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 Previous Article | Next Article 
The Journal of Neuroscience, February 15, 2000, 20(4):1324-1332
Molecular Cloning and Functional Characterization of a New
Modulatory Cyclic Nucleotide-Gated Channel Subunit from Mouse
Retina
Andrea
Gerstner1,
Xiangang
Zong1,
Franz
Hofmann1, and
Martin
Biel1, 2
1 Institut für Pharmakologie und Toxikologie der
Technischen Universität München, 80802 München,
Germany, and 2 Institut für Pharmazie-Zentrum
für Pharmaforschung, Ludwig-Maximilians-Universität
München, 81377 München, Germany
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ABSTRACT |
Cyclic nucleotide-gated (CNG) channels play a key role in olfactory
and visual transduction. Native CNG channels are heteromeric complexes
consisting of the principal  subunits (CNG1-3), which can form
functional channels by themselves, and the modulatory  subunits
(CNG4-5). The individual and subunits that combine to form the
CNG channels in rod photoreceptors (CNG1 + CNG4) and olfactory neurons
(CNG2 + CNG4 + CNG5) have been characterized. In contrast, only an subunit (CNG3) has been identified so far in cone photoreceptors. Here
we report the molecular cloning of a new CNG channel subunit (CNG6)
from mouse retina. The cDNA of CNG6 encodes a peptide of 694 amino
acids with a predicted molecular weight of 80 kDa. Among the CNG
channel subunits, CNG6 has the highest overall similarity to the CNG4
subunit (47% sequence identity). CNG6 transcripts are present in a
small subset of retinal photoreceptor cells and also in testis.
Heterologous expression of CNG6 in human embryonic kidney 293 cells did
not lead to detectable currents. However, when coexpressed with the
cone photoreceptor subunit, CNG6 induced a flickering channel
gating, weakened the outward rectification in the presence of
extracellular Ca2+, increased the sensitivity for
L-cis diltiazem, and enhanced the cAMP
efficacy of the channel. Taken together, the data indicate that CNG6
represents a new CNG channel subunit that may associate with the
CNG3 subunit to form the native cone channel.
Key words:
cone photoreceptor; cyclic nucleotide; cation channel; L-cis diltiazem; single-channel recording
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INTRODUCTION |
Cyclic nucleotide-gated (CNG)
channels are expressed in various cell types and tissues. Although the
functional significance of CNG channel expression in most nonsensory
tissues is still unclear, the role of the channels in signal
transduction pathways of vertebrate sensory neurons has been well
defined (Baylor, 1996 ; Finn et al., 1996; Schild and Restrepo, 1998).
In rod and cone photoreceptors as well as in olfactory neurons, CNG
channels control the influx of Ca2+ and
Na+ in response to signal-induced changes
of cGMP or cAMP levels. CNG channels are predicted to form tetrameric
structures (Gordon and Zagotta, 1995; Liu et al., 1996; Shammat and
Gordon, 1999). So far, five genes encoding CNG channels have been
identified in mammals (Biel et al., 1999a). These subunits have been
classified as and subunits based on expression studies. The subunits (CNG1-3) can form functional CNG channels when expressed in
various heterologous expression systems. The subunits (CNG4-5),
although presumably having the same general transmembrane structure as subunits, do not give rise to CNG channels when expressed alone. However, when combined with subunits they bestow the
hetero-oligomeric channels with properties that are characteristic of
native photoreceptor (Chen et al., 1993; Körschen et al., 1995)
and olfactory (Bradley et al., 1994; Liman and Buck, 1994; Sautter et
al., 1998; Bönigk et al., 1999) CNG channels. These subunit-controlled channel properties include single-channel
flickering, sensitivity to blockage by
L-cis-diltiazem, increased apparent affinity for
cyclic nucleotides, and altered interaction with
Ca2+. The subunit composition of native
CNG channels has been determined in two cases. First, the CNG channel
of rod outer segments consists of the CNG1 subunit (Kaupp et al.,
1989) and the long isoform of the CNG4 subunit (Körschen et
al., 1995). Second, the CNG channel of olfactory neurons is composed of
the CNG2 subunit (Dhallan et al., 1990; Ludwig et al., 1990) and
two distinct -subunits: a short isoform of CNG4 (Sautter et al.,
1998; Bönigk et al., 1999) and the CNG5 subunit (Bradley et al.,
1994; Liman and Buck, 1994). In contrast, the subunit composition of
the cone photoreceptor CNG channel has only been partially elucidated.
Expression studies (Bönigk et al., 1993; Weyand et al., 1994; Yu
et al., 1996; Biel et al., 1999b), gene deletion (Biel et al., 1999b),
and genetic analysis of human total color blindness (Kohl et al., 1998)
indicated that the CNG3 subunit forms the subunit of the native
cone channel. The properties of the expressed CNG3 channel, however,
are not completely consistent with the properties of native cone
channels. For example, CNG3 lacks the flickery gating that is typical
of native channels (Haynes and Yau, 1990; Weyand et al., 1994; Yu et
al., 1996; Zong et al., 1998) and is almost insensitive to L-cis diltiazem (Biel et al., 1994).
Expression studies and biochemical analysis suggest that in bovine
testis CNG3 associates with a short isoform of CNG4 to form a
functional channel (Biel et al., 1996; Wiesner et al., 1998). However,
antibodies directed against the C terminus (Chen et al., 1993) or
N-terminal glutamic acid-rich protein (GARP) domain of CNG4
(Körschen et al., 1999) did not detect the CNG4 subunit in cone
photoreceptors. Likewise, the CNG5 subunit is not expressed in
retina (Bradley et al., 1994; Liman and Buck, 1994; Bönigk et
al., 1999). These data suggest that the native cone channel is composed
of the CNG3 subunit and an as yet uncharacterized subunit.
