The Styryl Dye FM1-43 Suppresses Odorant Responses in a Subset of Olfactory Neurons by Blocking Cyclic Nucleotide-gated (CNG) Channels*

Many olfactory receptor neurons use a cAMP-dependent transduction mechanism to transduce odorants into depolarizations. This signaling cascade is characterized by a sequence of two currents: a cation current through cyclic nucleotide-gated channels followed by a chloride current through calcium-activated chloride channels. To date, it is not possible to interfere with these generator channels under physiological conditions with potent and specific blockers. In this study we identified the styryl dye FM1-43 as a potent blocker of native olfactory cyclic nucleotide-gated channels. Furthermore, we characterized this substance to stain olfactory receptor neurons that are endowed with cAMP-dependent transduction. This allows optical differentiation and pharmacological interference with olfactory receptor neurons at the level of the signal transduction.

The first step of odorant recognition in vertebrates begins at the level of the olfactory epithelium (OE). 2 This consists of three principal cell types: olfactory receptor neurons (ORNs), glia-like sustentacular cells, and basal cells. ORNs are primary sensory cells that transduce the binding of ligands to olfactory receptors through a second messenger pathway into sequences of action potentials. Although biophysically not entirely understood, a well known feature of olfactory transduction is the cascade of two generator channels, i.e. a Ca 2ϩ -permeable cyclic nucleotide-gated (CNG) channel driving a [Ca 2ϩ ]-dependent chloride channel (1). The transduction of odorants can be interfered with 1) at the level of olfactory receptors (2)(3)(4), 2) at the level of receptor potential modulation or transformation (e.g. cannabinoids (5), acetylcholine (6), carbachol (7), and adrenaline (8)), or 3) at the level of spike generation. Blocking olfactory transduction at the level of one or the other generator channel has proven difficult so far because of the lack of specific chloride channel blockers and the lack of CNG channel blockers that act at physiological membrane potentials. Pseudechetoxin, the only specific blocker of the CNG channel reported so far (9), is presently not available commercially. Obviously such blockers would be extremely useful to experimentally dissect the transduction cascade.
Here we set out to find a possibility to specifically block CNG channels in ORNs. For the following reasons, we speculated that FM1-43 might be a promising candidate.
Although FM1-43 is presently better known as a means to monitor membrane trafficking (10 -12) and vesicle endocytosis in cochlear hair cells (13,14), FM1-43 has also been reported to stain several sensory and neuronal cells in an endocytosis-independent way, e.g. sensory hair cells in the lateral line organ, cochlea hair cells of various vertebrate species (15)(16)(17)(18), Merkel cells, taste buds, nociceptive fibers, as well as primary sensory neurons in the trigeminal (V), geniculate (VII), petrosal (IX), nodose (X) and dorsal root ganglia (18 -20). In addition, FM1-43 has been reported to label the lateral line organ and epidermal cells at the nasal pits in Xenopus laevis tadpoles (15). Three years later (21), FM1-43 was shown to label dissociated ORNs. However, the question whether labeling with FM1-43 had any physiological effects in ORNs remained unanswered.
Apart from staining cells, FM1-43 has also been described as a blocker of cation currents. Gale et al. (17) observed that FM1-43 reversibly blocked mechanotransduction of cochlear hair cells, and Drew and Wood (19) reported that the dye blocked rapidly and slowly adapting mechanically activated cation currents in cultured dorsal root ganglion neurons. Additionally, FM1-43 has been known to permeate through mechanoelectric transduction channels of hair cells and of dorsal root ganglion cells (18,19) as well as through TRPV1 vanilloid receptors and purinergic P2X 2 receptors (18).
We therefore investigated the action of FM1-43 in the OE and characterized the mechanisms by which it acts therein. We found that FM1-43 stains the subset of ORNs that is endowed with the cAMP-dependent transduction cascade. Furthermore, extracellular FM1-43 turned out to inhibit CNG currents in the physiological range of membrane potentials.

