, or alternatively add to antiparkinsonian activity.
Kevwoa
: dopamine
:
Abbrevlatlons ([3H]SCH
agonists,
dopamine receptors,
human striatum,
Parkinson’s
5-(+)-8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-l
23390),7-hydroxy-N,N-di-n-propyl-Z-aminotetralin
disease -N-3-benzazepine
([3H]7-OH-DPAT).
Introduction
Striatal Parkinson’s
dopamine
receptors
are the primary targets
disease. Bromocriptine
is only marketed
and pergolide
in European countries
agonists
used in the treatment
are the most widely used dopamine
(Calne, 1993).
* Present address: Janssen Research Foundation,
for dopamine
Apomorphine
Beerse, Belgium
1147
is administered
agonists;
subcutaneously
of
lisuride or
1148
intranasally,
and
Parkinson’s
its
use is currently
disease (Montastruc
Based on a synergistic and non-human combined
to
overcome
sudden
“off’‘-periods
in advanced
et al., 1993).
effect
primates,
stimulation
restricted
c1 al.
of DT and D2 dopamine
it has been proposed
of both DT and D2
that
dopamine
receptor
agonism on locomotor
an ideal antiparkinsonian
receptors
(Walters
activity
treatment
et al., 1987;
in rats
requires
Gomez-Mancilla
a et
al., 1992). Traditionally, pergolide
bromocriptine
and lisuride
and apomorphine
Montastruc
et al.,1 993;
provide
a better
versus
DT /D2
are considered Beaulieu,
therapeutic receptor
are regarded
1987;
response
stimulation
to stimulate Ahlskog
as pure both
than bromocriptine
is based on measurements binding
receptors
in tissue culture
cells (Goldstein
et al., 1980;
agonist-induced
dyskinesias
have also suggested
receptors
(Ahlskog
localized
within
Landwehrmeyer
that
et al., 1992; the
limbic
et al., 1993;
Rosengarten
et al.,
on receptors
1983).
system,
including
the
Herroelen
et al., 1994),
whereas
(Came,
thus
activity
may result
from
receptors
in rodent
Studies
activation
of DT
are preferentially
(Sokoloff
and their activation
in D2
animal brain and cloned
Seeman & Van Tol, 1993).
striatum,
1993;
theoretically
the distinction
cyclase
from
D3 dopamine
ventral
could
However,
of adenylate
and radioligand
expressed
Pergolide
and lisuride.
experiments
agonists,
DT and D2 receptors
et al., 1992).
brain homogenates,
in animals
D2 receptor
et
al.,
1990;
might contribute
to drug-
of bromocriptine,
lisuride,
induced psychosis. In this study pergolide,
the authors
have compared
the pharmacological
specificity
for the D1 , D2, and D3 dopamine receptors
and apomorphine,
in postmortem
human striatum.
by the ethical committee
of the University
l&sue Preoar~ The use of postmortem
human brain tissue was approved
Hospital of the ‘Vrije Universiteit brains obtained
at autopsy
or psychiatric dopamine
disease,
agonists.
and stored
Postmortem
4°C in 50 mM Hepes/NaOH
were determined
[3H]SCH benzazepine)
23390
nucleus and putamen)
None of the patients
containing
had received
1 mM EDTA, and centrifuged
and centrifuged
containing
twice at 30,000
10% glycerol
(vol/vol),
were dissected
years) without
from
neurologic
antipsychotics
were homogenised
at 30,000
or at
g for 20 min.
g for 15 min. The final pellet and stored
at -80°C.
Protein
by the method of Lowry et al. (1951).
(5-(+)-8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-l-N-3-
and [3H]7-OH-DPAT
from Amersham.
at -80°C.
in buffer
in the same buffer
concentrations
(caudate
(5 men and 3 women; aged 46-82
delay was less than 12 hours. The pooled striata
(pH 7.5)
The pellets were resuspended was suspended
Brussel’. Striata
from 8 patients
[3H]spiperone
(7-hydroxy-N,N-di-n-propyl-2-aminotetralin)
was obtained
from New England Nuclear. Bromocriptine
were
obtained
was a gift from
Dopamine agonists and human striatal dopaminr Sandoz,
pergolide
the Janssen
from
Research
Eli Lilly, lisuride from Schering, Foundation.