Here we report the molecular cloning of a novel modulatory CNG channel
subunit (CNG6) from mouse retina. Expression in human embryonic kidney
(HEK) 293 cells indicates that CNG6 assembles with CNG3 to form a
heteromeric CNG channel with properties very similar to those of the
native cone photoreceptor channel.
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MATERIALS AND METHODS |
Cloning of mCNG6. Starting out from the human
expressed sequence tag (EST) HSA12972 and the sequence of rat CNG4
(Sautter et al., 1997), degenerate primers [600F:
5'-AAT/GCC/TG(TC)/GTT/TA(TC)/TA(TC)/TGG/GC-3' and CGKRev:
5'-A(GA)/(AG)(CG)T/(TGA)AT/(TC)TC/(TGCA)CC/(GA)AA-3'] were
designed, and a 686 bp cDNA fragment (corresponding to
N359-L587 of mCNG6) was
amplified by RT-PCR from rat retina cDNA, cloned, and sequenced. The
PCR was performed according to the following protocol: 94°C, 2 min;
40 cycles of 94°C, 50 sec; 51°C, 1 min; 72°C, 2 min; and 72°C,
5 min. An oligo(dT)-primed cDNA library was constructed in the pcDNA2
vector (Invitrogen, San Diego, CA) from 10 µg of
poly(A+) mRNA from mouse eye and screened
with the 686 bp fragment labeled with
32P-dCTP. One partial clone, pcBib1,
comprising nucleotide (nt) 1084-3210 of mCNG6 was obtained. The
primary sequence of pcBib1 contained the C-terminal half of the coding
sequence of mCNG6 starting from the S4 segment and part of the 3'
untranslated sequence. To obtain the 5' region of the mCNG6-cDNA, a
specific library was constructed from mouse retina cDNA primed with
CG6rev (5'-TCGATACTGCACACTCTG-3', corresponding to
Q465-R470 of mCNG6).
Screening of the library with a 329 bp
(AccI-AvaII-) fragment corresponding to
V342-M451 of mCNG6 resulted
in the isolation of one additional clone (pcBib2). The cDNA insert
contained the 5' sequence of mCNG6 (nt 10-1493 of mCNG6). The
sequences of pcBib1 and pcBib2 were identical over the whole
overlapping sequence region. The composed cDNA sequence of pcBib1 and
pcBib2 contained one open reading frame encoding a protein of 694 amino
acids. Because the initiation ATG (nt 84-86) was not preceded by an
in-frame stop codon, it was not clear whether the 5' end of the full
length cDNA was represented in pcBib2. Hence, extensive 5' rapid
amplification of cDNA ends (RACE) analysis was performed (Clontech
Marathon kit; Clontech, Heidelberg, Germany) to determine the absolute
5' end of the cDNA. Briefly, 1 µg of poly(A+) mRNA from mouse retina was
reverse-transcribed using primer CG6rev. The single-stranded cDNA was
ligated to the Marathon adaptor and PCR-amplified using the
anchor primer AP1 and the nested primers CNG276R
(5'-AGAGTTTCTTCTCCATTCTCCCTT-3', nt 130-153) or CNG278R (5'-TTTGGTGATATATTTGTAGACATTG-3', nt 556-580). PCR fragments >200 bp
were cloned into pUC18 vector. Approximately 500 colonies were hybridized with a 115 bp probe (nt 10-124) derived from the 5' end of
pcBib2. The five longest clones were sequenced on both strands. They
were identical with pcBib2 in the overlapping region and contained an
additional 5' sequence of up to 9 bp. The RACE technique was also
applied to determine the complete 3' end of the cDNA. Approximately 1 µg of poly(A+) mRNA was
reverse-transcribed using an oligo(dT) primer. The single-stranded cDNA
was PCR-amplified using the specific primer CNG271F (nt 2794-2812,
5'-GTTCAAATGTCCAAAGTAG-3') and an anchor primer. The PCR profile was as
follows: 94°C, 2 min; 40 cycles of 93°C, 30 sec; 58°C, 1 min;
68°C, 4 min; and 68°C, 7 min. PCR fragments >700 bp were cloned
into pCR-BluntII-TOPO vector (Invitrogen). Approximately 300 colonies
were hybridized with a 209 bp probe (nt 2823-3031) derived
from the 3' end of pcBib1. Several positive clones were isolated and
sequenced. The longest clone, pc3'-23, contained an additional 1.5 kb
3' terminus of mCNG6. In total, the cloned cDNA of CNG6 comprised 4710 bp, which is consistent with the length of the CNG6 transcript in
Northern blot (4.7 kb).
Northern blot analysis.
Poly(A+) mRNA (6 µg) was isolated from
mouse retina and size-fractioned on a 1% agarose gel, transferred to a
Hybond-N membrane (Amersham Pharmacia Biotech, Freiburg, Germany), and
cross-linked by ultraviolet light. Two different 32P-labeled probes specific for mCNG6 were
used (see Fig. 2A): a 915 bp fragment (probe a, nt
1222-2136 corresponding to
N380-L684) and a 1.2 kb
fragment (probe b, nt 3169-4405) derived from pc3'-23. Probe a was
also used for hybridization with a mouse multiple tissue Northern blot
(Clontech). Hybridization was performed at high stringency.
Radiographic exposure was for 7 d at  70°C.
In situ hybridization.
35S-labeled riboprobes were synthesized
in vitro in the presence of
(35S)-UTP using either T3 or T7 RNA
polymerase (Stratagene, La Jolla, CA) for sense or antisense direction,
respectively. DNA fragments representing the different probes for CNG1,
CNG3, CNG4, and CNG6 were subcloned into a modified pUC19 vector (pAL1)
(Ludwig et al., 1997) as follows: CNG1-probe: 183 bp, corresponding to
peptide I458 to V517 of
CNG1 (Barnstable and Wei, 1995); CNG4-probe: 199 bp, corresponding to
V528 to R594 of CNG4.3
(Sautter et al., 1998); CNG3-probe: 263 bp [nt 1155-1417 of CNG3
(Biel et al., 1999b)]; CNG6-probe d: 253 bp (nt 1398-1650 of mCNG6).