EXPERIMENTAL PROCEDURES
Ethical Approval-This study was performed on tadpoles of X. laevis (stage 51-54 (22)). For tissue slice preparations, the animals were anesthetized by chilling them in a mixture of ice and water and then sacrificed by decapitation. For electroporation experiments, tadpoles were anesthetized in 0.02% MS-222 (Sigma). Both procedures were performed as approved by the University of Göttingen Committee for Ethics in Animal Experimentation. The number of tadpoles used for each experimental series is indicated under "Results." In Vivo Labeling of ORNs with FM1-43-To stain ORNs with FM1-43, living tadpoles were transferred into distilled water for 5 min. Then they were placed, either for 7 min (standard staining) or for 1 min and 15 s (light staining), into 10 ml of distilled water with 2 M FM1-43 (stock solution: 2 mM in methanol, Molecular Probes, Leiden, Netherlands). In some experiments, where we were interested in the impact of certain substances on the staining efficiency, we added 2 mM CaCl 2 , 1 mM MgCl 2 , 200 M LY-83583, or 1 mM amiloride to the solution that contained FM1-43. In these cases, the exposure time in the respective incubation solution was 7 min.
OE Slice Preparation-OE tissue slices were made either from animals that had undergone an in vivo staining or from control animals that were equally treated, with the exception of FM1-43 being left out from the exposure solution. The tadpoles were chilled in a mixture of ice and water and decapitated. A block of tissue containing the OE, the olfactory nerves, and the brain was cut out and kept in bath solution. The tissue was then glued onto the stage of a vibrotome (VT 1200S, Leica, Bensheim, Germany) and cut horizontally into 130-to 150-mthick slices.
Explant of a Nose-Brain Preparation-For imaging [Ca 2ϩ ] i of glomeruli, ORNs were traced using electroporation of the OE with fluo-4 dextran. To this end, larval X. laevis were anesthetized in 0.02% MS-222 (Sigma). Crystals of fluo-4 dextran potassium salt (10 kDa, Invitrogen) were inserted into the nasal cavities, where it dissolved in the residual water. Subsequently, two platinum electrodes (diameter, 250 m) were placed 3 mm apart from each other into the nasal cavities, and the dye was electroporated by applying 12 30-V pulses (20 ms) of alternating polarity.
After being kept under standard conditions for 1 to 3 days in a water tank, the tadpoles were chilled in a mixture of ice and water and then decapitated. A block of tissue containing the OE, the olfactory nerves, and the brain was cut out and kept in bath solution. The tissue surrounding the ventral part of the olfactory bulb was removed, and the explant preparation was put under a grid in a recording chamber and viewed with a laser-scanning confocal microscope.
Imaging-The efficiency of staining with FM1-43 was assessed using a laser-scanning confocal microscope attached to an inverted microscope (LSM 510, Zeiss) with ϫ10/0.45 or ϫ40/1.3 objectives. The confocal pinhole was set to 120 -150 m to exclude fluorescence detection from more than one cell layer. Fluorescence images of FM1-43 (excitation at 488 nm, emission Ͼ 505 nm) in the OE were acquired together with a pseudo-bright field scanned transmission image for better orientation in the tissue.
For imaging [Ca 2ϩ ] i in ORN somata, tissue slices were incubated in 200 l of a bath solution that contained 50 M Ca 2ϩ indicator dye fluo-4 AM (Molecular Probes) and 50 M MK571 (Alexis Biochemicals, Grünberg, Germany). Fluo-4 AM was dissolved in dimethyl sulfoxide (Sigma) and Pluronic F-127 (Molecular Probes). The final concentrations of dimethyl sulfoxide and Pluronic F-127 did not exceed 0.5% and 0.1%, respec-tively. To avoid multidrug resistance transporter-mediated destaining of the slices, MK571, a specific inhibitor of the multidrug resistance-associated proteins, was added to the incubation solution (23). After incubation at room temperature for 30 min, the tissue slices were put under a grid in a recording chamber, which was placed on the stage of the LSM 510 or a custombuilt two-photon excitation microscope. Before starting the calcium imaging experiments, the slices were rinsed with bath solution for at least 5 min.