Apomorphine,
mianserin
(+)butaclamol,
1149
receptors
from
Organon,
and dopamine
and spiperone
from
were purchased
from
Sigma.
The DT receptors
were studied
with [3H]spiperone
with
[3H]SCH
23390
(De Keyser et al., 1989b),
(De Keyser
et al.,1 989a),
and the D3 receptors
the D2
receptors
with [3H]7-OH-DPAT
(Herroelen
et al., 1994). The striatal 23390
(87
membranes CVmmol)
at a final concentration
or [3H]spiperone
mM MgCl2 for 20 min at 30°C 7.5), containing Saturation
experiments
between
1 nM. For competition
[3H]SCH
23390,
0.5
and that
samples
were rapidly
filtered
a Beckman (LS 6000)
the following
0.3 mM was added to prevent
were
performed
6 concentrations
concentrations
(pH
adrenergic
receptors
6
with
of
[3H]SCH
(De Keyser et
0.3 I.IM mianserin
of 4 ml of ice-cold
GF/B glass fibre
with between
were used: 2 nM for Binding
of 100 nM spiperone
by the addition
over Whatman
filters.
buffer.
The filters
The were
remaining on the filters was counted
in
counter. was determined
for [3H]spiperone
pargyline
with
[3H]7-OH-DPAT.
and the radioactivity
23390
and for [3H]7-OH-DPAT
and al
were terminated
buffer,
1989b),
[3H]SCH
in 50 mM Hepes/NaOH
and [3H]7-OH-DPAT [3H]spiperone
and 1 nM for
under vacuum
of [3H]SCH
(De Keyser et al., 1989a),
Pata
23390
to 5-HTz
liquid scintillation
binding
CVmmol)
was masked by the addition
Incubations
washed 3 times with 4 ml ice-cold
Non-specific
[3H]SCH
of [3H]spiperone
(De Keyser et al., 1989b).
(100
with
20 mM NaCI-2
ascorbic acid, for 60 min at 20°C.
[3H]spiperone,
receptors
were incubated
in 20 ml Tris HCI (pH 7.4)-l
[3H]7-OH-DPAT
binding experiments,
nM for
to 5-HTz serotonin
al.,1989a),
with
of 0.3 mg protein/ml
Ci/mmol)
0.2 and 6 nM, and those with
0.05 and
23390
and with
2 mM MgCl2 and 0.005%
binding
concentrations
(81
in the presence
of 10 PM (+)butaclamol
in the presence of 1 PM (+)butaclamol
in the presence of 10 PM dopamine dopamine metabolism)
(De Keyser et al.,
(the monoamine
(Herroelen
oxidase inhibitor
et al., 1994).
Analvsis
Specific binding
binding
studies
was obtained
were analyzed
by subtracting by computerized
non-specific non-linear
constants
(Ki values) of the dopamine agonists were obtained
following
formula:
equilibrium
constant
Ki=ICSO/(
1 +L/Kd),
of the radioligand.
where
binding
from total
least-square
binding.
curve fitting.
from the corresponding
L corresponds
to the
Kd values were obtained
IC50 values by the
concentration
from Scatchard
Competition
The dissociation
and Kd to the
analysis of saturation
binding experiments.
The D3 receptor display
similar
belongs to the DE family of dopamine
affinity
for
cloned
DZ and D3 receptor
receptors, subtypes
and spiperone expressed
has been reported in tissue
culture
to
cells
J. Lk Kryser- (‘I ril.
1150
(Sokoloff
et al., 1990).