Another probe specific for CNG6 (probe c, see Fig.
1A) was obtained by cloning a PCR fragment comprising
nt 125-381 of CNG6 into the pCR-BluntII-TOPO vector (Invitrogen). This
was followed by transcription with T7 or SP6 RNA polymerase for sense
or antisense direction, respectively. In situ hybridization
was performed as described previously (Ludwig et al., 1997). Labeled
slides were exposed to Kodak Bio Max film for 7 d and to Kodak
NTB-2 film emulsion for 2 weeks (CNG1 and CNG4) or 5 weeks (CNG3 and
CNG6). After development, slides were counterstained with
hematoxylene/eosine and coverslipped.
Construction of the expression vector mCNG6-pcDNA3 and expression
in HEK293 cells. Various strategies to clone the full length coding region of mCNG6 into the multiple cloning site of either prokaryotic or eukaryotic vectors was without success. However, in an
attempt to ligate the PCR-generated HindIII-NdeI
fragment (nt 84-1103) containing an optimized sequence for initiation
of translation (5'-gccgccaccATG-3') and the
NdeI-NheI fragment (nt 1104-2229) of mCNG6 cDNA
into HindIII-XbaI-cut pcDNA3 vector (Invitrogen), a single clone was obtained
(mCNG6S-pcDNA3). Sequence analysis of
mCNG6S-pcDNA3 revealed that this clone was
identical to the cDNA sequence of mCNG6 with the exception of a single
point mutation at position nt 1112 leading to a stop codon (TAC TAA).
This finding led to the assumption that Escherichia coli
produced a toxic gene product from mCNG6, possibly by using an internal
promoter for mRNA transcription and by initiating protein translation
at a starting point localized upstream of nt 1112. By PCR analysis the
region responsible for the toxicity of wild-type mCNG6 could be further
narrowed down to the region between nt 1020 and 1112. To prevent
transcription and protein translation in E. coli, the
sequence of mCNG6 had to be modified as follows. (1) The methionine
upstream of the spontaneous stop mutation (M337
corresponding to nt 1092-1094) was mutated to a leucine, which is the
amino acid that rCNG4 carries at equivalent position (see Fig.
1A). The position corresponding to
M337 is not conserved in the CNG channel family,
making it very unlikely that channel properties are affected by the
exchange. (2) To suppress a possible internal promotor function, six
silent mutations (T1064C, C1079T, G1082T, T1088G, A1091C, T1106C) were introduced in the vicinity of the putative start codon that did not
change the amino acid sequence encoded by mCNG6. The introduction of
the silent mutations without the replacement of
M337 by leucine was not sufficient to prevent
toxicity in E. coli. The integrity of the modified mCNG6
cDNA was verified by sequencing. The eukaryotic expression vector
mCNG6-pcDNA3 was obtained by inserting the modified mCNG6 sequence (nt
84-2229), including an optimized Kozak sequence, into the
HindIII-XbaI site of the pcDNA3 plasmid. The DNA
of mCNG6-pcDNA3 was well propagated in E. coli and used for
transient expression in HEK293 cells after calcium phosphate
transfection. mCNG6-pcDNA3 was used either alone or in combination with
equimolar amounts of plasmid pcGK26/CMV (Biel et al., 1994) encoding
the bovine CNG3 channel. To demonstrate the correctness of the cloning
procedures and to control expression in cell culture, the modified cDNA
of mCNG6 was also cloned into pcDNA3.1/Myc-His vector (Invitrogen). As
predicted from the primary sequence, a monoclonal antibody directed
against the C-terminal myc epitope recognized a specific band of ~80
kDa in membrane fractions of HEK293 cells transfected with the
expression vector (data not shown).
Electrophysiological experiments. Macroscopic currents and
single-channel currents were recorded from inside-out patches excised from HEK293 cells by using an Axopatch 200B amplifier and pCLAMP7 software (Axon Instruments, Foster City, CA). The pipette and bath
solution were identical and contained (in mM): 140 NaCl, 5.0 KCl, 10 HEPES, 1.0 EGTA (divalent cation-free solution, pH 7.4 with
NaOH). For measurement of the currents in the presence of extracellular
Ca2+, the following solution was used in
the pipette (in mM): 140 NaCl, 5.0 KCl, 2 CaCl2, 10 HEPES, pH 7.4. A multi-barreled
perfusion pipette placed 200 µm away from the patch was used to
switch the superfusion solution. The membrane potential was held at 0 mV and stepped for 200 msec to ± 100 mV. The macroscopic current was defined as the mean current measured during a 200 msec voltage step. Capacitative transients and leak currents were subtracted using
currents recorded under the superfusion with solution without agonist.
Data were filtered at 2 kHz, digitized at 20 kHz, and analyzed with
Clampfit and Fetchan software (Axon Instruments). Dose-response curves
for cGMP and cAMP were generated by measuring the current response at
+60 mV and fitted with the Hill equation: I/Imax = (C) /((C) + Ka),
where Imax is the current at a
saturating concentration (1 mM) of cGMP,
(C) is the cyclic nucleotide concentration,
Ka is the activation constant, and  is the
Hill coefficient.
