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The Journal of Neuroscience, December 1, 2000, 20(23):8802-8811
Long-Term Nicotine Adaptation in Caenorhabditis
elegans Involves PKC-Dependent Changes in Nicotinic Receptor
Abundance
Laura E.
Waggoner1,
Kari A.
Dickinson1,
Daniel
S.
Poole1,
Yo
Tabuse2,
Johji
Miwa2, and
William R.
Schafer1
1 Department of Biology, University of California, San
Diego, La Jolla, California 92093-0349, and 2 Fundamental
Research Laboratories, NEC Corporation, Tsukuba 305, Japan
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ABSTRACT |
Chronic exposure to nicotine leads to long-term changes in both the
abundance and activity of nicotinic acetylcholine receptors, processes thought to contribute to nicotine addiction. We have found
that in Caenorhabditis elegans, prolonged nicotine
treatment results in a long-lasting decrease in the abundance of
nicotinic receptors that control egg-laying. In naive animals, acute
exposure to cholinergic agonists led to the efficient stimulation of
egg-laying, a response mediated by a nicotinic receptor functionally
expressed in the vulval muscle cells. Overnight exposure to nicotine
led to a specific and long-lasting change in egg-laying behavior, which
rendered the nicotine-adapted animals insensitive to simulation of
egg-laying by the nicotinic agonist and was accompanied by a
promoter-independent reduction in receptor protein levels. Mutants defective in the gene tpa-1, which encodes a homolog of
protein kinase C (PKC), failed to undergo adaptation to nicotine; after chronic nicotine exposure they remained sensitive to cholinergic agonists and retained high levels of receptor protein in the vulval muscles. These results suggest that PKC-dependent signaling pathways may promote nicotine adaptation via regulation of nicotinic receptor synthesis or degradation.
Key words:
nicotinic; acetylcholine; Caenorhabditis
elegans; protein kinase C; adaptation; levamisole
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INTRODUCTION |
After prolonged exposure to nicotine
or other agonists, nicotinic acetylcholine receptors undergo changes in
both activity and abundance. For example, in some cell types, long-term
nicotine treatment has been shown to cause a long-lasting inactivation of nicotinic receptors that is distinct in both time course and persistence from the rapid, receptor-intrinsic desensitization induced
by receptor agonists (Simasko et al., 1986 ; Lukas, 1991). In addition, chronic exposure to nicotinic agonists has been shown to
cause changes in the abundance of nicotinic receptors in both neurons
and muscle cells. For example, long-term exposure to nicotine leads to
an increase in the density of  2 4 nicotinic receptors in the
mammalian CNS (Wonnacott, 1990; Flores et al., 1992).
Conversely, chronic exposure to nicotinic agonists leads to a decreased
abundance of extrajunctional receptors in chick myotubes (Gardner and
Fambrough, 1979). Depending on the context and cell type,
7-containing receptors have been shown to be either downregulated
(Messing, 1982) or upregulated (Barrantes et al., 1995; Rogers and
Wonnacott, 1995; Molinari et al., 1998) by chronic nicotine treatment.
In some cases, agonist-induced changes in receptor abundance appear to be mediated at the transcriptional level (Changeaux, 1991), whereas in
other cases, a variety of post-transcriptional processes, including changes in rates of receptor assembly, intracellular targeting, and
protein turnover, have been implicated (Marks et al., 1992; Peng et
al., 1994; Bencherif et al., 1995; Rothhut et al., 1996). Yet despite
the importance of these processes to synaptic plasticity and their
potential involvement in nicotine addiction (Dani and Heinemann, 1996),
at present there is little information about the specific molecules and
intracellular signaling pathways that regulate nicotinic receptor
activity and abundance.
One way to investigate the mechanisms underlying nicotinic receptor
regulation is to use a genetically tractable animal such as
Caenorhabditis elegans. C. elegans has a simple, well
characterized nervous system and is well suited for investigating how
specific neurotransmitters, receptors, and signaling molecules function within the context of the nervous system to produce behavior. C. elegans contains a diverse family of nicotinic receptor genes (Ballivet et al., 1996; Bargmann, 1998; Mongan et al., 1998), including
both neuromuscular and neuronal receptor subtypes (Squire et al., 1995;
Treinin and Chalfie, 1995; Baylis et al., 1997). Several of these,
including the unc-29 gene, have been shown to encode
functional receptor subunits when expressed ectopically in oocytes
(Fleming et al., 1997). Nicotinic receptor agonists have specific and
easily assayed effects on several aspects of C. elegans
behavior, including locomotion, feeding, and egg-laying (Lewis et al.,
1980; Trent et al., 1983; Avery and Horvitz, 1990). A number of
paradigms for behavioral plasticity have been defined in C. elegans (Hedgecock and Russell, 1975; Rankin et al., 1990; Colbert
and Bargmann, 1995; Schafer and Kenyon, 1995; Wen et al., 1997),
demonstrating that these animals are capable of at least simple forms
of learning. Thus, it seemed reasonable to ask whether chronic exposure
to nicotine resulted in long-term changes in the abundance or activity
of C. elegans nicotinic receptors and, if so, to identify
molecules required for these processes.