To examine
labels D2 receptors,
we performed
spiperone.
displaced
Spiperone
in human striatal concentration
membranes
whether
[3H]spiperone
[3H]7-OH-DPAT
[3H]7-OH-DPAT
agonist competition
only labels D3 receptors, binding experiments,
inhibition of [3H].SCH 23390 Representative competition
[3H]SCH
23390
and [3H]spiperone
a low affinity represents
mediated
et al., 1989b).
presumption (KH=KL)
(Ki=KL).
the receptors
least partially Keyser
state
that
competition
two different
affinity
Only the
that
through
guanine
The monophasic
high- and low-affinity
(Seeman and Van Tol, 1993).
a high affinity
state (Levesque
Ki values of the dopamine Ki(D1 )/Ki(Dz) apomorphine.
ratio
was
23390
curves
state
coupled
nucleotide
with
(Log M)
and of [3H]spiperone (V), pergolide (0))
(2 nM) and [3H]spiperone
pergolide
and apomorphine
a high affinity
state
is pharmacologically
binding
proteins)
for bromocriptine
states
for these
[3H]7-OH-DPAT
agonist,
and
since
it
mechanisms
(at
et al., 1989a;
De
are explained
are identical
is a D3 receptor
(Ki=KH)
relevant,
(De Keyser
and lisuride
agonists
at the
are shown in Fig 1,
to cellular signal transduction
curves
that
or nearly
by the identical
and thus only labels
et al., 1992). agonists
23
The Ki(D3)/Ki(D2)
and 21 for apomorphine.
[3H]SCH
for the agonist:
high affinity
are functionally
unlabbeled
and that [3H]spiperone
binding to DI receptors, curves of bromocriptine
binding
states
selectively
with
only labels D2 receptors.
Dopamine agon~a co~ralion
lisuride (A), and apomorphine (0) for the binding of (0.5 nM) in human striatal membranes are shown.
were biphasic, indicating
membranes
experiments
binding curves for DI and D2 receptors
Oopamine agonistmncantratiin(Log M)
Fig 1. Dopamine agonist binding to D2 receptors.
binding
with a Ki value of 1 PM, indicating
the binding of [3H]7-OH-DPAT
of 0.5 nM, used in the competition
Representative
in human striatal
competition
for
for the 3 dopamine lisuride,
ratio
67
for
receptor
pergolide,
was 0.4 for lisuride,
subtypes 60 for
are listed in Table 1. The
bromocriptine,
1 for pergolide,
and
2.6
for
5.4 for bromocriptine,
Dopamine
agonists
and hl.mxm
striatal
dopaminr
1151
receptors
Table 1. Dissociation
(Ki values) of Dopamine Agonists for DT , Human Striatal Membranes
Constants
D2 receptors (nM)
D1 receptors (nM) bromocriptine lisuride pergolide
2170?416** 83? 9 ** 230 + 26 (43 f 2) 3130+ 91 48 f 4 (45 f 3) 1620f 76
KH (46/?/f) KL KH (%RH) KL
apomorphine
D2 and D3 Dopamine Receptors in
36 3.5 3.4 113 18 480
f 3** ?r 0.6 ** * 0.5 (52_+ 2) rt 26 f 3(49_+2) f 30
Values are the means + SD of 4 experiments
carried out in duplicate.
respectively
state
the high and low affinity
agonist
D3 receptors (nM)
of the receptor.
*
197 f20 1.6 + 0.1 3.4 t 0.2 389
+
4
KH and KL are the Ki values of *
[3H]7-OH-DPAT
only
labels
a
high affinity state of the D3 receptor;** KH = KL. (Ki values (dissociation constants) are the reciprocal of the affinity of a compound for a receptor. The lower the Ki value, the higher the affinity or potency. RH is the number of high affinity sites.
Bromocriptine lisuride
displayed
had a lo-fold
a higher affinity
higher
affinity
keeping with the clinical experience than
bromocriptine
receptor
(Calne,
is the primary
agreement
with
a previous
agonist/antagonist clinical potency
An important
receptors
(lower
Ki value)
et al., 1993;
in which
in human
cannot
brain.
motor
comparable
Gomez-Mancilla
affinities
and bromocriptine traditional appears adenylate 1980).
respectively
incorrect. cyclase
et al., 1992).
