 |
 Previous Article | Next Article 
The Journal of Neuroscience, June 15, 1999, 19(12):4804-4814
Upregulation of Surface  4 2 Nicotinic Receptors Is Initiated
by Receptor Desensitization after Chronic Exposure to Nicotine
Catherine P.
Fenster,
Terri L.
Whitworth,
Elise B.
Sheffield,
Michael W.
Quick, and
Robin A. J.
Lester
Department of Neurobiology, University of Alabama at Birmingham,
Birmingham, Alabama 35294
 |
ABSTRACT |
It is hypothesized that desensitization of neuronal nicotinic
acetylcholine receptors (nAChRs) induced by chronic exposure to
nicotine initiates upregulation of nAChR number. To test this hypothesis directly, oocytes expressing  4 2 receptors were
chronically incubated (24-48 hr) in nicotine, and the resulting
changes in specific [3H]nicotine binding to
surface receptors on intact oocytes were compared with functional
receptor desensitization. Four lines of evidence strongly support the
hypothesis. (1) The half-maximal nicotine concentration necessary to
produce desensitization (9.7 nM) was the same as that
needed to induce upregulation (9.9 nM). (2) The
concentration of [3H]nicotine for half-maximal
binding to surface nAChRs on intact oocytes was also similar (11.1 nM), as predicted from cyclical desensitization models. (3)
Functional desensitization of 34 receptors required 10-fold
higher nicotine concentrations, and this was mirrored by a 10-fold
shift in concentrations necessary for upregulation. (4) Mutant 42
receptors that do not recover fully from desensitization, but not
wild-type channels, were upregulated after acute (1 hr) applications of
nicotine. Interestingly, the nicotine concentration required for
half-maximal binding of 42 receptors in total cell membrane
homogenates was 20-fold lower than that measured for surface nAChRs in
intact oocytes. These data suggest that cell homogenate binding assays
may not accurately reflect the in vivo desensitization
affinity of surface nAChRs and may account for some of the previously
reported differences in the efficacy of nicotine for inducing nAChR
desensitization and upregulation.
Key words:
nicotine addiction; Xenopus oocytes; regulation; ion channel; radiolabeled binding; nicotinic receptor
subtypes; CNS
| |
INTRODUCTION |
Neuronal nicotinic acetylcholine
receptors (nAChRs) are ligand-gated cation channels activated by the
endogenous neurotransmitter acetylcholine and exogenous drugs, such as
nicotine (Role, 1992 ; Sargent, 1993). The effect of both acute and
chronic nicotine on the activity of different nAChR subtypes may be
relevant to tolerance, dependence, and withdrawal symptoms associated
with nicotine addiction (Wonnacott, 1990; Balfour, 1994; Dani and
Heinemann, 1996). One result of chronic exposure to tobacco-related
levels of nicotine (Benowitz et al., 1989) is the upregulation of
high-affinity 42 subunit-containing
[3H]nicotine binding sites in the CNS (Marks et
al., 1983; Benwell et al., 1988; Flores et al., 1992, 1997; Breese et
al., 1997). Such upregulation of receptor number may contribute to the
addiction process. The mechanism by which chronic nicotine exposure
leads to receptor upregulation is not known.
In addition to upregulation of receptor number, chronic nicotine
exposure can be associated with a long-lasting downregulation in
receptor responsiveness (Lukas, 1991; Marks et al., 1993; Peng et al., 1994; Hsu et al., 1996). This decrease in function is thought
to be, at least in part, a consequence of agonist-induced desensitization (Boyd, 1987). In addition, nicotine-induced receptor desensitization has been hypothesized to be responsible for receptor upregulation (Marks et al., 1983; Schwartz and Kellar, 1985). A
straightforward prediction of this hypothesis is that nicotine concentrations that produce receptor desensitization should also induce
receptor upregulation. Results of several studies suggest this
prediction to be false, because nicotine concentrations necessary to
induce desensitization and upregulation can differ by several orders of
magnitude (Peng et al., 1994; Bencherif et al., 1995; Whiteaker et al.,
1998). However, these conclusions are based on several assumptions.
First, that agonist equilibrium binding assays accurately assess the
desensitized state(s) of the receptor. This may not be true. Agonist
dose-dependencies for equilibrium binding and functional estimates of
desensitization can differ by several orders of magnitude (Marks et
al., 1996); such differences would account for the apparent nicotine
concentration mismatch between measures of desensitization and
upregulation. Second, agonist binding measured in standard membrane
homogenization assays are assumed to reflect agonist binding to
functional intact receptors, although some evidence suggests that this
is not true (Whiteaker et al., 1998).
A more direct test of the prediction would be to assess desensitization
functionally and compare this result with receptor upregulation
measured by agonist binding to intact, cell-surface receptors. In the
present study, 42 nAChRs expressed in Xenopus oocytes
were chronically incubated in nicotine. Nicotine dose-response relationships were constructed for functional receptor desensitization and for receptor upregulation assessed by surface
[3H]nicotine binding to intact oocytes. To further
examine the hypothesis that nicotine-induced receptor desensitization
is responsible for receptor upregulation, we also tested the
predictions that nAChRs with lower affinities for functional
desensitization will also have a lower affinity for receptor
upregulation and that mutant 42 nAChRs that fail to recover fully
from desensitization will upregulate after the removal of nicotine.
| |
MATERIALS AND METHODS |
Xenopus oocyte preparation and cRNA injection.
Procedures for preparation of oocytes have been described in detail
previously (Quick and Lester, 1994). Briefly, oocytes were
defolliculated and maintained at 18°C in incubation medium containing
ND96 (96 mM NaCl, 2 mM KCl, 1 mM
MgCl2, and 5 mM HEPES, pH 7.4), 1.8 mM CaCl2, 50 µg/ml gentamycin, and 5%
horse serum. Subunit cRNAs were synthesized in vitro
(Message Machine; Ambion, Austin, TX) from linearized plasmid templates
of rat cDNA clones. A mutant 4 subunit (4
S336A) was created in which a PKC consensus serine
phosphorylation site was mutated to alanine (pALTER 1; Promega,
Madison, WI). The mutation was verified by sequencing (Fenster et al.,
1999). Oocytes were injected with 25 ng of cRNA/subunit/oocyte; and subunit cRNAs were injected in 1:1 ratios. All salts and drugs were
obtained from Sigma (St. Louis, MO).
Electrophysiology. Whole-cell currents were measured at room
temperature (20-25°C), 24-120 hr after injection, with a GeneClamp 500 amplifier (Axon Instruments, Foster City, CA) in a standard two-microelectrode voltage-clamp configuration. Electrodes were filled
with 3 M KCl and had resistances of 0.5-2 M . Oocytes
were clamped between  40 and 60 mV and superfused continuously in ND96 containing 1.8 mM CaCl2 (ND96+Ca).
Nicotine was applied in these solutions. ()-Nicotine tartrate
(nicotine) was prepared from frozen stock solutions. All currents were
recorded on a chart recorder and/or on an 80486-based computer with
AxoScope software (Axon Instruments) after 50-100 Hz low-pass
filtering at a digitization frequency of 200 Hz. Solutions were gravity
fed via a six-way manual valve (Rainin Instruments, Woburn, MA) to the
oocyte in the recording chamber. Solution exchange considerations are
discussed by Fenster et al. (1997).
Criteria for functional data selection. Except for the
experiments shown in Figure
1B, oocytes with
initial nicotinic response amplitudes >3 µA and <50 nA were not
included in the data analysis. Additionally, responses were required to
be at least twofold greater than the holding current, and the holding
current at a given membrane potential was required to be <100 nA.
Functional receptor desensitization is usually calculated as the
reduction in response amplitude induced by a brief test pulse of
agonist after a period of continuous incubation with the desensitizing
agent (Katz and Thesleff, 1957: Feltz and Trautman, 1982). However,
because of the long incubations (24-48 hr) in the present
study, it is necessary to correct this measurement for any
time-dependent changes in basal receptor expression-function that
occur independent of nicotine exposure. Thus, response amplitudes in
control oocytes from the same batch (not incubated in nicotine) were
monitored over the same period. For each oocyte incubated in nicotine
(nic), the fractional desensitization was calculated as the ratio of
the current amplitude (I) at time
(t) to the initial current amplitude at t = 0,  nic = Inic(t)/Inic(t=0). This value was then normalized for changes in control receptor function, con = Icon(t)/Icon(t=0),
obtained from control (con) oocytes (see Fig. 3). Thus, the overall
estimate of desensitization was calculated as
nic/con (see Fig. 3). For statistical comparison of mean data, weighted means t tests
were performed.
View larger version (14K):
[in this window]
[in a new window]
|
Figure 1.
Specific [3H]nicotine binding
to intact oocytes. Oocytes were injected with 4 and 2 subunit
cRNAs and assayed 3 d after injection. A,
[3H]Nicotine binding is saturable. Individual
42-expressing oocytes were incubated in various
[3H]nicotine concentrations (0, 0.3, 1, 3, 10, 30, 100, and 300 nM) for 60 min.