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MATERIALS AND METHODS |
Egg-laying assays. Unless otherwise stated, nematodes
were grown and assayed at room temperature on standard nematode growth medium (NGM) seeded with Escherichia coli strain OP50 as a
food source. All animals tested were young adult (i.e., within 24 hr of
the L4-adult molt) hermaphrodites. For dose-response experiments, individual animals were placed in microtiter wells containing liquid M9
and the indicated concentration of drug. In the acute-response experiments (see Fig. 1), the number of eggs laid in response to
levamisole was assayed after 1 hr. For nicotine-adaptation experiments
(see Figs. 2, 4, 6), worms were placed on 30 mM
nicotine (Sigma, St. Louis, MO)-seeded NGM plates for varying lengths
of time and tested for the response to levamisole in individual liquid M9 assays. To maximize the possibility that a levamisole-sensitive animal would lay eggs, eggs were counted after 4 hr in levamisole in
these assays. Because of the relative impermeability of the nematode
cuticle, internal concentrations of all drugs have been estimated to be
several orders of magnitude lower than their concentrations in the
growth medium (Lewis et al., 1980).
Microscopy. The strain ZZ2001 (genotype,
unc-29(x29); Ex[rol-6d, unc-29:: GFP]; kindly
provided by Jim Lewis) was used for localization of UNC-29
receptors. For visualization of VC-vulval muscle synapses, we
used the strain NM670 [genotype, lin-15(n765); jsIs42x
[punc-4:: snb-1:: GFP, lin-15(+)]; kindly
provided by Mike Nonet (1999)]. For visualization of the
tpa-1 gene product protein kinase C (PKC), the
strain TF6 (see below) was used. Worms were placed on agar pads and
immobilized with 30 mM sodium azide. Green
fluorescent protein (GFP) was visualized using standard immunofluorescence techniques at a magnification of 100×. Images were
collected using a high-speed monochrome CCD camera (Hamamatsu) and
analyzed using Metamorph image-processing software. To quantitate fluorescence intensity, the average background intensity was determined for each image and subtracted from the final fluorescent intensity. Then, the average, maximum, and minimum intensities were measured, along with the average area of fluorescence.
unc-29:: GFP-expressing lines generated in our own
laboratory using dpy-20(+) as a coinjection marker showed
fluorescence in essentially the same set of cells as ZZ2001 (data not shown).
Generation of transgenic lines. Transgenic lines expressing
the UNC-29 protein in specific cell types were constructed in the
following manner. To express UNC-29 in the vulval muscles, a 2510 bp
piece of unc-29 cDNA was cut from the plasmid pPD95.86. This
piece was subcloned into the vector pSAK-10 (obtained from A. Fire)
downstream of the region containing 18 repeats of the vulval
muscle-specific ndE-box enhancer. This plasmid was injected at ~100 ng/µl into unc-29(x29); dpy-20(e1282) worms
using wild-type dpy-20(+) DNA as a coinjection marker (25 ng/µl). The F1 generation was scored for rescue of the dpy
phenotype. Transgenic lines transmitting an
ndE-box:: unc-29; dpy-20(+) extrachromosomal array
were identified by assaying the non-Dpy progeny of non-Dpy F1
transformants for egg-laying in the presence of 25 µM levamisole in M9.
tpa-1:: GFP reporter constructs. The
expression pattern of tpa-1 was evaluated using the strain
TF6 (genotype, unc-119(e2498); Is [tpa-1A:: GFP;
unc-119(+)]). Two mRNA species, tpa-1A and
tpa-1B, are transcribed from the tpa-1 gene,
which consists of 11 exons. The tpa-1A mRNA contains all of
the 11 exons, and the tpa-1B mRNA contains exons V-XI. The
tpa-1A:: GFP reporter construct was generated by
inserting a 9 kb NaeI fragment, which contained the
tpa-1A 5' upstream region along with the first two exons of
the tpa-1A-coding sequence, into the SmaI site of
the GFP expression plasmid pGFP-N3 (Clontech, Cambridge, UK). The
resulting plasmid tpa-1A:: GFP was injected into
the germ lines of unc-119 mutant animals using wild-type
unc-119(+) DNA as a cotransformation marker; rescued transgenic lines expressing tpa-1A:: GFP were
identified among the progeny. The [tpa-1A:: GFP;
unc-119(+)] extrachromosomal array was integrated into the
chromosome by UV irradiation.
Analysis of egg-laying patterns. Egg-laying in C. elegans occurs in a specific temporal pattern; egg-laying events
are clustered, with periods of active egg-laying, or active phases,
separated by long inactive phases during which eggs are retained. Both
the duration of the inactive phases ("intercluster intervals") and the duration of intervals between egg-laying events in a cluster ("intracluster intervals") model as exponential random variables with different time constants (Waggoner et al., 1998). We found (Table
1) that in wild-type animals treated
overnight with nicotine, the duration of the inactive phase was
significantly lengthened, while the rate of egg-laying within the
active phase was actually increased (Table 1, rows 1, 2). Even
after 24 hr in the absence of drug, nicotine-adapted animals exhibited
significantly longer inactive egg-laying periods (Table 1, row 3).
unc-29 mutant animals also showed a longer-than-normal
inactive phase (Table 1, row 4). The egg-laying behavior of individual
animals on solid media (NGM agar) was recorded for 4-8 hr as described
using an automated tracking system (Waggoner et al., 1998).
Maximum likelihood estimates of intercluster and intracluster time
constants were determined as described (Zhou et al., 1998). Briefly,
the intracluster time constant is the reciprocal of the estimated
parameter  1, and the intercluster time
constant is the reciprocal of the product of the parameters
p and 2. The expected variance of
estimated time constants was determined by generating 100 independent
sets of simulated egg-laying data using the coupled Poisson probability
density function and computing the SD of the parameters
estimated from these simulations.
