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The Journal of Neuroscience, August 1, 2001, 21(15):5494-5500
Vulnerability of 125I- -Conotoxin MII Binding Sites
to Nigrostriatal Damage in Monkey
Maryka
Quik1,
Yelena
Polonskaya1,
Jennifer M.
Kulak1, and
J. Michael
McIntosh2
1 The Parkinson's Institute, Sunnyvale, California
94089, and 2 Department of Biology and Psychiatry,
University of Utah, Salt Lake City, Utah 84112
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ABSTRACT |
Parkinson's disease, a neurodegenerative movement disorder
characterized by selective degeneration of nigrostriatal dopaminergic neurons, affects ~1% of the population over 50. Because nicotinic acetylcholine receptors (nAChRs) may represent an important therapeutic target for this disorder, we performed experiments to elucidate the
subtypes altered with nigrostriatal damage in parkinsonian monkeys. For
this purpose we used 125I- -conotoxin MII
(CtxMII), a relatively new ligand that identifies 3 and/or
6 subunits containing nAChR subtypes. In brain from untreated
monkeys, there was saturable 125I--CtxMII binding
to a single population of high-affinity nicotinic sites
(Kd = 0.9 nM), primarily
localized in the visual, habenula-interpeduncular, and
nigrostriatal-mesolimbic pathways. Administration of the selective dopaminergic neurotoxin
1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine resulted in damage
to the nigrostriatal system and parkinsonism. Autoradiographic analysis
showed that 125I--CtxMII sites were selectively reduced
( 99%) in the basal ganglia and that the lesion-induced decreases
correlated well with declines in the dopamine transporter, a marker of
dopaminergic neuron integrity. These findings may indicate that most or
all of 125I--CtxMII-labeled nAChR subtypes in the basal
ganglia are present on nigrostriatal dopaminergic neurons, in contrast
to 125I-epibatidine sites. These data suggest that the
development of ligands directed to nAChR subtypes containing 3
and/or 6 subunits may yield a novel treatment strategy for
parkinsonian patients with nigrostriatal dopaminergic degeneration.
Key words:
-conotoxin MII; 3 nAChRs; 6 nAChRs; MPTP; monkeys; autoradiography; nigrostriatal system; dopamine; Parkinson's
disease
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INTRODUCTION |
Accumulating evidence indicates that
neuronal nicotine acetylcholine receptors (nAChRs) may be
important in Parkinson's disease, a movement disorder characterized by
degeneration of the nigrostriatal dopaminergic system (Balfour and
Fagerstrom, 1996 ; Quik and Jeyarasasingam, 2000). Nicotinic receptors
are present in the basal ganglia (Marks and Collins, 1982; Schwartz et
al., 1982, 1984; Clarke et al., 1985; Perry et al., 1987, 1995; Aubert
et al., 1992; Marks et al., 1992, 1996; Gotti et al., 1997; Court et
al. 2000), and nAChR stimulation evokes striatal dopamine (DA) release
(Grady et al., 1992; Marshall et al., 1997; Wonnacott, 1997). Moreover,
nicotine and nAChR ligands modulate motor control in rodents, monkeys, and humans (Ishikawa and Miyatake, 1993; Fagerstrom et al., 1994; Schneider et al., 1998; Domino et al., 1999; Kelton et al., 2000), possibly through activation of 4 and/or 6 containing nAChRs (Sorenson et al., 1998; Arroyo-Jiminez et al., 1999; Le Novere et al.,
1999; Ross et al., 2000).
Not only does nicotinic receptor stimulation modulate locomotor
activity, but nicotine has also been reported to exert a
neuroprotective role against dopaminergic damage both in culture and
in vivo (Janson et al., 1988; Carr and Rowell, 1990;
Belluardo et al., 1998; Maggio et al., 1998; Quik and Jeyarasasingam,
2000). Moreover, over 50 epidemiological studies indicate that there is
an inverse relationship between tobacco use and Parkinson's disease
(Morens et al., 1995; Balfour and Fagerstrom, 1996; Gorell et al.,
1999), with the risk of developing Parkinson's disease reduced from 20 to 80% in tobacco users.