The relevance
(Dl
patients
agonists.
responses
(Schachter
to general thoughts, Very
the antiparkinsonian
In our study,
of such findings
that
is known
pergolide,
is doubtful,
efficacy
a 23-fold
lower affinity
stimulation)
models
apomorphine
Lisuride displayed
a 60 and 67-fold
receptor
little
in rats and primate
provides a more balanced D1 /D2
It has been reported activity
contrary
experiments
at DT and D2 receptors.
view that pergolide
it is likely that
to dopamine
endocrine
bromocriptine.
In
10 times more potent
to
the D2
This is in
D1
and D2
et al., 1980).
with the other three dopamine
and lisuride.
suggest that selective D1 agonism may potentiate et al. , 1987;
and
1987),
than
Pergolide and
agonists,
The
because
or intranasally.
bromocriptine
However,
Beaulieu,
response
in parkinsonian
be compared
from this study is that,
than
D2 receptors
Montastruc
of the antiparkinsonian
subcutaneously
conclusion
for these
and lisuride being approximately
drugs were investigated
properties
than at DT and D3 receptors.
of pergolide
study
of apomorphine
this drug is administered
D1 agonist
1993;
mediator
at D2 receptors
pergolide about
has no more
the
role of D1
of Parkinson’s
disease
of D2 agonists
(Walters
was the only agonist
showing
lower affinity,
and pergolide
at D1 than at D2 receptors. agonism than bromocriptine
unlike bromocriptine
in rat striatal since striatal
and lisuride,
homogenates homogenates
Thus the or lisuride
(Goldstein contain
enhances et al.,
a mixture
of
.J. DC Kqser
1152
receptors
which may influence
adenylate
cyclase
<'Icd
activity,
including
binding studies in animal tissue and cloned human dopamine pergolide for the high affinity
states of the D1 and DZ receptors
Van Tol, 1993).
there
(Creese
However,
et al., 1979),
for the corresponding results
is that
disease both
receptors
pergolide
(LeWitt
agonists,
and that
patients
(Sokoloff
in the way that
long-term
et al., 1990).
efficacy
require
of parkinsonian
disability,
&
bind agonists
identical to those
Consistent
in improving
with the present
features
of Parkinson’s
when used in monotherapy
I-dopa as an adjunct
of both D1 and Dz receptors
Previous
nM) (Seeman
receptors
are not necessarily
than bromocriptine
eventually
D2 receptors.
have shown that the Ki values of
were similar (KHxO.8
for cloned receptors
in native tissues
et al.,1 983), as most
improvement
species differences
affinities
is no more effective
Because a balanced stimulation optimal
exist
and agonist
inhibitory
receptors
is limited
for
et al., 1991).
(Caraceni
may be required to achieve and sustain an
the addition
of I-dopa may be necessary
to coactivate
D1 receptors.
0
or the Trnt Bromocriptine
of Parkinson s Dlsea
has a lower incidence of dyskinesias
al., 1993).
The finding
hypothesis
that activation
dyskinesias,
that
both
agonists
of D1 receptors
as has been suggested
is the main mechanism
from animal experiments
In both rat and human brain, D3 receptors and other implicating
limbic areas (Sokoloff a possible
are enriched
et al., 1990;
role in mental
and emotional
than bromocriptine
at D3 receptors
related,
and it may be possible that the activation
effects
of dopamine
agonist treatment.
agonists
the D1 and D2 receptors, 1994).
Bromocriptine,
and D3 receptors, efficacy
D3 receptors
implicating
exposed
Therefore,
genesis of dyskinesia.
functions.