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RESULTS |
Nicotinic receptors containing UNC-29 stimulate egg-laying in
C. elegans
Both nicotine and the more specific nicotinic agonist levamisole
have dramatic effects on nematode egg-laying behavior. For example,
both nicotine and levamisole stimulate egg-laying in hypertonic liquid
medium (M9), a condition that normally inhibits egg-laying (Trent et
al., 1983; Weinshenker et al., 1995). To identify the receptor that
mediates this response, we assayed the effect of these drugs on the
egg-laying behavior of mutants known to be defective in specific
nicotinic acetylcholine receptor (nAChR) subunit proteins. In the body
muscle, levamisole specifically activates a nicotinic receptor subtype
containing a non- subunit encoded by the unc-29 gene
(Fleming et al., 1997). We observed that whereas wild-type animals
showed a robust dose-dependent stimulation of egg-laying by levamisole,
mutants carrying recessive alleles of unc-29 showed little
or no response to levamisole (Fig. 1A).
unc-29 mutants were also less responsive to stimulation of egg-laying by acute treatment with the more general agonist nicotine (Fig. 1B). These results indicated that a nicotinic
receptor containing the UNC-29 subunit protein facilitated egg-laying
in C. elegans and that stimulation of egg-laying by the
agonist levamisole represents a functional assay for the activity of
these receptors in vivo.
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Figure 1.
Requirement of the UNC-29 receptor protein for the
acute response to nicotinic agonists. Egg-laying responses to
levamisole or nicotine were assayed in liquid M9 after 1 hr of drug
exposure. The unc-29(x29) allele contains a stop codon
that interrupts the conserved fourth transmembrane region of the UNC-29
receptor protein (D. S. Poole, unpublished observations) and thus
should result in a severe, if not complete, loss of receptor function.
The N2 strain is the wild-type strain in these assays.
A, Response of unc-29 mutants to
levamisole is shown. Animals carrying any of three
unc-29 mutant alleles showed a dramatic reduction in
levamisole-induced egg-laying. Individual points and
error bars indicate the mean and SEM of the following numbers of
trials: N2, 155; e193, 144; e1072, 96;
x29, 96. Asterisks indicate significantly
less egg-laying according to the Mann-Whitney rank-sum test
(**p < 0.001; *p < 0.01).
Other genes that were required for the levamisole response in this
assay included unc-38, unc-63, unc-74, lev-1, lev-8, and
lev-9 (Kim, Poole, and Schafer, unpublished
observations). B, Response of
unc-29 mutants to nicotine is shown.
unc-29 mutants showed a significant reduction in
nicotine-induced egg-laying. Individual points and error
bars indicate the mean and SEM of at least 12 trials.
Asterisks indicate significantly less egg-laying
according to the Mann-Whitney rank-sum test (*p < 0.01). C, Localization of GFP-tagged UNC-29 protein is
shown on a digital image of a ZZ2001 adult hermaphrodite (genotype:
unc-29(x29); Ex[ punc-29:: unc-29:: GFP,
rol-6d]), which expresses unc-29:: GFP
under the control of the unc-29 promoter. In this
ventral/lateral view, the VC5 neuronal cell body and one set of vulval
muscles are strongly fluorescent. Not shown in this view are other
fluorescent cells, including additional ventral cord motoneurons and
various unidentified head and tail neurons. Punctate body fluorescence
is caused by autofluorescence of gut granules. D, UNC-29
receptors function in the vulval muscles. The graph compares the
levamisole response of an unc-29 mutant [ZZ29,
unc-29(x29)] with that of a transgenic line that
express a functional unc-29 allele under control of the
vulval muscle-specific 18ndE-box enhancer (AQ497,
unc-29(x29); dpy-20(e1282); ljEx8[18ndE-box:: unc-29,
dpy-20(+)]). Individual points and error bars
indicate the mean and SEM of 20 or more trials. At 25 µM,
the AQ497 worms laid significantly more eggs according to the
Mann-Whitney rank-sum test (*p < 0.001).
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To understand how the UNC-29-containing receptor promotes egg-laying,
we investigated the expression pattern of the UNC-29 protein. Recently
published studies indicated that UNC-29 receptors are expressed in the
body wall muscle, as well as some unidentified neurons (Fleming et al.,
1997); however, UNC-29 receptor expression within the cells
involved in egg-laying was not reported. To determine whether the
egg-laying neurons or muscle cells contained UNC-29 receptors,
we used a sensitive CCD imaging system to investigate the
expression pattern of a chimeric UNC-29 protein tagged with GFP at its
C terminal. This UNC-29:: GFP chimera was expressed under the
control of its own promoter and could functionally rescue the movement
(Fleming et al., 1997) and egg-laying (see Fig. 3A) phenotypes of unc-29 recessive mutants. In multiple
independent transgenic lines, we observed expression of
UNC-29:: GFP protein in the vulval muscles (Fig.
1C). UNC-29:: GFP expression was also detected in
one of the two classes of egg-laying motoneurons, the VCs. To determine
whether activation of UNC-29 receptors in the vulval muscles functioned
to promote egg-laying, we analyzed the egg-laying behavior of animals
that expressed functional UNC-29 protein only in these cells. We
analyzed a transgenic line that carried an unc-29
loss-of-function allele on its chromosomes and expressed a functional
unc-29 gene under the control of the ndE-box promoter, which drives expression only in the vulval muscles (Harfe and
Fire, 1998). For this transgenic line, levamisole induced robust,
dose-dependent stimulation of egg-laying, indicating that the activity
of vulval muscle UNC-29 receptors was sufficient to promote egg-laying
(Fig. 1D). Thus, egg-laying in response to levamisole
resulted at least in part from the activity of UNC-29 receptors in the
vulval muscles.
Effects of long-term nicotine exposure on
egg-laying behavior
Using egg-laying as an assay, we investigated whether long-term
exposure to nicotinic agonists led to adaptation of
unc-29-dependent nicotinic responses. We therefore cultured
wild-type hermaphrodites for long (16 hr) periods in the presence of
nicotine and then assayed their egg-laying behavior. We observed that
chronic nicotine treatment did not prevent egg-laying muscle
contraction per se. However, the nicotine-adapted animals were strongly
resistant to stimulation of egg-laying by levamisole (Fig.
