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 Previous Article | Next Article 
The Journal of Neuroscience, January 1, 1998, 18(1):164-173
Phosphorylation of Mammalian Olfactory Cyclic Nucleotide-Gated
Channels Increases Ligand Sensitivity
Frank
Müller,
Wolfgang
Bönigk,
Federico
Sesti, and
Stephan
Frings
Forschungszentrum Jülich, Institut für Biologische
Informationsverarbeitung, 52425 Jülich, Germany
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ABSTRACT |
In vertebrate olfactory sensory neurons, odorant receptors couple
the sensory signal to the synthesis of the second messenger cAMP.
Cyclic nucleotide-gated (CNG) channels are activated by binding of cAMP
and conduct a depolarizing receptor current that leads to electrical
excitation of the neuron. The sensitivity of olfactory CNG channels for
cAMP can be significantly reduced by binding of calmodulin to a
regulatory domain that resides within the N-terminus of the  -subunit
of the channel. This regulatory domain also contains a consensus
phosphorylation sequence for protein kinase C (PKC). We have
investigated the effect of channel phosphorylation by PKC and found
that phosphorylation increases ligand sensitivity without counteracting
modulation of the channel by calmodulin. We have identified the amino
acid residue that is phosphorylated by PKC and have localized three
isoforms of PKC in olfactory sensory cilia. The results of this study
provide information about the control of ligand sensitivity in
olfactory CNG channels by an intrinsic regulatory domain, representing
both a calmodulin-binding site and a substrate for PKC.
Key words:
cyclic nucleotide-gated channels; olfaction; sensory
transduction; protein kinase C; protein phosphorylation; phorbol
ester
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INTRODUCTION |
Electrical excitation of olfactory
sensory neurons (OSNs) in vertebrates is initiated by binding of
odorants to receptor proteins in the plasma membrane of chemosensory
cilia (Buck and Axel, 1991 ; Buck, 1992). The subsequent activation of
adenylyl cyclase (Pace et al., 1985; Sklar et al., 1986; Lowe et al.,
1989; Pfeuffer et al., 1989; Bakalyar and Reed, 1990; Boekhoff et al.,
1990) causes an increase of the cAMP concentration within the ciliary lumen, and cyclic nucleotide-gated (CNG) cation channels are activated by binding of cAMP (Nakamura and Gold, 1987; Kurahashi, 1989; Firestein
et al., 1991; Frings et al., 1992; Lowe and Gold, 1993a; Zufall et al.,
1994). CNG channels are expressed at high density in the ciliary
membrane (Kurahashi and Kaneko, 1991) and conduct a receptor current
that leads to depolarization and electrical excitation of the
neuron.
Native CNG channels form hetero-oligomeric complexes (Chen et al.,
1993; Bradley et al., 1994; Liman and Buck, 1994; Körschen et
al., 1995; Liu et al., 1996). The best studied olfactory channel polypeptide is the -subunit, cloned from olfactory epithelia of
various species (Dhallan et al., 1990; Ludwig et al., 1990; Goulding et
al., 1992). Heterologously expressed -homomeric channels resemble
native olfactory CNG channels in many respects (sensitivity to cGMP,
lack of ligand-induced desensitization, cation permeability, blockage
by divalent cations, and modulation by calmodulin); however, they
clearly differ in some functional properties (sensitivity to cAMP and
channel gating). A number of key characteristics of olfactory CNG
channels have been elucidated through studies of heterologously
expressed -subunits, and a particularly significant finding is that
the ligand sensitivity is reduced by calmodulin (Chen and Yau, 1994;
Liu et al., 1994) and, possibly, other Ca2+-binding
proteins (Balasubramanian et al., 1996). The calmodulin-mediated modulation is expected to promote channel closure during adaptation when Ca2+ entry through CNG channels increases the
ciliary Ca2+ concentration (Leinders-Zufall et al.,
1997). Reduction of ligand sensitivity by binding of
Ca2+/calmodulin constitutes a negative feedback
mechanism that terminates the receptor current (Kurahashi and Menini,
1997). Thus, regulation of ligand sensitivity is an important aspect
for the role of CNG channels in olfactory signal transduction.
The activity of many ion channels is modulated through phosphorylation
and dephosphorylation by a variety of protein kinases and phosphatases
(for review, see Levitan, 1994). For CNG channels from rod
photoreceptors, there is some evidence that phosphorylation modulates
ligand sensitivity (Gordon et al., 1992). We investigated the
expression pattern of protein kinase C (PKC) isoforms in rat OSNs and
measured the ligand sensitivity of heterologously expressed -homomeric olfactory CNG channels after stimulation of PKC. Here we
show that the  ,  , and  isoforms of PKC are expressed in rat
OSNs, and that activation of PKC leads to an increased ligand sensitivity of -homomeric channels. The effect of PKC is mediated by
a serine residue located within a regulatory domain in the N-terminal
region of the channel, which also harbors the binding site for
calmodulin.