Studies to investigate the nAChR subtypes that mediate the effects of
nicotine are important because these receptors represent potential targets for Parkinson's disease therapy to ameliorate motor
symptoms and/or protect against neurodegeneration. nAChRs form a large
family of ligand-gated cation channels with diverse structures and
properties (Changeux et al., 1998; Jones et al., 1999; Lukas et al.,
1999; Picciotto et al., 2000). Subunit mRNAs present in basal ganglia
include 2 to 7 and  2 to 4 (Gotti et al., 1997;
Wonnacott, 1997; Quik et al., 2000a,b). There is thus the potential for
receptors with multiple subunit combinations. However, our knowledge of
the subtypes expressed in the basal ganglia has been limited in part by
the small number of subtype-selective nAChR radioligands. The use of
tritiated nicotine and cytisine provides some selectivity for 4- and
2-containing receptors, whereas
125I--bungarotoxin and
3H-methyllycaconitine selectively bind
7-containing receptors (Gotti et al., 1997; Lukas et al., 1999;
Whiteaker et al., 1999). However, radiolabeled epibatidine is
relatively nonselective for different nicotinic receptor subtypes and
may bind to receptors containing 2 through 6 subunits (Perry et
al., 1995; Davila-Garcia et al., 1997).
125I--conotoxin MII (CtxMII) is a relatively
new ligand that appears to be selective for receptors containing 3
and/or 6 subunits (Cartier et al., 1996; Kulak et al., 1997; Luo et
al., 1998; McIntosh et al., 1999; Vailati et al., 1999; Kuryatov et
al., 2000; Whiteaker et al., 2000a). Because this represents a valuable
new tool to define a subset of nicotinic receptors, we initiated
experiments with 125I--CtxMII in normal
and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-lesioned monkey
brain. Monkeys were selected for study because the neuroanatomical
organization of both the basal ganglia and the nAChR subunit mRNA
distribution closely resemble that of humans. Moreover, monkeys treated
with the neurotoxin MPTP exhibit behavioral, pathological, and
neurochemical changes similar to those observed in Parkinson's disease
(Langston et al., 2000; Quik et al., 2000a,b,c).
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MATERIALS AND METHODS |
Animals. Twenty young adult male and female squirrel
monkeys (Saimiri sciureus) weighing from 0.595 to 0.752 kg
were obtained from Osage Research Primates (Osage Beach, MO). All
animals were housed in a 13/11 hr light/dark cycle with ad
libitum access to food and water. After quarantine and testing
according to standard veterinary practice, the animals were randomly
assigned to the control or MPTP treatment groups. All procedures used
in this study conform to the National Institutes of Health (NIH)
Guide for the Care and Use of Laboratory Animals and were
approved by the Institutional Animal Care and Use Committee.