[3H]Nicotine binding was determined in the absence
(total [3H]nicotine binding, open
squares) or presence (nonspecific
[3H]nicotine binding, open circles)
of 100 µM nonradiolabeled acetylcholine. Specific
[3H]nicotine binding (filled
squares) was determined by subtracting nonspecific counts from
total counts. Each data point represents the measurement of five to six
oocytes; for clarity, the mean ± SEM across all nicotine
concentrations is plotted with the symbols at the 300 nM
nicotine value. B, Specific
[3H]nicotine binding is correlated with
nicotine-induced currents. 42-expressing oocytes were
voltage-clamped at 40 mV, and peak currents were elicited using 100 µM nicotine. Specific surface
[3H]nicotine binding was then determined in these
same oocytes by incubation in 60 nM
[3H]nicotine for 1 hr. The correlation for these
two measurements was 0.94.
|
|
[3H]nicotine binding assays. Binding
assays were performed on both intact oocytes and on oocyte membranes
after homogenization. Binding to intact oocytes was performed
essentially as described previously (Chang and Weiss, 1999). Uninjected
oocytes or nAChR-injected oocytes were visually inspected to ensure
that collagenase treatment (2 mg/ml; Type A; Boehringer Mannheim,
Indianapolis, IN) successfully removed follicle cells from around the
oocyte membrane. The presence of the follicle layer resulted in high,
nonspecific [3H]nicotine labeling that prevented
accurate assessment of specific [3H]nicotine
binding (our unpublished observations). The oocytes were removed
from incubation media and rinsed in ND96+Ca for several minutes.
Individual oocytes were next placed in a single well of a 96-well plate
containing 40 µl of ND96+Ca. Stocks (5×) of [3H]nicotine
[()-[N-methyl-3H]nicotine; 82.0 Ci/mmol;
DuPont-NEN, Boston, MA] were prepared by dilution in ND96+Ca.
The assay (60 min at room temperature) was initiated with the addition
of 10 µl of 5× [3H]nicotine to the well,
followed by gentle trituration of the media for several seconds so as
not to disrupt the integrity of the cell. The assay was terminated in
one of two ways: the oocyte was either suspended from the cut end of a
pipette tip by light suction or pipetted into the cut end of a pipette
tip along with 4 µl of assay solution. In the former case, the oocyte
was then submerged sequentially into four different 2.5 ml wells
containing ice-cold ND96+Ca. The total wash time for all four wells was
16 sec (4 sec/well). In the latter case, the oocyte was dropped into each wash well and repipetted into the next well. Based on a set of
control experiments, the total wash time for all four wells was
18.8 ± 2.1 sec (n = 15 trials). Radioactivity was
measured in one of two ways. After the final wash, the oocyte was
placed directly into a scintillation vial containing nonaqueous liquid scintillation cocktail (Scintisafe F; Fisher Scientific, Houston, TX).
The amount of radioactivity was estimated within 2 min of the wash
step. In some experiments after washing, the oocyte was placed in one
well of a 96-well plate containing ND96+Ca, and the bound
[3H]nicotine was allowed to dissociate (see below;
Fig. 2C). The contents of each
well were then subjected to liquid scintillation counting. Where
compared, these two methods yielded similar results. Oocyte batches in
which nonspecific [3H]nicotine binding to
uninjected oocytes was higher than 100 cpm were not used in data
collection; based on this constraint, ~30% of the oocyte batches
were usable.
View larger version (14K):
[in this window]
[in a new window]
|
Figure 2.
Upregulation of surface 42 receptors after
chronic nicotine incubation. A, Specific
[3H]nicotine binding to intact oocytes is
upregulated by nicotine. Oocytes were uninjected (open
bars) or injected (filled bars) with 4
and 2 subunit cRNAs. Twenty-four hours later, oocytes were placed in
ND96+Ca with (two right-most bars) or without 60 nM nicotine. Surface binding assays were performed 24 hr
later using 60 nM [3H]nicotine.
Nonradiolabeled ACh (60 µM) was used on some oocytes to
determine nonspecific binding. Data are from five oocytes per
condition. B, Upregulation is nicotine
concentration-dependent. 42-expressing oocytes were incubated in
various nicotine concentrations for 24 hr and then subjected to [3H]nicotine
binding assays using 60 nM
[3H]nicotine. A dose-response curve was then
constructed from the relative increase in specific
[3H]nicotine binding at each nicotine incubation
concentration. Data are plotted as the amount of specific
[3H]nicotine binding for oocytes incubated in
nicotine compared with the specific [3H]nicotine
binding for control oocytes not incubated in nicotine
(n = 4-9 oocytes per data point).
C, Nicotine dissociates rapidly from chronically
incubated oocytes. 42-expressing oocytes were incubated in 300 nM [3H]nicotine for 24 hr.
Dissociation of bound [3H]nicotine was determined
as described in Materials and Methods and plotted with respect to time.
The solid line is an exponential fit to the data
(n = 3 oocytes).
|
|
Specific [3H]nicotine binding and channel
function. Direct comparison of functional desensitization and
receptor upregulation in intact oocytes has three requirements: that we
can accurately measure specific [3H]nicotine
binding; that the measures of specific binding correlate with
functional expression; and that the measured binding is occurring only
on surface nAChRs. Control experiments demonstrating measurement of
specific [3H]nicotine binding are shown in Figure
1A. Oocytes expressing 42 nAChRs were incubated
for 1 hr in various concentrations of
[3H]nicotine. Specific binding was calculated as
the total counts per minute minus the nonspecific counts per
minute; nonspecific counts per minute was defined as the counts per
minute of oocytes measured in the presence of 100 µM
unlabeled acetylcholine. These data show that
[3H]nicotine binding to intact oocytes is
saturable and that nicotinic receptor agonists are competitive with
[3H]nicotine binding. Figure 1B
shows that 42 nAChRs currents activated by saturating
concentrations of nicotine (100 µM) and subsequent
[3H]nicotine binding (60 nM) to the
same intact oocyte are highly correlated (r = 0.94).
From the slope of the regression fit (37 nA/cpm), it is possible to
calculate the number of bound nicotine molecules per functional channel. The number of functional channels can be estimated from the
ratio of the measured peak current to the single channel current, assuming that all the channels are open at the peak. The single channel
current will be 0.8 pA at 60 mV using a single channel conductance of
13.3 pS (Papke et al., 1989). Thus, there will be ~4.625 *
104 nAChR channels/cpm. The number of bound nicotine
molecules per counts per minute was estimated as 6.12 *
106 from the following:
|
(1)
|
where SA is the specific activity of
[3H]nicotine in Curie per moles,  is the factor
for converting disintegrations per second to counts per minute
with a counting efficiency of 0.54, and NA is
Avagadro's number. Thus, these data predict 132 molecules of nicotine
for each functional channel. Assuming that two molecules of nicotine
bind per channel, these data imply that only ~2% channels are
functional. In terms of a single oocyte with ~300 cpm (Fig. 1B), the number of bound
[3H]nicotine molecules would be ~1.8 *
109, corresponding to ~109
total receptors, of which ~2 * 107 would be
functional. Because of some nonspecific binding in this instance, and a
likely underestimation of the number of channels as a result of
noninstantaneous solution-exchange, this will be a lower limit for the
percentage of functional channels. With ~20% nonspecific binding
(Fig. 2A) and assuming only one-third of channels are
open at peak, the number of functional channels could be ~6%.
Similar discrepancies between toxin binding and channel conductance
have been noted for sodium channels (Ritchie and Rogart, 1977). For
nAChRs reported here, the excess silent receptors could represent a
reserve pool and/or desensitized receptors (Margiotta et al., 1987;
Bencherif et al., 1995). Because 42 nAChRs can enter persistently
inactive conformations after chronic nicotine treatment (Lukas, 1991;
Peng et al., 1994), it is not unreasonable to suggest that such
conformations may pre-exist on the cell surface. Because of the strong
correlation between the amounts of total binding and currents (Fig.
1B), functional and silent receptor pools are likely
to be in equilibrium. Thus, despite the apparent excess of binding
sites, these data strongly support the suggestion that functional
nAChRs are a subpopulation of the receptor pool that is measured in a
binding assay.
[3H]nicotine labels surface receptors in
intact oocytes. Three sets of experiments were performed to verify
that the binding assays were measuring specific binding to surface
nAChRs (i.e., to eliminate the contribution of radioactivity associated
with internalized [3H]nicotine). Two experiments
were designed to test that the nonaqueous scintillation cocktail was
only counting external [3H]nicotine. (1)
Nonexpressing oocytes were injected with 5000 cpm (as determined by
previous scintillation counting of various [3H]nicotine aliquots). Intact oocytes were then
subjected to liquid scintillation counting. Some oocytes were then
crushed and recounted; others were removed from the nonaqueous
scintillation cocktail and placed in aqueous scintillation cocktail
(Scintisafe Econo 1; Fisher Scientific). The crushed oocytes and the
intact oocytes counted in aqueous scintillation cocktail revealed
radioactive emissions of ~5000 cpm; the intact oocytes measured in
nonaqueous scintillation cocktail revealed radioactive emissions of
~20 cpm (0.004% of total injected counts; n = 6).
(2) [3H]Nicotine binding assays were performed on
oocytes expressing 42 nAChRs using 60 nM
[3H]nicotine. Specific binding was determined as
described above (Fig. 1A). One subset of oocytes
(n = 5) was counted by placing the intact oocyte in
nonaqueous scintillation cocktail; the counts from a second subset of
oocytes from the same oocyte batch were determined by permitting the
radioactivity to dissociate for 2 min into a well containing ND96+Ca
and counting the well contents. If a significant amount of
[3H]nicotine was internalized and subsequently
counted, then the counts from the intact oocyte should be much higher
than in the dissociation study. However, adjusting for the rate of
dissociation (see below; Fig. 2C), the number of counts
measured in the intact oocytes (167 ± 23 cpm; n = 7) was comparable with that counted by the dissociation method
(138 ± 30 cpm; n = 4).
