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Volume 16, Number 23,
Issue of December 1, 1996
pp. 7458-7468
Copyright ©1996 Society for Neuroscience
Two Alternatively Spliced Forms of the cGMP-Gated Channel
 -Subunit from Cone Photoreceptor Are Expressed in the Chick
Pineal Organ
Wolfgang Bönigk1,
Frank Müller1,
Ralf Middendorff2,
Ingo Weyand1, and
U. Benjamin Kaupp1
1 Institut für Biologische
Informationsverarbeitung, Forschungszentrum Jülich, D-52425
Jülich, Germany, and 2 Anatomisches Institut,
Universitätskrankenhaus Eppendorf, D-20246 Hamburg, Germany
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Light sensitivity of the pineal has been retained in most
vertebrates, except mammals. Retinal photoreceptors and pinealocytes share common components of light-dependent signaling pathways. In
particular, an ion channel gated by cGMP has been
electrophysiologically identified in chick pinealocytes; however, the
physiological function of a light-sensitive enzyme cascade is not
known, and primary structures of only a few pineal components have been
determined. By PCR analysis and cloning of the respective cDNA, we show
that the chick pineal expresses the  -subunit of the cyclic
nucleotide-gated (CNG) channel of rod photoreceptors and two short
forms of the cone CNG channel. Analysis of the chick cone CNG channel
gene reveals that these forms are produced by alternative splicing, which removes either one or two exons from the transcript. The shorter
splice variant is functional when heterologously expressed, and it is
approximately twofold more sensitive to activation by cGMP than the
cone CNG channel. The chick cone CNG channel and the pineal splice form
are both modulated by Ca2+/calmodulin (CaM). The CaM
sensitivity might be mediated by a putative CaM-binding site in an
N-terminal segment encoded by exon 4. This exon is missing in the gene
for the rod CNG channel -subunit. Pineal CNG channels are candidates
for receptor-mediated Ca2+ entry into pinealocytes and may
be an important element of signaling pathways that control the light
response and secretion of the pineal hormone melatonin.
Key words:
ion channels;
cyclic nucleotides;
calmodulin;
calcium;
signal transduction;
pineal gland
INTRODUCTION
The pineal regulates various physiological
functions by nocturnal secretion of the hormone melatonin. The control
of melatonin release differs between mammals and birds. Chick
pinealocytes exhibit an intrinsic circadian rhythm of melatonin
secretion (Deguchi, 1979 ; Takahashi et al., 1989), whereas in mammals,
a circadian clock in the suprachiasmatic nucleus of the hypothalamus
controls pineal activity (for review, see Takahashi, 1995).
Two neural pathways, one involving noradrenaline (NE) and the other
involving vasoactive intestine peptide (VIP), regulate the synthesis of
melatonin (for review, see Takahashi et al., 1989). Modulation of
melatonin secretion by NE differs among vertebrates. In the chick, NE
inhibits the nocturnal elevation of melatonin levels (Pratt and
Takahashi, 1989), whereas in the rat pineal it stimulates melatonin
synthesis (Klein, 1986). Both inhibitory and stimulatory effects of NE
are mediated by a cAMP-signaling pathway. In the chick, NE inhibits
adenylate cyclase via 2-adrenergic receptors (Voisin and
Collin, 1986), whereas in the rat it stimulates cAMP synthesis via
1- and  -adrenergic receptors. Thus, although cAMP
stimulates melatonin synthesis in both avian and mammalian pinealocytes, the mechanisms that control cAMP levels differ. In both
chick and rat, VIP stimulates the synthesis of melatonin, and it is
believed that this effect is also mediated by a cAMP-signaling pathway
(Yuwiler, 1983; Kaku et al., 1985; Pratt and Takahashi, 1989).
In addition, NE and VIP increase the concentrations of cGMP and
Ca2+ (Sugden et al., 1987; D'Souza and Dryer, 1994; Schaad
et al., 1995; Schomerus et al., 1995). Although the physiological
functions of both messenger molecules and their cellular targets in the pineal are poorly understood, some evidence supports a modulatory role
of Ca2+ for melatonin synthesis (Takahashi et al., 1989);
however, the mechanisms that give rise to changes in intracellular
Ca2+ concentration ([Ca2+]i) have
not been identified unequivocally (D'Souza and Dryer, 1994; Saez et
al., 1994; Chik et al., 1995; Schaad et al., 1995).
Recently, cyclic nucleotide-gated (CNG) channel activity has been
recorded from chick pinealocytes (Dryer and Henderson, 1991, 1993).
Because of their substantial Ca2+ permeability (for review,
see Kaupp, 1995), CNG channels may be utilized by G-protein-coupled
receptor pathways to control [Ca2+]i in
pinealocytes through changes in the concentration of cAMP and cGMP. CNG
channels comprise two homologous polypeptides, designated - and
-subunits (Chen et al., 1993; Bradley et al., 1994; Liman and Buck,
1994; Körschen et al., 1995). Three different genes encoding
-subunits have been identified in vertebrates. They were first
discovered in rod and cone photoreceptors and olfactory sensory neurons
(OSNs), but they are also expressed in other cellular systems (for
reviews, see Eismann et al., 1993; Finn et al., 1996). CNG channels
vary considerably in their ability to conduct Ca2+ (Perry
and McNaughton, 1991; Frings et al., 1995; Picones and Korenbrot,
1995). In some cellular systems, the principal if not exclusive
function of CNG channels even might be to control
[Ca2+]i rather than to change the membrane
voltage by passing Na+ or K+ ions.
To study the function of CNG channels in pinealocytes, we have
identified CNG channel isoforms by cloning, functional expression, and
immunohistochemical localization. Here, we report that chick pineals
express the -subunit of the rod CNG channel and two splice variants
of the cone CNG channel -subunit. Analysis of the structure of the
cone -subunit gene revealed that either one or two exons are missing
in the splice variants. These exons encode two segments in the
cytoplasmic N-terminal region. Expression of one splice variant in
Xenopus oocytes and a mammalian cell line gave rise to
cGMP-activated currents. The splice variant is roughly twofold more
sensitive to cGMP than the cone CNG channel itself. The activity of the
cone CNG channel and of the splice variant is modulated by
Ca2+/CaM. Modulation is probably mediated by an N-terminal
domain that shares a high sequence similarity with a CaM-binding region in the -subunit of the olfactory CNG channel (Liu et al., 1994). CNG
channels in the pineal may subserve two distinct functions: generation
of the light response and regulation of
[Ca2+]i by efferent neural pathways.
MATERIALS AND METHODS
Preparation of RNA and synthesis of cDNA.
Poly(A)+ RNA was isolated with a FastTrack Kit (Invitrogen,
San Diego, CA) from 20 pineals of 1- and 12-d-old chicks, 10 chick
retinae,  1 gm of chick testis tissue, and 0.1 gm of bovine pineal
tissue, respectively. First-strand cDNA was synthesized with M-MLV
reverse transcriptase (BRL, Bethesda, MD) using oligo-dT17
as primer. Primers were removed by ultrafiltration with a Centricon 100 spin column (Amicon, Beverly, MA).
Amplification of PCR fragments and construction of complete cDNA
clones. The presence of CNG channel transcripts in the pineal, the
retina, and the testis was probed by amplification of PCR fragments
with primers specific for the CNG channels of chick rod or cone
photoreceptors and OSNs. First-strand cDNA transcribed from the
respective poly(A)+ RNA was used as template. The coding
region of the -subunit of the chick cone photoreceptor CNG channel
(clone pCCG8B of Bönigk et al., 1993) was amplified using primer
pair CC1 (TGGAGGCTGTCAACTTCG; positions  37 to 21) and CC2
(TCCTTCGTTACCTTTCG; inverse complement of positions 1405 to 1422), and
primer pair CC3 (ATGATTTCCAACATGAA; positions 1330 to 1346) and CC4
(GATGGACCAAATCTCCC; inverse complement of positions 2392 to 2418).