Behavioral testing and MPTP treatment. Quantitative activity
assessment was performed using a computerized movement monitor cage
containing an array of infrared sensors (Quik et al., 2000b). After an
initial acclimatization period, the locomotor activity of the monkeys
was monitored for a 1 hr period for 8-12 consecutive days, at the same
time daily. Then, the animals were assigned randomly to treatment with
MPTP (2 mg/kg, s.c.) or saline. Two to 3 weeks later, locomotor
activity was measured again as described above, and animals were rated
by two raters, one of whom was blinded, for motor deficits using a
parkinsonian rating scale for nonhuman primates (Langston et al.,
2000). The disability scores ranged from 0 to 20 in this scale, with 0 being normal and 20 very severely parkinsonian. The composite score was
obtained using five clinical parameters, each having a 5 point range
with 0 being normal (Langston et al., 2000). These include (1) spatial
hypokinesia (reduction in use of the available cage space), (2) body
bradykinesia (increased slowness in body movement), (3) manual
dexterity, (4) balance, and (5) freezing. If the total Parkinson score
was <3, the monkeys were given a second injection of MPTP at a lower
dose (1.75 mg/kg, s.c.) than the first because our previous studies
indicated that readministration of 2 mg/kg occasionally (<5%) led to
animal mortality. Two to 3 weeks after this second MPTP injection
treatment, locomotor motor activity and parkinsonism were determined
again as described above. The monkeys were killed 4 weeks after
either the first or second MPTP injection. Ketamine hydrochloride
(15-20 mg/kg, i.m.) was administered to sedate the animals, followed
by injection of 0.22 ml/kg intravenous euthanasia solution (390 mg
sodium pentobarbital and 50 mg phenytoin sodium/ml). All procedures
were performed in accordance with the recommendations of the Panel on
Euthanasia of the American Veterinary Medical Association and conform
to the NIH Guide for the Care and Use of Laboratory
Animals.
Tissue preparation. The brains were removed, rinsed, placed
in a mold, and cut into 6-mm-thick blocks that were frozen in isopentane on dry ice and stored at  80°C. The blocks were cut into
20 µm sections using a cryostat. The sections were
thaw-mounted onto poly-L-lysine-coated
slides, dried, and stored at 80°C. The sections were thawed and
used directly for receptor and DA transporter autoradiography.
125I--CtxMII
autoradiography. -CtxMII was synthesized and iodinated as
previously described (Whiteaker et al., 2000a). Quantitative autoradiography with
125I--CtxMII was performed using a
similar procedure as Whiteaker et al. (2000a). Sections were
preincubated in buffer [binding buffer containing (in
mM): 144 NaCl, 1.5 KCl, 2 CaCl2, 1 MgSO4, 20 HEPES,
0.1% BSA, pH 7.5] plus 1 mM
phenylmethylsulfonyl fluoride at room temperature (RT) for 15 min. This
was followed by a 2 hr incubation at room temperature in binding buffer
plus 5% BSA, also containing 5 mM EDTA, 5 mM EGTA, and 10 µg/ml each of aprotinin, leupeptin, and pepstatin A, and 0.8 nM
125I--CtxMII, unless otherwise
indicated. After incubation with 125I--CtxMII, the slides were rinsed
for 30 sec in binding buffer at room temperature, followed by another
30 sec wash in ice-cold buffer (0°C), two washes for 5 sec in 0.1×
binding buffer (0°C), and two 5 sec washes at 0°C in water.
Nonspecific 125I--CtxMII binding was
defined using 0.1 µM epibatidine. The sections were then air-dried and apposed to Hyperfilm -Max (Amersham, Mt.
Prospect, IL) for 2-4 d together with
125I standards.
[125I]RTI-121
autoradiography.
3-(4-[125I]iodophenyl)tropane-2-carboxylic
acid isopropyl ester ([125I]RTI-121;
2200 Ci/mmol; NEN, Boston, MA) was used to identify DA transporters
(Quik et al., 2000c). Thawed sections were preincubated in buffer
containing (in mM): 50 Tris-HCl, pH 7.4, 120 NaCl, and 5 KCl two times for 15 min at RT. This was followed by a 2 hr incubation in the same buffer, also containing 0.025% BSA, 1 µM fluoxetine, and 50 pM
[125I]RTI-121. The sections were washed
four times for 15 min at 4°C in preincubation buffer, dipped in
ice-cold water, air-dried, and placed against Hyperfilm -film for
1-3 d with 125I-microscale standards. The
uptake inhibitor nomifensine (100 µM) was used
to define nonspecific binding. There was no binding of the radiolabel
to the tissue sections in the presence of nomifensin, with blank
binding being identical to the film background.