Although these experiments suggested that internal radioactivity will
not be counted, a potential confound is that any nonspecific internal
accumulation of [3H]nicotine during a 1 hr
incubation would begin to leak back out of the oocyte between the end
of the assay and the scintillation counting step (~2 min). To examine
the contribution of this effect to our measurements, we put a known
number of counts of [3H]nicotine (corresponding to
300 nM [3H]nicotine, the highest
concentration we used in the experiments described in this paper) into
one well of a 96-well plate with one nonexpressing oocyte and
determined the amount of [3H]nicotine that
accumulated inside of the oocyte during 1 hr. This amount was between 6 and 11% of the starting external value and varied based on the oocyte
batch (three oocyte batches, seven oocytes per batch). We then injected
other nonexpressing oocytes with [3H]nicotine
corresponding to the number of counts internalized in 1 hr and
determined the number of counts that emerged from these oocytes in 2 min. At the highest concentrations tested, this amount corresponded to
9% of the injected counts. Thus, the maximum contamination
resulting from the re-emergence of internalized counts during an
assay would be ~1%.
These controls demonstrate that, although
[3H]nicotine will accumulate inside the oocyte
during a 1 hr assay, it will not be detected by counting intact oocytes
in nonaqueous scintillation cocktail. Any
[3H]nicotine that leaks back out will contribute
negligibly to the total number of counts. Thus, ACh-displacable
[3H]nicotine binding to intact oocytes will
primarily reflect surface membrane nAChR labeling.
Protocols for specific experiments involving intact oocytes.
Specific binding of [3H]nicotine to intact oocytes
was used to measure three different parameters. (1) To measure the
nicotine concentration necessary for half-maximal nAChR upregulation
after chronic nicotine incubation, oocytes were chronically incubated
(24-48 hr) in various concentrations of unlabeled nicotine. Assays
were performed as described above using final
[3H]nicotine concentrations of 60 nM
for 42 nAChRs and 300 nM for 34 nAChRs. (2) To
determine the nicotine concentration necessary for half-maximal
42 nAChR binding, assays were performed as described above; final
[3H]nicotine concentrations used ranged from 0.1 to 300 nM. For both the upregulation and equilibrium
binding assays performed on intact oocytes, nonspecific binding was
determined in the presence of 1000-fold excess of unlabeled
acetylcholine. (3) To estimate the dissociation rate of bound
[3H]nicotine, assays were performed as described
above using a final [3H]nicotine concentration of
60 nM. At the end of the assay, the oocyte was suspended
from the cut end of a pipette tip by light suction, washed sequentially
in four different 2.5 ml wells containing ice-cold ND96+Ca, and then
sequentially submerged (20 sec/well) into individual wells of a 96-well
plate containing ND96+Ca and 60 µM unlabeled ACh (at room
temperature). The contents of each well were then subjected to liquid
scintillation counting.
Preparation of total homogenized oocyte membranes. For
comparison, the concentrations of nicotine required for equilibrium binding and for receptor upregulation were also determined on oocyte
membranes after homogenization. For equilibrium binding assays using
cell homogenates, oocyte membranes were prepared as described
previously (Corey et al., 1994). Briefly, oocyte membranes were
isolated by centrifugation in 0.32 M sucrose in TE buffer
(50 mM Tris-HCl, pH 7.5, and 1 mM EDTA)
containing protease inhibitors (200 mM
phenylmethylsulfonylfluoride, 10 µg/ml aprotinin, and 10 µg/ml
leupeptin) using 10-15 strokes of a tight-fitting pestle in a chilled
Dounce homogenizer. The homogenate was centrifuged twice at 4°C, 5 min, 1000 × g to remove cell debris, and the remaining supernatant fraction was homogenized at 4°C, 30 min, 100,000 × g. The membrane pellet was resuspended in homogenization
buffer (50 mM Tris-HCl, pH 7.5, and 1 mM EDTA).
Equilibrium [3H]nicotine binding assays were
performed by adding various concentrations of
[3H]nicotine (0.1-10 nM) to the
resuspended membranes for 1 hr. Specific binding was determined in the
presence of excess ACh (60 µM). The assay was terminated
by filtration, using Whatman (Clifton, NJ) GFA filters soaked in
polyethyleneimine (0.3% w/v). The filters were washed three times and
subjected to liquid scintillation counting. Protein content was
determined by the method of Bradford. For receptor upregulation,
oocytes (16-20 per group) were incubated, before assay, in various
concentrations of nicotine (1-300 nM) for 24 hr. Membranes
were prepared as described above, and specific binding was estimated
using 60 nM [3H]nicotine. Upregulation
was expressed as the increase in binding relative to a control group.
| |
RESULTS |
42 nAChRs are upregulated after chronic
nicotine treatment
To directly compare the dose-dependency for nicotine-induced
upregulation of [3H]nicotine binding sites with
that of receptor desensitization, we performed binding assays (see
Materials and Methods) on intact oocytes with and without chronic
nicotine treatment. In a representative example (Fig.
2A), oocytes expressing 42 receptors showed
9.7-fold higher levels of surface [3H]nicotine
binding than uninjected oocytes. To determine the amount of specific
surface [3H]nicotine binding, we tested a subset
of 42-expressing oocytes in the presence of excess unlabeled ACh.
Unlabeled ACh reduced [3H]nicotine counts to
levels seen in uninjected control oocytes, permitting two conclusions:
(1) that the majority of the [3H]nicotine counts
were a result of specific binding to nAChRs, and (2) because ACh is a
membrane-impermeant agonist (Whiteaker et al., 1998), that the majority
of specific binding was associated with receptors on the plasma
membrane (see Materials and Methods). Treatment of 42-expressing
oocytes with 60 nM nicotine for 24 hr before assay resulted
in a 2.8-fold increase in [3H]nicotine binding
compared with 42-expressing oocytes not incubated in nicotine.
This increase in binding caused by nicotine incubation was not seen in
uninjected oocytes. Together, these data demonstrate that surface
42 nAChR expression is upregulated by chronic nicotine incubation. This result is likely attributable to an actual increase in
the number of surface receptors because chronic agonist treatment fails
to alter the apparent agonist binding affinity (Marks et al.,
1983).
Similar [3H]nicotine binding assays were repeated
after 24 hr chronic nicotine treatment using nicotine concentrations
ranging from 0.1 to 300 nM. Figure 2B
shows a dose-response curve constructed from the relative increases in
specific [3H]nicotine binding after chronic
nicotine treatment at eight different nicotine concentrations.
Half-maximal upregulation of 42 nAChR expression was calculated
to occur at nicotine incubation concentrations of 9.9 nM.
Chronic incubation using unlabeled nicotine raises a potential
confound; that is, the unlabeled nicotine must fully dissociate from
the receptor during the time of the binding assay. Otherwise, the
number of [3H]nicotine binding sites will be
underestimated. To rule out this possibility and to determine the rate
at which nicotine dissociates from 42 nAChRs, we performed an
agonist dissociation assay (Fig. 2C). Oocytes were incubated
in 300 nM [3H]nicotine for 24 hr. In
intact oocytes, dissociation (as described in Materials and Methods) of
[3H]nicotine from these receptors followed a
single exponential time course with a time constant of 65 sec (Fig.
1C), which is similar to previous estimates (Marks and
Collins, 1982; Lippiello et al., 1987). These data show that nicotine
fully dissociates from 42 receptors within minutes and suggest
that estimates of receptor upregulation after chronic nicotine
treatment are likely not to be underestimated.
42 nAChRs are desensitized after chronic
nicotine treatment
To test the prediction that the concentrations of nicotine
necessary for upregulation are similar to the nicotine concentrations necessary for desensitization, we measured desensitization functionally by two-electrode voltage clamp. Functional desensitization was assessed
by measuring the fraction of activable receptors remaining after a 24 hr nicotine incubation at concentrations ranging from 3 to 1000 nM. Changes in receptor responsiveness were estimated from
whole-cell response amplitudes to nicotine test pulses applied near the
EC50 for activation (10-20 µM) (Fenster et
al., 1997). Test pulses were administered before and immediately after
incubation in nicotine (Katz and Thesleff, 1957; Feltz and Trautmann,
1982). Example test pulses are shown in Figure
3A. As illustrated in the
traces from oocytes not treated with nicotine, control
responses were often larger when measured 24 hr later (e.g., because of continual protein synthesis). To account for changes in whole-cell receptor responses, which were independent of nicotine and occurred over the incubation time period, the fractional response remaining after 24 hr nicotine incubation was normalized to that of control oocytes not incubated in nicotine (see Materials and Methods).
View larger version (17K):
[in this window]
[in a new window]
|
Figure 3.
Functional desensitization of 42 nAChRs
after chronic nicotine incubation. A, Representative
traces measured before and after incubation. Peak
currents in 42-expressing oocytes induced by a nicotine test
pulse (10 µM, 5 sec) were measured. The oocyte was then
incubated for 24 hr in ND96+Ca in the absence (top
traces) or presence (bottom traces) of 60 nM nicotine. Peak currents were remeasured immediately
after removal from 24 hr incubation. To account for changes in basal
receptor expression over the 24 hr incubation (top
traces), the magnitude of nicotine-induced desensitization was
defined as the ratio of the fractional response remaining after
nicotine exposure to the fractional response remaining over the same
period of time in the absence of nicotine (see Materials and Methods).