Fluorescence images at the LSM 510 (excitation at 488 nm, emission Ͼ 505 nm for fluo-4 imaging; and emission from 505-530 nm and Ͼ 560 nm for fluo-4 and FM1-43 imaging, respectively) and at the two-photon microscopy (excitation at 800 nm, emission from 470 -550 nm for fluo-4) were acquired at 1 to 2 Hz, with three to 20 images taken as control images before the onset of odor delivery. The fluorescence changes ⌬F/F of fluo-4 were calculated for individual ORNs (or glomeruli) as ⌬F/F ϭ (F 1 -F 2 )/F 2 , where F 1 is the fluorescence averaged over the pixels of an ORN soma (or glomerulus) and F 2 is the average fluorescence of the same pixels prior to stimulus application averaged over five images. A response was assumed if the following two criteria were met: 1) the first two intensity values after stimulus arrival at the mucosa, ⌬F/F(t 1 ) and ⌬F/F(t 2 ), had to be larger than the maximum of the prestimulus intensities; and 2) ⌬F/F(t 2 ) Ͼ ⌬F/F(t 1 ) with t 2 Ͼ t 1 . Data analysis was performed with Matlab (Mathworks). Paired t-tests were used to assess statistical significance. Rhod-2 fluorescence images (excitation at 543 nm, emission Ͼ 560 nm, pinhole set to 120 m) of FM1-43-loaded ORNs were acquired at one to two frames/s, with three to ten images taken as control images before odor delivery. The fluorescence changes, ⌬F/F, were calculated for individual ORNs.

Uncaging of cAMP in ORNs Viewed with Confocal
FM1-43/Alexa Fluor 488 Labeling of ORNs-First, ORNs were loaded with FM1-43 as described above. Then, ORNs were backfilled by putting a small crystal of biocytin Alexa Fluor 488 (Molecular Probes) into the cut nerve of a chilled tadpole. The lesion was closed with cyanoacrylic glue (Roti-Coll 1, Roth, Karlsruhe, Germany). After 3 h, tadpoles were decapitated, and acute slice preparations were prepared and put into a recording chamber. The preparation was placed on the stage of an Axiovert 200M equipped with an LSM510-Meta confocal microscope (Carl Zeiss, Jena, Germany). Excitation was at 488 nm, and emission light was observed in 19 spectral channels ranging from 497-700 nm. The fluorescence intensities of FM1-43 and Alexa Fluor 488 were obtained, respectively, by non-negative linear unmixing (24).
Patch-clamp Recordings of the CNG Current-Patch-clamp recordings (25) from ORNs were done in OE slices using an EPC7 patch-clamp amplifier (List, Darmstadt, Germany). The slices were viewed under Nomarski optics (Axioskop 2, Zeiss). Pipettes with a tip resistance of 6 -10 M⍀ were pulled from borosilicate glass (diameter, 1.8 mm, Hilgenberg, Malsfeld, Germany) using a two-stage pipette puller (PC-10, Narishige) and filled with 4 l of a cAMP-and cGMP-containing pipette solution. Pulse protocol and data acquisition programs were written in C.
The responsiveness of a patch-clamped cell was assessed in the on-cell configuration (u hold 0 V) by stimulating it with forskolin (50 M, Sigma) dissolved in bath solution. Then the whole-cell configuration was established after setting the holding potential to Ϫ70 mV and replacing the external solution by Ca 2ϩ -and Mg 2ϩ -free bath solution with or without 10 M FM1-43. The recorded currents were plotted using Matlab (Mathworks). Analysis of variance was used to assess the statistical significance of the current response amplitude upon forskolin application.
The recording chamber was perfused with bath solution by gravity feed through a funnel applicator. The funnel's outflow was through a syringe needle, the outlet of which was placed in front of the OE. Changes of the external solution were done by starting the influx of a bath solution into the funnel applicator and simultaneously stopping the influx of another one.