Quantitation and data analysis. The squirrel monkey
(Saimiri sciureus) atlas of Emmers and Akert (1963) was used
for identification of the different brain regions. Nissl-stained
sections were used to identify brain areas. The area delineating the
appropriate regions was quantitated using computer-assisted
densitometry (ImageQuant; Molecular Dynamics, Sunnyvale, CA) under
standardized light and power conditions. Optical densities of the film
images were determined by subtracting background from tissue values.
The optical density values were converted to femtomoles per milligram
of tissue by interpolation from standard curves that were generated
from 125I standards exposed with the
tissue sections. The sample optical density readings for both the
receptor and transporter data were within the dynamic (linear) range of
the film. The saturation and competition data represent the results of
three or four experiments, using one or two tissue sections per
experiment for each concentration of radiolabeled
125I--CtxMII (saturation) or competing
ligand. In all other experiments, the value for the receptor binding
for any brain region per monkey was obtained by taking the average
value from two to four independent experiments, with one or two
consecutive tissue sections used in each experiment. All values are
expressed as the mean ± SEM of the indicated number of animals. For
statistical analysis, data were evaluated by Student's t
test, where p  0.05 was considered significant. For
saturation experiments, the Kd and
Bmax values were determined using
GraphPad Prism (San Diego, CA). Values for Ki (inhibition binding constant) were
derived by the method of Cheng and Prusoff (1973) using the equation
Ki = IC50/1 ± (L/Kd) and the GraphPad Prism program. The data
are expressed as mean ± SEM and were compared using Student's
t test or one-way ANOVA followed by Newman-Keuls multiple
comparison test.
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RESULTS |
125I--CtxMII binding sites are present in the
visual, habenular-interpeduncular, and dopaminergic systems in control
monkey brain
The autoradiographic distribution
125I--CtxMII binding at different
rostral to caudal levels of the monkey brain is illustrated in Figure
1. The highest specific
125I--CtxMII binding was obtained in
the habenular-interpeduncular pathway (Table
1). Prominent labeling was also observed
in the supraoptic decussation, superior colliculus, and lateral
geniculate nucleus, areas associated with the visual system. Moderate
expression was detected in the nigrostriatal dopaminergic pathway, with
greater binding in the caudate and putamen than substantia nigra.
Similar levels of binding were observed in mesolimbic dopaminergic
areas, including the nucleus accumbens, olfactory tubercle, and ventral tegmental area. In addition, binding was identified at low levels in
various cortical areas, hippocampus, and septum (Table 1). Whiteaker et
al. (2000a) obtained a similar distribution in mouse brain, although
the intensity of expression in different brain areas appears to vary
somewhat in the two species.
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Figure 1.
Autoradiographic distribution of
125I--CtxMII binding in control monkey brain. Expression
is observed predominantly in the nigrostriatal and visual systems, as
illustrated by representative sections throughout the brain (14.0 mm
anterior to the interaural line, A14.0; 12.0 mm, A12.0; 5.0 mm,
A5.0; and 2.0 mm, A2.0). Nonspecific
125I--CtxMII (CTX-NS) binding using 0.1 µM epibatidine is depicted in the set of brain sections
at the left, total 125I--CtxMII
(CTX-Total) binding is in the
center, and dopamine transporter
(DAT) binding
([125I]RTI-121) is at the right.
Cd, Caudate; Cx, cortex;
LG, lateral geniculate nucleus; IP,
interpeduncular nucleus; MH, medial habenula;
NA, nucleus accumbens; OT, olfactory
tubercle; Put, putamen; SN, substantia
nigra; SC, superior colliculus; SOD,
supraoptic decussation; VTA, ventral tegmental area.
Scale bar, 1.0 cm.
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125I--CtxMII binds to receptors with nicotinic
characteristics in control monkey brain
Because of our interest in the nigrostriatal system, we focused on
the monkey caudate and putamen for the characterization work.