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MATERIALS AND METHODS |
Immunohistochemistry. Adult Wistar rats were
anesthetized with fluothane and decapitated. The olfactory epithelium
was excised and immersion-fixed in 0.1 M phosphate buffer
(PB), pH 7.4, containing 4% paraformaldehyde, for 1 hr. After several
rinses in PB, the tissue was cryoprotected in PB containing 30%
sucrose overnight, embedded in OCT compound (Miles, Elkhart, IN), and
frozen at  20°C. Sixteen-micrometer-thick vertical sections
(perpendicular to the mucosal surface) were cut on a cryostat and
collected on gelatinized slides. Sections were air-dried, fixed in 4%
paraformaldehyde for 5 min, washed in PB, and incubated in 10% normal
goat serum (NGS; Sigma, St. Louis, MO) and 0.5% Triton X-100 in PB for
1 hr. Anti-PKC antibodies (Transduction Laboratories, Lexington, KY)
were diluted in 5% NGS, 0.5% Triton X-100, and 0.05%
NaN3 in PB (, 1:1000;  , 1:2000; , 1:4000; ,
1:500;  , 1:100; , 1:250; µ, 1:500;  , 1:100;  , 1:200).
Sections were incubated overnight at room temperature with primary
antibodies. After several rinses in PB, sections were incubated in
anti-mouse-biotin (Sigma, 1:80) diluted in 5% NGS and 0.5% Triton
X-100 for 1.5 hr, washed in PB, and subsequently incubated with
ExtrAvidin-HRP (Sigma, 1:300) diluted in PB for 1.5 hr. After several
rinses in PB, antibodies were visualized using diaminobenzidine (DAB)
as a chromogen (0.05% DAB and 0.01% H2O2 in
PB). Sections were covered with Mowiol (Hoechst Pharmaceuticals,
Frankfurt, Germany) and photographed using Nomarski optics.
Electrophysiological measurements of ligand sensitivity.
Human embryonic kidney (HEK) 293 cells were transfected with cDNA encoding the olfactory CNG channel -subunit of rat (Dhallan et al.,
1990) or cattle (Ludwig et al., 1990) by calcium phosphate coprecipitation (Chen and Okayama, 1987) using the pcDNAI vector (Invitrogen, San Diego, CA) as described previously (Baumann et al.,
1994). During phorbol ester treatment and patch-clamp experiments (Hamill et al., 1981), cells were held in a solution containing (in
mM): 120 NaCl, 5 NaOH, 3 KCl, 1 CaCl2, 3 MgCl2, 50 glucose, and 10 HEPES, pH 7.4. For
patch-clamp experiments with rat channels (inside-out configuration),
both the external (pipette) and the internal (bath) solutions contained
(in mM): 110 NaCl, 12 NaOH, 2 EDTA, and 10 HEPES, pH 7.4. For experiments with bovine channels, the external (pipette) solution
contained (in mM): 120 NaCl, 25 NaOH, 3 KCl, 10 EGTA, and
10 HEPES, pH 7.4. The internal (bath) solution contained (in
mM): 120 KCl, 25 KOH, 5 NaCl, 10 EGTA, and 10 HEPES, pH
7.2. In the calmodulin experiments, the composition of the internal
solution was (in mM): 140 KCl, 10 KOH, 5 NaCl, 0.3 CaCl2, and 10 HEPES, pH 7.2. Bovine brain calmodulin
(Calbiochem, La Jolla, CA) was dissolved at 100 µM in
distilled water and added to the internal solution containing 0.3 mM Ca2+. Phorbol 12-myristate 13-acetate
(PMA, 4- isoform; Sigma) and 4--PMA (Alexis, San Diego, CA) were
dissolved in DMSO at 1 mg/ml (1.62 mM) and used at a final
concentration of 0.5 µM. Cells were incubated with
phorbol ester for 30-60 min at 37°C, after which patch-clamp
experiments were performed for up to 2 hr. cAMP and cGMP were obtained
from Sigma, and 8-bromo-cAMP (8-Br-cAMP) was obtained from Biolog
(Bremen, Germany). All cyclic nucleotide concentrations >1
µM were measured spectrophotometrically ( = 260 nm;
= 15,000 cm2/mol for all cyclic nucleotides).
After current recordings were obtained with a series of cyclic
nucleotide concentrations, leak currents (recorded in internal solution
without cyclic nucleotides) were subtracted, and a dose-response
relation was constructed for each patch by fitting to the data a
Hill-type function, I/Imax = cn/[cn + Kn1/2],
where Imax is the current at saturating
concentrations of the ligand, c is the ligand concentration,
n is the Hill coefficient, and K1/2 is the
concentration for half-maximal channel activation. The mean values for
K1/2 and n from all patches were used to
construct the solid lines in the dose-response plots. The figures also
show the mean values of I/Imax for
each concentration with SDs. In the text, results are given as
means ± SD and numbers of experiments in parentheses. All
dose-response relations were obtained at a membrane voltage
(Vm) of +40 mV.
Construction of mutant bovine CNG channels. The truncated
mutants MD30 and MP101 were constructed by PCR using pCHOLF102
(Altenhofen et al., 1991) as template and the following primers: a 5
adapter primer [containing an EcoRV restriction site, a
consensus sequence for eukaryotic ribosomal-binding site (Kozak, 1984),
an initiation codon, and 18 nucleotides following the initiation
codon] and a gene-specific 3 primer. Using suitable restriction
sites, the original sequence of pCHOLF102 was replaced by the truncated
fragments. The point mutations S93A and S93E were introduced by PCR
according to the method of Herlitze and Koenen (1990) using pCHOLF102
as template and oligonucleotides containing the desired nucleotide substitutions. All mutations were verified by sequencing the inserted PCR fragment, and the recombinant cDNA sequences were subcloned into
the pcDNAI vector.