Primer pair CC5 (TAGAGCGTATCCGAGGG; positions 299 to 315) and CC6
(CAAGGAAGCCTGTCCTG; inverse complement of positions 792 to 808) were
used to amplify a smaller fragment from the 5 region of ccCNGC (see
Fig. 2). PCR fragments of the chick rod photoreceptor CNG channel
(clone pCCG6 of Bönigk et al., 1993) were amplified using primer
pair CR1 (AAGAAGCAGCAGATTAC; positions 43 to 27) and CR2
(GCTACTCGGAGCAGTCG; inverse complement of positions 676 to 692), and
primer pair CR3 (GTCAATCATACCAACTG; positions 609 to 625) and CR4
(GTCAGGAAAACCTGCAG; inverse complement of positions 2203 to 2219).
Primer CR5 (CAGGCATTGTGATGCAG, inverse complement of positions 366 to
382) was used together with CR1 to amplify a smaller fragment from the
5 region of crCNGC (see Fig. 2). The primer pair CO1
(TCTCCAAGGCCATAGGC) and CO2 (AATGTAATCCCCTGGGC) were used for the
amplification of a fragment specific for the olfactory CNG channel of
chick (W. Bönigk, unpublished result). PCR was performed with 44 cycles. For each amplification, negative controls were run to which no
template DNA was added. PCR fragments were gel-purified, subcloned into
pBluescript vector, and sequenced. Recombinant plasmids carrying the
complete coding region of the two splice variants of the cone CNG
channel (pccCNGC 5-6 and pccCNGC6)
were constructed from the respective overlapping PCR fragments by
making use of the internal EcoRI restriction site.
Fig. 2.
Transcript structure of ccCNGC
and crCNGC. Blot hybridization of PCR
fragments amplified from cDNA with ccCNGC-specific (A) and crCNGC-specific
(B) primer pairs (CC5/CC6 and CR1/CR5, respectively).
The blot was hybridized with radioactively labeled DNA probes amplified
with the same primer set and using cDNA clones pCCG6 and pCCG8B
(Bönigk et al., 1993) as templates. Lanes in A: 1, retina; 2, pineal;
3, testis. Lanes in B:
1, retina; 2, pineal. For negative
control PCR, no hybridization signals were detected (data not
shown).
[View Larger Version of this Image (17K GIF file)]
Similar experiments were performed with cDNA derived from
poly(A)+ RNA of bovine pineal tissue. Two overlapping
fragments, harboring either the 5 or 3 part of the coding region for
rod and cone CNG channels were amplified by two sets of primers similar
to those used for amplification of fragments from chick cDNA.
Analysis of genomic structure of chick cone CNG channel. A
chick genomic library in  FIXII-vector (Stratagene, La Jolla, Ca) was
screened with two cDNA probes (F5, nucleotides 39 to 926, and F3,
nucleotides 882 to 2391 of pCCG8B; Bönigk et al., 1993). Probe
F5 and F3 yielded 12 and 7 positive signals, respectively. Two
overlapping clones were chosen for further analysis. Clones were
digested with SacI, XbaI, EcoRI,
BamHI, SalI, and each possible combination of two
endonucleases. Fragments were separated by agarose electrophoresis and
those containing exon sequences were identified by Southern blotting
using probes F5 and F3. These fragments were isolated and analyzed by
PCR and sequencing using primers from the coding region.
Immunocytochemistry. Immunoreactivity was tested using
a combination of techniques involving the peroxidase-antiperoxidase (PAP)- and the avidin-biotin-peroxidase (ABC) reaction (Davidoff and Schulze, 1990). Pineal organs were dissected from 1- to 3-d-old chicks and fixed by immersion in 4% paraformaldehyde in 0.1 M phosphate buffer (PB), pH 7.4, for 1-2 hr. Fixed pineals
were washed in PB, suspended in 30% sucrose overnight, and embedded in
OCT medium. Horizontal sections (12 µm) were cut with a cryostat and
collected on chrome-gelatin-precoated glass slides. Sections were
preincubated with a solution of 1.25% (v/v)
H2O2 in absolute methanol to inhibit endogenous
peroxidase activity and then with 2% (v/v) normal swine serum in PBS
to block nonspecific binding sites. Sections were incubated at 4°C
for 24 hr with purified antibodies 63-4 and PPcCC1 (directed against a
C-terminal peptide of ccCNGC; Bönigk et al., 1993).
Antibodies were diluted 1: 20 to 1:100 in PBS containing 0.25% Triton
X-100, 0.2% sodium azide, and 0.1% bovine serum albumin. Finally,
sections were sequentially treated with biotinylated anti-rabbit IgG
(Dakopatts, Copenhagen, Denmark) (1:250) added to 2% (v/v) normal
chick serum (60 min at 20°C), with rabbit PAP (Dakopatts) (1:200; 30 min at 20°C) and with ABC (ABC-Elite, Vector, Burlingame, CA) (1:250;
30 min at 20°C). For visualization of the peroxidase activity, the
nickel glucose oxidase technique was used (Záborszky and
Léránth, 1985). The solution contained
3,3-diaminobenzidine, glucose oxidase, glucose, ammonium chloride,
and nickel(II)-sulfate hexahydrate in PB.
Bovine pineal organs were fixed by immersion in Bouin's fluid
for 12 hr at 20°C. Subsequently, tissue blocks were embedded in
paraffin and sections (6 µm) were mounted on
chrome-gelatin-precoated glass slides. After being deparaffinized and
rehydrated, sections were treated in the same way as described above
for chick; however, biotinylated anti-rabbit IgG was added in 2% fetal
calf serum/PBS. Antibody PPc15 directed against bcCNGC
(Weyand et al., 1994) was diluted 1:100.
In control experiments, sections were used in which primary,
secondary, or tertiary antibodies were omitted and in which only the
development of the peroxidase activity was performed. For negative
controls, antibodies in their optimal dilution were preadsorbed with 20 µg/ml of the corresponding antigen, or, alternatively, sections were
incubated with normal rabbit serum. For positive controls, sections
were treated with a monoclonal antibody against hydroxyindole-o-methyl-transferase (HIOMT), which
specifically stains pinealocytes (Sato et al., 1994).
Functional expression. The chick cone CNG channel was
expressed in Xenopus oocytes and splice variants in a human
embryonic kidney cell line (HEK 293). For the expression in
Xenopus oocytes or HEK 293 cells, cDNA was subcloned into
vectors pGEM-HE (Liman et al., 1992; gift of Dr. Tytgat, Leuven,
Belgium) or pcDNAI (Invitrogen), respectively. A perfect Kozak
consensus sequence preceding the start codon was introduced in all
plasmids used for expression (Kozak, 1984). cRNA was synthesized
in vitro using the respective linearized plasmid cDNA as
template. In vitro transcription of cDNA, injection of cRNA
into oocytes, and preparation of oocytes for patch-clamp experiments
were performed as described (Bönigk et al., 1993, and references
therein). Expression in HEK 293 cells was performed as described in
Baumann et al. (1994). Dose-response relations of cGMP-activated
currents were studied in excised inside-out patches of plasma membrane
as described for oocytes (Altenhofen et al., 1991; Bönigk et al.,
1993) and HEK 293 cells (Baumann et al., 1994). The solution in the
pipette and the perfusion medium contained (in mM): 100 KCl, 10 HEPES-KOH, pH 7.4, and 10 EGTA-KOH. Leak currents recorded in
the absence of cGMP were subtracted from currents measured in the
presence of the ligand (5-1000 µM cGMP).