Saturation analysis (Fig. 2) showed that
the binding of 125I--CtxMII plateaued
with a Kd of 0.93 ± 0.14 nM
(n = 4) and 0.92 ± 0.14 nM
(n = 4) for the caudate and putamen, respectively, and a Bmax for caudate of 2.28 ± 0.30 fmol/mg tissue (n = 4) and for putamen of
1.93 ± 0.13 fmol/mg tissue (n = 4).
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Figure 2.
Saturation binding of
125I--CtxMII to monkey caudate and putamen. Sections
were incubated with concentrations of 125I--CtxMII
ranging from 0.1 to 6.0 nM for 2 hr. Data points are means
from four experiments. For the caudate, the
Kd = 0.93 ± 0.14 nM (n = 4), and the
Bmax = 2.28 ± 0.30 fmol/mg tissue
(n = 4); for the putamen, the
Kd = 0.92 ± 0.14 nM
(n = 4), and the
Bmax = 1.93 ± 0.13 fmol/mg tissue
(n = 4).
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The potency of different drugs for inhibiting
125I--CtxMII binding in the caudate and
putamen was subsequently examined (Table 2). Competition studies showed that
125I--CtxMII binding was displaced by
picomolar concentrations of epibatidine (0.08 ± 0.03 nM, n = 4), and low nanomolar
concentrations of cytisine (2.01 ± 0.40 nM, n = 3) and nicotine
(2.87 ± 0.21 nM, n = 4).
Although the pharmacological characteristics of
125I--CtxMII sites in the monkey brain
closely resemble those in the rodent, they were not identical. The
Ki for epibatidine in the monkey
caudate putamen (0.08 nM) was similar to that in
the rodent striatum (0.11 nM). However, the
Ki for cytisine (2.01 nM) and nicotine (2.87 nM)
in monkey caudate putamen were very similar to each other, in contrast
to rodent striatum in which the values were significantly higher (23 nM for cytisine and 348 nM
for nicotine) and also an order of magnitude different (Whiteaker et
al., 2000a).
The nonselective nicotinic blocker D-tubocurarine inhibited
125I--CtxMII binding in the high
nanomolar range (263 ± 115, n = 3) in monkey
striatum. Thus D-tubocurarine appears to interact with a
somewhat higher affinity at nicotinic receptors labeled by -CtxMII
as compared with other nicotinic receptor sites (Marks and Collins,
1982; Schwartz et al., 1982; Davila-Garcia et al., 1997; Whiteaker et
al., 2000b). Alternatively, it may indicate a species difference
between primates and rodents. This observation, together with the
finding described above that cytisine and nicotine exhibit a similar
Ki, may suggest that
-CtxMII-sensitive sites in the monkey striatum represent a unique
population of nicotinic receptors.
The 7 receptor antagonist -bungarotoxin had no effect up to a
concentration of 0.1 µM, nor did the muscarinic
antagonist atropine (at concentrations up to 100 µM).
These experiments, together with the results of the saturation
analysis, suggest that 125I--CtxMII
binds to a site(s) in monkey caudate and putamen with the
characteristics of an nAChR.
MPTP treatment results in nigrostriatal damage and
motor deficits
Monkeys were treated with the neurotoxin MPTP to selectively
damage the dopaminergic nigrostriatal system. The animals fell into two
groups, those with moderate and those with more severe nigrostriatal
damage that was assessed using the dopamine transporter as a
biochemical marker for the effectiveness of MPTP treatment (Figs.
3, 4,
5).
[125I]RTI-121 binding was reduced
to 28 and 23% of control in the caudate and putamen, respectively, in
the moderate group and to 5% in both these regions in the severely
lesioned animals (Fig. 4). The DA transporter levels in the substantia
nigra were reduced to 56 and 49% of control in the moderate and severe
group, respectively (Fig. 5).
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Figure 3.
Autoradiographic images showing the effect of MPTP
administration on 125I--CtxMII binding and the DA
transporter in caudate putamen. Monkeys were treated with saline
(CON) or MPTP as described in Materials and
Methods and killed 4 weeks later. Note the dramatic reduction in
125I--CtxMII binding after MPTP treatment in parallel
with the loss of dopamine transporter. Cd, Caudate;
Put, putamen.