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RESULTS |
Three isoforms of PKC are expressed in rat
olfactory epithelium
A set of nine different monoclonal antibodies was used to localize
PKC immunoreactivity in vertical sections of rat olfactory epithelium.
The , , and isoforms are expressed in the sensory cilia of
OSNs (Fig. 1A, ;
B, ; D, ). Labeling appears as a dark
reaction product within the mucociliary layer, which consists of
olfactory mucus and the sensory cilia. No staining above background could be found in somata of OSNs, in supporting cells, or in the submucosal tissue. When the primary antibodies were omitted, no immunoreactivity was found in cilia (Fig. 1C). PKC was
also found in dendritic knobs of OSNs. In the tissue section shown in
Figure 1E, most of the cilia were lost during
preparation, thus exposing the dendritic knobs, which can be seen at
higher magnification. All knobs show strong immunolabeling
(arrow). The localization of three PKC isoforms in
chemosensory cilia and of PKC in dendritic knobs suggests a role of
these enzymes in chemoelectrical signal transduction. With antibodies
raised against the PKC , , , µ, , and isoforms, no
immunolabeling was observed, suggesting that these isoforms are not
expressed at all or at levels below detection threshold in OSNs.
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Figure 1.
PKC-like immunoreactivity in vertical sections of
the rat olfactory epithelium. All photomicrographs were taken with
Nomarski optics. A, A monoclonal antibody against PKC
strongly labeled olfactory cilia (c).
OE, Olfactory epithelium; SM, submucosal layer. B, PKC-like immunoreactivity in cilia.
C, Omission of the first antibody abolished
immunostaining in cilia. D, E, PKC-like immunoreactivity is strong in cilia (D) but also
in dendritic knobs (E). In E, the
tissue was sectioned slightly oblique. Most of the cilia were lost
during preparation of this tissue, enabling clear identification of
immunolabeled dendritic knobs (arrow). Scale bar:
A-D, 50 µm; E, 20 µm.
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Phorbol ester treatment increases ligand sensitivity in olfactory
CNG channels
Both PKC and olfactory CNG channels are expressed specifically in
sensory cilia and dendritic knobs of OSNs. We, therefore, looked for
effects of increased PKC activity on ligand sensitivity of olfactory
CNG channels. For these studies, we used heterologously expressed
-homomeric CNG channels from rat (Dhallan et al., 1990) and bovine
(Ludwig et al., 1990) olfactory epithelium, which display almost
identical properties with regard to activation by cAMP and cGMP. HEK
293 cells expressing olfactory channels were incubated for 30-60 min
with 0.5 µM PMA, a phorbol ester that specifically activates most PKC isoforms by substituting for diacylglycerol (Nishizuka, 1986). Cells were then transferred to PMA-free solution, and inside-out patches were taken and exposed to a series of solutions containing various concentrations of cAMP. The
I-Vm relations depicted in Figure
2A show macroscopic
currents activated by cAMP in a patch from an untreated cell expressing
rat CNG channels. Figure 2B shows
I-Vm relations from a cell treated
with 0.5 µM PMA. The cAMP sensitivity of the channels was
strongly increased so that lower cAMP concentrations were sufficient
for activation. The dose-response relations in Figure 2C
illustrate the shift of current activation to lower cAMP concentrations
induced by PMA. The cAMP sensitivity of channels from control cells
(circles) was characterized by an activation constant,
K1/2, of 75 ± 12 µM cAMP, and a Hill
coefficient, n, of 2.5 ± 0.4 (11 patches). These
values are in good agreement with earlier reports (Dhallan et al.,
1990; Altenhofen et al., 1991; Bradley et al., 1994; Liman and Buck,
1994). Fitting the Hill equation to the data from PMA-treated cells
(triangles) yielded K1/2 of 12.7 ± 1.3 µM and n of 2.2 ± 0.16 (three patches).
The PMA-induced increase of cAMP sensitivity persisted in excised
patches and did not depend on the presence of Ca2+,
indicating that PMA treatment causes a stable, probably covalent modification of the channels.
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Figure 2.
Modulation of cAMP sensitivity of rat
-homomeric CNG channels by treatment with 0.5 µM PMA.
A, I-Vm
relations recorded from an inside-out patch from an untreated HEK 293 cell expressing rat olfactory channels. The respective cAMP
concentrations are indicated at each trace.
B, I-Vm
relations obtained from a cell after treatment with 0.5 µM PMA, showing increased cAMP sensitivity of CNG
channels. C, Dose-response relations for current
activation by cAMP at Vm = +40 mV in control
(circles) and PMA-treated (triangles) cells. Solid lines were constructed by fitting to the
normalized current a Hill-type function, as described in Materials and
Methods. Fitting parameters were K1/2 = 75 ± 12 µM; n = 2.5 ± 0.4 (11 patches) for control and K1/2 = 12.7 ± 1.3 µM; n = 2.2 ± 0.16 (3 patches) for PMA-treated channels.
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Olfactory CNG channels display a much higher sensitivity to several
analogs of cAMP, including 8-Br-cAMP and 8-chlorophenylthio-cAMP (Frings et al., 1992). We tested whether PMA treatment would also increase 8-Br-cAMP sensitivity and obtained from dose-response relations for control cells a K1/2 of 13.3 ± 1.7 µM, with n = 2.2 ± 0.1 (five
patches) and for channels from PMA-treated cells a K1/2 of
3.0 ± 1.12 µM, with n = 1.70 ± 0.17 (five patches) (data not shown). Thus, PMA treatment increased
the ligand sensitivity for cAMP and 8-Br-cAMP to a similar extent.