2A). Because these
animals still laid eggs in response to the neurotransmitter serotonin,
long-term nicotine treatment appeared to downregulate specifically the
egg-laying response to levamisole. This adaptive response to nicotine
was induced slowly, because loss of the levamisole response occurred
only after 1-3 hr of nicotine exposure (Fig. 2B).
Adaptation to nicotine was also surprisingly long lasting; when
nicotine-adapted animals were transferred to drug-free medium, even 24 hr after removal from nicotine most animals remained levamisole insensitive (Fig. 2C). Only at 36 hr after removal from
nicotine did the nicotine-adapted animals recover their full
responsiveness to levamisole. Thus, prolonged exposure to nicotine
resulted in a persistent loss of sensitivity to nicotinic agonists with
respect to egg-laying behavior. Because transgenic lines that expressed functional UNC-29 only in the vulval muscles also became levamisole insensitive after overnight nicotine treatment (Fig.
2D), this adaptation to nicotine appeared to affect
the nicotinic response of the vulval muscles themselves.
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Figure 2.
Long-term adaptation of levamisole receptors to
nicotine. A, Effect of overnight nicotine treatment on
the levamisole response. Shown are levamisole dose-response curves for
wild-type animals cultured overnight in the presence of nicotine (30 mM); the dose-response curve of naive animals under the
same conditions is shown as a control. Egg-laying was measured after 4 hr at the indicated condition. Points and error bars
indicate the mean and SEM of 18 or more trials; at 25 µM,
the nicotine-adapted animals laid significantly fewer eggs than did the
naive animals according to the Mann-Whitney rank-sum test
(*p < 0.001). These nicotine-adapted animals
responded normally to serotonin; egg-laying rates in M9 salts
containing 7.5 mM serotonin were as follows: naive,
2.7 ± 1.2 eggs/hr; nicotine-adapted, 2.5 ± 0.6 eggs/hr
(n = 12 in both cases). B, Time
course of nicotine adaptation. N2 hermaphrodites were placed on seeded
NGM containing 30 mM nicotine for the indicated length of
time and then assayed individually for egg-laying in M9 + 25 µM levamisole as described in A.
Points and error bars indicate the mean and SEM of 18 trials. C, Long-term persistence of nicotine adaptation.
The histogram shows the time course of recovery of levamisole responses
in nicotine-adapted animals. N2 animals were grown overnight on NGM
with 30 mM nicotine and then transferred to drug-free NGM
plates for the indicated times; egg-laying in response to 25 µM levamisole was tested as described.
Asterisks indicate time points in which the levamisole
response was significantly lower in the nicotine-adapted animals than
in the mock-treated animals grown on NGM without nicotine
(*p < 0.001). Vertical
bars and error bars indicate the mean and SEM of at
least 18 trials. D, Nicotine adaptation in animals
expressing only vulval muscle UNC-29 receptors. Shown are the
levamisole dose-response curves for nicotine-treated animals
expressing unc-29 only in the vulval muscles; naive
animals are shown as a control. Animals of the strain AQ497 (genotype
unc-29(x29); dpy-20(e1282); ljEx8 [18ndE-box:: unc-29,
dpy-20(+)]) were cultured overnight on NGM containing 30 mM nicotine and then assayed for egg-laying in response to
levamisole as described. Points and error bars represent
the mean and SEM of 20 or more trials. An asterisk
indicates significantly less egg-laying according to the Mann-Whitney
rank-sum test (*p < 0.001).
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Long-term nicotine treatment also caused changes in egg-laying behavior
in the absence of drug. Egg-laying in C. elegans occurs in a
specific temporal pattern; egg-laying events are clustered, with
periods of active egg-laying, or active phases, separated by long
inactive phases during which eggs are retained. Both the duration of
the inactive phases (intercluster intervals) and the duration of
intervals between egg-laying events in a cluster (intracluster intervals) model as exponential random variables with different time constants (Waggoner et al., 1998). Although wild-type
hermaphrodites that had been exposed to nicotine overnight could still
lay eggs, their pattern of egg-laying behavior was abnormal; their
overall rate of egg-laying was lower, and the inactive egg-laying phase was significantly longer than that of naive animals under the same
condition. This temporal pattern was similar to (although more severely
abnormal than) the pattern seen in animals carrying mutations in
unc-29 (Table 1). These results were therefore consistent with the possibility that the alteration in egg-laying behavior induced
by long-term nicotine exposure resulted at least in part from a loss of
unc-29 function in the vulval muscles.
Chronic nicotine treatment results in decreased
UNC-29 abundance
In principle, inactivation of UNC-29 receptor activity could occur
by a variety of mechanisms. One possibility we considered was that
chronic nicotine exposure could cause changes in the expression or
localization of the UNC-29 receptor protein, leading to a reduction in
the number of receptors at the cell surface. To investigate this
possibility, we used transgenic animals expressing GFP-tagged UNC-29
protein to examine the effect of long-term nicotine exposure on UNC-29
protein levels. The unc-29:: GFP chimera we used
functionally rescued the behavioral abnormalities of unc-29 loss-of-function mutations, including those associated with egg-laying, and the levamisole response mediated by the chimeric receptor protein
was also subject to adaptation by long-term nicotine treatment (Fig.