The CaM sensitivity of cGMP-activated currents was determined in either
oocytes (ccCNGC) or HEK 293 cells
(ccCNGC5-6). The experimental procedures for either
expression system were similar. For HEK 293 cells, KCl-based solutions
were used; however, to suppress Ca2+-activated
Cl currents in the oocyte membrane, KCl was replaced by
K+-gluconate. An intrapipette salt bridge similar to that
described by Baumann et al. (1994) was used. The basic solutions in the pipette and the bath contained (in mM): 100-120
K+ salt, 10 HEPES-KOH, pH 7.4, and the indicated additions
of EGTA, nitrilotriacetic acid (NTA)/Ca2+ buffer, CaM, and
cGMP.
After excision, the membrane patch first was perfused for 1-2 min with
a solution containing 10 mM EGTA to remove all endogenous CaM that might have been bound to the channel in the oocyte or the HEK
293 cell. Subsequently, leak currents were recorded in a solution
containing 50 µM free Ca2+ (0.8 mM Ca2+ salt and 2 mM NTA).
Finally, current-voltage (I-V) relations were recorded in 50 µM free Ca2+ with and
without CaM (0.6-1.2 µM) at saturating (500 µM) and nonsaturating (20 µM)
concentrations of cGMP.
RESULTS
Characterization of CNG channel transcripts and organization of the
chick cone CNG channel gene
Expression of CNG channels in pineal tissue was examined by PCR,
using as template first-strand cDNA synthesized from pineal poly(A+) RNA. Overlapping cDNA fragments were amplified by
two sets of primers specific for the CNG channel -subunit of either
chick rod (crCNGC) or cone photoreceptor
(ccCNGC) (Bönigk et al., 1993). No amplification
products could be detected using primers for the CNG channel
-subunit of chick olfactory epithelium (coCNGC), indicating that only photoreceptor CNG channels are expressed in the
pineal.
Primer pairs were chosen that allow amplification of the entire coding
region in two overlapping fragments (for positions of primers, see Fig.
1A). PCR with the
ccCNGC-specific primer pair CC1/CC2 produced two
fragments, which were both shorter than expected from the structure of
the cDNA cloned from retina (clone pCCG8B of Bönigk et al.,
1993). Sequencing of cloned fragments revealed that segments of
different length were missing in the region coding for the
intracellular N-terminal domain (Fig.
2A). Amplification with primer pair
CC3/CC4 produced a single fragment that matched in size and sequence
the corresponding fragment amplified from pCCG8B. These results suggest
that two alternatively spliced forms of ccCNGC are
expressed in the pineal organ.
Fig. 1.
Gene structure of the chick cone CNG channel.
A, Top, Restriction map of chromosomal
DNA encompassing exons 1-9 of the chick cone CNG channel gene.
B, BamHI; E,
EcoRI; S, SacI;
X, XbaI. A, Bottom,
Comparison of the exon structure of the chick cone CNG channel
(ccCNGC) and the human rod CNG channel
(hrCNGC; Dhallan et al., 1992) with the
transmembrane topology of CNG channels. Solid and
open boxes, respectively, refer to noncoding and coding regions of exons. Gray boxes refer to transmembrane
segments S1-S6, the pore region, and the cGMP-binding site
(cGMP); the striped box indicates the
highly charged domain in the N-terminal region of the polypeptide. The
arrows refer to primer pairs CC1/CC2, CC3/CC4, and
CC5/CC6 used for amplification of cone-specific cDNA fragments, or to
the primer pairs CR1/CR2, CR3/CR4, and CR1/CR5 used for amplification
of rod-specific cDNA fragments. B, Nucleotide sequence
(with splice junction donor and acceptor sequences of exon/intron
boundaries in the cDNA) and deduced amino acid sequence of
ccCNGC. Intron sequences at intron/exon boundaries
are given in small letters. Numbering of nucleotide
positions refers to the cDNA sequence and begins with +1 at the adenine
nucleotide of the start codon. Figure continues.
[View Larger Versions of these Images (18 + 41K GIF file)]
To exclude possible PCR artifacts, we elucidated the structure of the
cone CNG channel gene. Comparison of genomic and cDNA sequences
revealed that the ccCNGC gene is composed of at least nine exons (Fig. 1A). We cannot exclude the
possibility that additional exons exist in the 5 noncoding region.
Consensus sequences of donor/acceptor splice sites are observed at most
of the exon/intron boundaries (Fig. 1B). The
boundaries of exon 5 and 6 are identical with the positions of
deletions. Thus, alternative splicing in the pineal produces an
internal in-frame deletion of either 44 or 62 codons belonging to exons
6 or 5 and 6, respectively. The longer channel form, designated
ccCNGC6, encodes a polypeptide of 691 amino acid
residues with a calculated Mw of 79.5 kDa; the shorter channel form, designated ccCNGC5-6, encodes a
polypeptide of 673 amino acid residues with a Mw
of 77.4 kDa.
The genomic organizations of the human rod
(hrCNGC; Dhallan et al., 1992) and chick
cone CNG channels are similar in that the N-terminal third of both
polypeptides is encoded by seven small exons, whereas the C-terminal
two thirds, following transmembrane segment S2, are encoded by a single
large exon (Fig. 1A,B). Exons 3, 4, 5, 8, 9, and 10 of hrCNGC correspond to exons 2, 3, 5, 7, 8, and 9 of ccCNGC, respectively. Exons 6 and 7 of
hrCNGC correspond to a single exon 6 in the
ccCNGC gene. The equivalent of exon 4 in the
ccCNGC gene is missing in the
hrCNGC gene (see below).
With each of the crCNGC-specific primer pairs CR1/CR2 and
CR3/CR4 (see Fig. 1A), single fragments were
amplified from retinal and pineal cDNA, which matched in size and
nucleotide sequence the corresponding fragments amplified from cDNA
encoding crCNGC (clone pCCG6 of Bönigk et al.,
1993) (also see Fig. 2B). This result demonstrates
that no splice form of the rod CNG channel exists in either retina or
pineal.
The cellular responses of pinealocytes and their control by neural
pathways are fundamentally different in mammals and birds (Takahashi et
al., 1989). Therefore, we also examined the expression of CNG channels
in bovine pineal tissue. Fragments encoding CNG channel -subunits of
rod and cone photoreceptors could be amplified using bovine pineal cDNA
(data not shown), which were identical to the fragments amplified from
cloned cDNA (clone pCGTE of Weyand et al., 1994, and clone pRCG1 of
Kaupp et al., 1989). Thus, in bovine pineal, only the respective
photoreceptor forms of channel -subunits exist.
Expression of splice variants in other tissues
To examine whether pineal splice forms of ccCNGC
occur in other tissues as well, primer pair CC5/CC6 instead of CC1/CC2
was used, which amplifies smaller fragments of the respective region and thereby facilitates detection of bands with a different size. Amplification of pineal cDNA with primer pair CC5/CC6 produced two
fragments of 324 bp and 378 bp (Fig. 2A, lane
2), whereas only a single fragment of 510 bp was amplified from
retinal cDNA (Fig. 2A, lane 1), which was
identical to the corresponding fragment amplified from cloned cDNA of
ccCNGC. This result demonstrates that the pineal splice
variants of ccCNGC are not expressed in the
retina.
Recently, it has been reported that the -subunit of the cone CNG
channel is expressed in bovine spermatozoa (Weyand et al., 1994).