Olfactory CNG channels can also be activated by cGMP. In fact, the cGMP
sensitivity of -homomeric channels is much higher than the
sensitivity to cAMP and closely resembles the cGMP sensitivity of the
native channel (Dhallan et al., 1990; Altenhofen et al., 1991; Frings
et al., 1992). We investigated whether the sensitivity for cGMP is
affected by PMA treatment. Figure
3A shows a family of
I-Vm relations for cGMP-activated
current obtained from a control cell expressing bovine CNG channels
(without PMA), and Figure 3B shows
I-Vm relations from a PMA-treated
cell. The corresponding dose-response relations in Figure
3C were fitted with K1/2 of 1.45 ± 0.36 µM; n = 2.23 ± 0.33 (seven patches)
for control currents (filled circles) and with
K1/2 of 0.30 ± 0.1 µM;
n = 2.03 ± 0.24 (18 patches) for currents from
PMA-treated cells (triangles), indicating similar effects on
the sensitivities for cGMP and cAMP.
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Figure 3.
Increase of cGMP sensitivity in bovine
-homomeric CNG channels after PMA treatment. A,
I-Vm relations recorded from
an inside-out patch of untreated HEK 293 cells expressing bovine
olfactory CNG channel -subunits. B,
I-Vm relations from a patch
after treatment of the cell with PMA showing activation of channel
current by lower cGMP concentrations. C, Dose-response
relations for channel activation by cGMP obtained from patches without
(filled circles) and with
(triangles) PMA treatment (Vm = +40 mV). Fitting parameters are given in Table 1. The PMA isomer
4--PMA, which does not activate PKC, does not modulate sensitivity
in olfactory CNG channels (open circles).
D, Single-channel currents recorded from an
-homomeric olfactory CNG channel. The recordings were obtained from
an inside-out patch of an untreated cell with 2 µM cGMP,
at the indicated values of Vm. Sample rate,
3 kHz; low-pass filter, 1 kHz. E, Single-channel recordings from a PMA-treated cell with 0.5 µM cGMP.
F, Voltage dependence of the single-channel current of
control (circles) and PMA-treated
(triangles) channels. The slope conductances are 36.8 ± 2.7 pS (11 patches) for control, and 38.2 ± 3.2 pS
(4 patches) for PMA-treated channels.
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To distinguish stimulation of PKC by PMA from unspecific effects of the
phorbol ester, we repeated the experiments using 4--PMA, a PMA
isomer that does not activate PKC (VanDuuren et al., 1979). As shown in
Figure 3C (open circles), the cGMP sensitivity of the channels was not significantly changed by 4--PMA
(K1/2 = 1.48 ± 0.13 µM;
n = 2.4 ± 0.24; six patches). We, therefore,
conclude that the PMA effect on ligand sensitivity is specifically
mediated by PKC, and that the activation of endogenous PKC in HEK 293 cells leads to phosphorylation of the olfactory channel protein,
resulting in increased sensitivity of the channel to its ligand.
Most patches maintained high ligand sensitivity after patch excision.
However, 3 of 18 patches showed a partial or complete reset of cGMP
sensitivity to control values 15-25 min after excision (data not
shown). In one patch, the current activation shortly after excision
from a PMA-treated cell was characterized by
Imax = 745 pA, K1/2 = 0.3 µM, and n = 2.2 (Vm = +40 mV). Twenty-five minutes later,
Imax was 720 pA, whereas K1/2 was
increased to ~2 µM, indicating that the ligand
sensitivity had been reset to the control value. We cannot explain this
observation, but, possibly, some phosphatase activity was preserved in
the excised patch configuration, sufficient to dephosphorylate the
channels in these patches.
To test for possible effects of phosphorylation on channel conductance
in cGMP-activated channels, we obtained single-channel recordings from
control cells (Fig. 3D) and from PMA-treated cells (Fig.
3E). The recordings from control cells were obtained at 2 µM cGMP and the indicated values of
Vm. The voltage dependence of single-channel
current derived from these recordings is shown in Figure 3F
(circles) and indicates a conductance of 36.8 ± 2.7 pS
(11 patches) for control channels. Single-channel traces from PMA-treated cells were recorded at 0.5 µM cGMP to obtain
a comparable open probability of the channels. The conductance of
phosphorylated channels (38.2 ± 3.2 pS; four patches) is not
significantly different from the value observed in untreated channels
(Fig. 3F, triangles). Thus, phosphorylation enhances the
ligand sensitivity of olfactory CNG channels by increasing their open
probability without affecting their conductance.
The PKC effect is mediated by a single amino acid residue
Recently it was shown (Liu et al., 1994) that the ligand
sensitivity of olfactory CNG channels is controlled by a stretch of
amino acid residues within the cytoplasmic N-terminal region of the
-subunit (Fig. 4A,
CaM, FR). This domain exhibits a high degree of sequence
homology among all cloned olfactory -subunits (Fig.
4B). It contains a binding site for calmodulin (Fig.
4, CaM) and a flanking region (Fig. 4, FR)
that extends in the C-terminal direction from the calmodulin-binding
site. Both regions control the ligand sensitivity of the channel. If
either of the two regions is deleted, the ligand sensitivity is
reduced. Binding of calmodulin causes a similar decrease of ligand
sensitivity as deletion of either of the two regions (Chen and Yau,
1994; Liu et al., 1994).