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Figure 4.
Quantitative assessment of the decline in
125I--CtxMII binding and the DA transporter in monkey
caudate and putamen after moderate (Mod) and severe
(Sev) nigrostriatal damage. Each value represents the
mean ± SEM of five to seven monkeys. Significance of difference
from control: ***p 0.001.
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Figure 5.
125I--CtxMII binding and the
DA transporter in monkey substantia nigra after moderate
(Mod) and severe (Sev) nigrostriatal
damage. Each value represents the mean ± SEM of four to five
monkeys. The declines in 125I--CtxMII binding were
similar to those obtained for the DA transporter. Significance of
difference from control: **p 0.01;
***p < 0.001.
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To evaluate the behavioral effects of MPTP treatment, animals were
tested for the development of parkinsonism and alterations in baseline
motor activity. The animals with moderate nigrostriatal damage
exhibited very mild parkinsonism (1.57 ± 0.32). However, they
showed a 39% decline in spontaneous locomotor activity (most likely
reflecting bradykinesia and hypokinesia), a finding suggesting that
measurement of motor activity using infrared activity monitoring may be
a more sensitive index of nigrostriatal damage. The animals with more
severe nigrostriatal damage had a more pronounced parkinsonian syndrome
(7.75 ± 0.89, of a total score of 20) with locomotor activity
diminished by 91%. The control animals did not exhibit parkinsonian
features, and their locomotor activity was similar to the pretreatment
saline value.
MPTP treatment decreases 125I--CtxMII binding in
caudate, putamen, and substantia nigra
The effect of MPTP-induced nigrostriatal damage on
125I--CtxMII binding in the caudate and
putamen is depicted in the autoradiograms in Figure 3 and quantitated
in Figure 4. In the severely lesioned group,
125I--CtxMII binding is eliminated,
whereas the dopamine transporter is reduced to ~5% of control. In
the animals with the moderate MPTP lesion, the DA transporter and
125I--CtxMII binding were 28 and 5% of
control, respectively, in the caudate, and 23 and 7% of control,
respectively, in the putamen. As is evident, the decline in
125I--CtxMII binding in caudate and
putamen was significantly greater than the decrease in the dopamine
transporter (p < 0.05), an observation suggesting that the toxin binding sites are present on a more vulnerable population of nigrostriatal dopaminergic neurons.
Consistent with previous work (Quik et al., 2000c), declines in the DA
transporter were substantially less severe in the substantia nigra than
in the caudate putamen after MPTP treatment (Fig. 5). 125I--CtxMII binding sites in the
substantia nigra decreased to a similar extent as the DA transporter.
In the moderately lesioned animals, binding was reduced to 61% of
control, and binding of the DA transporter was reduced to 56% of
control. For the severely lesioned animals, binding sites were
decreased to 50% of control, and the transporter was decreased to 49%
of control.
The MPTP-induced decline in 125I--CtxMII binding
occurs only in the basal ganglia
Despite an almost complete disappearance of sites in the caudate
and putamen and an approximate 50% reduction in the substantia nigra,
there were no declines in 125I--CtxMII
binding sites after MPTP treatment in other brain areas at similar
anatomical levels (Table 3). This
includes the interpeduncular nucleus, medial habenula, and lateral
geniculate nucleus, regions that are located at a similar level as the
substantia nigra (A5.5 to A4.0). Similarly, there are no changes
in the supraoptic decussation present at the level of the caudate
putamen (A13.0 to A11.0). These results indicate that the effects of
the lesion were selective for the basal ganglia.
Correlation between 125I--CtxMII binding sites and
the DA transporter in basal ganglia in control and lesioned animals
suggests a presynaptic localization
As an approach to assessing the relationship between
125I--CtxMII binding sites and the DA
transporter in the caudate, putamen, and substantia nigra, correlation
analysis was performed for control and MPTP-lesioned animals (Fig.