3A). Interestingly, we
observed that chronic nicotine treatment also caused a dramatic
reduction in the level of UNC-29:: GFP fluorescence in the
vulval muscles (Fig. 3B). This nicotine-induced reduction in
UNC-29:: GFP did not require the unc-29 promoter or
3'-untranslated region (3'-UTR), because transgenic animals that
expressed UNC-29:: GFP in the vulval muscles under the control of the ectopic myo-3 promoter and unc-54 3'-UTR
showed a qualitatively and quantitatively similar response (Fig.
3C). The time course of downregulation of
UNC-29:: GFP abundance was slow; 12-24 hr of nicotine
exposure was required to observe the maximum effect (Fig.
3D). The loss of UNC-29:: GFP fluorescence was not
merely the result of a nonspecific effect of nicotine on GFP, because long-term nicotine exposure did not alter the fluorescent intensity of
a VC-expressed VAMP:: GFP synaptic marker (Fig.
4A) or of GFP itself
expressed in the vulval muscles under the control of the tpa-1 promoter (see Fig. 5).
Thus, the inhibitory effect of chronic nicotine on vulval muscle nAChR
activity was apparently accompanied by a corresponding reduction in
UNC-29 receptor abundance in the vulval muscle cells, an effect most
likely mediated via a post-transcriptional regulatory mechanism.
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Figure 3.
Effect of long-term nicotine on UNC-29
receptor abundance. A, Nicotine response and adaptation
in animals expressing UNC-29:: GFP chimeric receptors. The
levamisole dose-response curves for nicotine-adapted (i.e., cultured
overnight on 30 mM nicotine) and naive animals of the
strain ZZ2171 (genotype, unc-29(x29);
Ex[pmyo-3:: unc-29:: GFP, rol-6d]), which
expresses GFP-tagged UNC-29 protein in vulval and body
muscles, are shown. Points and error bars
represent the mean and SEM of 20 or more trials.
Asterisks indicate significantly less egg-laying
according to the Mann-Whitney rank-sum test (*p < 0.05; **p < 0.02). Similar results were obtained
in animals expressing UNC-29:: GFP under the control of the
unc-29 promoter (data not shown). B,
Effect of chronic nicotine on vulval muscle UNC-29:: GFP
levels. Shown is a digital image of a nicotine-treated adult
hermaphrodite expressing UNC- 29:: GFP in the vulval
muscles under the control of the unc-29 promoter
(indicated by long arrows; the vulva
indicated by a short arrow). An image of
a naive animal of the same transgenic line (strain ZZ2001; genotype,
unc-29(x29); Ex[punc- 29:: unc-29:: GFP,
rol-6d]) is shown for comparison. C, Effect of
nicotine on vulval muscle UNC-29 levels in
pmyo-3:: unc-29:: GFP animals. Shown
are images of nicotine-adapted and naive ZZ2171 hermaphrodites, which
express UNC-29:: GFP in the vulval muscles under the control
of the muscle myosin promoter pmyo-3.
Long arrows indicate vulval muscles; a
short arrow indicates the vulva.
D, Time course of loss of UNC-29:: GFP
expression in the vulval muscles. ZZ2171 hermaphrodites were placed on
seeded NGM containing 30 mM nicotine for the indicated
length of time; fluorescence intensity of the vulval muscles is
indicated. Vertical bars and error bars
indicate the mean and SEM of five or more trials.
Asterisks indicate significantly less fluorescence
according to the Mann-Whitney rank-sum test (*p < 0.05; **p < 0.001). Lost UNC-29:: GFP
fluorescence was 60% recovered after 24 hr on drug-free medium and
completely recovered after 36 hr (data not shown).
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Figure 4.
Specificity of the long-term effects of nicotine
on egg-laying. A, Effect of long-term nicotine on
VC-vulval muscle synapses. Shown here is the expression pattern of a
synaptic marker (VAMP:: GFP) that illuminates the VC-vulval
muscle synapse, in both nicotine-treated (right) and
naive (left) adult animals (synapse identified by
long arrows; the vulva identified by a
short arrow). Animals of the strain NM670
(genotype, lin-15(n765); jsIs42x [punc-4:snb-1:: GFP,
lin-15(+)]) were cultured on NGM containing 30 mM
nicotine overnight, and images were captured as described in Materials
and Methods. Naive animals cultured on NGM alone are shown for
comparison. B, Effect of chronic levamisole treatment on
the levamisole response. Shown is the levamisole dose-response curve
of wild-type animals grown in the presence of levamisole; the
dose-response curve of naive animals under the same conditions is
shown as a control. N2 hermaphrodites were cultured overnight on NGM
containing 50 µM levamisole and then assayed individually
for egg-laying for 4 hr under the indicated condition as described in
Figure 2. Points and error bars indicate the mean and
SEM of 18 or more trials. C, Effect of chronic
levamisole treatment on UNC-29 receptor abundance. The histogram
compares the UNC-29:: GFP fluorescence intensity in the vulval
muscles between naive ZZ2171 animals (see Fig. 3) and ZZ2171 animals
treated overnight with levamisole (50 µM) or nicotine (30 mM). Vertical bars and error
bars indicate the mean and SEM of five or more trials;
asterisks indicate a statistically significant
difference from naive animals according to the Mann-Whitney rank-sum
test (*p < 0.02). D, Effect of
nicotine on vulval muscle UNC-29 protein levels in lev-1
mutants. Shown are digital images of naive (left) and
nicotine-treated (right) lev-1
hermaphrodites expressing UNC-29:: GFP in the vulval muscles.
Animals of the strain AQ533 (genotype, unc-29(x29); lev-1(e211);
Ex [punc-29:: unc-29:: GFP; rol-6d]) were
cultured on NGM containing 30 mM nicotine overnight;
UNC-29:: GFP fluorescence was measured as described previously
(long arrows indicate vulval muscles, a
short arrow indicates the vulva). Average
fluorescence intensities were 120 ± 20 (naive) and 0 ± 0 (nicotine-treated); the difference between these values was
statistically significant (p < 0.001)
according to the Mann-Whitney rank-sum test. Similar effects were seen
in lev-8 and lev-9 mutant animals (J. Kim
and W. R. Schafer, unpublished observations).