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Figure 4.
A, Schematic representation of the
transmembrane topology of the olfactory CNG channel -subunit
according to Henn et al. (1995); S1-S6, Transmembrane
regions; P, pore region. The N-terminus harbors a
regulatory domain consisting of a calmodulin-binding site
(CaM; Phe66-Trp79
in boCNC) and its flanking region (FR).
The border of the FR region toward the S1
segment is not known. The C-terminus contains the cyclic
nucleotide-binding site (cAMP;
Gly461-Leu578 in
boCNC). B, Alignment of the amino acid
sequence of the NH2-terminal regulatory domain of bovine
olfactory -subunits (boCNC; Ludwig et al., 1990) with the
corresponding domains of rat (roCNC; Dhallan et al., 1990),
rabbit (raCNC; Biel et al., 1993), and catfish (foCNC; Goulding et al., 1992).
Boxed amino acid residues are the hydrophobic residues
that represent positions 1 and 14 of the calmodulin-binding site, as
well as a serine residue (Ser93 in
boCNC) that is part of a consensus site for
protein phosphorylation (RXXS).
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Because this domain is crucial for modulating the ligand sensitivity,
we investigated its involvement in the PKC effect. We first constructed
a truncated version of the bovine olfactory -subunit, which did not
contain the calmodulin-binding site and the adjacent 21 amino acid
residues of the flanking region. This construct, MP101 (truncated until
Gly100), was expressed in HEK 293 cells and
subjected to the same PMA treatment as the wild-type channels. In
accordance with results obtained in the rat -subunit (Liu et al.,
1994), MP101 displayed a reduced cGMP sensitivity (K1/2 = 8.2 ± 1.07 µM; n = 2.76 ± 0.29; seven patches) (Fig. 5A,
circles). The cGMP sensitivity of MP101 did not increase after
treatment with PMA (triangles) but was slightly reduced
(K1/2 = 11.9 ± 2.2 µM;
n = 2.42 ± 0.32; five patches). Figure
5B shows that the truncated channel is not sensitive to
calmodulin. As control experiments, inside-out patches were perfused
with internal solution containing 0.3 mM
Ca2+ but no calmodulin (circles). The
K1/2 was 14.6 ± 3.1 µM, with n = 2.2 ± 0.32 (five patches) under control
conditions. (All olfactory channels tested show a slightly reduced
ligand sensitivity in the presence of elevated
[Ca2+]i; cf. Table
1.) After exposure of the patches to 0.5 µM calmodulin for 3 min, the cGMP sensitivity was
virtually unchanged (K1/2 = 15.5 ± 3.6 µM; n = 1.88 ± 0.13; five patches)
(Fig. 5B, triangles). Under the same experimental protocol,
calmodulin caused a sevenfold increase of K1/2 in the
wild-type channel (see below). Thus, both PKC-mediated increase and
calmodulin-induced decrease of ligand sensitivity are absent in the
truncated channel MP101. A second truncated channel polypeptide, MD30,
which contained both the calmodulin-binding site and the flanking
region (truncated until Lys29) showed responses to
calmodulin and to PMA treatment similar to the wild-type channels
(Table 1). These experiments show that the PKC-induced modulation of
ligand sensitivity in olfactory channels involves a segment of the
N-terminal region between Lys29 and
Gly100.
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Figure 5.
Localization of the amino acid residue that
mediates the PMA-induced effect on ligand sensitivity.
A, Loss of PMA effect in the mutant channel MP101
(truncated N-terminally until Gly100).
Dose-response relations were obtained at Vm = +40 mV in Ca2+-free internal solution from cells
expressing mutant channels without (circles) and with
(triangles) PMA treatment. The phorbol ester treatment
did not increase but slightly decreased the cGMP sensitivity of the
channel. For comparison, a dose-response relation of the untreated
wild-type channel is shown (dotted line).
B, Loss of calmodulin sensitivity in MP101.
Dose-response relations in the presence of internal solution
containing 0.3 mM Ca2+ before
(circles) and after (triangles) exposure
of patches to 0.5 µM calmodulin for 3 min. The same
protocol causes a sevenfold increase of K1/2
in wild-type channels (see Fig. 6). The dotted line
shows the dose-response relation of the wild-type channel in internal
solution containing 0.3 mM Ca2+ without
calmodulin. C, Replacement of Ser93
abolishes the effect of PMA. Dose-response relations of S93A mutant
channels without (circles) and with
(triangles) PMA treatment show that the mutant does not
respond to activation of PKC, whereas its cGMP sensitivity under
control conditions is only slightly reduced with respect to the wild
type (dotted line).
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The flanking region (Fig. 4, FR) contains a consensus
phosphorylation sequence
(Arg90-Ser93 in the bovine
channel) that may form a recognition site for PKC (Pearson and Kemp,
1991). To test whether phosphorylation of Ser93
mediates the PMA effect on ligand sensitivity, we replaced
Ser93 with alanine (mutant S93A) and measured the
cGMP sensitivity with and without PMA treatment (Fig. 5C).
Under control conditions (circles), S93A showed a cGMP
sensitivity similar to that of the wild type (K1/2 = 1.93 ± 0.15 µM; n = 2.03 ± 0.35; five patches). After PMA treatment (triangles), the
cGMP sensitivity was not changed significantly (K1/2=
2.2 ± 0.56 µM; n = 2.06 ± 0.27; six patches). This lack of PMA effect in S93A strongly suggests
that a PKC-mediated phosphorylation of Ser93 is
responsible for the increase of ligand sensitivity.