Amino Acids (26 -28), amines (29 -33), bile acids (34,35), and alcohols (36) are known to be odorants for aquatic species. The odorants were dissolved in bath solution (stocks of 10 mM or 25 mM) and used at a final concentration of 100 M in all of the experiments. Stimulus solutions were prepared immediately before use and were pipetted directly into the funnel for bath perfusion without stopping the flow. The time course of stimulus arrival at the OE was simulated by applying the fluorescent dye avidin Alexa Fluor 488 as a dummy stimulus and by measuring the fluorescence time course after avidin Alexa Fluor 488 application to the funnel. The delay of stimulus arrival caused by the syringe, i.e. the time from pipetting the dye into the funnel to the resulting fluorescence increase in the OE, was ϳ2 s. The minimum interstimulus interval between odorant applications was 2 min.
Fluorispectrometry-The fluorescence of FM1-43 mixed with amiloride or LY-83583 dissolved in pipette solution was assessed with a fluorescence spectrophotometer (F-2700, Hitachi). Excitation was at 488 nm, and emission was observed from 505-700 nm with a slit width of 5 nm and a scan speed of 300 nm/min.

FM1-43 Stains a Subset of ORNs-
In a first set of experiments, living X. laevis tadpoles were put into water containing the styryl dye FM1-43 (2 M). Thereafter the animals were sacrificed and tissue slices were prepared from the OE. When the slices were viewed with a confocal laser scanning microscope, a large number of cells were stained in the entirety of their cytosol (Fig. 1A, n ϭ 20 slices), whereas control slices showed no fluorescence (Fig. 1C, n ϭ 15). For a better orientation, we overlaid the fluorescence images with the corresponding transmission images scanned through wide-field optics. Fig. 1B shows the magnified rectangular area of A as a z-projection (three-dimensional projection) to illustrate the fine structure of the stained cells. Dendrites running to the surface of the OE, where cilia or microvilli issued from dendritic knobs, and axons running into the opposite direction to join the olfactory nerve defined these cells as ORNs. No staining at all was found in the vomeronasal organ (not shown).
FM1-43 never stained the entire OE. It rather appeared to stain a certain subset of ORNs. To visualize this subset, tadpoles were bathed in FM1-43 for 7 min, and ORNs were then backfilled with Alexa Fluor 488. The fluorescence intensities of the two dyes were spectrally unmixed (24), which allowed illustrating either dye individually (Fig. 1D). Only a fraction of the backtraced ORNs (green) were double-labeled with FM1-43 (red).
As the staining protocol did not allow FM1-43 loading of slice preparations and FM1-43 severely interfered with [Ca 2ϩ ] i imaging, we first labeled ORNs of living tissue and afterward tried to characterize the ORNs of this subset by testing their sensitivity to amino acids, bile acids, amines, alcohols, and a mixture of all (100 M for each substance). 156 of 165 stained ORNs did not respond to any of the stimuli, which is in stark contrast to the high responsiveness of Xenopus tadpole ORNs as seen in previous studies (37,38). Only nine ORNs were responsive to the mixture, one of them to alcohols and four to amines. Fig. 1, E-I gives a typical example showing primarily two things. First, this ORN was sensitive to alcohols ( Fig. 1, E, G, and H) but not to amino acids (F). Second, the response amplitudes to both the stimulus mixture (Fig. 1, E and I) and to alcohols (G and H) rapidly declined over time and then vanished. The facts that FM1-43 stained only a subset of ORNs and that most of the stained ORNs did not respond at all, although those few which initially did lost their responsiveness rapidly, suggested that the responsiveness of the stained ORNs was severely compromised by FM1-43.
FM1-43 Is Selectively Taken up by ORNs Endowed with the cAMP Cascade-As FM1-43 was taken up in the OE in vivo, it certainly passed through the plasma membrane of the compartments exposed to the principal cavity, i.e. through cilia, microvilli, and/or dendritic knobs. The interstitial space was never stained so that the possibility for dye molecules crossing the tight junction barrier could be excluded. Further, as the FM1-43 fluorescence was cytosolic and as it built up rapidly in the cytosol, FM1-43 permeated presumably via ion channels rather than via transport proteins. We therefore checked whether CNG channels were permeable for FM1-43, whereby we took advantage of the well known permeability properties of AUGUST 12, 2011 • VOLUME 286 • NUMBER 32 divalents in CNG channels as well as of the effect of two nonspecific blockers of CNG channels.