Spontaneous channel activity was determined by applying 200 msec
depolarization pulses from 0 to +80 mV at a frequency of 0.5 Hz. The
mean spontaneous current (Isp) was
determined by averaging the current from 50 pulses. For baseline
correction, five blank traces containing no opening event were averaged
and subtracted from each current trace. At the end of each recording of
spontaneous activity, 300 µM of cGMP was
applied to the same patch to determine the maximal current amplitude
(Imax). The number of channels present in the patch (n) was calculated using
n = Imax/i,
where i is the single-channel current. It was assumed that
the open probability of the channels at saturating cGMP concentrations
(Pmax, cGMP) equals 1. Although the
Pmax, cGMP of the heteromeric channel
may be slightly smaller than that of the homomeric channel because of
the flickery gating, the error introduced by this difference is
expected to be small. All experiments were performed at room temperature (20°22°C). Values are given as mean + SEM.
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RESULTS |
Primary structure of CNG6
To identify new members of the CNG channel family, we performed a
BLAST search of the EST database using the CNG4 protein as a
query sequence. We retrieved the human EST HSA12972, encoding part of a
new putative CNG channel that was designated CNG6. A 686 bp fragment
was amplified from rat retina by RT-PCR using a pair of degenerate
primers derived from EST HSA12972 and a portion of the cyclic
nucleotide binding domain (CNBD) that is highly conserved among
mammalian CNG channels. The full-length sequence of CNG6 was cloned
from mouse retina by using a combination of cDNA library screening and
RACE techniques. The sequence of murine CNG6 (mCNG6) consists of 4710 bp and contains an open reading frame coding for a protein of 694 amino
acids with a molecular mass of 80 kDa (Fig.
1A). The predicted
protein has the hallmark features of CNG channels, namely six
transmembrane segments (S1-S6), a pore region (P), and a CNBD in the C
terminus. Within the CNG channel family, CNG6 is most closely related
to the CNG4 subunit (47% sequence identity at the amino acid
level). In contrast, CNG6 has only a weak homology with the CNG channel
subunits CNG1-3 (35% identity) and with the CNG5 subunit
(33%) (Fig. 1B). The homology between CNG6 and CNG4
is most pronounced in the transmembrane core and the CNBD (65%
sequence identity). The pore region of CNG6 is clearly related to that
of CNG4. In both subunits, the glutamate residue that forms a
high-affinity binding site for Ca2+ in CNG
channel subunits and controls channel gating and ion permeation
(Root and MacKinnon, 1993; Eismann et al., 1994) is replaced by a
glycine residue (position 402 in CNG6). The primary sequences of CNG4
and CNG6 diverge most strongly from each other in their respective
cytoplasmic N termini. In particular, CNG6 does not contain a GARP
domain (Sugimoto et al., 1991) that is present in the extended
cytosolic N terminus of the CNG4 subunit (Körschen et al., 1995;
Ardell et al., 1996; Colville and Molday, 1996; Sautter et al., 1997).
In addition, the calcium-calmodulin (CaM)-binding site that has been
identified in the N terminus of CNG4
(A168-D209 of CNG4.3)
(Grunwald et al., 1998; Weitz et al., 1998) is only poorly conserved in
CNG6 (30% sequence identity). A sequence corresponding to the
C-terminal CaM-binding site of CNG4 (Grunwald et al., 1998; Weitz et
al., 1998) is completely missing in CNG6. There is also no evidence for
a CaM-binding site similar to that found in the olfactory CNG channel
subunit (Liu et al., 1994).
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Figure 1.
Primary structure of murine CNG6.
A, Alignment of the amino acid sequence of mCNG6 with
rCNG4.3 and a partial sequence of rCNG6 (the prefix indicates the
species: m = mouse; r = rat).
Amino acids identical between mCNG6 and rCNG4.3 or all three proteins
are boxed. The putative transmembrane segments
(S1-S6), the pore region,and the CNBD are underlined. Gaps in the
sequences are represented by dashes.
Arrowheads in the N terminus of mCNG6 indicate the
region corresponding to probe c used for in situ
hybridization. Arrows mark the sequence corresponding to
the EST HSA12972. An asterisk indicates the methionine
at position 337 in the sequence of CNG6 that was replaced by leucine in
the CNG6 expression vector. The sequence of mCNG6 is available from the
European Molecular Biology Laboratory database under the accession
number AJ243572. B, Phylogenetic tree of the mammalian
CNG channel subunits. The tree was calculated based on the pairwise
comparison with the transmembrane domains and the cyclic nucleotide
binding domain of the respective subunits. The sequences are derived
from mouse [CNG1 (Pittler et al., 1992); CNG3 (Biel et al., 1999b);
CNG6 (this paper)] or rat [CNG2 (Dhallan et al., 1990); CNG4 (Sautter
et al., 1998); CNG5 (Bradley et al., 1994)].
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Northern blot analysis of CNG6 expression
To examine the tissue expression of CNG6 mRNA, we designed probes
a and b that were derived from the coding region (probe a) and the 3'
untranslated region (probe b) of the CNG6 cDNA, respectively (Fig.
2A). Probe b detected a
4.7 kb transcript in mouse retina (Fig. 2B). A
transcript of the same size was also found with probe a (data not
shown). The size of the CNG6 mRNA is in good agreement with the length
of the cloned cDNA (4710 bp), indicating that the cloned cDNA covers
the full-length sequence of the mRNA. Expression of CNG6 mRNA was also
observed in testis. However, the mRNA detected in testis was
significantly smaller (2.6 kb) than the retinal isoform and may
represent an alternatively spliced transcript of the CNG6 gene.
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Figure 2.
Expression of CNG6 transcripts in mouse tissues.
A, Scheme of the mCNG6 cDNA. The protein coding region
of CNG6 is represented by a box. The transmembrane
segments (1-6), the pore (P), and the CNBD are
indicated. The 3' and 5' untranslated sequences are shown by a
thin line. The location of probes a and
b used for Northern analysis are indicated below the
sequence. B, Northern analysis of CNG6 expression.