Therefore, we analyzed the transcript structure of CNG channels
expressed in chick testis with the same set of primers. A single
fragment of 324 bp was amplified (Fig. 2A, lane
3). This fragment was identical to the shorter fragment amplified
from pineal cDNA, suggesting that one of the pineal forms of
ccCNGC is also expressed in chick spermatozoa.
Figure 2B illustrates the absence of any splice
variants of the rod CNG channel in the pineal and the retina.
Immunocytochemical localization
Using antibody 63-4 directed against a C-terminal peptide from
ccCNGC (Bönigk et al., 1993), immunoreactivity was
revealed in chick pineal organs. Antibody 63-4 stained the apical
region of most cells that reach into the lumen of the pineal follicle (Fig. 3A,B). These cells most likely
represent modified pineal photoreceptors consisting of a rudimentary
outer segment and an inner segment. Immunoreactivity was also detected
in the basal part of the follicle, where para-follicular pinealocytes
are localized (Voisin et al., 1988). When antibody 63-4 was omitted
(data not shown) or was preincubated with the corresponding antigen
(Fig. 3E), no staining of chick follicular pinealocytes was
observed. Similar results were obtained with another antibody against
the same channel peptide (PPcCC1; data not shown).
Fig. 3.
Immunohistochemical localization of cone CNG
channel in chick and bovine pineal organ. A, Horizontal
cryostat section (12 µm) of the chick pineal organ stained with
antibody 63-4 and visualized by peroxidase reaction. Cells of two
pineal follicles are labeled, whereas pinealocytes outside the follicle
are stained less prominently. Scale bar, 20 µm. B,
Same as in A at higher magnification. Scale bar, 10 µm. C, Horizontal paraffin section (6 µm) of the
bovine pineal organ stained with antibody PPc15 and visualized by
peroxidase reaction. PPc15 immunoreactivity is observed in only a few
cells in the cortex of the pineal, whereas cells of the medullary part of the organ are not labeled. Scale bar, 20 µm. D,
Same as in C at higher magnification. Scale bar, 10 µm. E, Control section of chick pineal. Specific
staining is abolished after preincubation of antibody 63-4 with the
respective antigenic peptide (20 µg/ml). Scale bar, 20 µm.
F, Control section of bovine pineal. No staining was
observed when the primary antibody PPc15 was omitted. Picture was taken
with Nomarski optics. Scale bar, 20 µm.
[View Larger Version of this Image (89K GIF file)]
Antibody PPc15, directed against the C-terminal domain of the bovine
cone CNG channel bcCNGC (Weyand et al., 1994), stained few circular or ellipsoid structures in the lateral aspects, i.e., the
cortex, of the bovine pineal (Fig. 3C,D). Some of these
structures ( 4-5 µm) are smaller than the majority of bovine
pinealocytes ( 15-18 µm). Small cellular structures were also
recognized by an HIOMT antibody that specifically stains pinealocytes.
It is difficult to decide whether these structures represent a subset of small pinealocytes or subcellular compartments, which could indicate
a regional expression of the antigen within a cell. When antibody PPc15
was omitted (Fig. 3F) or was preincubated with the
corresponding antigen (data not shown), no staining of cells in the
periphery of the bovine pineal was observed.
Functional expression
When injected into Xenopus oocytes, cRNA derived from
clone pccCNGC6 did not give rise to cGMP-stimulated
currents. Expression in a human embryonic kidney cell line (HEK 293)
was also not successful. Antibody PPcCC1 that specifically recognizes
ccCNGC (Bönigk et al., 1993) only weakly stained a
few transfected HEK 293 cells. We did not further pursue heterologous
expression of ccCNGC6. Expression of the shorter
splice variant ccCNGC5-6 in oocytes or HEK 293 cells
gave rise to cGMP-stimulated channel activity.
Figure 4 shows a series of macroscopic
I-V recordings from inside-out patches of HEK
293 cells at different concentrations of cGMP. Mean values for
half-maximal activation K1/2 ± SD (number of experiments) and the Hill coefficient n
determined from the Hill equation
I/Imax = CcnG/(CcnG + K1/2n) for
ccCNGC5-6 were 24.1 ± 8.1 µM,
n = 1.8 ± 0.5 (10) at 80 mV, and 14.6 ± 6.2 µM, n = 1.9 ± 0.6 (10) at +80
mV. Mean values for K1/2 of the chick
ccCNGC were 47 ± 8.5 µM,
n = 2.1 ± 0.5 (6), and 23.5 ± 9.2 µM, n = 2.1 ± 0.5 (6) at 80 mV
and +80 mV, respectively.
Fig. 4.
Activation of splice variant
ccCNGC5-6 by cGMP. Series of
I-V recordings in the presence of
different cGMP concentrations. Inside-out patch of HEK 293 cells
transfected with plasmid pccCNGC5-6. The inset
shows the dose-response relation at 60 mV. The
K1/2 value was 30 µM, and
the Hill coefficient was n = 1.8. The cGMP concentrations
were trace 1, 5 µM; 2, 10 µM; 3, 20 µM;
4, 30 µM; 5, 50 µM; 6, 80 µM;
7, 100 µM; 8, 300 µM; 9, 1000 µM.
[View Larger Version of this Image (22K GIF file)]
Modulation by Ca2+/CaM
Exon 4 of ccCNGC encodes a segment of 61 amino acid
residues that is highly homologous to a slightly shorter N-terminal
region in CNG channels of OSNs. Sequence alignment of this region from two cone-specific and two olfactory-specific CNG channels is shown in
Figure 5. In the rat olfactory CNG channel, this segment
carries a CaM-binding site (Liu et al., 1994), which provides the
channel with a pronounced CaM sensitivity. In contrast, the -subunit of the rod CNG channel, which is lacking this segment, requires for CaM
sensitivity a 240 kDa polypeptide (Hsu and Molday, 1993) that has been
identified as -subunit (Körschen et al., 1995). The
CaM-binding motif is characterized by two aromatic or long-chain residues separated by 12 amino acid residues and by a basic amphiphilic structure (Fig. 5B) (O'Neil and DeGrado, 1990; Ikura et
al., 1992). A CaM-binding motif suggests that the activity of cone
similar to olfactory CNG channels may be modulated by binding of CaM to the -subunit.
Fig. 5.
Sequence comparison of regions containing a
CaM-binding motif in cone and olfactory CNG channels. Sequence
alignment of exon 4-encoded region of ccCNGC with a
homologous region of CNG channels from bovine cone photoreceptor
(bcCNGC; Weyand et al., 1994), rat olfactory
epithelium (roCNGC; Dhallan et al., 1990), and fish
olfactory epithelium (foCNGC; Goulding et al., 1992).
Arrowheads indicate the two aromatic or long-chain amino
acid residues; + indicates the basic residues; and h
refers to hydrophobic residues in the amphiphilic domain of the
CaM-binding site. The stars above the sequences indicate
that at least three residues at this position are identical;
open circles indicate that at least three residues at
this position are conserved.
[View Larger Version of this Image (16K GIF file)]
This prompted us to examine the modulation of cGMP-activated currents
of the cone CNG channel by Ca2+/CaM. Figure
6A shows an experiment with
ccCNGC. In the presence of saturating cGMP concentrations
(500 µM), only a small or no difference was observed
between current recordings with or without 1.2 µM CaM and
with 50 µM Ca2+ in the perfusion medium (Fig.
6A, traces 1 and 2). When the
cGMP concentration (20 µM) roughly equalled the
K1/2 value of channel activation,
however, the current was suppressed almost twofold by
Ca2+/CaM (Fig. 6A, traces
3 and 4). The current suppression by
Ca2+/CaM was reversible. When the patch was perfused for a
few minutes with EGTA and no CaM, the current amplitude recovered and
usually reached the value before perfusion with CaM. Occasionally, the current level did not recover completely. Because the saturating current was also decreased, this effect was not attributable to incomplete removal of CaM but rather was attributable to unspecific run-down of patch current.
