Pharmacological Properties and Functional Role of a TRP-Related Ion Channel in Lobster Olfactory Receptor Neurons

doi:10.1152/jn.00990.2004

Pharmacological Properties and Functional Role of a TRP-Related Ion Channel in Lobster Olfactory Receptor Neurons

Yuriy V. Bobkov¹ and Barry W. Ache¹^,2

¹Whitney Laboratory for Marine Bioscience, ²Departments of Zoology and Neuroscience, Center for Smell and Taste, and McKnight Brain Institute, University of Florida, Gainesville, Florida

Submitted 21 September 2004; accepted in final form 26 October 2004

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Odors activate lobster olfactory receptor neurons (ORNs) throughphosphoinositide signaling that appears to target a Na⁺-gatednonselective cation channel. The Na⁺-gated channel is a potentialmember of the growing family of transient receptor potential(TRP) channels. Here, we test the effect of potential antagonistson the channel in cell-free patches from cultured lobster ORNs.We show that the channel is antagonized by H⁺ and the TRP channelblockers 2-aminoethoxydiphenyl borate, SKF96365 ruthenium red,Al³⁺, Gd³⁺, and La³⁺. We then use this enhanced antagonist profiletogether with the agonists Na⁺ and Ca²⁺ to implicate the channelin signal amplification in the cells.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Phosphoinositide signaling plays an increasingly appreciatedrole in chemosensory transduction. Vertebrate taste receptorcells for bitter, sweet, and possibly amino acids signal througha common TRP ion channel, TRPM5, and PLC ${beta}$ 2 (Clapp et al. 2004;Liu and Liman 2003; Margolskee 2002; Pérez et al. 2003;Zhang et al. 2003). The vomeronasal organ (VNO), which playsan essential role in the detection of pheromones (Dulac andTorello 2003; Trinh and Storm 2003) in vertebrates, likely relieson phosphoinositide signaling because the TRPC2 channel geneexpressed in all VNO receptor cells (Liman et al. 1999) is essentialfor VNO function (Leypold et al. 2002; Stowers et al. 2002)and most members of the TRPC subfamily appear to be regulatedvia the canonical phosphatidylinositol turnover pathway, althoughdetails of VNO activation are still being resolved (Brann etal. 2002; Cinelli et al. 2002; Liman 2003; Lucas et al. 2003;Spehr et al. 2002). Whether phosphoinositide signaling playsa role in the main olfactory organ of vertebrates is less clear,although there is emerging evidence that it does (Spehr et al.2002).

The involvement of phosphoinositide signaling in olfaction isbetter understood in lobster ORNs. In what could be an interestingparallel to invertebrate phototransduction (e.g., Ranganathanet al. 1995), activation of lobster ORNs is primarily mediatedby phosphoinositide signaling (e.g., Fadool and Ache 1992).The outer dendrites of the cells express the major elementsof the canonical turnover pathway, including a G ${alpha}$ q, PLC ${beta}$ , andan inositol 1,4,5 trisphosphate receptor (IP₃R) (McClintocket al. 1997; Munger et al. 2000). An IP₃R and PLC activity canbe functionally localized to the outer dendrites (Boekhoff etal. 1994; Hatt and Ache 1994), and PLC ${beta}$ associates with G proteinsin response to odorants (Xu and McClintock 1999). There is alsoan emerging, but still to be understood, role of phosphatidylinositide3-kinase (PI3K)-mediated signaling in these ORNs (Zhainazarovet al. 2001). A potential target of phosphoinositide signalingin lobster ORNs is a sodium-gated nonselective cation (SGC)channel (McClintock and Ache 1990; Zhainazarov and Ache 1995,1997) that contributes to the generation of a substantial partof the depolarizing receptor potential (Zhainazarov et al. 1998).The channel, a presumptive member of the growing family of TRPchannels, can be modulated by exogeneous phosphoinosotides incell-free patches (Zhainazarov and Ache 1999; Zhainazarov etal. 2001). Establishing this channel as a target of phosphoinositidesignaling in situ would provide an interesting link betweenphosphoinositide signaling in olfaction and that in other chemosensorysystem where TRP channels are targeted.

Here, we test the effect of potential antagonists of the lobsterSGC channel in cell-free patches from cultured lobster ORNs.We show that the channel is antagonized by H⁺ and the TRP channelblockers 2-aminoethoxydiphenyl borate (2-APB), SKF96365 rutheniumred (RR), Al³⁺, Gd³⁺, and La³⁺. We then use this enhanced antagonistprofile together with the agonists Na⁺ and Ca²⁺ to implicatethe channel in signal amplification in the cells in situ.