Psychotic
coactivation
showed
side-
are not restricted
D2
to the
similar to that of
as well (Herroelen
et al.,
when given to animals or
has a 5-fold lower affinity activation
of D3 receptors
a higher
are dose-
when more selective
properties
D3 receptor
accumbens)
On the other hand, the authors
function
in view of the similar high affinity
et the
et al., 1994),
to the psychiatric
the whole striatum
role in motor
it may be possible that
(nucleus
manifestations
contributes
throughout
BBdard against
agonist-induced
Herroelen
labelled by [3H]7-OH-DPAT
a possible
we cannot exclude that
striatum
will only be confirmed
to I-dopa (BBdard et al, 1993),
Alternatively,
dopamine
Lisuride and pergolide
of D3 receptors
distribution
argues
et al., 1983).
et al., 1993;
which stands out as having little dyskinetic
humans not previously for DE receptors.
in the ventral
and apomorphine.
This hypothesis
but show a widespread
et al., 1992; ratio
mediating
will become available for studies in humans.
have found that in human striatum, nucleus accumbens,
(Ahlskog
(Rosengarten
Landwehrmeyer
affinity
and D3 receptor
than pergolide
share a similar Ki(D1 )/Ki(DZ)
for D3 than
is associated
of pergolide
with
the
and lisuride for D2
may add to the antiparkinsonian
of these agonists. These questions can only be answered when selective
D3 receptor
agonists will
become available for studies in humans. It is expected properties differences,
that
or with
new agonists very
high
and that agonist
are not necessarily
will be developed
selectivity. affinities
with either combined
It is important
for cloned dopamine
identical to those for the corresponding
to
emphasise
receptors
receptors
dopamine that
expressed
receptor
there
exist
subtype species
in tissue culture
in native tissues.
cells
To obtain a more
1 15.3
Dopamine agonists and human striatal dopamine receptors accurate
insight in the functional
also include research
receptor
binding
aimed at unravelling
will be of great
properties studies
of dopamine agonists,
in
postmortem
the functional
human
pharmacodynamic brain tissue.
roles of the different
help for the design of new dopamine
agonists
receptor
with
better
evaluations
It is likely subtypes efficacy
should
that
future
in human
brain
and less adverse
effects.
Our results support primarily
the hypothesis
by D2 receptors.
properties receptors
than
that the antiparkinsonian
In human striatal
bromocriptine
membranes,
and lisuride.
Pergolide
effect
pergolide
of dopamine
agonists
is mediated
seems to have no more D1 agonist
and lisuride display
a higher
affinity
for the D3
than bromocriptine.
This study
was supported
by a grant
from
the
Belgian
‘Nationaal
Fonds voor
Wetenschappelijk
Onderzoek’
AHLSKOG, J.E., MUENTER, M.D., BAILEY, P.A. and STEVENS ,P.M. (1992) Dopamine agonist treatment of fluctuating Parkinsonism. D-Z (controlled-release MK-458) vs combined D-l and D-2 (pergolide). Arch. Neurol. B: 560-568. BEAULIEU, M. (1987) 402-406.
Clinical importance
of D-1 and D-2 receptors.
Can. J. Neurol.
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(suppl):
BEDARD, P.J., GOMEZ-MANCILLA, B., BLANCHETTE, P., GAGNON, C., FALARDEAU, P. and DI PAOLO, T. (1993) Role of selective Dl and D2 agonists in inducing dyskinesia in drug-naive MPTP monkeys. Adv. Neurol. a: 1 13-l 18. CALNE, DB. (1993)
Treatment
of Parkinson’s
disease
New Engl. J. Med. x,
1021-l
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CARACENI, T., GEMINIANI, G., GENITRINI, S. and SOLIBERI, P. (1991) D2 dopamine agonists in the treatment of Parkinson’s disese. In: Current trends in the treatment of Parkinson’s disease, Y. Agid (Ed.), pp 203-208, John Libbey, London. CREESE, I., STEWART, K. and SNYDER, S.H. (1979) Eur. J. Pharmacol. 6Q: 55-66.
Species variations
in dopamine
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