Fig. 6.
Modulation of channel activity by
Ca2+/CaM. A, Effect of Ca2+/CaM
on the cGMP-activated current of ccCNGC expressed in
Xenopus oocytes (inside-out patch). The bath solutions
contained 120 mM K+-gluconate, 10 mM HEPES-KOH, 50 µM Ca2+, and the
following additions: 500 µM cGMP (trace
1); 500 µM cGMP and 1.2 µM CaM
(trace 2); 20 µM cGMP (trace
3); 20 µM cGMP and 1.2 µM CaM
(trace 4). B, Effect of
Ca2+/CaM on the cGMP-activated current of splice variant
ccCNGC5-6 expressed in HEK 293 cells. Same
conditions as in A except that the CaM concentration was
600 nM, and the solution was based on KCl instead of
K+-gluconate.
[View Larger Version of this Image (12K GIF file)]
We also examined whether channel modulation by Ca2+/CaM is
altered in the splice variant ccCNGC5-6. Figure
6B shows I-V recordings with
ccCNGC5-6 similar to those shown in A for
ccCNGC. The current at a subsaturating cGMP concentration
was reduced significantly in the presence of CaM (600 nM),
similar to the effect observed with ccCNGC (Fig.
6B, traces 3 and 4). At
a saturating cGMP concentration, CaM had no effect (Fig.
6B, traces 1 and 2). In
conclusion, the significantly shorter region between the putative
CaM-binding site and the first membrane-spanning segment S1 in the
pineal form of the cone CNG channel does not alter the
Ca2+/CaM effect.
Table 1 summarizes modulation of
K1/2 values by Ca2+/CaM
from several experiments with ccCNGC and
ccCNGC5-6. The effect was small but was observed
consistently in all experiments and was of similar size as that
reported for the rod CNG channel (Hsu and Molday, 1993; Gordon et al.,
1995; Körschen et al., 1995; Nakatani et al., 1995).
DISCUSSION
Expression of CNG channels in the pineal
Here we demonstrate by PCR analysis of the respective cDNA that
the -subunit of the cone photoreceptor CNG channel itself or two
shorter splice variants are expressed in the pineal organs of bovine
and chick, respectively.
Antibodies against the chick cone CNG channel recognize the majority of
modified photoreceptors in the chick pineal follicle, although the
immunoreactivity seems to be weaker as compared with cone
photoreceptors (Bönigk et al., 1993, their Fig. 5). In the bovine, only few cells in the periphery of the pineal are labeled by an
antibody specific for the bovine cone channel. A similar labeling
pattern has also been observed in the rat pineal with an antibody
directed against recoverin (Korf et al., 1992). Although rod CNG
channel-specific sequences can be amplified from pineal cDNA of chick
and bovine (Distler et al., 1994; Schaad et al., 1995), two different
antibodies directed against the bovine rod CNG channel failed to
specifically mark pineal tissue (data not shown). This discrepancy and
the moderate staining of the chick pineal with the cone
channel-specific antibody probably arises from a low channel density.
This conclusion is supported by studies that estimated that excised
membrane patches of chick pinealocytes contain 3-10 copies of a CNG
channel (Dryer and Henderson, 1991, 1993). This channel density is
roughly 100-fold lower than in the outer segment membrane of rod
photoreceptors, but of the same order as that observed in the inner
segment of rod (Matthews and Watanabe, 1988; Torre et al., 1992) and
the synaptic region of cone (Rieke and Schwartz, 1994) photoreceptors.
In these regions, CNG channels also escape unequivocal detection by
immunohistochemical methods (F. Müller, unpublished
observations).
Previously, components of the light-dependent enzyme cascade of retinal
photoreceptors, such as arrestin, recoverin, rhodopsin kinase,
phosducin, guanylate cyclase, and cGMP-specific phosphodiesterase, have
been demonstrated in the pineal (Kalsow and Wacker, 1978; Somers and
Klein, 1984; Korf et al., 1985; Palczewski et al., 1990; Reig et
al., 1990; Korf et al., 1992; Carcamo et al., 1995; Yang et al., 1995;
for reviews, see Lolley et al., 1992; Korf, 1994). Some polypeptides
have been identified by cloning or isotype-specific antibodies. For
example, pineal arrestin and phosducin are virtually identical with
their rod photoreceptor forms (Abe and Shinohara, 1990; Abe et al.,
1990), whereas the cone-specific PDE is present in rat and bovine
pineal (Carcamo et al., 1995). Pinopsin, a unique rhodopsin-like
molecule, is expressed exclusively in the pineal (Okano et al., 1994;
Max et al., 1995). Our results demonstrate that for the CNG channel
both rod and cone photoreceptor isoforms and some splice variants
co-exist in the pineal. In conclusion, the pineal polypeptide inventory
seems to be rather complex, raising several intriguing questions. Are
the rod- and cone-specific isoforms of signaling components expressed
in the same cells or in different subtypes of pinealocytes? Do pineal
signaling pathways mix components from rod and cone photoreceptors or
are these segregated to different cellular regions where they subserve
diverse functions? It will be an interesting and formidable task for
future research to answer these questions with immunohistochemical
techniques on a cellular or subcellular level.
Physiological function
The existence of different splice forms and the dissimilar
expression pattern of the cone CNG channel in bovine and chick pineal
could reflect the difference in the regulation of pineal function in
mammals and birds. Modified pinealocytes of birds and lower vertebrates
retained light sensitivity, and the cone CNG channel is likely to be
involved in light-dependent signaling in rudimentary outer segments. At
sites of synaptic input by VIP and NE, which are known to increase
cellular cGMP concentrations, the cone CNG channel, because of its high
Ca2+ permeability (Perry and McNaughton, 1991; Frings et
al., 1995; Picones and Korenbrot, 1995), could serve as a
Ca2+ entry pathway and mediate the rise in
[Ca2+]i by VIP (D'Souza and Dryer, 1994) or
other neurotransmitters. This may even be the exclusive function in
mammalian pinealocytes that do not respond to light.
The splice variants of the cone CNG channel in the chick pineal are
lacking a highly charged segment in the N-terminal region encoded by
exon 6. This segment is present in CNG channels from both rod and cone
photoreceptors (Bönigk et al., 1993) but is much less pronounced
in olfactory CNG channels. In this respect, the two splice variants are
more akin to the olfactory CNG channel. The N-terminal region, by
allosteric interaction with the ligand binding site in the C terminus,
co-determines the ligand sensitivity (Goulding et al., 1994), which is
higher in olfactory than in photoreceptor CNG channels. Therefore, the
shorter N-terminal region in the splice variant most likely is
responsible for the twofold higher ligand sensitivity compared with the
complete cone CNG channels. Other functions of this region, if any, are
not known; it may control assembly of the multimeric channel complex or
direct expression of splice variants to different sites such as, for
example, the rudimentary outer segment or the synaptic region of the
cell.
Modulation by Ca2+/CaM
It has been shown previously that rod and olfactory CNG channels
are modulated by Ca2+/CaM (Hsu and Molday, 1993; Chen and
Yau, 1994), whereas a similar modulation has not yet been demonstrated
for the native cone CNG channel. Ca2+/CaM can decrease the
cAMP sensitivity of the olfactory CNG channel by almost 20-fold (Chen
and Yau, 1994). A segment of roughly 16 residues in the N-terminal
region has been identified as a CaM-binding site in the -subunit of
the rat olfactory CNG channel (Liu et al., 1994). The effect of CaM on
the rod CNG channel is at least 10-fold weaker (Hsu and Molday, 1993;
Gordon et al., 1995; Nakatani et al., 1995) and requires the 240 kDa
-subunit (Hsu and Molday, 1993; Körschen et al., 1995). Thus,
the extent and site of modulation by Ca2+/CaM is different
for rod and olfactory CNG channels.