FM1-43 Blocks CNG Channels in Olfactory Neurons
When CaCl 2 (2 mM, n ϭ 5) or MgCl 2 (1 mM, n ϭ 5) was added to the water during the in vivo incubation with FM1-43, the fluorescence intensity of ORNs was reduced to almost zero (Fig.  2, A (CaCl 2 ), B (MgCl 2 ), and C (control). This would be consistent with an uptake of FM1-43 through CNG channels, as Mg 2ϩ and Ca 2ϩ have been reported to exert a permeation block in these channels (39).
If FM1-43 permeates through CNG channels, its permeation should be affected by LY-83583 or amiloride. When LY-83583 (200 M), which blocks CNG channels and the soluble guanylyl cyclase (40), was added during dye incubation, the uptake of FM1-43 was blocked completely (Fig. 2, D (n ϭ 10) and F (control)). The presence of amiloride (1 mM), which blocks CNG channels, Na ϩ channels, T-type Ca 2ϩ channels, and several transporters (41)(42)(43)(44), during incubation also reduced the FM1-43 uptake dramatically (Fig. 2E, n ϭ 8). It can be excluded that the reduction of FM1-43 fluorescence is primarily because of quenching because LY-83583 quenches the emission maximum of FM1-43 to about 60%, and amiloride even increases the emission maximum (Fig. 2G). These results suggest that CNG channels have a sizable permeability for FM1-43. The ORNs stained by FM1-43 may thus correspond to the subset of ORNs endowed with the canonical cAMP-transduction cascade.
The direct test of this hypothesis would be to evoke responses to cAMP in FM1-43-stained cells. Of course, this is conflicting with the hypothesis itself, as FM1-43 would suppress the responses. We tried to circumvent this problem by exposing the animals to FM1-43 for a relatively short time to have a correspondingly weak staining and at least some CNG channels left functional. In fact, under these conditions, the ORN staining with FM1-43 was rather faint, but forskolin, which is reported to activate the cAMP cascade (45) clearly induced reproducible responses (Fig. 2H, ⌬F/F ϭ 10%). Similar results were obtained in 10 of 13 cells (five slices). The three non-responding cells all came from the same slice. Uncaging of caged cAMP in FM1-43-loaded ORNs also resulted in a small, transient fluorescence increase of the calcium indicator dye rhod-2 (Fig. 2I, ⌬F/F ϭ 5%, five of five cells, three slices).
Taken together, the blockage of FM1-43 uptake by divalents and by CNG channel blockers as well as the responses of faintly stained ORNs to forskolin and cAMP is consistent with the hypothesis that FM1-43 enters ORNs through CNG channels.
CNG Generator Currents Are Inhibited by Extracellular FM1-43-Patch-clamped ORNs in untreated OE tissue slices were first classified as cAMP-dependent or cAMP-independent by stimulation with forskolin in the on-cell mode of the patch-clamp technique. Some ORNs responded to forskolin with a transient firing rate increase (Fig. 3, A and B, upper

FM1-43 Blocks CNG Channels in Olfactory Neurons
traces), whereas others, presumably because of the lack of CNG channels, showed no response to forskolin (C, upper trace). Although the parameters (latency, frequency, and duration) of the responses to forskolin commonly vary from cell to cell (46), responding and non-responding cells could always be clearly distinguished. In a second step of the experiment, the same cells were recorded in the whole-cell mode, with cAMP and cGMP added to the pipette solution. The effect of the second messengers diffusing from the pipette into the cell was observed either with (Fig. 3B, lower trace) or without FM1-43 (A, lower trace) added to the bath solution. Without any FM1-43 in the bath, an inward current set in immediately after breakthrough. To avoid, as much as possible, the activation of Ca 2ϩ -activated Cl Ϫ channels downstream of the CNG channels, Ca 2ϩ was omitted from the bath in these experiments so that the recorded current was a current through CNG channels carried by Na ϩ ions. Its average amplitude was 213.8 Ϯ 21.2 pA (S.E., n ϭ 5). FM1-43 in the bath solution (10 M) significantly (analysis of variance, p Ͻ 0.001) reduced the inward current in cAMP-dependent cells upon breakthrough to 54.5 Ϯ 31.6 pA (Fig. 3B, lower trace, n ϭ 6). In non-cAMP-dependent ORNs, cAMP and cGMP never had any effect on the current (Fig. 3C, lower black trace, n ϭ 4). A summary of the reduced CNG current amplitudes is given in Fig. 3D.