First lane, Left, Six micrograms of
poly(A+) RNA isolated from mouse eyes was hybridized
with probe b. Right blot, A mouse
multiple tissue blot (Clontech) was analyzed with probe
a. Each lane contained ~2 µg of
poly(A+) RNA from the following tissues: heart,
brain, spleen, lung, liver, skeletal muscle, kidney, testis.
Audioradiographic exposure was for 7 d at 70°C.
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Expression of CNG channel transcripts in mouse retina
The retinal localization of CNG6 and other CNG channel transcripts
was investigated by performing in situ hybridizations of 35S-labeled antisense RNA probes to
cryostat sections (Fig. 3). Probes
directed against the rod photoreceptor subunit CNG1 (Fig. 3A) and subunit CNG4 (Fig. 3B) strongly and
uniformly labeled the inner segment layer (IS) of photoreceptors. This
result is consistent with the expression of both subunits in rods that
in mice make up >90% of all photoreceptors. Surprisingly, both probes also labeled the outer plexiform layer (OPL) where the synapses of
photoreceptors are located. The physiological relevance of the presence
of mRNA in the OPL is not known so far. The CNG6-specific probe (probe
c) predominantly detected expression in retinal photoreceptors and also
labeled the inner nuclear cell layer (Fig.
3D,F). However, in contrast
to CNG1 and CNG4, the transcript of CNG6 was only present in a minor
subset of the photoreceptors. A very similar clustered expression
pattern was found with hybridization of the CNG3-specific probe (Fig.
3C). We performed two controls to confirm the specificity of
the in situ hybridizations. (1) Hybridization with a second
probe directed against CNG6 (probe d, see Materials and Methods)
yielded the same expression pattern as detected by probe c (data not
shown). (2) A sense probe for CNG6 did not hybridize to retinal
sections (Fig. 3E). Sense probes for CNG1, CNG3, and CNG4
also did not label retinal sections (data not shown). Taken together,
the expression level and localization of the CNG6 message corresponded
well with the expression of CNG3, whereas it was clearly different from
the expression of CNG1 and CNG4.
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Figure 3.
Expression of CNG channel subunits in mouse retina
as determined by in situ hybridization. Shown are
dark-field photographs of cryosections of mouse retina hybridized with
35S-labeled antisense riboprobes specific for CNG1
(A), CNG4 (B), CNG3
(C), and CNG6 (probe c) (D,
F) and with a sense riboprobe specific for CNG6
(E). CNG1- and CNG4-specific probes detected
strong expression in retinal photoreceptors as indicated by the
reaction product localized to the inner segments (IS) of
these cells. CNG3- and CNG6-specific probes only labeled a subset of
photoreceptors and also hybridized weakly with the inner nuclear layer
(INL). A sense probe directed against CNG6 produced no
signal (E). Exposure to film emulsion was 2 weeks
for CNG1 and CNG4 and 5 weeks for CNG3 and CNG6. OS,
Outer segment; IS, inner segment; ONL,
outer nuclear layer; IPL, inner plexiform layer;
OPL, outer plexiform layer; GCL, ganglion
cell layer. Scale bars, 30 µm.
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Functional expression of CNG6 in HEK293 cells
As anticipated from the structural relationship of CNG6 to the rod
photoreceptor subunit, CNG6 did not produce a functional CNG
channel when expressed in HEK293 cells. Because in situ
hybridizations indicated that CNG6 was colocalized with CNG3, we
co-transfected HEK293 cells with equimolar amounts of cDNAs
for both subunits. Currents measured from excised inside-out patches of
CNG3/CNG6 differed in several aspects from the current induced by CNG3
alone, indicating that CNG6 is a modulatory CNG channel subunit. The cGMP-induced single-channel current of the CNG3 channel was
characterized by the presence of both brief (<1 msec) and considerably
longer (~10 msec or longer) openings (Fig.
4A). Instead, similar
to the native channel from vertebrate photoreceptors (Haynes and Yau, 1990; Quandt et al., 1991), patches containing the CNG3/CNG6 channel (n = 6) always revealed bursts of flickery activity
consisting of opening events lasting ~1 msec or less. The heteromeric
channel (Fig. 4B) had a single-channel conductance of
~42 pS, which was comparable to that of the CNG3 channel (46 pS).
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Figure 4.
Single-channel activity of homomeric and
heteromeric channels. The recordings show single-channel currents from
an inside-out patch of HEK293 cells transfected either with an
expression vector encoding CNG3 (A) or equimolar
amounts of expression plasmids encoding CNG3 and CNG6
(B). The currents were evoked by 1 µM cGMP at a membrane potential of +80 mV.
o, Open channel; c, closed channel.
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Like the rod photoreceptor subunit, CNG6 influenced the
interaction of the CNG channel with
Ca2+. Figure
5 shows the macrosopic
current-voltage relations for the CNG3 and the CNG3/CNG6 channel at a
saturating cGMP concentration in the presence of 2 mM Ca2+ on the extracellular
side of the membrane. Under these conditions the outward rectification
resulting from divalent blockage was less pronounced in the heteromeric
channel than in the homomeric channel.
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Figure 5.
Current-voltage relations of CNG3 and CNG3/CNG6
channels in the presence of 2 mM extracellular
Ca2+. The currents were activated by 300 µM cGMP and normalized to the current at +60 mV
(I+60). The points represent
means ± SEM from four (CNG3) or six (CNG3/CNG6) patches.
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L-cis diltiazem is a known blocker of native CNG
channels of photoreceptor outer segments (Stern et al., 1986; Haynes,
1992). We therefore tested the sensitivity of homomeric and heteromeric channels for this drug (Fig. 6). The
current amplitude of the homomeric channel activated by a saturating
cGMP concentration was not significantly altered by the addition of 10 µM diltiazem on the intracellular side (Fig.