The region of the cone CNG channel -subunit encoded by exon 4 is
highly homologous to a region of the olfactory CNG channel that harbors
the CaM-binding site. At first sight, both conservation of this motif
and the moderate yet significant CaM sensitivity of chick cone
-subunit would argue for a regulatory role of Ca2+/CaM
in vivo. Several observations, however, caution against a rash interpretation. First, although the binding motifs in cone and
olfactory CNG channels are rather similar, the Ca2+/CaM
effect in the cone -subunit is much smaller than in the olfactory
-subunit. In fact, it is as small as that in the native rod CNG
channel (Gordon et al., 1995; Körschen et al., 1995; Nakatani et
al., 1995). CaM-binding motifs similar to those in the -subunits of
cone or olfactory CNG channels, however, cannot be identified in the
-subunit that confers CaM sensitivity to the rod CNG channel (Hsu
and Molday, 1993; Körschen et al., 1995). This suggests that
sites for CaM recognition must be significantly different in - and
-subunits. Finally, no modulation by Ca2+/CaM was
detected for the native cone CNG channel from catfish (Haynes and
Stotz, 1996) and the heterologously expressed bovine cone CNG channel
-subunit (F. Müller, unpublished observations).
Recently, Gordon et al. (1995) provided some preliminary evidence that
an unknown cellular factor, in addition to or instead of CaM, may
control CNG channel activity in rod photoreceptors. An unknown factor
may also control the activity of the cone CNG channel by binding to a
site that can be used promiscuously by CaM in some but not all species.
It will be an important task for future research to characterize the
physiological significance of this putative CaM-binding motif.
FOOTNOTES
Received July 10, 1996; revised Sept. 5, 1996; accepted Sept. 12, 1996.
This work was supported by a grant from the Deutsche
Forschungsgemeinschaft (I.W.). We thank Drs. H.-W. Korf and E. Maronde (Frankfurt) for the initial supply of chick and bovine pineals, and
Drs. H.-W. Korf and J. Olcese (Hamburg) for comments on an earlier
version of this manuscript. We are particularly grateful to Dr. E. Eismann for many helpful suggestions on this manuscript. We express our
gratitude to Dr. R. S. Molday (Vancouver) for a gift of antibodies
63-4 and PPcCC1. We thank M. Bruns for technical assistance and A. Eckert for preparing this manuscript.
Correspondence should be addressed to Dr. U. Benjamin Kaupp,
IBI-1, Forschungszentrum Jülich, Postfach 1913, D52425
Jülich, Germany.
REFERENCES
-
Abe T,
Nakabayashi H,
Tamada H,
Takagi T,
Sakuragi S,
Yamaki K,
Shinohara T
(1990)
Analysis of the human, bovine and rat 33 kDa proteins and cDNA in retina and pineal gland.
Gene
91:209-215 .
[Web of Science][Medline]
-
Abe T,
Shinohara T
(1990)
S-antigen from the rat retina and pineal gland have identical sequences.
Exp Eye Res
51:111-112 .
[Web of Science][Medline]
-
Altenhofen W,
Ludwig J,
Eismann E,
Kraus W,
Bönigk W,
Kaupp UB
(1991)
Control of ligand specificity in cyclic nucleotide-gated channels from rod photoreceptors and olfactory epithelium.
Proc Natl Acad Sci USA
88:9868-9872 .
[Abstract/Free Full Text]
-
Baumann A,
Frings S,
Godde M,
Seifert R,
Kaupp UB
(1994)
Primary structure and functional expression of a Drosophila cyclic nucleotide-gated channel present in eyes and antennae.
EMBO J
13:5040-5050 .
[Web of Science][Medline]
-
Bönigk W,
Altenhofen W,
Müller F,
Dose A,
Illing M,
Molday RS,
Kaupp UB
(1993)
Rod and cone photoreceptor cells express distinct genes for cGMP-gated channels.
Neuron
10:865-877 .
[Web of Science][Medline]
-
Bradley J,
Li J,
Davidson N,
Lester HA,
Zinn K
(1994)
Heteromeric olfactory cyclic nucleotide-gated channels: a new subunit that confers increased sensitivity to cAMP.
Proc Natl Acad Sci USA
91:8890-8894 .
[Abstract/Free Full Text]
-
Carcamo B,
Hurwitz MY,
Craft CM,
Hurwitz RL
(1995)
The mammalian pineal expresses the cone but not the rod cyclic GMP phosphodiesterase.
J Neurochem
65:1085-1092 .
[Web of Science][Medline]
-
Chen T-Y,
Peng Y-W,
Dhallan RS,
Ahamed B,
Reed RR,
Yau K-W
(1993)
A new subunit of the cyclic nucleotide-gated cation channel in retinal rods.
Nature
362:764-767 .
[Medline]
-
Chen T-Y,
Yau K-W
(1994)
Direct modulation by Ca2+-calmodulin of cyclic nucleotide-activated channel of rat olfactory receptor neurons.
Nature
368:545-548 .
[Medline]
-
Chik CL,
Liu Q-Y,
Li B,
Karpinski E,
Ho AK
(1995)
cGMP inhibits L-type Ca2+ channel currents through protein phosphorylation in rat pinealocytes.
J Neurosci
15:3104-3109 .
[Abstract]
-
Davidoff M,
Schulze W
(1990)
Combination of the peroxidase antiperoxidase (PAP)- and the avidin-biotin-peroxidase complex (ABC)-techniques: an amplification alternative in immunocytochemical staining.
Histochemistry
93:531-536 .
[Web of Science][Medline]
-
Deguchi T
(1979)
Role of adenosine 3,5-monophosphate in the regulation of circadian oscillation of serotonin N-acetyltransferase activity in cultured chicken pineal gland.
J Neurochem
33:45-51 .
[Web of Science][Medline]
-
Dhallan RS,
Yau K-W,
Schrader KA,
Reed RR
(1990)
Primary structure and functional expression of a cyclic nucleotide-activated channel from olfactory neurons.
Nature
347:184-187 .
[Medline]
-
Dhallan RS,
Macke JP,
Eddy RL,
Shows TB,
Reed RR,
Yau K-W,
Nathans J
(1992)
Human rod photoreceptor cGMP-gated channel: amino acid sequence, gene structure, and functional expression.
J Neurosci
12:3248-3256 .
[Abstract]
-
Distler M,
Biel M,
Flockerzi V,
Hofmann F
(1994)
Expression of cyclic nucleotide-gated cation channels in non-sensory tissues and cells.
Neuropharmacology
33:1275-1282 .
[Web of Science][Medline]
-
Dryer SE,
Henderson D
(1991)
A cyclic GMP-activated channel in dissociated cells of the chick pineal gland.
Nature
353:756-758 .
[Medline]
-
Dryer SE,
Henderson D
(1993)
Cyclic GMP-activated channels of the chick pineal gland: effects of divalent cations, pH, and cyclic AMP.
J Comp Physiol [A]
172:271-279 .
[Medline]
-
D'Souza T,
Dryer SE
(1994)
Intracellular free Ca2+ in dissociated cells of the chick pineal gland: regulation by membrane depolarization, second messengers and neuromodulators, and evidence for release of intracellular Ca2+ stores.
Brain Res
656:85-94.