The effect of phosphorylation can sometimes be mimicked by replacing
the amino acid residue serving as the kinase substrate by glutamate or
aspartate. These residues can substitute for the negative charge
otherwise provided by phosphate and, thereby, can produce the phenotype
corresponding to the phosphorylated state of the protein (e.g., Smith
and Goldin, 1996). We generated an S93E mutant of the olfactory CNG
channel to test whether replacement of Ser93 by a
glutamate residue would produce a channel with constitutively increased
cGMP sensitivity. However, S93E displayed the same properties as S93A
(Table 1). Thus, the modulation of ligand sensitivity by
phosphorylation of Ser93 cannot be explained by the
introduction of a negative charge into the region flanking the
calmodulin-binding site.
Calmodulin-induced modulation is preserved in the
phosphorylated channel
We examined whether the PKC-mediated increase of ligand
sensitivity interferes with the antagonistic modulation of the channel by calmodulin. Inside-out patches from transfected cells were first
washed in Ca2+-free solution to remove any
endogenous Ca2+-binding proteins of the HEK 293 cells. To obtain dose-response relations for channel activation under
control conditions, I-Vm curves were
first recorded in internal solution containing 0.3 mM
Ca2+ and various concentrations of cGMP. Patches
were then exposed for 3 min to the same solution containing 0.5 µM calmodulin and no cGMP to saturate the channels with
calmodulin. Subsequently, I-Vm
relations were again recorded at increasing cGMP concentration in the
presence of 0.3 mM Ca2+ (Fig.
6A). The dose-response
relations in Figure 6B demonstrate a
calmodulin-induced shift of cGMP sensitivity from the control (K1/2 = 1.76 ± 0.26 µM;
n = 2.47 ± 0.38; seven patches) (Fig. 6A, circles) to the calmodulin-bound state
of the channel (K1/2 = 12.0 ± 2.8 µM;
n = 2.8 ± 0.9; 14 patches) (Fig.
6A, triangles). A similar
calmodulin-induced increase of K1/2 was reported earlier for -homomeric channels of the rat (Chen and Yau, 1994). The calmodulin effect was readily reversible; washing the patch for 2-5
sec in Ca2+-free internal solution caused
dissociation of calmodulin from the channel and the consequent reset of
control cGMP sensitivity (data not shown). When patches from
PMA-treated cells were subjected to the same calmodulin treatment, we
observed a strong decrease of the cGMP sensitivity; recordings from
phosphorylated channels without calmodulin (Fig. 6C,
circles) yielded a K1/2 of 0.35 ± 0.03 µM and n = 1.85 ± 0.19 (six
patches). After exposure to calmodulin (triangles),
activation was characterized by a K1/2 of 14.4 ± 2.3 µM and n = 2.35 ± 0.7 (six
patches). K1/2 was reversed to the control value by brief
exposure to Ca2+-free solution. These results show
that the PKC-mediated phosphorylation of Ser93
induces an increase of ligand sensitivity only if the
calmodulin-binding site is not occupied. They also demonstrate that the
dynamic range of the calmodulin-dependent modulation is much larger
when Ser93 is phosphorylated; the value of
K1/2 increases during binding of calmodulin 40-fold in
phosphorylated channels but only sevenfold in channels from untreated
cells. Mutation of Ser93 did not change the
sensitivity of the channel for calmodulin; application of calmodulin to
mutant S93A reduced the cGMP sensitivity from control (K1/2 = 2.19 ± 0.48 µM; n = 2.34 ± 0.19; seven patches) to the calmodulin-bound state (K1/2 = 17.3 ± 6.1 µM; n = 1.8 ± 0.47; five patches) by a similar extent as observed with wild-type channels (eightfold).
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|
Figure 6.
The calmodulin effect on ligand sensitivity is not
counteracted by PKC-mediated phosphorylation. A,
I-Vm relations recorded from
an inside-out patch of a cell expressing wild-type channels after
exposure to 0.5 µM calmodulin for 3 min. The patch was
held in internal solution containing 0.3 mM
Ca2+, and the indicated concentrations of cGMP were
applied. Before calmodulin application, and also after removal of
calmodulin in Ca2+-free internal solution, the patch
showed almost maximal channel activation by 3 µM cGMP
(data not shown). The nonlinear shape of the
I-Vm relations results from
voltage-dependent channel blockage by internal Ca2+.
B, Dose-response relations for channel activation
obtained from untreated wild-type channels before
(circles) and after (triangles) exposure
to calmodulin. Both relations were derived at
Vm = +40 mV with internal solution
containing 0.3 mM Ca2+.
C, Calmodulin-induced reduction of cGMP sensitivity in
wild-type channels after PMA treatment. Inside-out patches from
PMA-treated cells were exposed to internal solution containing 0.3 mM Ca2+ and various concentrations of
cGMP before (circles) and after (triangles) incubation with 0.5 µM
calmodulin. The dose-response relations show a 40-fold increase of
K1/2 for channel activation caused by the
exposure of the phosphorylated channels to calmodulin.
|
|
| |
DISCUSSION |
Recent results from several groups indicate that the ligand
sensitivity of olfactory CNG channels can be regulated through binding
of calmodulin or other cytosolic components. During odorant stimulation, olfactory channels can carry substantial
Ca2+ currents into the cilia (Frings et al., 1995),
causing the ciliary Ca2+ concentration to increase
(Lowe and Gold, 1993b; Tareilus et al., 1995; Leinders-Zufall et al.,
1997). At elevated ciliary Ca2+ concentration,
calmodulin and, possibly, other Ca2+-binding
proteins present in OSN (Bastianelli et al., 1995; Balasubramanian et
al., 1996; Boekhoff et al., 1997) reduce ligand sensitivity, promote closure of the channels, and terminate the excitatory phase of
the odorant response (Kurahashi and Menini, 1997).