METHODS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Cell preparations

The lobster SGC channel was studied in three different preparations.First, freshly isolated vesicles of the outer dendritic membraneof lobster ORNs were obtained by incubating the olfactory organ(antennule) for 10–20 min in a solution containing (inmM) 210 NaCl, 696 glucose, 10 HEPES, 0.1 CaCl₂, and 1 EGTA bufferedto a free calcium concentration of $~$ 10 nM, and cutting the tipsof the olfactory sensilla (aesthetascs) into the same solution,as described earlier (Hatt and Ache 1994). Membrane patcheswere excised from these vesicles. Second, primary cultures oflobster ORNs were prepared as described previously (Fadool etal. 1991). Membrane patches were excised from the soma of cellscultured from 1 to 7 days. Finally, the cells were studied insitu using a modification of the preparation developed earlier(Doolin et al. 2001). Separate perfusion contours washed theORN somata with Panulirus saline (PS, see Solutions) and theouter dendrites in the olfactory sensilla with either PS orPS containing an odorant or drug. Solution switching times of5–50 ms were controlled using a nine-channel rapid solutionchanger (RSC-100/160, Bio-Logic).

Electrophysiology and data analysis

Currents were measured with an Axopatch 200A or 200B patch-clampamplifier (Axon Instruments) through a digital interface (Digidata1320A, Axon Instruments), low-pass filtered at 5 kHz, sampledat 20 kHz and digitally filtered at 1–1.4 kHz. Data werecollected and analyzed with pCLAMP 8.1/9.0 software (Axon Instruments)in combination with Microcal Origin 6.0 (Microcal Software)and SigmaPlot 5.0/8.02 (SPSS). Channel activity was investigatedin steady-state conditions at a holding potential of –70mV unless otherwise noted. The polarity of the currents is presentedconventionally, i.e., relative to intracellular membrane surface,in spite of the membrane patch configuration. Open probabilitiesin the case of multichannel patch recordings were estimatedassuming P_o = I/Ni, where I is integral current, N is the numberof channels, and i is the single channel current amplitude.Appropriate corrections for liquid junction potentials weremade when necessary. Patch pipettes were fabricated from borosilicatecapillary glass (Sutter Instrument, BF150-86-10) using a Flaming-Brownmicropipette puller (P-87, Sutter Instrument). Extracellularin situ recordings were conducted using standard glass electrodefilled with PS. Odor-evoked activity was examined after 30-to 60-s incubation with the solution(s) of interest. In multi-cellextracellular recordings, the discharge rates of individualcells were estimated using template search procedure providedby pCLAMP 9.0 software. The data are presented as means ±SE of n observations. All recordings were performed at roomtemperature ( $~$ 21°C). Two modifications of the Hill equationwere used to fit the experimental data: F(x) = F_max*x^h/(x_1/2^h+ x^h) for activation and F(x) = 1 – F_max*x^h/(x_1/2^h + x^h)for inhibition, where F is the open probability, normalizedcurrent or frequency of action potentials, x is the agonist/antagonistconcentration, x_1/2 is the half-effective agonist/antagonistconcentration, and h is the Hill coefficient. An additionalparameter reflecting the basal level of F (Fb) was incorporatedwhen necessary.

Solutions

PS contained (in mM) 458 NaCl, 13.4 KCl, 13.4 Na₂SO₄, 13.6 CaCl₂,9.8 MgCl₂, 2 glucose, and 10 HEPES, pH 8. In some cases, theNa₂SO₄ in PS was replaced with equimolar NaCl. Low-calcium sodiumsolution contained (in mM) 210 NaCl, 1 EGTA, 0.1 CaCl₂, 696glucose, and 10 HEPES, pH 7.8. Low-calcium lithium solutionconsisted of (in mM) 210 LiCl, 1 EGTA, 0.1 CaCl₂, 696 glucose,and 10 HEPES, pH 7.8. The estimated free calcium concentration([Ca²⁺]_free) in low-calcium sodium/lithium solutions was $~$ 10nM. Solutions containing >1 µM Ca²⁺/Mg²⁺ were preparedwithout chelating agents. PS without Ca²⁺ contained: 486 NaCl,13.4 KCl, 23.4 MgCl₂, 10 HEPES, 0.5 EGTA, pH 8. PS without Na⁺contained 486 LiCl instead of NaCl. Solutions with pH <7(adjusted with Tris-HCl) contained 5 mM MES and 5 mM HEPES.An aqueous extract of TetraMarin (TET, Tetra Werke, Melle, Germany),a commercially available fish food, was used as an odorant andprepared as described earlier (Schmiedel-Jacob et al. 1990).All inorganic salts were purchased from Fisher Scientific, exceptfor AlCl₃ and LaCl₃, GdCl₃, which were purchased from SigmaScientific. All organic compounds were obtained from Sigma exceptfor 2-APB, which was obtained from Calbiochem.