[Web of Science][Medline]
-
Eismann E,
Bönigk W,
Kaupp UB
(1993)
Structural features of cyclic nucleotide-gated channels.
Cell Physiol Biochem
3:332-351.[Web of Science]
-
Finn JT,
Grunwald ME,
Yau K-W
(1996)
Cyclic nucleotide-gated ion channels: an extended family with diverse functions.
Annu Rev Physiol
58:395-426 .
[Web of Science][Medline]
-
Frings S,
Seifert R,
Godde M,
Kaupp UB
(1995)
Profoundly different calcium permeation and blockage determine the specific function of distinct cyclic nucleotide-gated channels.
Neuron
15:169-179 .
[Web of Science][Medline]
-
Gordon SE,
Downing-Park J,
Zimmerman AL
(1995)
Modulation of the cGMP-gated ion channel in frog rods by calmodulin and an endogenous inhibitory factor.
J Physiol (Lond)
486:533-546 .
[Abstract/Free Full Text]
-
Goulding EH,
Ngai J,
Kramer RH,
Colicos S,
Axel R,
Siegelbaum SA,
Chess A
(1992)
Molecular cloning and single-channel properties of the cyclic nucleotide-gated channel from catfish olfactory neurons.
Neuron
8:45-58 .
[Web of Science][Medline]
-
Goulding EH,
Tibbs GR,
Siegelbaum SA
(1994)
Molecular mechanism of cyclic-nucleotide-gated channel activation.
Nature
372:369-374 .
[Medline]
-
Haynes LW,
Stotz SC
(1996)
Modulation of cone photoreceptor cGMP-gated channels.
Biophys J
70:A138.
-
Hsu Y-T,
Molday RS
(1993)
Modulation of the cGMP-gated channel of rod photoreceptor cells by calmodulin.
Nature
361:76-79 .
[Medline]
-
Ikura M,
Clore GM,
Gronenborn AM,
Zhu G,
Klee CB,
Bax A
(1992)
Solution structure of a calmodulin-target peptide complex by multidimensional NMR.
Science
256:632-638 .
[Abstract/Free Full Text]
-
Kaku K,
Tsuchiya M,
Matsuda M,
Inoue Y,
Kaneko T,
Yanaihara N
(1985)
Light and agonist alter vasoactive intestinal peptide binding and intracellular accumulation of adenosine 3,5-monophosphate in the rat pineal.
Endocrinology
117:2371-2375 .
[Abstract/Free Full Text]
-
Kalsow CM,
Wacker WB
(1978)
Pineal gland involvement in retina-induced experimental allergic uveitis.
Invest Ophthalmol Vis Sci
17:774-783 .
[Abstract/Free Full Text]
-
Kaupp UB,
Niidome T,
Tanabe T,
Terada S,
Bönigk W,
Stühmer W,
Cook NJ,
Kangawa K,
Matsuo H,
Hirose T,
Miyata T,
Numa S
(1989)
Primary structure and functional expression from complementary DNA of the rod photoreceptor cyclic GMP-gated channel.
Nature
342:762-766 .
[Medline]
-
Kaupp UB
(1995)
Family of cyclic nucleotide gated ion channels.
Curr Opin Neurobiol
5:434-442 .
[Web of Science][Medline]
-
Klein DC
(1986)
Photoneural regulation of the mammalian pineal gland.
Ciba Found Symp
117:38-56.
-
Korf H-W,
White BH,
Schaad NC,
Klein DC
(1992)
Recoverin in pineal organs and retinae of various vertebrate species including man.
Brain Res
595:57-66 .
[Web of Science][Medline]
-
Korf H-W
(1994)
The pineal organ as a component of the biological clock.
Ann NY Acad Sci
719:13-42 .
[Web of Science][Medline]
-
Korf H-W,
Møller M,
Gery I,
Zigler JS,
Klein DC
(1985)
Immunocytochemical demonstration of retinal S-antigen in the pineal organ of four mammalian species.
Cell Tissue Res
239:81-85 .
[Web of Science][Medline]
-
Körschen HG,
Illing M,
Seifert R,
Sesti F,
Williams A,
Gotzes S,
Colville C,
Müller F,
Dosé A,
Godde M,
Molday L,
Kaupp UB,
Molday RS
(1995)
A 240 kDa protein represents the complete -subunit of cyclic nucleotide-gated channel from rod photoreceptors.
Neuron
15:627-636 .
[Web of Science][Medline]
-
Kozak M
(1984)
Compilation and analysis of sequences upstream from the translational start site in eukaryotic mRNAs.
Nucleic Acids Res
12:857-872 .
[Abstract/Free Full Text]
-
Liman ER,
Tytgat J,
Hess P
(1992)
Subunit stoichiometry of a mammalian K+ channel determined by construction of multimeric cDNAs.
Neuron
9:861-871 .
[Web of Science][Medline]
-
Liman ER,
Buck LB
(1994)
A second subunit of the olfactory cyclic nucleotide-gated channel confers high sensitivity to cAMP.
Neuron
13:611-621 .
[Web of Science][Medline]
-
Liu M,
Chen T-Y,
Ahamed B,
Li J,
Yau K-W
(1994)
Calcium-calmodulin modulation of the olfactory cyclic nucleotide-gated cation channel.
Science
266:1348-1354 .
[Abstract/Free Full Text]
-
Lolley RN,
Craft CM,
Lee RH
(1992)
Photoreceptors of the retina and pinealocytes of the pineal gland share common components of signal transduction.
Neurochem Res
17:81-89 .
[Web of Science][Medline]
-
Matthews G,
Watanabe S-I
(1988)
Activation of single ion channels from toad retinal rod inner segments by cyclic GMP: concentration dependence.
J Physiol (Lond)
403:389-405 .
[Abstract/Free Full Text]
-
Max M,
McKinnon PJ,
Seidenman KJ,
Barrett RK,
Applebury ML,
Takahashi JS,
Margolskee RF
(1995)
Pineal opsin: a nonvisual opsin expressed in chick pineal.
Science
267:1502-1506 .
[Abstract/Free Full Text]
-
Nakatani K,
Koutalos Y,
Yau K-W
(1995)
Ca2+ modulation of the cGMP-gated channel of bullfrog retinal rod photoreceptors.
J Physiol (Lond)
484:69-76 .
[Abstract/Free Full Text]
-
O'Neil KT,
DeGrado WF
(1990)
How calmodulin binds its targets: sequence independent recognition of amphiphilic -helices.
Trends Biochem Sci
15:59-64.
[Web of Science][Medline]
-
Okano T,
Yoshizawa T,
Fukada Y
(1994)
Pinopsin is a chicken pineal photoreceptive molecule.
Nature
372:94-97 .
[Medline]
-
Palczewski K,
Carruth ME,
Adamus G,
McDowell JH,
Hargrave PA
(1990)
Molecular, enzymatic and functional properties of rhodopsin kinase from rat pineal gland.
Vision Res
30:1129-1137 .
[Web of Science][Medline]
-
Perry RJ,
McNaughton PA
(1991)
Response properties of cones from the retina of the tiger salamander.
J Physiol (Lond)
433:561-587 .
[Abstract/Free Full Text]
-
Picones A,
Korenbrot JI
(1995)
Permeability and interaction of Ca2+ with cGMP-gated ion channels differ in retinal rod and cone photoreceptors.
Biophys J
69:120-127 .
[Web of Science][Medline]
-
Pratt BL,
Takahashi JS
(1989)
Vasoactive intestinal polypeptide and 2-adrenoceptor agonists regulate adenosine 3,5-monophosphate accumulation and melatonin release in chick pineal cell cultures.
Endocrinology
125:2375-2384 .