The purpose of the present study was to investigate a second regulatory
mechanism of ligand sensitivity in olfactory CNG channels: phosphorylation of the -subunit by PKC. There is ample evidence for
an involvement of PKC in olfactory signal transduction. PKC was first
detected in ciliary preparations of amphibian OSNs by Anholt et al.
(1987), and, more recently, PKC was shown to participate in adaptation
by inactivating odorant receptors (Boekhoff and Breer, 1992; Boekhoff
et al., 1992). Moreover, activation of PKC appears to increase the
odorant-stimulated cAMP synthesis in amphibian olfactory epithelium
(Frings, 1993), suggesting a modulatory role of this enzyme also in the
excitation of the neuron.
We have shown that the -, -, and isoforms of PKC are
expressed in the sensory cilia of rat OSNs. This set of enzymes covers the entire range of known PKC isoforms (for review, see Dekker, 1997).
The isoform belongs to the group of "classic" PKCs that are
Ca2+-dependent, activated by diacylglycerol, and
exhibit comparably low substrate specificity. The isoform is a
"novel" and the isoform an "atypical" PKC, both
characterized by Ca2+-independent activity and a
more restricted substrate profile. Interestingly, PKC is not
sensitive to diacylglycerol or phorbol esters and may be activated by
arachidonic acid or phosphatidylinositol 3,4,5-trisphosphate (Akimoto
et al., 1994). Regulation of the three PKC isoforms in OSNs as well as
their cellular targets has yet to be identified. Our data suggest that
the olfactory CNG channel could be the target of PKC-mediated
phosphorylation. Activation of PKC in HEK 293 cells leads to an
increase of ligand sensitivity of heterologously expressed
-homomeric channels. This effect is brought about by phosphorylation
of Ser93, an amino acid residue situated in the
intracellular N-terminal region of the channel polypeptide.
Ser93 is located near the calmodulin-binding site.
But while calmodulin binding decreases ligand sensitivity,
phosphorylation of Ser93 has the opposite effect.
Thus, the regulatory domain within the N-terminal region (consisting of
the calmodulin-binding site and the flanking region that contains
Ser93) can serve two opposing functions.
Interestingly, binding of calmodulin reduces the ligand sensitivity
regardless of the phosphorylation state of Ser93,
suggesting that the conformational transition induced by binding of
calmodulin is the main determinant of sensitivity. On the other hand,
deleting only the flanking region renders the channel insensitive to
calmodulin (Liu et al., 1994), although calmodulin presumably still
binds. It thus appears that both parts of this regulatory domain are
involved in channel opening, and that both can contribute to the
determination of ligand sensitivity.
These findings give further evidence for a critical allosteric role of
the N-terminal region in the gating of CNG channels, which was
demonstrated previously in mutagenesis studies (Goulding et al., 1994;
Tibbs et al., 1997). It appears that the N-terminus determines the ease
with which the binding of cyclic nucleotides to the C-terminus is
converted into channel opening. Most recently, Varnum and Zagotta
(1997) showed that the N- and C- termini of olfactory CNG
channels interact. The calmodulin-binding site and part of the flanking
region in the N-terminus bind to an identified domain in the
C-terminus. This interdomain interaction facilitates channel opening,
and it may be that phosphorylation of Ser93
increases gating efficacy of the channel by stabilizing this interdomain complex.
Does phosphorylation modulate the native olfactory
CNG channel?
Phosphorylation of Ser93 profoundly affects the
ligand sensitivity of the -homomeric channel. However, the native
olfactory CNG channel most probably consists of at least two different
subunits, and we do not know whether modulation by PKC is conserved in
the heteromeric protein. Direct evidence can only be obtained from intact OSNs or, alternatively, from heterologously expressed CNG channels with correct subunit composition.
To measure ligand sensitivity of native channels, OSNs must be isolated
from the olfactory epithelium, and patch-clamp recordings can then be
obtained from the membrane of dendritic knobs (Frings et al., 1992;
Balasubramanian et al., 1995, 1996). Because of the small size of
sensory cilia (diameter, 0.2 µm), ciliary CNG channels are not
accessible for such recordings. We measured the cAMP sensitivity of
native rat channels in membrane patches from dendritic knobs. We
obtained a K1/2 of 4.13 ± 1.9 µM;
n = 1.65 ± 0.1 (four patches) for control
channels and a K1/2 of 3.50 ± 0.9 µM;
n = 1.50 ± 0.2 (eight patches) for channels
measured after OSNs had been treated with 1 µM PMA and
0.6 µM okadaic acid (to inhibit phosphatase activity)
before, during, and after the dissociation procedure (data not shown).