The previous experiment demonstrated that FM1-43 inhibits CNG channels, but the conditions adopted there were unphysiological in that the recordings were made in a tissue slice preparation and in that there was no or very little Ca 2ϩ flux through the CNG channels. On the one hand, the generator current blockage shown in Fig. 3B does thus not necessarily mean that FM1-43 would block odor responses under physiological conditions, i.e. with Ca 2ϩ permeating CNG channels. On the other hand, FM1-43, once having entered the cell in divalent-free medium, could have blocked odor responses in many ways intracellularly. To exclude such a possibility, we carried out two further experiments regarding the effect of extracellularly applied FM1-43. Specifically, we imaged either ORN somata deep in the OE of an acute slice preparation using  AUGUST 12, 2011 • VOLUME 286 • NUMBER 32 two photon excitation microscopy or axons of ORNs in the olfactory bulb of a whole-mount preparation with intact OEs using confocal laser scanning microscopy.  0.01, Fig. 4D).

FM1-43 Blocks CNG Channels in Olfactory Neurons
This phenomenon can also be observed at a higher stage of the system. Fig. 4E shows a preparation of an olfactory bulb, and F shows forskolin-induced fluorescence changes of fluo-4 at the response peak in the medial cluster of a larval Xenopus olfactory bulb in an explant preparation. Forskolin applications elicited [Ca 2ϩ ] i transients in a multitude of glomeruli. One of them is encircled, and its response is illustrated in Fig. 4G (black trace).

DISCUSSION
The starting point of this work were the following observations. First, the styryl dye FM1-43 stained ORNs in the OE only  when living tadpoles were exposed to the dye in distilled water. Second, only a subset of ORNs in the OE were stained, and third, ORNs that were stained mostly failed to respond to odorants. We then carried out a number of experiments that demonstrated that FM1-43 entered and permeated through CNG channels under divalent-free conditions. This result explains all of the observations made.
First, staining with FM1-43 had not been observed before because most experiments with ORNs had been done on isolated ORNs or on ORNs in tissue slices where physiological saline including divalent ions was used. In the numerous cases where odor stimuli were applied to aquatic mucosae, FM1-43 was usually not added to the stimulus. However, Nishikawa and Sasaki (15) reported that FM1-43 labeled epidermal cells at nasal pits, and 3 years later, Rankin et al. (21) showed that FM1-43 labeled dissociated ORNs. In these experiments, FM1-43 was internalized and appeared in cell body, dendrite, and knob after stimulation with L-glutamate. Rankin et al. (21) postulated a novel endocytosis-like mechanism for dye uptake for which we have not found any evidence in our experiments.
FM1-43 may have entered the OE through its tight junctions, although it had been shown that the tight junctions of the OE prevent most molecular species from crossing them (47,48). However, in our experiments, the FM1-43 staining was never extracellular. Instead it was consistently confined to the cytosol of ORNs, so that the OE tight junctions must be assumed to be impermeable for FM1-43. Therefore, dye uptake had to occur at the level of the cilia, which were exposed to the principal cavity. In agreement with this finding, FM1-43 uptake in hair cells also occurred at the stereocilia, and removal of the cilia prevented dye uptake (17,18).
Second, the finding that only a subset of ORNs in the OE was stained can also be explained by FM1-43 permeating CNG channels. It has been reported in a number of publications (26,45,49) that only a fraction of X. laevis ORNs possess the canonical, cAMP-dependent olfactory transduction cascade. FM1-43, when permeating CNG channels, must thus be supposed to stain these ORNs. Other ORNs, in particular those responsive to amino acids, cannot be stimulated this way and are therefore believed to express a different kind of generator channel. If FM1-43 would permeate those channels, too, one would expect the vast majority of ORNs in the OE to be stained. As this was not the case, we conclude that the ORN generator channels involved in the detection of amino acids are not permeable for FM1-43.