B, Representative fractional nicotine-induced responses
after 24 hr nicotine incubation. 42-expressing oocytes were
incubated for 24 hr in control media or media containing 3, 30, 60, or
1000 nM nicotine. Measurement of peak currents before and after incubation and calculation of
desensitization are described in A. For the 30 and 60 nM conditions, peak responses were also determined 2 and 24 hr after removal from nicotine. C, Inhibition
dose-response curves constructed from fractional responses as
described in B. Data are shown both uncorrected
(open circles) and corrected (filled
circles) for the amount of upregulation (i.e., relative
increases in [3H]nicotine binding) observed after
24 hr incubation in nicotine at the same concentration. The amount of
upregulation at a given concentration is taken from the data in Figure
2B. The corrected values were calculated by
dividing decreases in receptor function by the amount of upregulation
(see Materials and Methods). The solid lines are
logistic fits to mean data from which the half-maximal nicotine
concentration for desensitization was n = 3-32
oocytes per data point.
|
|
Chronic incubation with increasing concentrations of nicotine resulted
in a dose-dependent decrease in 42 receptor function (Fig.
3C). The data in Figure 3B also show the effect
of removal of nicotine on the relative responses of these oocytes.
There was a small increase in peak currents 1-2 hr after removing the oocytes from nicotine incubation but almost no recovery thereafter. This increase in response may represent the return of some of the
desensitized receptors to the activable state in the first 2 hr after
removal from nicotine incubation. Both the decreases in 42
receptor function after 24 hr nicotine incubation and the limited
recovery after removal of nicotine are similar to results reported
previously (Hsu et al., 1996).
Figure 3C shows a dose-response curve constructed from the
relative decrease in 42 receptor function after chronic nicotine treatment at six different nicotine concentrations (open
circles). Half-maximal desensitization of 42 nAChRs was
calculated to occur at nicotine incubation concentrations of 31 nM. Thus, it might be concluded that the concentrations of
nicotine necessary to induce desensitization are approximately
threefold higher than those required for upregulation. However, the
calculated relative decrease in receptor function after nicotine
exposure does not directly reveal the fraction of receptors that are
activatable after incubation, because the total number of 42
receptors is upregulated during the 24 hr nicotine incubation. It is
therefore necessary to correct for this change in receptor number. We
normalized the relative response remaining after nicotine incubation by
the amount of receptor upregulation observed at the particular nicotine incubation concentration (Fig. 2B). For example,
after chronic incubation with 60 nM nicotine, the relative
increase in [3H]nicotine binding (b)
was 178 ± 16%, and the fractional response remaining
(f) was 0.36 ± 0.04 (i.e., 1.78 of the
initial number of receptors were now responsible for 0.36 of the
relative response). After correction
(f/b), the fraction of activable receptors
remaining at the end of the 24 hr treatment with 60 nM
nicotine was estimated to be 0.20. After correction of all
concentration points, the half-maximal desensitization of 42
nAChRs was calculated to occur at nicotine incubation concentrations of
9.7 nM (Fig. 3C, filled circles). The
similarity between the half-maximal values for upregulation of specific
surface [3H]nicotine binding to intact oocytes
(Fig. 2B) and functional desensitization is
consistent with the idea that desensitization is a trigger for upregulation.
Upregulation and desensitization of lower affinity nAChRs
are correlated
If desensitization is a common trigger for upregulation of many
different nAChRs, then an nAChR that has a lower affinity for
nicotine-induced desensitization should exhibit a comparably lower
affinity for upregulation. To test this hypothesis, we examined the
concentration-dependence of nicotine-induced desensitization and
upregulation for 34 nAChRs, a receptor subtype with ~10-fold lower affinity for nicotine than 42 nAChRs (Fenster et al., 1997). As described for 42 nAChRs in Figure 3, functional
desensitization was assessed from changes in receptor responsiveness
after 24 hr incubation in nicotine at concentrations ranging from 30 nM to 10 µM. Representative traces
for 34-expressing oocytes untreated or treated for 24 hr in 3 µM nicotine are shown in Figure
4A. The relative
responses remaining after incubation at two different concentrations, 1 and 10 µM, are shown in Figure 4B.
These data were normalized to the responses of control oocytes not
incubated in nicotine to factor in changes in receptor expression.
Also, similar to the results shown for 42 nAChRs, little recovery of function from 24 hr nicotine incubation was evident in
34-expressing oocytes, even after 24 hr in the absence of
nicotine. Similar experiments were repeated at several other nicotine
incubation concentrations to obtain a dose-response curve for
functional desensitization of 34 nAChRs caused by chronic
nicotine treatment. The uncorrected half-maximal nicotine concentration
for functional 34 desensitization was calculated to be 462 nM (Fig. 4C, open circles).
View larger version (25K):
[in this window]
[in a new window]
|
Figure 4.
Desensitization and upregulation of 34
nAChRs. A, Representative traces measured
before and after incubation. Experiments are the same as in Figure
3A, except that test pulses were performed with 60 µM nicotine and the 24 hr incubation was performed with 3 µM nicotine. B, Representative fractional
nicotine-induced responses after 24 hr nicotine incubation.
34-expressing oocytes were incubated for 24 hr in control media
or media containing 300 nM or 10 µM nicotine.
Measurement of peak currents before and after incubation and
calculation of desensitization are described in Figure
3A. Peak responses were also determined 2 and 24 hr
after removal from nicotine. C, Inhibition
dose-response curves constructed from fractional responses as
described in B. Data are shown both uncorrected
(open circles) and corrected (filled
circles) for the amount of upregulation (i.e., relative
increases in [3H]nicotine binding) observed after
24 hr incubation in nicotine at the same concentration (Fig.
3C). The amount of upregulation at a given concentration
is taken from the data in Figure 4D. The
solid lines are logistic fits to mean data from which
the half-maximal nicotine concentration for desensitization was
n = 3-15 oocytes per data point. D,
Upregulation is nicotine concentration-dependent.
[3H]Nicotine binding assays were performed as
described in Figure 2B. Data are plotted as the
amount of specific [3H]nicotine binding for
oocytes incubated in nicotine compared with the specific
[3H]nicotine binding for control oocytes not
incubated in nicotine (n = 4-9 oocytes per data
point).
|
|
To determine the levels of nicotine necessary for 34
upregulation, we examined specific surface
[3H]nicotine binding to 34 nAChRs in intact
oocytes after 24 hr nicotine incubation using concentrations ranging
from 30 nM to 10 µM. An upregulation
dose-response curve was constructed from the relative increases in
[3H] nicotine binding, and these data are plotted
in Figure 4D. The half-maximal nicotine concentration
for upregulation was estimated to be 215 nM. As described
above for 42 nAChRs, we then used the relative increases in
34 binding at each nicotine concentration to correct for the
relative response measured in the desensitization assays. The
correction yielded a half-maximal nicotine concentration for functional
34 desensitization of 141 nM (Fig. 4C,
filled circles). Thus, 34 receptors require ~10-fold
higher nicotine concentrations to induce half-maximal desensitization
than 42 receptors, and this shift is paralleled by a comparable
shift in the nicotine concentrations necessary for upregulation.
Receptors that do not recover from desensitization upregulate after
brief applications of nicotine
Previously, we produced a mutant 4 subunit in which a putative
PKC phosphorylation site was eliminated (S336A).
Briefly, when this subunit is coexpressed with a wild-type 2
subunit, it forms receptors in oocytes that exhibit many functional properties similar to the wild-type 42 receptors. For example, (1) dose-response relationships for nicotine-induced activation estimate an EC50 value of 13 µM, which is
similar to the estimated EC50 value for wild-type receptors
(15 µM) (Fenster et al., 1997); and (2) rates into the
desensitized state (induced by 2 min applications of 10 µM nicotine) are the same as for wild-type 42
receptors. However, 4S336A2 receptors
are different from wild-type receptors in one way that is important for
the present studies; whereas wild-type 42 receptors recovered
fully from desensitization (with a time constant of ~43 min),
4S336A2 receptors showed <20% total recovery
(Fenster et al., 1999). We reasoned that if desensitization is the
trigger for upregulation, then we should be able to make specific
predictions regarding upregulation in the mutant that would be
different from wild-type 42 receptors.
Because the mutant 42 receptor does not readily return to the
activatable state after desensitization, one prediction is that once
mutant receptors are desensitized by nicotine, then nicotine will no
longer be required to produce upregulation. This would not be true of
wild-type receptors, which would recover from desensitization in the
absence of nicotine. To test this prediction, we subjected oocytes
injected with either wild-type or mutant receptors to periodic nicotine
treatment. Specifically, the oocytes were incubated for 1 hr every 12 hr in 60 nM nicotine. The rationale was that 1 hr treatment
would desensitize both receptor types, but the wild-type receptors
would recover in the absence of nicotine during the subsequent hour;
nicotine was added for 1 hr at 12 hr intervals to desensitize any new
receptors that had been inserted during the assay. Data obtained from
oocytes in the periodically incubated condition were compared with
oocytes that were untreated or incubated continuously for 48 hr in 60 nM nicotine. Wild-type nAChRs were not significantly
upregulated after periodic treatment. In contrast, the mutant nAChRs
were upregulated to levels comparable with that seen with continuous nicotine treatment (Fig.
5C).
View larger version (24K):
[in this window]
[in a new window]
|
Figure 5.