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Figure 5.
Expression of tpa-1 in the vulval
muscles. Shown are digital images of adult hermaphrodites of the
tpa-1A:: GFP-expressing strain TF6. In these
ventral/lateral views, the vulval muscles are strongly fluorescent and
are identified by arrows. Not shown in this
view are other fluorescent cells, including vulval epidermal cells, the
canal-associated neuron (CAN), and various unidentified head and
tail neurons (Tabuse and Miwa, unpublished observations). Expression
was never detected in the egg-laying motoneurons VC4, VC5, or the
HSNs. Punctate fluorescence in the body is caused by
autofluorescence of gut granules.
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Interestingly, the more specific nicotinic agonist levamisole appeared
to be less potent in inducing adaptation than was nicotine. Although
animals treated with levamisole overnight were less sensitive to
subsequent stimulation of egg-laying by levamisole, they retained significantly more responsiveness to levamisole than did
nicotine-adapted animals (Fig. 4B). Moreover,
long-term exposure to levamisole caused only a small (although
significant) reduction in the abundance of GFP-tagged UNC-29 protein in
the vulval muscles (Fig. 4C). One possible explanation of
these results was that nicotine and levamisole might interact with the
UNC-29 receptor molecule in different ways; alternatively, the
long-term effect of nicotine on UNC-29 receptors might depend on a
second, levamisole-insensitive nicotinic receptor in the vulval
muscles. In agreement with the latter hypothesis, we found that the
acute egg-laying response to nicotinic agonists was genetically
separable from the long-term response to nicotine. Several genes,
including lev-8, lev-9, and lev-1, are required
for the acute stimulation of egg-laying by levamisole (J. Kim, D. S. Poole, and W. R. Schafer, unpublished observations), although
they are not necessary for the assembly of levamisole-binding nAChRs
(Lewis et al., 1987; Fleming et al., 1997). However, we observed that
none of these genes was required for the downregulation of
UNC-29:: GFP abundance in the vulval muscles in response to
chronic nicotine treatment (Fig. 4D). Thus, although
levamisole-sensitive UNC-29 receptors may be necessary for the acute
effects of nicotine on egg-laying, a second nicotinic receptor may be
at least partially responsible for nicotine's long-term effects on
this behavior.
The PKC homolog TPA-1 is required for
UNC-29 downregulation
What genes are required for nicotine adaptation in the egg-laying
muscles? To investigate this question, we assayed C. elegans mutants with defects in genes encoding signaling molecules that function in the vulval muscles. One such gene was tpa-1,
which encodes a C. elegans isoform of protein kinase C. Recessive mutations in tpa-1 confer resistance to phorbol
esters but do not dramatically impair the health, fertility, or
behavior of the worm (Tabuse et al., 1989). We had demonstrated
previously that TPA-1 is required for the acute stimulation of
egg-laying by serotonin (Waggoner et al., 1998). To determine whether
tpa-1 was actually expressed in the vulval muscles, we
generated transgenic lines expressing a GFP reporter under the control
of one of the two tpa-1 promoters. We observed that one of
these promoter fusions, tpa-1A:: GFP, was strongly
expressed in the vulval muscles, as well as in vulval epidermal cells
and a variety of neurons, including the canal-associated neuron and
many unidentified cells in the head and tail (Fig. 5). The other
promoter fusion, tpa-1B:: GFP, was expressed in the
lateral epidermis and in a few head neurons (Y. Tabuse and J. Miwa,
unpublished observations). Thus, tpa-1 indeed appeared to
encode an isoform of protein kinase C that was expressed in the vulval muscles.
To assess the possible role of tpa-1 in nicotine adaptation,
we first assayed the effect of tpa-1 mutations on the
induction of egg-laying by levamisole and on the inactivation of this
response by long-term nicotine treatment. We found that naive
tpa-1 mutant animals laid eggs in response to levamisole
over the same range of concentrations as did wild-type, although the
magnitude of this stimulation was somewhat lower in the
tpa-1 mutant (Fig. 6A). Strikingly,
however, we observed that tpa-1 mutants showed little or no
reduction in levamisole-induced egg-laying after overnight exposure to
nicotine (Fig. 6B), indicating that tpa-1 mutant animals were completely defective in nicotine adaptation. We
also tested the effect of tpa-1 on the ability of nicotine to decrease UNC-29 receptor abundance in the vulval muscles. We observed that tpa-1 mutant animals expressing the
UNC-29:: GFP protein chimera in the vulval muscles retained
high levels of fluorescence even after overnight nicotine treatment
(Fig. 6C,D). Thus, the tpa-1-encoded isoform of
PKC appeared to be necessary for the nicotine-induced downregulation of
UNC-29 receptor abundance and biological activity in the vulval
muscles.
View larger version (46K):
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|
Figure 6.
Dependence of nicotine adaptation on PKC.
A, Response of tpa-1 mutants to
levamisole. Levamisole dose-response curves for wild-type (N2) and
tpa-1 mutant animals are shown. Animals were assayed for
4 hr under the indicated condition; points and error
bars indicate the mean and SEM of at least 12 trials. B,
Defect of tpa-1 mutants in nicotine adaptation.