The third of our initial observations was that ORNs that were stained by FM1-43 mostly failed to respond to odorants. This observation is also well explained by FM1-43 entering CNG channels. Either an odorant acts on ORNs that do not possess the cAMP-dependent transduction cascade (then it does, per definition, not act on FM1-43-stained ORNs), or an odorant acts on ORNs that do possess the cAMP-dependent transduction cascade (then the CNG channels are likely to be blocked by FM1-43, and no odor response would be detectable).
FM1-43 entered ORNs in the absence of a stimulus. Generally, it is hard if not impossible to perfectly exclude the presence of any olfactory stimulus. Apart from this caveat, CNG channels in ORNs are reported to gate spontaneously and ligand-independently, thereby producing a detectable macroscopic conductance (50). Although Tibbs et al. (51) calculated an open probability of heterologously expressed CNG channels with the ␣ subunit to 0.002, Kleene (52) estimated the open probability of spontaneously gating CNG channels in dissociated grass frog ORNs to be 0.03, which would be sufficient for a spontaneous dye uptake.
The uptake of dyes through plasma membrane channels seems to be a more general process than previously assumed. For example, YO-PRO permeates purinergic receptors (53). Besides CNG and hair cell mechanotransducer channels, other sensory channels, like the vanilloid receptor TRPV1, the purinergic receptor P2X 2 , and mechanoelectric transduction channel of dorsal root ganglion cells (18,19), were shown to be permeable for FM1-43.
Although FM1-43 permeates CNG channels, it blocks the ionic current through these channels and thereby odorant responses. These properties are characteristic for permeation blockers (54). This is rather useful, as there are virtually no specific blockers for CNG channels. L-cis-diltiazem, amiloride and its derivates, dichloro-benzamil, LY-83583, or tetracain analogues are either unspecific, block at positive membrane potentials, or both (40,44,(55)(56)(57)(58)(59)(60). Because of these unfavorable properties, the required concentrations of the unspecific CNG channel blockers are usually rather high. In our study, LY-83583 and amiloride were used at 200 M and 1 mM, respectively. In contrast to the mentioned inhibitors, FM1-43 blocks CNG channels under physiological conditions. Cells can thus be stained in vivo at resting membrane potential and without stimulation. 10 M FM1-43 reduced the CNG current to ϳ25% at resting membrane potential. The CNG current was measured in the absence of Ca 2ϩ and Mg 2ϩ and was therefore carried by monovalent ions only (39). FM1-43 has also been found to be a blocker of cation currents in two other studies. Gale et al. (17) observed that extracellular FM1-43 reversibly blocked mechanotransduction of cochlear hair cells in culture. FM1-43 reduced the currents in a voltage-dependent way so that the block was most effective at Ϫ4 mV (K d ϭ 1.2 M) and less effective at large positive and negative potentials. Further, the block was strongly dependent on extracellular Ca 2ϩ , most effective at low Ca 2ϩ concentrations. In a study by Drew and Wood (19), extracellular FM1-43 blocked both rapidly and slowly adapting mechanically activated cation currents in cultured dorsal root ganglion neurons. The K d was reported to be 5 M and 3 M, respectively. The block was equally efficient at Ϫ70 and Ϫ35 mV. It was, however, significantly reduced at positive holding potentials. At low extracellular Ca 2ϩ concentrations, the FM1-43 block of the currents was more effective that at higher concentrations.
Taken together, FM1-43 appears to exert a permeation block of CNG channels. It is a novel mechanism to label a distinct subset of ORNs and, conversely, to identify non-labeled cells such as sustentacular cells or ORNs that do not use cAMP in their transduction cascade. Further, it allows staining and blocking in vivo and under physiological conditions. It seems therefore particularly useful for studies of olfactory transduction cascades. Finally, the fluorescence of FM1-43 may turn out AUGUST 12, 2011 • VOLUME 286 • NUMBER 32

JOURNAL OF BIOLOGICAL CHEMISTRY 28047
to be well suited for studying ciliary processes and channel densities.