Upregulation and equilibrium binding to mutant
(S336A) 42 receptors. A,
Mutant, but not wild-type, 42 receptors are upregulated by
periodic nicotine treatment. Expressing oocytes were incubated
continuously for 48 hr in ND96+Ca (open bars),
continuously for 48 hr in 60 nM nicotine
(filled bars), or periodically (hatched
bars; 1 hr in 60 nM nicotine every 12 hr for 48 hr). Specific surface [3H]nicotine binding to
intact oocytes was then measured for 1 hr using 60 nM
[3H]nicotine. Data are from five to seven oocytes
per condition. *p < 0.05; unpaired
t test. B, Equilibrium binding to intact
oocytes expressing wild-type (filled circles) or
mutant (S336A; open circles) 42
receptors. Assays were performed for 1 hr using
[3H]nicotine concentrations from 0.1 to 300 nM. Dose-response curves were constructed from the amount
of specific [3H]nicotine binding normalized to
maximal [3H]nicotine binding
(n = 5-6 oocytes per data point).
|
|
A potential explanation for these data are that nicotine remains bound
to the mutant receptors and thus the "periodic" treatment is in
fact "continuous" treatment. To rule out this possibility, we
examined the dissociation rate of [3H] nicotine
from 4S336A2 receptors. The dissociation time
constant was 69 sec (data not shown), which is similar to that observed
for wild-type 42 nAChRs (Fig. 2C). The most
straightforward interpretation of the periodic treatment data are that,
at least in the case of the mutant receptor, the unoccupied
desensitized state is sufficient to induce upregulation.
Mutant 42 nAChRs have a higher apparent affinity
for nicotine
In addition to the finding that periodic treatment with
nicotine could upregulate mutant receptors, continuous incubation with
60 nM nicotine for 48 hr resulted in a greater amount of mutant nAChR upregulation (~150%) compared with wild-type receptor nAChR upregulation (~80%; Fig. 5A). These data imply that
the mutant nAChRs may have a higher affinity for nicotine (i.e.,
upregulation would occur at lower agonist concentrations). To test this
idea, we replotted the [3H]nicotine saturation
data presented in Figure 1A for wild-type 42
nAChRs measured in intact oocytes (Fig. 5B, filled
circles). The concentration of nicotine required for half-maximal
binding to wild-type receptors in intact oocytes was estimated to be 11 nM. In comparison, the concentration of nicotine required
for half-maximal binding to mutant 4S336A2
receptors in intact oocytes was estimated to be 6 nM. Thus, mutant 42 receptors are more readily upregulated than wild-type nAChRs, and this difference is correlated with a shift in equilibrium nicotine binding.
Equilibrium binding to 42 nAChRs is altered by
membrane homogenization
The present data suggest that upregulation and desensitization are
closely related phenomena. Previous estimates of these parameters have
not revealed such a close association between the concentration of
nicotine necessary for upregulation and that which produces
desensitization (Peng et al., 1994; Whiteaker, 1998). In both of these
studies, however, estimates of the potency of nicotine for
desensitization was obtained from equilibrium [3H]nicotine binding. Therefore, one possibility
for the apparent concentration mismatch between upregulation and
desensitization is that equilibrium binding studies measure receptors
in an altered state(s) from that encountered when measuring functional
desensitization. In the present study, the half-maximal value obtained
for equilibrium binding of [3H]nicotine to
42 nAChRs in intact oocytes (11 nM) (Fig.
5B) is comparable with that for desensitization (10 nM) (Fig. 3C). Together with our observation
that the number of surface agonist binding sites and functional
channels are correlated (Fig. 1B), these data suggest
that equilibrium [3H]nicotine binding to intact
surface receptors and functional desensitization are likely measuring
the same population of 42 nAChRs in the same state(s).
Another explanation for large differences between previously observed
dose-response curves for receptor upregulation and equilibrium binding
is that the majority of binding studies have been performed on membrane
homogenates. Such preparations may differ from surface binding in
intact preparations because of contributions from nonsurface receptors
and/or changes in the biochemical state of the receptor (Wonnacott,
1987). To test this hypothesis, we performed saturation [3H]nicotine binding assays on cell lysates
obtained from oocytes expressing 42 nAChRs and compared the
results with those obtained from the intact oocyte experiments (Fig.
6). After membrane homogenization, the
dose-response curve for equilibrium nicotine binding was shifted significantly to the left; the concentration of nicotine for
half-maximal binding was estimated to be 0.4 nM. These data
demonstrate that the apparent affinity of nAChRs for nicotine is
altered after membrane homogenization (Whiteaker et al., 1998),
implying that equilibrium binding may not always accurately reflect
in vivo receptor desensitization. In addition, at near
saturating concentrations of [3H]nicotine (60 nM), specific binding to membrane homogenates was approximately sixfold greater than for surface binding to intact oocytes, implying that >80% of the binding in membrane homogenates was to intracellularly localized receptors. Together, the increase in
both the apparent affinity and the number of receptors after membrane
homogenization argues that most nAChRs in oocytes exist in a
high-affinity intracellular pool, with a smaller receptor population on
the cell surface that has a lower apparent affinity for nicotine.
View larger version (20K):
[in this window]
[in a new window]
|
Figure 6.
Equilibrium binding to intact and homogenized
oocyte membranes. 42-expressing oocytes from the same oocyte
batch were subjected to membrane-intact (filled
circles) or membrane-homogenate (open circles)
[3H]nicotine binding assays. Assays were performed
for 1 hr using [3H]nicotine concentrations from
0.1 to 300 nM. Dose-response curves were constructed from
the amount of specific [3H]nicotine binding
normalized to maximal [3H]nicotine binding
(n = 5-6 oocytes per data point).
|
|
Upregulation of 42 nAChRs in total membrane homogenates
If desensitization of surface 42 receptors is the trigger
for upregulation of intracellular, as well as surface, receptors (Whiteaker et al., 1998), then the half-maximally effective
concentration for upregulation of both populations should be the same.
If, however, these populations are regulated independently, then their
concentration requirements for upregulation may be different. As we
have shown for surface receptors, upregulation occurs at concentrations
that induce desensitization. Because intracellular receptors (the
majority of binding sites on homogenized membranes) appear to have a
higher apparent affinity than surface receptors, it might be predicted that upregulation will occur at lower concentrations of nicotine. However, after chronic (24 hr) exposure to nicotine, we observed that
upregulation of specific [3H]nicotine binding to
isolated membranes required higher agonist concentrations than those
necessary for upregulation of surface receptors. The half-maximal
concentration of nicotine for upregulation of intracellular nAChRs was
58 nM (Fig. 7). Thus, as
others have observed previously, there is a discrepancy between the
concentrations required for half-maximal equilibrium binding and those
necessary for upregulation in homogenized membranes (Peng et al., 1994; Bencherif et al., 1995; Warpman et al., 1998; Whiteaker et al., 1998).
View larger version (16K):
[in this window]
[in a new window]
|
Figure 7.
Upregulation of total 42 receptors after
chronic nicotine incubation. Specific [3H]nicotine
binding to homogenized membranes is upregulated by nicotine. Oocytes
were injected with 4 and 2 subunit cRNAs. Twenty-four hours
later, oocytes were placed in ND96+Ca in the absence or presence of
various concentrations of nicotine for 24 hr. After preparation of
homogenized membranes, binding assays were performed using 60 nM [3H]nicotine. The plot shows a
dose-response curve constructed from the relative increase in specific
[3H]nicotine binding to homogenized membranes at
each nicotine incubation concentration. Data are plotted as the amount
of specific [3H]nicotine binding for oocytes
incubated in nicotine compared with the specific
[3H]nicotine binding for control oocytes not
incubated in nicotine (n = 16-20 oocytes per data
point).
|
|
| |
DISCUSSION |
In the present study, we provide several lines of evidence to
suggest that, for 42 nAChRs on the surface of oocytes, receptor upregulation is directly related to receptor desensitization: (1) the
half-maximal value for nicotine-induced upregulation is equal to the
half-maximal effective concentrations of nicotine required for both
functional receptor desensitization and equilibrium binding to surface
nAChRs in intact oocytes; (2) the half-maximal value for upregulation
of 34 nAChRs is ~10-fold higher than for 42 nAChRs, and
this shift is mirrored by a 10-fold shift in the half-maximal
concentration necessary for functional desensitization; and (3) mutant
42 receptors, for which recovery from the desensitized state does
not readily occur (Fenster et al., 1999), can be upregulated in the
absence of nicotine. Additionally, we find that much lower concentrations of [3H]nicotine are needed for
half-maximal equilibrium binding to receptors after membrane
homogenization. These latter data may account for some, but not all, of
the discrepancies between apparent affinities for equilibrium binding
and upregulation observed here and in other systems (Peng et al., 1994;
Whiteaker et al., 1998).
42 nAChR equilibrium binding and
functional desensitization
Based on the Katz and Thesleff (1957) cyclical model of
desensitization, as illustrated below, nAChRs may exist either in activable states R or higher affinity desensitized states
D, where L is equal to the ratio of desensitized
to activatable receptors D/R.
Because the affinity of nicotine is higher for the desensitized
state compared with the activatable state (i.e.,
Ko  K1) (Katz
and Thesleff, 1957; Feltz and Trautmann, 1982), prolonged nicotine
exposure should stabilize receptors in the agonist-bound desensitized
state AD. Based on this model, the apparent affinity of the
desensitized state can be estimated using either measures of functional
desensitization or equilibrium binding (Lippiello et al., 1987;
Grady et al., 1994). Consistent with this idea, we and others (Higgins
and Berg, 1988; Grady et al., 1994) find that apparent affinities for
equilibrium binding and functional desensitization are similar.