[Abstract/Free Full Text]
-
Reig JA,
Yu L,
Klein DC
(1990)
Pineal transduction: adrenergic-cyclic-AMP-dependent phosphorylation of cytoplasmic 33 kDa protein (MEKA) which binds beta, gamma-complex of transducin.
J Biol Chem
265:5816-5824 .
[Abstract/Free Full Text]
-
Rieke F,
Schwartz EA
(1994)
A cGMP-gated current can control exocytosis at cone synapses.
Neuron
13:863-873 .
[Web of Science][Medline]
-
Sato T,
Kaneko M,
Fujieda H,
Deguchi T,
Wake K
(1994)
Analysis of the heterogeneity within bovine pineal gland by immunohistochemistry and in situ hybridization.
Cell Tissue Res
277:201-209 .
[Web of Science][Medline]
-
Sáez JC,
Moreno AP,
Spray DC
(1994)
Norepinephrine induces Ca2+ release from intracellular stores in rat pinealocytes.
J Pineal Res
16:57-64 .
[Web of Science][Medline]
-
Schaad NC,
Vanecek J,
Rodriguez IR,
Klein DC,
Holtzclaw L,
Russell JT
(1995)
Vasoactive intestinal peptide elevates pinealocyte intracellular calcium concentrations by enhancing influx: evidence for involvement of a cyclic GMP-dependent mechanism.
Mol Pharmacol
47:923-933 .
[Abstract]
-
Schomerus C,
Laedtke E,
Korf H-W
(1995)
Calcium responses of isolated, immunocytochemically identified rat pinealocytes to noradrenergic, cholinergic and vasopressinergic stimulations.
Neurochem Int
27:163-175 .
[Web of Science][Medline]
-
Somers RL,
Klein DC
(1984)
Rhodopsin kinase activity in the mammalian pineal gland and other tissues.
Science
226:182-184 .
[Abstract/Free Full Text]
-
Sugden LA,
Sugden D,
Klein DC
(1987)
1-adrenoceptor activation elevates cytosolic calcium in rat pinealocytes by increasing net influx.
J Biol Chem
262:741-745 .
[Abstract/Free Full Text]
-
Takahashi JS
(1995)
Molecular neurobiology and genetics of circadian rhythms in mammals.
Annu Rev Neurosci
18:531-553 .
[Web of Science][Medline]
-
Takahashi JS,
Murakami N,
Nikaido SS,
Pratt BL,
Robertson LM
(1989)
The avian pineal, a vertebrate model system of the circadian oscillator: cellular regulation of circadian rhythms by light, second messengers, and macromolecular synthesis.
Recent Prog Horm Res
45:279-352 .
-
Torre V,
Straforini M,
Sesti F,
Lamb TD
(1992)
Different channel-gating properties of two classes of cyclic GMP-activated channel in vertebrate photoreceptors.
Proc R Soc Lond [Biol]
250:209-215 .
[Medline]
-
Voisin P,
Guerlotté J,
Collin J-P
(1988)
An antiserum against chicken hydroxyindole-O-methyltransferase reacts with the enzyme from pineal gland and retina and labels pineal modified photoreceptors.
Mol Brain Res
4:53-61.
-
Voisin P,
Collin J-P
(1986)
Regulation of chicken pineal arylalkylamine-N-acetyltransferase by postsynaptic 2-adrenergic receptors.
Life Sci
39:2025-2032 .
[Web of Science][Medline]
-
Weyand I,
Godde M,
Frings S,
Weiner J,
Müller F,
Altenhofen W,
Hatt H,
Kaupp UB
(1994)
Cloning and functional expression of a cyclic-nucleotide-gated channel from mammalian sperm.
Nature
368:859-863 .
[Medline]
-
Yang R-B,
Foster DC,
Garbers DL,
Fülle H-J
(1995)
Two membrane forms of guanylyl cyclase found in the eye.
Proc Natl Acad Sci USA
92:602-606 .
[Abstract/Free Full Text]
-
Yuwiler A
(1983)
Vasoactive intestinal peptide stimulation of pineal serotonin-N-acetyltransferase activity: general characteristics.
J Neurochem
41:146-153 .
[Web of Science][Medline]
-
Záborszky L,
Léránth C
(1985)
Simultaneous ultrastructural demonstration of retrogradely transported horseradish peroxidase and choline acetyltransferase immunoreactivity.
Histochemistry
82:529-537 .
[Web of Science][Medline]
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S.-K. Chen, G. Y.-P. Ko, and S. E. Dryer
Somatostatin Peptides Produce Multiple Effects on Gating Properties of Native Cone Photoreceptor cGMP-Gated Channels That Depend on Circadian Phase and Previous Illumination
J. Neurosci.,
November 7, 2007;
27(45):
12168 - 12175.
[Abstract]
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C. Peng, E. D. Rich, C. A. Thor, and M. D. Varnum
Functionally Important Calmodulin-binding Sites in Both NH2- and COOH-terminal Regions of the Cone Photoreceptor Cyclic Nucleotide-gated Channel CNGB3 Subunit
J. Biol. Chem.,
June 27, 2003;
278(27):
24617 - 24623.
[Abstract]
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M. C. Trudeau and W. N. Zagotta
Calcium/Calmodulin Modulation of Olfactory and Rod Cyclic Nucleotide-gated Ion Channels
J. Biol. Chem.,
May 23, 2003;
278(21):
18705 - 18708.
[Abstract]
[Full Text]
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D. Henry, S. Burke, E. Shishido, and G. Matthews
Retinal Bipolar Neurons Express the Cyclic Nucleotide-Gated Channel of Cone Photoreceptors
J Neurophysiol,
February 1, 2003;
89(2):
754 - 761.
[Abstract]
[Full Text]
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U. B. Kaupp and R. Seifert
Cyclic Nucleotide-Gated Ion Channels
Physiol Rev,
July 1, 2002;
82(3):
769 - 824.
[Abstract]
[Full Text]
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F. Muller, M. Vantler, D. Weitz, E. Eismann, M. Zoche, K.-W. Koch, and U B. Kaupp
Ligand sensitivity of the {alpha}2 subunit from the bovine cone cGMP-gated channel is modulated by protein kinase C but not by calmodulin
J. Physiol.,
April 15, 2001;
532(2):
399 - 409.
[Abstract]
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M. R. Meyer, A. Angele, E. Kremmer, U. B. Kaupp, and F. Muller
A cGMP-signaling pathway in a subset of olfactory sensory neurons
PNAS,
September 12, 2000;
97(19):
10595 - 10600.
[Abstract]
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M. E. Grunwald, H. Zhong, J. Lai, and K.-W. Yau
Molecular determinants of the modulation of cyclic nucleotide-activated channels by calmodulin
PNAS,
November 9, 1999;
96(23):
13444 - 13449.
[Abstract]
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D. R. S. Roy and C. J. Barnstable
Temporal and Spatial Pattern of Expression of Cyclic Nucleotide-gated Channels in Developing Rat Visual Cortex
Cereb Cortex,
June 1, 1999;
9(4):
340 - 347.
[Abstract]
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B. Wiesner, J. Weiner, R. Middendorff, V. Hagen, U. B. Kaupp, and I. Weyand
Cyclic Nucleotide-gated Channels on the Flagellum Control Ca2+ Entry into Sperm
J. Cell Biol.,
July 27, 1998;
142(2):
473 - 484.
[Abstract]
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S. Blackshaw and S. H. Snyder
Developmental Expression Pattern of Phototransduction Components in Mammalian Pineal Implies a Light-Sensing Function
J. Neurosci.,
November 1, 1997;
17(21):
8074 - 8082.
[Abstract]
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