6). The results show that there was a
good correlation between 125I--CtxMII
binding sites and the DA transporter in both the caudate putamen
(R2 = 0.80; p < 0.001) and substantia nigra
(R2 = 0.75; p < 0.001).
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Figure 6.
Correlation between the distribution of the DA
transporter and 125I--CtxMII binding sites in the
caudate putamen (left) and the substantia nigra
(right). For the caudate putamen, each
symbol represents the mean values for 7 control and 12 MPTP-treated animals. For the substantia nigra, the symbols
represent the mean values for four control and nine MPTP-treated
animals.
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DISCUSSION |
The present results are the first to investigate the localization
of 125I--CtxMII sites in monkey brain.
They show that 125I--CtxMII binds to an
apparently homogenous population of high-affinity (Kd = 0.92 nM)
nAChRs. The areas expressing
125I--CtxMII sites are similar to those
in the rodent (Whiteaker et al., 2000a), although the intensity of
binding in the various regions differs between the two species. In
monkey, the habenular-interpeduncular system exhibited the greatest
125I--CtxMII binding, followed by areas
associated with vision, with similar binding in the nigrostriatal and
mesolimbic dopaminergic systems. In contrast, in rodents, the highest
expression of 125I--CtxMII sites is in
the visual system (Whiteaker et al., 2000a), with a similar intensity
of binding in the habenular-interpeduncular pathway and the mesolimbic
dopaminergic system, but a somewhat lower expression in the
nigrostriatal pathway. These variations in expression between species
are not uncommon (Quik et al., 2000a,b) and may reflect differences in
the relative functional roles of these systems, for instance, the
visual system in the rodent as compared with the monkey.
The present data show that the lesion-induced declines in
125I--CtxMII sites parallel those in
the DA transporter in both the caudate putamen and substantia nigra.
These data support the contention that
125I--CtxMII binding sites and the DA
transporter share a similar cellular localization, specifically
nigrostriatal dopaminergic neurons. The observation that the decline in
125I--CtxMII sites is somewhat greater
than that in the DA transporter most likely reflects a greater
vulnerability to MPTP of the dopaminergic neurons on which the
125I--CtxMII sites reside (Schneider et
al., 1987).
The marked declines in 125I--CtxMII
sites in caudate and/or putamen of moderately (93%) and
severely (100%) lesioned monkeys is in contrast to results obtained
with other radioligands in this brain area.
125I-epibatidine binding, which recognizes
2-6 subunits, is reduced by only 40-60% in animals with
moderate to severe nigrostriatal damage (Kulak and Quik, 2000; Quik et
al., 2000b), whereas 3H-cytisine, which
may be selective for a subset of
125I-epibatidine sites containing the 4
subunit, is reduced by only ~30% (our unpublished
observation). Furthermore, the sites labeled by
125I--bungarotoxin, which most likely
represent 7-containing nAChRs, are increased ~100% over control
in the caudate and putamen of severely lesioned animals (Kulak and
Quik, 2000). These observations suggest that
125I--CtxMII is binding to a unique
nAChR population in the caudate and/or putamen that appears to
be exclusively located on dopaminergic neurons, in contrast to other
nAChR subtypes that show a differential localization possibly on other
neurotransmitter afferents and/or postsynaptically on GABAergic or
cholinergic interneurons.
A question arises in regard to the nAChR subtype(s) identified
by 125I--CtxMII in monkey basal
ganglia. Electrophysiological studies in oocytes expressing nAChRs,
binding experiments in nAChR transfected cell lines, and work using
rodent brain slices or synaptosomes indicate that -CtxMII acts on
3 and/or 6-containing receptors (Cartier et al., 1996; Kulak et
al., 1997; Luo et al., 1998; McIntosh et al., 1999; Vailati et al.,
1999; Kuryatov et al., 2000; Whiteaker et al., 2000a). In the monkey,
the 3 receptor subunit mRNA appears to be expressed at very low
levels in substantia nigra (our unpublished observations) or not
at all (Han et al., 2000), whereas the 6 transcript is very
prominently localized primarily to the substantia nigra (Han et al.,
2000; Quik et al., 2000a,b), similar to the rodent (Le Novere et al.,
1996). These results suggest that the receptors identified by
125I--CtxMII in monkey basal ganglia
contain primarily the 6, rather than 3 nicotinic receptor subunit.