After chronic exposure to low concentrations of nicotine, our
functional assessment of 42 nAChR desensitization measures the
relative fraction of activatable receptors
R/Rmax remaining (Feltz and
Trautmann, 1982):
![<FR><NU>R</NU><DE>R<SUB><UP>max</UP></SUB></DE></FR>=<FR><NU>1+L</NU><DE>1+L(1+[A]/K<SUB>1</SUB>)</DE></FR>](/content/vol19/issue12/fulltext/4804/img002.gif)
|
(2)
|
At equilibrium, [3H]nicotine binding will
measure the fraction of total receptors in the desensitized state
AD:
![ƒAD=<FR><NU>1</NU><DE>1+<FR><NU>K<SUB>1</SUB></NU><DE>[A]</DE></FR><FENCE>1+<FR><NU>1</NU><DE>L</DE></FR></FENCE></DE></FR>](/content/vol19/issue12/fulltext/4804/img003.gif)
|
(3)
|
Both assessments of the potency of nicotine for inducing
desensitization will be influenced by the ratio of desensitized to
activatable receptors L (Marks et al., 1996); thus, the
half-maximal effective concentrations of nicotine that we have
calculated are related, but not equal, to the affinity of nicotine for
the desensitized state. The true affinity of the desensitized state
K1 can be determined only if an independent
estimate of L is obtained (Lippiello et al., 1987). More
importantly for the present study, Equations 2 and 3 predict the same
half-maximal agonist values for functional desensitization and
equilibrium binding if K1 and L
remain constant for both types of measurements. The most
straightforward empirical method for doing this is to determine these
two half-maximal concentrations under comparable conditions. Measuring
both specific radiolabeled binding to surface nAChRs in intact oocytes
and functional desensitization in the same oocytes (or oocytes from the
same batch) is one such approach.
It has been hypothesized that chronic nicotine-induced upregulation in
the number of high affinity (42) binding sites in the CNS is a
consequence of receptor desensitization (Marks et al., 1983; Schwartz
and Kellar, 1985). From the model, upregulation will be directly
related to occupation of the desensitized state by nicotine, and
therefore the concentration of nicotine required for upregulation can
be predicted from Equation 3. Then, if the desensitization hypothesis
is correct, the half-maximal nicotine concentrations for both
upregulation and equilibrium [3H]nicotine binding
should be the same. Our data for nAChRs expressed on the surface of
intact oocytes are consistent with this hypothesis.
Receptor pools and apparent [3H]nicotine
equilibrium binding affinities
We observed a >20-fold decrease in the half-maximal
[3H]nicotine concentration necessary for 42
nAChR equilibrium binding after membrane homogenization compared with
that measured for surface receptors in intact oocytes. In addition,
membrane homogenization revealed a population of receptors (~80% of
total receptors) not measured during surface binding assays on intact
oocytes. From these observations, we may conclude that the majority of
nAChRs are intracellular (Whiteaker et al., 1998), with a higher
apparent affinity for nicotine than surface receptors. Why then is the surface pool of receptors not detected as a lower affinity component (~20%) of [3H] nicotine binding to homogenized
membranes? Aside from the potential difficulty in distinguishing this
component, it may be that membrane homogenization affects the integrity
of surface receptors, allowing them to enter higher affinity states.
From cyclical models of desensitization, there are two ways of altering
the apparent agonist binding affinity (Marks et al., 1996): a change in
the microscopic affinity constant K1 or a change in the ratio of desensitized to activatable receptors L.
Because the dissociation rate of nicotine from intact oocytes is
similar to that obtained after membrane homogenization (Marks and
Collins, 1982), the microscopic affinity of the desensitized state
K1 is likely unaffected by cell lysis. Thus, the
effect of membrane homogenization may be in part explained by a shift
in L, the initial fraction of receptors in the desensitized
state. If this shift favors more receptors in the desensitized state,
then the apparent binding affinity will increase and approach the
microscopic affinity of the desensitized state (Marks et al.,
1996).
We suggest that some of the differences in the apparent affinity of
nicotine for receptors on internal and/or homogenized membranes
compared with intact surface receptors are a result of altered
biochemical regulation. Consistent with this idea, it has been shown
that recovery from desensitization of 42 nAChRs is enhanced by
PKC activation and phosphatase inhibition (Eilers et al., 1997; Fenster
et al., 1999). Because recovery from desensitization likely proceeds
via the transition from desensitized to activatable receptors, then the
allosteric constant L will be increased by phosphorylation,
which will in turn lead to a decrease in the apparent binding affinity
(Equation 3). In support of this suggestion, we report here that mutant
42 receptors have an approximately twofold higher apparent
[3H]nicotine binding affinity than wild-type
receptors. Because the rate of nicotine dissociation from the
desensitized state is not changed in mutant receptors, the increased
affinity of mutant channels is predicted from the decrease in
L that likely results from the slowed rate of recovery from
desensitization in the mutant channel (Fenster et al., 1999).
Based on the above interpretation, we suggest that, in contrast to
wild-type 42 nAChRs, mutant receptors become trapped in the
unbound desensitized state, after chronic exposure to nicotine. It
follows that because the mutant receptor can upregulate in the absence
of ligand (Fig. 5), the unoccupied desensitized state may be sufficient
for inducing upregulation under certain circumstances. This result is
consistent with the finding that chronic PKC inhibition, which alone
can downregulate 42 receptor function (Eilers et al., 1997),
presumably by shifting more receptors into the desensitized state
(Fenster et al., 1999), can cause upregulation (Golpalakrishnan et al.,
1997) in the absence of nicotine.
Is desensitization a general trigger for upregulation
of nAChRs?
If upregulation of both surface and intracellularly localized
receptors is triggered through a common mechanism, e.g., the interaction of nicotine with cell surface receptors (Whiteaker et al.,
1998), then upregulation of both pools should have the same dependency
on nicotine concentration. However, the half-maximal concentration of
nicotine required for upregulation of the intracellular pool (in
homogenized membranes) was higher (~60 nM) than that necessary for upregulation of surface nAChRs (~10 nM).
These data imply that, unlike surface nAChRs, upregulation of
intracellular 42 receptors in oocytes is not initiated through an
interaction with the desensitized state of surface nAChRs. Moreover, if
the apparent binding affinity for nicotine (~400 pM) in
homogenized membranes primarily reflects desensitized intracellular
receptors, it is very unlikely that upregulation is mediated via
occupation of the desensitized state of this pool of receptors. Based
on our suggestion for surface receptors, it may be that intracellular nAChRs are shifted to a higher affinity state by membrane
homogenization. However, because there is only a twofold
difference in the apparent agonist binding affinities to intracellular
chick 42 nAChRs between intact M10 cells and isolated membranes
(Whiteaker et al., 1998), this seems improbable. Thus, in the case of
intracellular receptors, we, like many others, are left to explain why
greater than saturating concentrations of nicotine are required for
receptor upregulation (Peng et al., 1994; Bencherif et al., 1995;
Warpman et al., 1998; Whiteaker et al., 1998). One explanation is that nicotine directly (i.e., in a nonreceptor-mediated manner) interferes with processes that regulate the number of nAChRs. To answer this question, it will be necessary to more fully understand the factors that control the movement of receptors between functional and silent
surface pools and intracellular pools.
Conclusions
The overall problem of how chronic nicotine alters the number and
function of nAChRs remains unresolved; however, we suggest that
desensitization plays an important role in upregulation of the
population of receptors on the plasma membrane. Although other factors
must be taken into account in vivo (Rowell and Li, 1997), the relationship between desensitization and upregulation should be
useful for predicting the long-term consequences of tobacco-related levels of nicotine on different subtypes of nAChRs in the CNS.
| |
FOOTNOTES |
Received Jan. 19, 1999; revised April 1, 1999; accepted April 7, 1999.
This research was supported by United States Public Health Service
Grants DA-11940 and NS-31669 (R.A.J.L.) and W. M. Keck Foundation
Grant 931360. We thank Drs. Y. Chang and D. S. Weiss for sharing
their methods on radiolabeled ligand binding in single oocytes before publication.
Correspondence should be addressed to Robin A. J. Lester, Department of
Neurobiology, CIRC 560, University of Alabama at Birmingham, 1719 Sixth Avenue South, Birmingham, AL 35294-0021.
| |
REFERENCES |
-
Balfour DJ
(1994)
Neural mechanisms underlying nicotine dependence.
Addiction
89:1419-1423[Web of Science][Medline].
-
Bencherif M,
Fowler K,
Lukas RJ,
Lippiello PM
(1995)
Mechanisms of up-regulation of neuronal nicotinic acetylcholine receptors in clonal cell lines and primary cultures of fetal rat brain.
J Pharmacol Exp Ther
275:987-994[Abstract/Free Full Text].
-
Benowitz NL,
Porchet H,
Jacob III P
(1989)
Nicotinic dependence and tolerance in man: pharmacokinetic and pharmocodynamic investigations.
Prog Brain Res
79:279-287[Web of Science][Medline].
-
Benwell M,
Balfour DJK,
Anderson J
(1988)
Evidence that tobacco smoking increases the density of ()-[3H] nicotine binding sites in human brain.
J Neurochem
50:1243-1247[Web of Science][Medline].
-
Boyd ND
(1987)
Two distinct kinetic phases of desensitization of acetylcholine receptors of clonal rat PC12 cells.
J Physiol (Lond)
389:45-67[Abstract/Free Full Text].
-
Breese CR,
Marks MJ,
Logel J,
Adams CE,
Sullivan B,
Collins AC,
Leonard S
(1997)
Effect of smoking history on [3H]nicotine binding in human postmortem brain.
J Pharmacol Exp Ther
283:7-13[Abstract/Free Full Text].
-
Chang Y,
Weiss DS
(1999)
Channel opening locks agonist onto the GABAC receptor.