6A,C). In contrast, the current of
the heteromeric channel was blocked by
L-cis diltiazem under the same
conditions in a time- and voltage-dependent manner (Fig. 6B,D). At +80 mV, 10 µM diltiazem reduced the current amplitude by
65.0 ± 2.5% (n = 12), whereas at negative
voltages the block was significantly less pronounced (inhibition of
current amplitude by 22.8 ± 3.9% at 80 mV; n = 12). Thus, the characteristics of the
L-cis diltiazem block of the CNG3/CNG6
channel are in agreement with the blocking parameters (i.e., inhibitory
concentration range, kinetics, and voltage-dependence) described for
the native cone channel (Haynes, 1992).
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Figure 6.
Sensitivity of homomeric and heteromeric channels
to L-cis diltiazem. Current traces of the
CNG3 (A) and the CNG3/CNG6 channels
(B) induced at ±80 mV in the absence ( ) and
presence ( ) of 10 µM intracellular
L-cis-diltiazem (Dilt.).
C, D, Steady-state current-voltage relations of the
CNG3 (C) and CNG3/CNG6 currents
(D) in the presence and absence of 10 µM L-cis diltiazem. cGMP (300 µM) was used to activate the channels in
A-D.
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We next studied the influence of CNG6 on the channel activation by
cyclic nucleotides. As shown by the current traces in Figure 7A, cAMP is a partial agonist
of the CNG3 channel, activating only ~15% of the current that was
activated by a saturating cGMP concentration
(IcAMP/IcGMP = 0.14 ± 0.02; n = 11). In the heteromeric CNG3/CNG6 channel (Fig. 7B), the maximal cAMP current was
significantly elevated and made up ~60% of the maximal
cGMP-activated current (IcAMP/IcGMP = 0.58 ± 0.02; n = 13). In addition to increasing the relative efficacy of cAMP, CNG6 also altered the time-dependence of
the macroscopic current. At positive voltages, the cGMP-activated current of the CNG3/CNG6 channel revealed an initial decay with characteristic relaxation to a plateau level. The initial decay after
addition of cAMP was very small and was also not observed at negative
potentials (Fig. 6B, bottom trace). In
contrast to its prominent effect on the cAMP efficacy, coexpression of
CNG6 did not alter the apparent affinities for either cyclic
nucleotides (Fig. 7C).
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Figure 7.
Increase of cAMP efficacy induced by CNG6.
Currents were induced at +80 mV in excised inside-out patches
containing either CNG3 (A) or CNG3/CNG6
(B) by a saturating concentration of cGMP (1 mM) or cAMP (10 mM). Note that the initial
decay of the cGMP current in B does not occur in the
homomeric channel (A). C,
Dose-response curves for CNG3 (open symbols) and
CNG3/CNG6 (closed symbols) currents induced by cGMP
(circles) or cAMP (triangles). Curves
were normalized to the response at 1 mM of cGMP. Each point
represents the mean ± SEM from five to seven patches. The
solid lines are best fits calculated by the Hill
equation (see Materials and Methods). Concentrations are as follows (in
µM): CNG3, cGMP: Ka = 16.6 ± 2.2, = 2.4 ± 0.1 (n = 6); cAMP: Ka = 1690 ± 70, = 1.8 ± 0.1 (n = 5); CNG3/CNG6,
cGMP: Ka = 20.2 ± 0.6, = 2.2 ± 0.1 (n = 7); cAMP:
Ka = 735 ± 60, = 1.5 ± 0.1 (n = 6).
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According to allosteric models of CNG channel activation (Tibbs et al.,
1997; Paoletti et al., 1999), an increase in cyclic nucleotide efficacy
can result from a decrease in the energetic cost of the intrinsic
opening reaction of the unliganded channel. To examine whether such a
mechanism holds true for the increase of the cAMP efficacy evoked by
the CNG6 subunit, we measured the spontaneous channel openings in
inside-out patches containing either homomeric or heteromeric channels.
In HEK293 cells transfected with an empty expression vector, a 42-46
pS conductance comparable to that induced by expression of CNG3 or
CNG3/CNG6 was not observed. Examples of spontaneous activity from an
individual patch containing either CNG3 or CNG3/CNG6 are illustrated in
Figure 8, A and B, respectively. Currents were recorded at +80 mV in the absence of
ligand. It is evident that many more opening events occurred in the
patch containing the CNG3/CNG6 channel than in the patch containing the
CNG3 channel alone. The higher number of opening events did not simply
reflect the presence of a higher number of channels in the CNG3/CNG6
patch. The maximal current induced by a saturating cGMP concentration
was roughly the same in both patches (Fig. 8C,D),
and both channels have a comparable single-channel conductance (Fig.
4A,B). The ratio between the
spontaneous current and the maximal cGMP-activated current
(Isp/Imax),
as determined from six individual patches of cells expressing each
channel was 2.1 ± 0.3 × 10 4 for the
CNG3 channel and 2.7 ± 0.7 × 103 for the
CNG3/CNG6 channel. Thus, the heteromeric channel has an approximately
13-fold higher spontaneous activity than the homomeric channel.
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Figure 8.
Ligand-independent openings of homomeric and
heteromeric channels. In two individual patches containing
approximately 60 channels of either CNG3 (A) or
CNG3/CNG6 (B), currents were activated by
applying 200 msec pulses at 0.5 Hz from a holding potential of 0 to +80
mV. For each patch 50 consecutive pulses, 10 of which are shown, were
analyzed. The mean spontaneous current
(Isp) was defined as the average
current measured from 50 pulses. After the ligand-independent
activation, the patches were perfused with a saturating cGMP
concentration and again depolarized to +80 mV to activate the maximal
current (Imax) of the CNG3
(C) and CNG3/CNG6 (D)
channel. o, Open channel; c, closed
channel.