The subunits with which the 6 (and/or possibly 3) subunit
combine to form functional receptors may include 2 and/or 3. Evidence for this stems from rodent studies showing that 3 subunit knockout mice exhibit a decreased binding in
125I--CtxMII, whereas animals not
expressing the 2 subunit show a complete absence of
125I--CtxMII sites (Allen et al., 1998;
Whiteaker et al., 1998). These data suggest that receptors composed of
62 and/or 623 subunits are expressed in monkey basal
ganglia. With respect to a functional role of 6-containing
receptors, the recent work of Le Novere et al. (1999) indicates that
intraventicular administration of 6 antisense to rats modulates
locomotor activity, possibly by decreasing receptors containing the
6 nicotinic subunit. These data suggest that 6-containing nAChRs
may be involved, at least in part, in motor control mediated through
the nigrostriatal pathway.
In summary, this study shows that
125I--CtxMII binds to a high-affinity
nAChR population, likely containing the 6 subunit. The decline in
125I--CtxMII binding sites after
nigrostriatal damage is selective to the basal ganglia with no changes
in other brain areas. The decrease in binding occurs in parallel with
changes in the DA transporter, a marker of dopaminergic neuron
integrity. This observation suggests that
125I--CtxMII sites are selectively
localized to dopaminergic neurons in the basal ganglia. The
dopaminergic neurons with 125I--CtxMII
binding sites may be particularly vulnerable to the effects of MPTP
because the decrease in toxin binding is generally more severe than
that in the DA transporter. These results suggest that receptor ligands
directed to 6-containing nAChRs may be important for Parkinson's
disease therapy to restore motor function and/or protect against
nigrostriatal damage.
| |
FOOTNOTES |
Received Feb. 6, 2001; revised April 30, 2001; accepted May 8, 2001.
This work was supported by the California Tobacco Related Disease
Research Program Grant TRDRP 7RT-015 (M.Q.), National Institute on Drug
Abuse Grant DA12242 (J.M.M.), National Institute of Mental Health Grant
MH53631 (J.M.M.), and National Institute of General Medical Sciences
Grant GM48677 (J.M.M.).
Correspondence should be addressed to Dr. Maryka Quik, The
Parkinson's Institute, 1170 Morse Avenue, Sunnyvale, CA 94089. E-mail:
mquik{at}parkinsonsinstitute.org.
| |
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C. Dowell, B. M. Olivera, J. E. Garrett, S. T. Staheli, M. Watkins, A. Kuryatov, D. Yoshikami, J. M. Lindstrom, and J. M. McIntosh
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M. Quik, T. Bordia, M. Okihara, H. Fan, M. J. Marks, J. M. McIntosh, and P. Whiteaker
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[Abstract]
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M. Quik, J. D. Sum, P. Whiteaker, S. E. McCallum, M. J. Marks, J. Musachio, J. M. Mcintosh, A. C. Collins, and S. R. Grady
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J. M. Kulak, J. L. Musachio, J. M. McIntosh, and M. Quik
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P. Whiteaker, C. G. Peterson, W. Xu, J. M. McIntosh, R. Paylor, A. L. Beaudet, A. C. Collins, and M. J. Marks
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J. M. Kulak, J. M. McIntosh, and M. Quik
Loss of Nicotinic Receptors in Monkey Striatum after 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine Treatment Is Due to a Decline in alpha -Conotoxin MII Sites
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TOP
ABSTRACT
INTRODUCTION