Nat Neurosci
2:219-225.[Web of Science][Medline]
-
Corey JL,
Davidson N,
Lester HA,
Brecha N,
Quick MW
(1994)
Protein kinase C modulates the activity of a cloned
 -aminobutyric acid transporter expressed in Xenopus oocytes via regulated subcellular redistribution of the transporter.
J Biol Chem
269:14759-14767[Abstract/Free Full Text]. -
Dani JA,
Heinemann S
(1996)
Molecular and cellular aspects of nicotine abuse.
Neuron
16:905-908[Web of Science][Medline].
-
Eilers H,
Schaeffer E,
Bickler PE,
Forsayeth JR
(1997)
Functional deactivation of the major neuronal nicotinic receptor caused by nicotine and a protein kinase-C dependent mechanism.
Mol Pharmacol
52:1105-1112[Abstract/Free Full Text].
-
Feltz A,
Trautmann A
(1982)
Desensitization at the frog neuromuscular junction: a biphasic process.
J Physiol (Lond)
322:257-272[Abstract/Free Full Text].
-
Fenster CP,
Rains M,
Noerager B,
Quick MW,
Lester RAJ
(1997)
Influence of subunit composition on desensitization of neuronal acetylcholine receptors at low concentrations of nicotine.
J Neurosci
17:5747-5759[Abstract/Free Full Text].
-
Fenster CP,
Beckman ML,
Parker JC,
Sheffield EB,
Whitworth TL,
Quick MW,
Lester RAJ
(1999)
Regulation of 42 nicotinic receptor desensitization by calcium and protein kinase C.
Mol Pharmacol
55:432-443[Abstract/Free Full Text].
-
Flores CM,
Rogers SW,
Pabreza LA,
Wolfe BB,
Kellar KJ
(1992)
A subtype of nicotinic cholinergic receptor in rat brain is composed of 4 and 2 subunits and is upregulated by chronic nicotine treatment.
Mol Pharmacol
41:31-37[Abstract].
-
Flores CM,
Davila-Garcia MI,
Ulrich YM,
Kellar KJ
(1997)
Differential regulation of neuronal nicotinic receptor binding sites following chronic nicotine administration.
J Neurochem
69:2216-2219[Web of Science][Medline].
-
Golpalakrishnan M,
Molinari EJ,
Sullivan J
(1997)
Regulation of human 42 neuronal nicotine acetylcholine receptors by cholinergic channel ligand and second messenger pathways.
Mol Pharmacol
52:524-534[Abstract/Free Full Text].
-
Grady SR,
Marks MJ,
Collins AC
(1994)
Desensitization of nicotine-stimulated [3H]dopamine release from mouse striatal synaptosomes.
J Neurochem
62:1390-1398[Web of Science][Medline].
-
Higgins LS,
Berg DK
(1988)
A desensitized form of neuronal nicotinic acetylcholine receptor detected by [3H]-nicotine binding on bovine adrenal chromaffin cells.
J Neurosci
8:1436-1446[Abstract].
-
Hsu Y-N,
Amin J,
Weiss DS,
Wecker L
(1996)
Sustained nicotine exposure differentially affects 32 and 42 neuronal nicotinic receptors expressed in Xenopus oocytes.
J Neurochem
66:667-675[Web of Science][Medline].
-
Katz B,
Thesleff S
(1957)
A study of the "desensitization" produced by acetylcholine at the motor end-plate.
J Physiol (Lond)
138:63-80.
-
Lippiello PM,
Sears SB,
Fernandes KG
(1987)
Kinetics and mechanism of L-[3H]nicotine binding to putative high affinity receptor sites in rat brain.
Mol Pharmacol
31:392-400[Abstract].
-
Lukas RJ
(1991)
Effects of chronic nicotinic ligand exposure on functional activity of nicotinic acetylcholine receptors expressed by cells of the PC12 rat pheochromocytoma or the TE671/RD human clonal line.
J Neurochem
56:1134-1145[Web of Science][Medline].
-
Margiotta JF,
Berg DK,
Dionne VE
(1987)
Cyclic AMP regulates the proportion of functional acetylcholine receptors on chicken ciliary ganglion neurons.
Proc Natl Acad Sci USA
84:8155-8159[Abstract/Free Full Text].
-
Marks MJ,
Collins AC
(1982)
Characterization of nicotine binding in mouse brain and comparison with the binding of -bungarotoxin and quinuclidinyl benzilate.
Mol Pharmacol
22:554-564[Abstract].
-
Marks MJ,
Burch JB,
Collins AC
(1983)
Effects of chronic nicotine infusion on tolerance development and cholinergic receptors.
J Pharmacol Exp Ther
226:806-816[Abstract/Free Full Text].
-
Marks MJ,
Grady SR,
Collins AC
(1993)
Downregulation of nicotine receptor function after chronic nicotine infusion.
J Pharmacol Exp Ther
266:1268-1276[Abstract/Free Full Text].
-
Marks MJ,
Robinson SF,
Collins AC
(1996)
Nicotinic agonists differ in activation and desensitization of 86Rb+ efflux from mouse thalamic synaptosomes.
J Pharmacol Exp Ther
277:1383-1396[Abstract/Free Full Text].
-
Papke RL,
Boulter J,
Patrick J,
Heinemann S
(1989)
Single-channel currents of rat neuronal nicotinic acetylcholine receptors expressed in Xenopus oocytes.
Neuron
3:589-596[Web of Science][Medline].
-
Peng X,
Gerzanich V,
Anand R,
Whiting PJ,
Lindstrom J
(1994)
Nicotine-induced increase in neuronal receptors results from a decrease in the rate of receptor turnover.
Mol Pharmacol
46:523-530[Abstract].
-
Quick MW,
Lester HA
(1994)
Methods for expression of excitability proteins in Xenopus oocytes.
In: Methods in neurosciences (Conn PM,
ed), pp 261-271. San Diego: Academic.
-
Ritchie JM,
Rogart RB
(1977)
Density of sodium channels in mammalian myelinated nerve fibers and nature of the axonal membrane under the myelin sheath.
Proc Natl Acad Sci USA
74:211-215[Abstract/Free Full Text].
-
Role LW
(1992)
Diversity of primary structure and function of neuronal nicotinic acetylcholine receptors.
Curr Opin Neurobiol
2:254-262[Medline].
-
Rowell PP,
Li M
(1997)
Dose-response relationship for nicotine-induced up-regulation of rat brain nicotinic receptors.
J Neurochem
68:1982-1989[Web of Science][Medline].
-
Sargent PB
(1993)
The diversity of neuronal acetylcholine receptors.
Annu Rev Neurosci
16:403-443[Web of Science][Medline].
-
Schwartz RD,
Kellar KJ
(1985)
In vivo regulation of [3H]acetylcholine recognition sites in brain by nicotinic cholinergic drugs.
J Neurochem
45:427-433[Web of Science][Medline].
-
Warpman U,
Friberg L,
Gillespie A,
Hellström-Lindahl E,
Zhang X,
Nordberg A
(1998)
Regulation of nicotinic receptor subtypes following chronic nicotinic agonist exposure in M10 and SH-SY5Y neuroblastoma cells.
J Neurochem
70:2028-2037[Medline].
-
Whiteaker P,
Sharples C,
Wonnacott S
(1998)
Agonist-induced up-regulation of 42 nicotine acetylcholine receptors in M10 cells: pharmacological and spatial definition.
Mol Pharmacol
53:950-962[Abstract/Free Full Text].
-
Wonnacott S
(1987)
Brain nicotine binding sites.
Hum Toxicol
6:343-353[Web of Science][Medline].
-
Wonnacott S
(1990)
The paradox of nicotinic acetylcholine receptor upregulation by nicotine.
Trends Pharmacol Sci
11:216-219[Medline].