Thus, PMA treatment does not significantly increase ligand sensitivity
in CNG channels from dendritic knobs of isolated OSNs. However, several
aspects have to be considered for the interpretation of this
observation: (1) OSNs may be damaged during dissociation, may lose the
ability to phosphorylate the channel, or may allow dephosphorylation
during cell isolation; (2) channels in dendritic knobs analyzed here
are colocalized only with PKC, which may not recognize
Ser93 as a substrate, whereas
Ser93 of channels expressed in the ciliary membrane
could be phosphorylated by the and isoforms; (3)
phosphorylation of native channels may be specifically mediated by
PKC, which is not activated by phorbol esters; (4) channels may be
constitutively phosphorylated so that activation of PKC does not lead
to a change of ligand sensitivity; and (5) additional channel subunits
may obstruct phosphorylation of the -subunit or may prevent the
change of ligand sensitivity in the phosphorylated channel. Because
these problems cannot be investigated in isolated OSNs, the most
promising approach is the heterologous coexpression of different
channel subunits and phosphorylation experiments with channels of the correct subunit composition. This will probably be feasible in the near
future, because the subunits that contribute to the native olfactory
channel of the rat have been identified recently (F. Sesti, W. Bönigk, J. Bradley, F. Müller, S. Frings, and U. B. Kaupp,
unpublished data).
Indirect evidence supporting a role of phosphorylation in the
modulation of ligand sensitivity comes from studies of rod
photoreceptor CNG channels. Gordon et al. (1992) have demonstrated that
the cGMP sensitivity of CNG channels in membrane patches excised from the outer segment of isolated photoreceptors can be changed by application of protein phosphatases. This observation suggests that CNG
channels in these cells are phosphorylated, and that the
phosphorylation state determines ligand sensitivity. Thus, native
photoreceptor CNG channels seem to be modulated by phosphorylation much
like other ligand-gated channels. Modulation by protein phosphorylation is well documented for receptors of acetylcholine, GABA, glycine, and
glutamate (for review, see Swope et al., 1992). To understand the role
of phosphorylation in the regulation of olfactory channels, it will be
crucial to identify physiological activators of PKC in OSNs. Promising
candidates may be agents that activate phospholipase C, such as
neurotransmitters (Frings, 1993) and certain types of odorants
(Boekhoff et al., 1990), or activators of PKC that use other
pathways of lipid metabolism.
A possible physiological role for phosphorylation of olfactory
CNG channels
In an earlier report (Frings, 1993), we have shown that frog OSNs
in situ respond more strongly to odorant stimulation when the olfactory epithelium is incubated with phorbol ester, an effect that is probably mediated by PKC. Under conditions of enhanced PKC
activity, the stimulus-induced synthesis of cAMP is potentiated so that
more CNG channels can be activated, resulting in an increased receptor
current. If such a neurotransmitter-controlled PKC activity is also
functional in mammalian OSNs, it affords the neurons with a way of
optimizing the transduction efficiency. At increased PKC activity, both
cAMP synthesis by the olfactory adenylyl cyclase and the cAMP
sensitivity of CNG channels would be high, and weak odorant stimuli are
sufficient to elicit electrical excitation. In this speculative
concept, phosphorylation of the CNG channel -subunit contributes to
an increase of olfactory sensitivity. Moreover, the
Ca2+-dependent adaptation of OSNs may also be
affected by channel phosphorylation, because
K1/2 in phosphorylated channels shifts 40-fold
on binding of Ca2+/calmodulin, instead of sevenfold
in control channels. Interestingly, native olfactory CNG channels
respond to calmodulin with a 20-fold (Chen and Yau, 1994) to 60-fold
(Balasubramanian et al., 1996) increase of K1/2.
Whether this extended range of modulation reflects a modification of
the calmodulin effect by other subunits or is attributable to
constitutive phosphorylation of the -subunit needs to be clarified
in further experiments. Taken together, our results suggest that
phosphorylation of the -subunit may influence both excitation and
adaptation of OSNs.
In addition to the olfactory epithelium, the olfactory CNG channel
-subunit is also expressed in other tissues, including aorta (Biel
et al., 1993) and various parts of the brain (El-Husseini et al., 1995;
Kingston et al., 1996; Bradley et al., 1997). Because this channel
readily conducts Ca2+, it is expected to function as
a Ca2+ entry pathway that couples the cyclic
nucleotide metabolism to cytosolic Ca2+ homeostasis
in neuronal somata and synaptic terminals. Activation of CNG channels
is currently discussed as a factor contributing to synaptic plasticity,
neuronal growth, and axon guidance (for review, see Zufall et al.,
1997). Considering the substantial increase of ligand sensitivity
described here, it is tempting to speculate that phosphorylation of the
olfactory CNG channel -subunit in hippocampus, cerebellum, and
olfactory bulb contributes to the regulation of neuronal growth and
plasticity.
| |
FOOTNOTES |
Received Sept. 8, 1997; revised Oct. 20, 1997; accepted Oct. 23, 1997.
This work was supported by European Community Grant CHRX-CT94-0543 and
Ministerium Für Wissenschaft und Forschung des Landes Nordrhein-Westfalen Grant IVA6-10201095. We gratefully acknowledge the
assistance of Mechthilde Bruns, Helga Vent, and Helmut Erkens. We thank
Drs. Benjamin Kaupp and Ingo Weyand for advice and discussions and Dr.
Jonathan Bradley for roCNC DNA.
Correspondence should be addressed to Dr. Stephan Frings, Institut
für Biologische Informationsverarbeitung, Forschungszentrum Jülich, 52425 Jülich, Germany.
| |
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Top
Abstract
Introduction