Levamisole dose-response curves (assayed at 4 hr) for wild-type and
tpa-1 mutant strains after overnight treatment with 30 mM nicotine are shown. Points and error bars
indicate the mean and SEM of at least 12 trials. The responses of both
tpa-1 mutants were significantly greater than that of
the wild-type under this condition according to the Mann-Whitney
rank-sum test (*p < 0.001). By the same test, the
tpa-1 mutants showed no significant reduction in
response to levamisole after overnight nicotine treatment
(p > 0.5). C, Effect of
nicotine on vulval muscle UNC-29 protein levels in tpa-1
mutants. Shown here are digital images of naive (left)
and nicotine-treated (right) tpa-1 mutant
hermaphrodites expressing UNC-29:: GFP in the vulval muscles
under the control of the myo-3 promoter (see Fig. 4).
Long arrows indicate vulval muscles, and a
short arrow indicates the vulva. Animals
of the strain AQ521 (genotype, unc-29(x29); tpa-1(k501); Ex
[pmyo-3:: unc-29:: GFP; rol-6d]) were
cultured on NGM containing 30 mM nicotine overnight;
UNC-29:: GFP fluorescence was measured as described
previously. D, Quantification of UNC-29:: GFP
and SNB-1:: GFP fluorescence in nicotine-treated and untreated
animals. The average intensity of fluorescence for nicotine-treated and
naive animals expressing UNC-29:: GFP protein under the
control of the unc-29 promoter
(unc-29:: GFP) or the
myo-3 promoter
(myo-3:: unc-29:: GFP) or the
synaptic marker VAMP:: GFP under the control of the
VC-specific unc-4 promoter
(punc-4:: snb-1:: GFP) are
shown. Asterisks indicate significantly less
fluorescence after nicotine treatment according to the Mann-Whitney
rank-sum test (*p < 0.001). The histogram and
error bars represent the mean and SEM of five trials.
|
|
| |
DISCUSSION |
Nicotinic agonists have both acute and chronic effects on
egg-laying behavior in C. elegans. We have shown that the
acute stimulation of egg-laying by nicotine and the nicotinic agonist levamisole is mediated by nAChRs containing the subunit protein UNC-29.
We found that these UNC-29 receptors are expressed in the vulval
muscles, and expression of functional UNC-29 protein in the vulval
muscles alone is sufficient to confer egg-laying sensitivity to
nicotinic agonists. Thus, nicotinic agonists appear to stimulate
egg-laying at least in part via direct excitation of UNC-29-containing
receptors in the vulval muscles. However, because unc-29
mutants are still capable of laying eggs, UNC-29 receptors do not
appear to be necessary for egg-laying muscle contraction. The
dispensability of UNC-29 for muscle contraction could be caused by a
second, levamisole-insensitive nAChR in the vulval muscles that
displays some functional redundancy with the UNC-29 receptor, as has
been observed in the C. elegans body muscle (Richmond and
Jorgensen, 1999). Alternatively, the vulval muscles, like the C. elegans pharyngeal muscles, could possess intrinsic contractile
activity and use nicotinic receptors only as a means to induce more
rapid contraction (Raizen and Avery, 1994).
Chronic exposure to nicotinic agonists had dramatic effects on C. elegans egg-laying behavior that were long lasting and specific. Overnight treatment with nicotine induced a strong and persistent resistance to the stimulation of egg-laying by levamisole and resulted
in an altered egg-laying pattern resembling that of nicotinic receptor-deficient mutants. Yet this adaptation to nicotine did not
prevent egg-laying muscle contraction per se, nor did it affect the
stimulation of egg-laying by noncholinergic agents such as serotonin.
Chronic nicotine treatment also attenuated the levamisole responses of
animals expressing functional UNC-29 protein only in the vulval
muscles, indicating that the behavioral effects of long-term nicotine
treatment result at least in part from effects on the vulval muscles
themselves. Interestingly, chronic exposure to levamisole, an agonist
that appears to be somewhat specific for UNC-29-containing receptors,
downregulated UNC-29 receptor abundance only moderately. Moreover, the
ability of nicotine to downregulate UNC-29 receptor levels was
independent of several genes that are required for acute stimulation of
egg-laying by levamisole, including another candidate subunit of the
levamisole receptor (i.e., lev-1). Thus, the regulation by
nicotine of UNC-29 receptor abundance in the vulval muscles may not be
simply a consequence of prolonged activation of levamisole receptors in
the vulval muscles but rather might depend on the activity of other
levamisole-insensitive nicotinic receptors in the egg-laying muscles
and/or neurons.
Interestingly, the loss of behavioral sensitivity to nicotinic agonists
was accompanied by a concomitant reduction in UNC-29 protein abundance
in the vulval muscle cells. This effect on UNC-29 protein level was
independent of the unc-29 promoter, because downregulation
still occurred in transgenic animals that expressed UNC-29:: GFP under the control of the myo-3 muscle
myosin promoter. Downregulation was also independent of the
unc-29 3'-UTR sequences, which in nearly all cases are the
critical determinant of mRNA stability, export, and translatability in
C. elegans (Ahringer and Kimble, 1991; Seydoux, 1996; Graves
et al., 1999). Because the unc-29-coding region appeared to
be sufficient to confer UNC-29 downregulation in the vulval muscles,
this suggests that this downregulation most likely involves a
post-translational mechanism. Post-translational regulation of
nicotinic receptor levels has been observed in a number of vertebrate
systems (Marks et al., 1992; Peng et al., 1994; Bencherif et al.,
1995); however, the genetic and molecular requirements for these
processes remain primarily uncharacterized. Because the chronic effect
of nicotine on C. elegans egg-laying behavior depends on a
process at least formally analogous to nAChR downregulation in
vertebrates, genetic analysis of these processes in nematodes may
provide important clues to the molecular basis of nAChR regulation in
other organisms.