Copyright © 1999 Society for Neuroscience 0270-6474/99/19124804-11$05.00/0
This article has been cited by other articles:
|
|
|
|
 
X. W. Fu, J. Lindstrom, and E. R. Spindel
Nicotine Activates and Up-Regulates Nicotinic Acetylcholine Receptors in Bronchial Epithelial Cells
Am. J. Respir. Cell Mol. Biol.,
July 1, 2009;
41(1):
93 - 99.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. X. Albuquerque, E. F. R. Pereira, M. Alkondon, and S. W. Rogers
Mammalian Nicotinic Acetylcholine Receptors: From Structure to Function
Physiol Rev,
January 1, 2009;
89(1):
73 - 120.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
X. Sun, J. D. Ritzenthaler, Y. Zheng, J. Roman, and S. Han
Rosiglitazone inhibits {alpha}4 nicotinic acetylcholine receptor expression in human lung carcinoma cells through peroxisome proliferator-activated receptor {gamma}-independent signals
Mol. Cancer Ther.,
January 1, 2009;
8(1):
110 - 118.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. Rezvani, Y. Teng, D. Shim, and M. De Biasi
Nicotine Regulates Multiple Synaptic Proteins by Inhibiting Proteasomal Activity
J. Neurosci.,
September 26, 2007;
27(39):
10508 - 10519.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Wada, M. Naito, H. Kenmochi, H. Tsuneki, and T. Sasaoka
Chronic Nicotine Exposure Enhances Insulin-Induced Mitogenic Signaling via Up-Regulation of {alpha}7 Nicotinic Receptors in Isolated Rat Aortic Smooth Muscle Cells
Endocrinology,
February 1, 2007;
148(2):
790 - 799.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Kishi and J. H. Steinbach
Role of the Agonist Binding Site in Up-Regulation of Neuronal Nicotinic {alpha}4beta2 Receptors
Mol. Pharmacol.,
December 1, 2006;
70(6):
2037 - 2044.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. P. Lau, L. Li, A. J. Merched, A. L. Zhang, K. W.S. Ko, and L. Chan
Nicotine Induces Proinflammatory Responses in Macrophages and the Aorta Leading to Acceleration of Atherosclerosis in Low-Density Lipoprotein Receptor-/- Mice
Arterioscler. Thromb. Vasc. Biol.,
January 1, 2006;
26(1):
143 - 149.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y.-H. Jo, D. Wiedl, and L. W. Role
Cholinergic Modulation of Appetite-Related Synapses in Mouse Lateral Hypothalamic Slice
J. Neurosci.,
November 30, 2005;
25(48):
11133 - 11144.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Chin, J. J. Palop, J. Puolivali, C. Massaro, N. Bien-Ly, H. Gerstein, K. Scearce-Levie, E. Masliah, and L. Mucke
Fyn Kinase Induces Synaptic and Cognitive Impairments in a Transgenic Mouse Model of Alzheimer's Disease
J. Neurosci.,
October 19, 2005;
25(42):
9694 - 9703.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. B. Ficklin, S. Zhao, and G. Feng
Ubiquilin-1 Regulates Nicotine-induced Up-regulation of Neuronal Nicotinic Acetylcholine Receptors
J. Biol. Chem.,
October 7, 2005;
280(40):
34088 - 34095.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. F. Vallejo, B. Buisson, D. Bertrand, and W. N. Green
Chronic Nicotine Exposure Upregulates Nicotinic Receptors by a Novel Mechanism
J. Neurosci.,
June 8, 2005;
25(23):
5563 - 5572.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. B. Free, S. B. McKay, P. D. Gottlieb, R. T. Boyd, and D. B. McKay
Expression of Native {alpha}3{beta}4* Neuronal Nicotinic Receptors: Binding and Functional Studies Investigating Turnover of Surface and Intracellular Receptor Populations
Mol. Pharmacol.,
June 1, 2005;
67(6):
2040 - 2048.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Alkondon and E. X. Albuquerque
Nicotinic Receptor Subtypes in Rat Hippocampal Slices Are Differentially Sensitive to Desensitization and Early in Vivo Functional Up-Regulation by Nicotine and to Block by Bupropion
J. Pharmacol. Exp. Ther.,
May 1, 2005;
313(2):
740 - 750.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-H. Cho, W. Song, K. Leitzell, E. Teo, A. D. Meleth, M. W. Quick, and R. A. J. Lester
Rapid Upregulation of {alpha}7 Nicotinic Acetylcholine Receptors by Tyrosine Dephosphorylation
J. Neurosci.,
April 6, 2005;
25(14):
3712 - 3723.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Carvajal, M. C. Sanchez-Amate, F. Sanchez-Santed, and I. Cubero
Neuroanatomical Targets of the Organophosphate Chlorpyrifos by c-fos Immunolabeling
Toxicol. Sci.,
April 1, 2005;
84(2):
360 - 367.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Cormier, Y. Paas, R. Zini, J.-P. Tillement, G. Lagrue, J.-P. Changeux, and R. Grailhe
Long-Term Exposure to Nicotine Modulates the Level and Activity of Acetylcholine Receptors in White Blood Cells of Smokers and Model Mice
Mol. Pharmacol.,
December 1, 2004;
66(6):
1712 - 1718.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Y. Lopez-Hernandez, J. Sanchez-Padilla, A. Ortiz-Acevedo, J. Lizardi-Ortiz, J. Salas-Vincenty, L. V. Rojas, and J. A. Lasalde-Dominicci
Nicotine-induced Up-regulation and Desensitization of {alpha}4{beta}2 Neuronal Nicotinic Receptors Depend on Subunit Ratio
J. Biol. Chem.,
September 3, 2004;
279(36):
38007 - 38015.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. N. Placzek, F. Grassi, T. Papke, E. M. Meyer, and R. L. Papke
A Single Point Mutation Confers Properties of the Muscle-Type Nicotinic Acetylcholine Receptor to Homomeric {alpha}7 Receptors
Mol. Pharmacol.,
July 1, 2004;
66(1):
169 - 177.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Sallette, S. Bohler, P. Benoit, M. Soudant, S. Pons, N. Le Novere, J.-P. Changeux, and P. J. Corringer
An Extracellular Protein Microdomain Controls Up-regulation of Neuronal Nicotinic Acetylcholine Receptors by Nicotine
J. Biol. Chem.,
April 30, 2004;
279(18):
18767 - 18775.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. L. Parker, Y. Fu, K. McAllen, J. Luo, J. M. McIntosh, J. M. Lindstrom, and B. M. Sharp
Up-Regulation of Brain Nicotinic Acetylcholine Receptors in the Rat during Long-Term Self-Administration of Nicotine: Disproportionate Increase of the {alpha}6 Subunit
Mol. Pharmacol.,
March 1, 2004;
65(3):
611 - 622.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
V. I. Pidoplichko, J. Noguchi, O. O. Areola, Y. Liang, J. Peterson, T. Zhang, and J. A. Dani
Nicotinic Cholinergic Synaptic Mechanisms in the Ventral Tegmental Area Contribute to Nicotine Addiction
Learn. Mem.,
January 1, 2004;
11(1):
60 - 69.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K G Paradiso and J. H. Steinbach
Nicotine is highly effective at producing desensitization of rat {alpha}4{beta}2 neuronal nicotinic receptors
J. Physiol.,
December 15, 2003;
553(3):
857 - 871.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. N. Nguyen, B. A. Rasmussen, and D. C. Perry
Subtype-Selective Up-Regulation by Chronic Nicotine of High-Affinity Nicotinic Receptors in Rat Brain Demonstrated by Receptor Autoradiography
J. Pharmacol. Exp. Ther.,
December 1, 2003;
307(3):
1090 - 1097.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. R. A. Wooltorton, V. I. Pidoplichko, R. S. Broide, and J. A. Dani
Differential Desensitization and Distribution of Nicotinic Acetylcholine Receptor Subtypes in Midbrain Dopamine Areas
J. Neurosci.,
April 15, 2003;
23(8):
3176 - 3185.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. L. Gentry, L. H. Wilkins Jr., and R. J. Lukas
Effects of Prolonged Nicotinic Ligand Exposure on Function of Heterologously Expressed, Human alpha 4beta 2- and alpha 4beta 4-Nicotinic Acetylcholine Receptors
J. Pharmacol. Exp. Ther.,
January 1, 2003;
304(1):
206 - 216.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. Lin, E. M. Jeanclos, M. Treuil, K.-H. Braunewell, E. D. Gundelfinger, and R. Anand
The Calcium Sensor Protein Visinin-like Protein-1 Modulates the Surface Expression and Agonist Sensitivity of the alpha 4beta 2 Nicotinic Acetylcholine Receptor
J. Biol. Chem.,
October 25, 2002;
277(44):
41872 - 41878.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Chang, E. Ghansah, Y. Chen, J. Ye, and D. S. Weiss
Desensitization Mechanism of GABA Receptors Revealed by Single Oocyte Binding and Receptor Function
J. Neurosci.,
September 15, 2002;
22(18):
7982 - 7990.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Dourado and P. B. Sargent
Properties of Nicotinic Receptors Underlying Renshaw Cell Excitation by alpha -Motor Neurons in Neonatal Rat Spinal Cord
J Neurophysiol,
June 1, 2002;
87(6):
3117 - 3125.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Katsura, Y. Mohri, K. Shuto, Y. Hai-Du, T. Amano, A. Tsujimura, M. Sasa, and S. Ohkuma
Up-regulation of L-type Voltage-dependent Calcium Channels after Long Term Exposure to Nicotine in Cerebral Cortical Neurons
J. Biol. Chem.,
March 1, 2002;
277(10):
7979 - 7988.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Girod and L. W. Role
Long-Lasting Enhancement of Glutamatergic Synaptic Transmission by Acetylcholine Contrasts with Response Adaptation after Exposure to Low-Level Nicotine
J. Neurosci.,
July 15, 2001;
21(14):
5182 - 5190.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. T. Dineley, M. Westerman, D. Bui, K. Bell, K. H. Ashe, and J. D. Sweatt
{beta}-Amyloid Activates the Mitogen-Activated Protein Kinase Cascade via Hippocampal {alpha}7 Nicotinic Acetylcholine Receptors: In Vitro and In Vivo Mechanisms Related to Alzheimer's Disease
J. Neurosci.,
June 15, 2001;
21(12):
4125 - 4133.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. Buisson and D. Bertrand
Chronic Exposure to Nicotine Upregulates the Human {alpha}4{beta}2 Nicotinic Acetylcholine Receptor Function
J. Neurosci.,
March 15, 2001;
21(6):
1819 - 1829.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. H Hicks, J. A Dani, and R. A J Lester
Regulation of the sensitivity of acetylcholine receptors to nicotine in rat habenula neurons
J. Physiol.,
December 15, 2000;
529(3):
579 - 597.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. G. V. Sharples, S. Kaiser, L. Soliakov, M. J. Marks, A. C. Collins, M. Washburn, E. Wright, J. A. Spencer, T. Gallagher, P. Whiteaker, et al.
UB-165: A Novel Nicotinic Agonist with Subtype Selectivity Implicates the alpha 4beta 2* Subtype in the Modulation of Dopamine Release from Rat Striatal Synaptosomes
J. Neurosci.,
April 15, 2000;
20(8):
2783 - 2791.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