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| |
DISCUSSION |
In this study we report the molecular cloning and functional
expression of a new CNG channel subunit, CNG6, from murine retina. The
phylogenetic analysis indicates that within the CNG channel family CNG6
is most closely related to the CNG4 subunit. Both subunits form a
distinct branch of the phylogenetic tree that has separated from other
CNG channels early during evolution. The structural similarity between
CNG4 and CNG6 is seen mainly in the transmembrane segments, the
ion-conducting pore region, and the CNBD, whereas C and N termini are
only poorly conserved between both proteins. Interestingly, unlike CNG4
the sequence of CNG6 does not contain a large GARP domain in the N
terminus. In accordance with this finding, a GARP protein was not
identified in cones, suggesting that GARP has a function that is
specific to rods and absent in cones (Körschen et al., 1999). The
CNG4 primary transcript is extensively spliced, resulting in various isoforms that differ from each other in the N terminus (Körschen et al., 1995; Ardell et al., 1996; Sautter et al., 1998; Wiesner et
al., 1998). So far we have no evidence for alternatively spliced isoforms of CNG6 in retina. However, the presence of a smaller CNG6
transcript in mouse testis points to the possibility that splice
products of CNG6 may exists in other tissues.
In situ hybridization with CNG6-specific probes indicated
that the expression level of CNG6 in retina is comparable with that of
the cone CNG channel subunit CNG3 but is very low with respect to
the expression levels of rod photoreceptor subunits CNG1 and CNG4. In
particular, the CNG6 transcript is similar to CNG3 in that it is only
present in a small subset of photoreceptor cells. It has been
demonstrated that CNG3 is exclusively expressed in cones (Bönigk
et al., 1993; Weyand et al., 1994; Biel et al., 1999b) which represent
only ~3% of murine photoreceptors (Carter-Dawson and LaVail, 1979).
Thus, the clustered expression of CNG6 would be consistent with the
colocalization of this subunit with CNG3 in cones. Transcripts of CNG6
were also detected in the inner nuclear layer (INL) of the retina. This
layer contains cell bodies of bipolar, amacrine, Müller glial,
and horizontal cells (Wheater et al., 1987). There is evidence for the
presence of a CNG channel in On-bipolar cells (Nawy and Jahr, 1990;
Shiells and Falk, 1992). A putative cGMP-activated channel has also
been detected in retinal Müller glial cells (Kusaka et al.,
1996). So far the primary sequence and subunit composition of the
respective CNG channels have not yet been determined. The expression of
the CNG6 transcript in the INL suggests that CNG6 may form a subunit of
these channels.
The heterologous expression of CNG6 in HEK293 cells confirmed that CNG6
is a CNG channel subunit and that it associates with CNG3 to form a
heteromeric CNG channel. As predicted from the primary structure
analysis, CNG6 does not give rise to functional CNG channels when
expressed alone. However, when coexpressed with CNG3 it confers various
new channel properties that are not observed with the homomeric CNG3
channel but are characteristic of native cone photoreceptor channels.
These new properties include the induction of single-channel
flickering, the increase of the sensitivity for
L-cis diltiazem, and the weakening of the
outward rectification induced by Ca2+. In
addition, heteromeric CNG3/CNG6 channels differ from homomeric channels
by a significantly higher cAMP efficacy and a voltage-dependent transient peak of the cGMP current. To our knowledge, these two properties have not yet been described for native cone channels. However, cone channels have been studied only in two species of fish
(Haynes and Yau, 1985, 1990; Picones and Korenbrot, 1994). Thus, it has
not been determined whether the observed novel properties are
intrinsic to the heterologously expressed CNG3/CNG6 channel or whether
they reflect the species difference between fish and mouse.
The CNG6 subunit induces a significant increase of the spontaneous
channel activity in the absence of cyclic nucleotides. A high
ligand-independent activity was also detected in native cone
photoreceptors of fish (Picones and Korenbrot, 1995). In fish cones the
spontaneous current was ~4.5% of that measured under saturating cGMP
concentrations, being approximately 15-fold higher than observed for
the murine CNG3/CNG6 channel. This difference may be caused by the
intrinsic properties of the respective CNG channel subunits in fish and
mouse. Alternatively, the spontaneous activity could be regulated by
cellular factors that are present in cones but absent in HEK293 cells.
Taken together, our results demonstrate that coexpression of CNG6 with
the CNG3 channel restores various, if not all, functional properties of
the native cone photoreceptor channel that are not present in the
homomeric CNG3 channel. This finding, together with the data from
in situ hybridization, strongly suggests that CNG3 and CNG6
constitute subunits of the native cone photoreceptor channel. In cell
types other than cone photoreceptors, CNG3 may be associated with other
subunits. For example, it was shown that in bovine sperm, CNG3 is
colocalized with specific splice variants of the CNG4 subunit (Wiesner
et al., 1998). In heterologous expression systems, CNG3 and CNG4 are
able to form a heteromeric CNG channel (Biel et al., 1996). It is thus
tempting to speculate that depending on the respective tissue, cell
type, or species, different subunits are used to generate various
heteromeric CNG channels with distinct functional properties and
physiological functions.
| |
FOOTNOTES |
Received Sept. 9, 1999; revised Nov. 24, 1999; accepted Nov. 30, 1999.
This work was supported by grants from Deutsche Forschungsgemeinschaft,
Bundesministerium für Bildung und Forschung, and Fond der Chemie.
We thank K. Kohler and E. Zrenner for providing sections of mouse
retina. L-cis diltiazem was kindly provided by H. Yabana (Tanabe Seiyaku Co., Japan).
GenBank Accession Number of mCNG6: AJ243572.