One gene that we found to be essential for the nicotine-induced
downregulation of UNC-29 abundance was tpa-1, which encodes a homolog of protein kinase C. In contrast to wild-type animals, tpa-1 mutants maintained high levels of UNC-29 receptors in
the vulval muscles and remained sensitive to the behavioral effects of
levamisole after long-term exposure to nicotine. The mechanistic basis
for why TPA-1/PKC is required for nicotine regulation of UNC-29
receptor abundance remains to be determined. Probably the simplest
model for TPA-1 action is that direct phosphorylation of one or more
subunits of the nicotinic receptors in the vulval muscles by TPA-1/PKC
somehow targets them for increased degradation. The UNC-29 protein,
like other candidate subunits of the levamisole receptor (e.g., LEV-1
and UNC-38), contains consensus sequences for PKC phosphorylation
within the M3-M4 cytoplasmic loop (Pearson and Kemp, 1991; Fleming et
al., 1997), and preliminary biochemical experiments indicate that these
sequences can serve as substrates for the human ortholog of TPA-1
in vitro (L. E. Waggoner, unpublished observations).
Thus, direct phosphorylation of one or more subunits of the vulval
muscle levamisole receptors is a reasonable possibility. It is well
established that phosphorylation of the M3-M4 loop by protein kinases
can modulate the activity of nAChRs by enhancing their rate of
desensitization (Huganir and Greengard, 1983; Huganir et al., 1984,
1986; Eusebi et al., 1985; Downing and Role, 1987; Safran et al., 1987;
Hopfield et al., 1988). It is reasonable to suppose that receptor
phosphorylation by PKC may also be linked to processes affecting nAChR
abundance, such as protein targeting or degradation. In this regard, it
is interesting to note that in rat muscle cells, a variety of
intracellular signaling pathways have been shown to regulate the
degradation rate of nicotinic receptors during formation of the
neuromuscular junction (O'Malley et al., 1997). Alternatively, some or
all of the effects of PKC could be indirect, and the actual substrates
of PKC could be molecules that directly or indirectly regulate the
stability or targeting of the receptor. For example, rapsyn, a
peripheral membrane protein that acts to stabilize nicotinic receptors
in skeletal muscle (Wang et al., 1999), contains a potential target
sequence for PKC; thus, phosphorylation of a C. elegans
rapsyn might inhibit its ability to stabilize UNC-29 receptors, leading
to increased receptor turnover. It is also possible that PKC signaling
in neighboring cells, for example, the vulval epidermis, could
influence nicotinic receptor abundance in the vulval muscles via
neuroendocrine signaling. The availability of simple and robust assays
for nicotinic receptor activity and abundance in C. elegans
should make it possible to use genetic analysis to identify the PKC
target(s) relevant to nicotine adaptation, along with other molecules
that participate in long-term responses to nicotine.
| |
FOOTNOTES |
Received July 5, 2000; revised Aug. 24, 2000; accepted Sept. 5, 2000.
This work was supported by the National Institute on Drug Abuse Grants
DA 11556 and DA 12891 (W.R.S.); additional support for work in our lab
was provided by National Science Foundation Award IBN-9723250 (W.R.S.),
awards from the Beckman, Sloan, and Klingenstein Foundations (W.R.S.),
and a National Institutes of Health predoctoral training grant (L.E.W).
We express our appreciation to Jim Lewis for his generous assistance.
We thank Jim Lewis, Mike Nonet, Kelly Liu, and the
Caenorhabditis Genetics Center for strains; Jinah Kim
for assistance in strain construction; and Cori Bargmann, Darwin Berg,
Cynthia Kenyon, and Rachel Kindt for comments on this manuscript.
Correspondence should be addressed to Dr. William Schafer, Department
of Biology, University of California, San Diego, 9500 Gilman Drive, La
Jolla, California 92093-0349. E-mail: wschafer{at}ucsd.edu.
| |
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I. A. Bany, M.-Q. Dong, and M. R. Koelle
Genetic and Cellular Basis for Acetylcholine Inhibition of Caenorhabditis elegans Egg-Laying Behavior
J. Neurosci.,
September 3, 2003;
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8060 - 8069.
[Abstract]
[Full Text]
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B. D. Ackley, S. H. Kang, J. R. Crew, C. Suh, Y. Jin, and J. M. Kramer
The Basement Membrane Components Nidogen and Type XVIII Collagen Regulate Organization of Neuromuscular Junctions in Caenorhabditis elegans
J. Neurosci.,
May 1, 2003;
23(9):
3577 - 3587.
[Abstract]
[Full Text]
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S. M. Trailovic, A. P. Robertson, C. L. Clark, and R. J. Martin
Levamisole receptor phosphorylation: effects of kinase antagonists on membrane potential responses in Ascaris suum suggest that CaM kinase and tyrosine kinase regulate sensitivity to levamisole
J. Exp. Biol.,
December 15, 2002;
205(24):
3979 - 3988.
[Abstract]
[Full Text]
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W. M. Nuttley, S. Harbinder, and D. van der Kooy
Regulation of Distinct Attractive and Aversive Mechanisms Mediating Benzaldehyde Chemotaxis in Caenorhabditis elegans
Learn. Mem.,
May 1, 2001;
8(3):
170 - 181.
[Abstract]
[Full Text]
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J. Kim, D. S. Poole, L. E. Waggoner, A. Kempf, D. S. Ramirez, P. A. Treschow, and W. R. Schafer
Genes Affecting the Activity of Nicotinic Receptors Involved in Caenorhabditis elegans Egg-Laying Behavior
Genetics,
April 1, 2001;
157(4):
1599 - 1610.
[Abstract]
[Full Text]
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TOP
ABSTRACT
INTRODUCTION