Correspondence should be addressed to Martin Biel, Institut für
Pharmakologie und Toxikologie der Technischen Universität München, Biedersteiner Strasse 29, 80802 München, Germany.
E-mail: biel{at}ipt.med.tu-muenchen.de.
| |
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C. Liu and M. D. Varnum
Functional consequences of progressive cone dystrophy-associated mutations in the human cone photoreceptor cyclic nucleotide-gated channel CNGA3 subunit
Am J Physiol Cell Physiol,
July 1, 2005;
289(1):
C187 - C198.
[Abstract]
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F. Shi and T. Wang
Stage- and Cell-Specific Expression of Soluble Guanylyl Cyclase Alpha and Beta Subunits, cGMP-Dependent Protein Kinase I Alpha and Beta, and Cyclic Nucleotide-Gated Channel Subunit 1 in the Rat Testis
J Androl,
March 1, 2005;
26(2):
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[Abstract]
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M. C. Trudeau and W. N. Zagotta
Dynamics of Ca2+-Calmodulin-dependent Inhibition of Rod Cyclic Nucleotide-gated Channels Measured by Patch-clamp Fluorometry
J. Gen. Physiol.,
August 30, 2004;
124(3):
211 - 223.
[Abstract]
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A. Okada, H. Ueyama, F. Toyoda, S. Oda, W.-G. Ding, S. Tanabe, S. Yamade, H. Matsuura, I. Ohkubo, and K. Kani
Functional Role of hCNGB3 in Regulation of Human Cone CNG Channel: Effect of Rod Monochromacy-Associated Mutations in hCNGB3 on Channel Function
Invest. Ophthalmol. Vis. Sci.,
July 1, 2004;
45(7):
2324 - 2332.
[Abstract]
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D. Trankner, H. Jagle, S. Kohl, E. Apfelstedt-Sylla, L. T. Sharpe, U. B. Kaupp, E. Zrenner, R. Seifert, and B. Wissinger
Molecular Basis of an Inherited Form of Incomplete Achromatopsia
J. Neurosci.,
January 7, 2004;
24(1):
138 - 147.
[Abstract]
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F. Hofmann, M. Biel, and U. B. Kaupp
International Union of Pharmacology. XLII. Compendium of Voltage-Gated Ion Channels: Cyclic Nucleotide-Modulated Channels
Pharmacol. Rev.,
December 1, 2003;
55(4):
587 - 589.
[Abstract]
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R. L. Brown, L. L. Lynch, T. L. Haley, and R. Arsanjani
Pseudechetoxin Binds to the Pore Turret of Cyclic Nucleotide-gated Ion Channels
J. Gen. Physiol.,
November 24, 2003;
122(6):
749 - 760.
[Abstract]
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B. Much, C. Wahl-Schott, X. Zong, A. Schneider, L. Baumann, S. Moosmang, A. Ludwig, and M. Biel
Role of Subunit Heteromerization and N-Linked Glycosylation in the Formation of Functional Hyperpolarization-activated Cyclic Nucleotide-gated Channels
J. Biol. Chem.,
October 31, 2003;
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[Abstract]
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C. Peng, E. D. Rich, and M. D. Varnum
Achromatopsia-associated Mutation in the Human Cone Photoreceptor Cyclic Nucleotide-gated Channel CNGB3 Subunit Alters the Ligand Sensitivity and Pore Properties of Heteromeric Channels
J. Biol. Chem.,
September 5, 2003;
278(36):
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[Abstract]
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H. Zhang, N. Cuenca, T. Ivanova, J. Church-Kopish, J. M. Frederick, P. R. MacLeish, and W. Baehr
Identification and Light-Dependent Translocation of a Cone-Specific Antigen, Cone Arrestin, Recognized by Monoclonal Antibody 7G6
Invest. Ophthalmol. Vis. Sci.,
July 1, 2003;
44(7):
2858 - 2867.
[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;
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[Abstract]
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M. C. Trudeau and W. N. Zagotta
Calcium/Calmodulin Modulation of Olfactory and Rod Cyclic Nucleotide-gated Ion Channels
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May 23, 2003;
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H. Zhong, J. Lai, and K.-W. Yau
Selective heteromeric assembly of cyclic nucleotide-gated channels
PNAS,
April 29, 2003;
100(9):
5509 - 5513.
[Abstract]
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U. B. Kaupp and R. Seifert
Cyclic Nucleotide-Gated Ion Channels
Physiol Rev,
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[Abstract]
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P. J Kemp, K.-J. Kim, Z. Borok, and E. D Crandall
Re-evaluating the Na+ conductance of adult rat alveolar type II pneumocytes: evidence for the involvement of cGMP-activated cation channels
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November 1, 2001;
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[Abstract]
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H. M. Lee, Y. S. Park, W. Kim, and C.-S. Park
Electrophysiological Characteristics of Rat Gustatory Cyclic Nucleotide-Gated Channel Expressed in Xenopus Oocytes
J Neurophysiol,
June 1, 2001;
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[Abstract]
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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):
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[Abstract]
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R. H. Kramer and E. Molokanova
Modulation of cyclic-nucleotide-gated channels and regulation of vertebrate phototransduction
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January 9, 2001;
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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;
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10595 - 10600.
[Abstract]
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S. Kohl, B. Baumann, M. Broghammer, H. Jagle, P. Sieving, U. Kellner, R. Spegal, M. Anastasi, E. Zrenner, L. T. Sharpe, et al.
Mutations in the CNGB3 gene encoding the {beta}-subunit of the cone photoreceptor cGMP-gated channel are responsible for achromatopsia (ACHM3) linked to chromosome 8q21
Hum. Mol. Genet.,
September 1, 2000;
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[Abstract]
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TOP
ABSTRACT
INTRODUCTION