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

General properties of the lobster SGC channel

The SGC channel was studied in patches obtained from both outerdendritic vesicles and cultured lobster ORNs without obviousdifferences. Although the SGC channel occurs in both Ca²⁺-sensitiveand -insensitive forms (Bobkov and Ache 2003), we focused onthe Ca²⁺-sensitive form in both preparations because it predominatesin the outer dendritic vesicles. We first demonstrate that generalproperties of the channel studied here are consistent with thosepreviously reported and extend our characterization of thoseproperties. Na⁺ (1–300 mM) applied to the cytosolic sideof the patch reversibly activates the channel in a concentration-dependentmanner (Fig. 1A and B). At low (10 nM) Ca²⁺ (Fig. 1B, ${circ}$ ), theNa⁺ concentration required for a half-maximal effect, [Na⁺]_1/2,is 112.6 ± 6.1 mM, with a cooperativity coefficient,h, of 4.9 ± 1.2, and a maximal open probability, P_max,of 0.44 ± 0.04 (n = 6–10). Higher concentrationsof Ca²⁺ (100 µM; Fig. 1B, ${bullet}$ ) dramatically increase themaximal open probability of the channel activated by Na⁺, alteringthe degree of cooperativity and decreasing the Na⁺ activationthreshold, with P_max = 0.92 ± 0.08, h = 0.94 ±0.19, and [Na⁺]_1/2 = 28.7 ± 7.6 mM (n = 5–12).

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FIG. 1. Basic properties of the Ca²⁺-sensitive form of the lobster sodium-gated channel (SGC). A: original recordings of SGC channel activity in the presence of different [Na⁺] (as noted below the current traces) and either 10 nM (top) or 100 µM (bottom) Ca²⁺. B: plot of the dependence of SGC channel open probability on [Na⁺]_i (in range 1–300 mM) in the presence of 10 nM ( ${circ}$ ) and 100 µM ( ${bullet}$ ) Ca²⁺. —, Hill-equation fit with the following parameters: [Na⁺]_1/2 = 112.6 ± 6.12 mM, h = 4.9 ± 1.2 (n = 6–10) for 10 nM Ca²⁺ and [Na⁺]_1/2 = 28.7 ± 7.6 mM, h = 0.94 ± 0.19 (n = 5–12) for 100 µM Ca²⁺. Open probability was estimated assuming P_o = I/Ni. Data were obtained in inside-out patch recordings; HP, –70 mV; electrode solution, NaCl 210 mM + Ca²⁺ 10 nM. Voltage (C) and calcium (D) dependences of the channel. Current-voltage (I-V) characteristics obtained from an inside-out patch by applying a voltage ramp in the presence of different [Ca²⁺]_i (10 nM, 520 nM, 3.3 µM, 10 µM, 50 µM, 100 µM and 1 mM—noted by gray level). Only the negative segment of I-V relations are shown. A 30-ms hyperpolarizing step to –100 mV preceded linear voltage changing (ramp, diagram in C). Ramp duration, 200 ms. Each line is an average of 40 ramps generated in the corresponding [Ca²⁺]. Corresponding corrections were introduced by successive subtraction of leakage ramp current obtained in conditions without sodium. D: calcium dependence of normalized (I/I_max) current at different voltages. Parameters of the calcium dependent augmentation of the normalized (I/I_max) current at –70 mV ([Ca²⁺]_1/2 = 665 ± 146 nM, h = 1.39 ± 0.4, n = 4) and reduction at –10 mV ([Ca²⁺]_1/2 = 25.8 ± 9 µM, h = 1 ± 0.2, n = 4) were estimated using corresponding Hill equation modifications (see METHODS). Current values were obtained from I-V relations at corresponding voltages (C, · · · ) and represented by gray level.

The current-voltage (I-V) relationship of the channel showschannel block by permeant polyvalent cations, including Ca²⁺,in which the current is characteristically reduced at more depolarizingvoltages (Fig. 1C). The current through the channel increasesas a function of increasing [Ca²⁺] from 10 µM to 1 mM(represented by gradual reduction of gray color intensity) at–70 mV, while it decreases over the same range at –10mV (n = 4, Fig. 1, C and D).

Mg²⁺ applied to the intracellular side of the patch in the absenceof Ca²⁺ (0 Ca²⁺, 50 µM EGTA) reversibly blocked the channelboth by decreasing the open probability ([Mg²⁺]_1/2 = 811 ±90 µM, h = 1.33 ± 0.3, n = 8) and reducing thesingle channel amplitude (16.2 ± 0.4 pA in control conditionsvs. 15.07 ± 0.2 pA in the presence 1 mM Mg²⁺, n = 7,–70 mV, data not shown). The ratio of [Mg²⁺] to [Ca²⁺]and/or presumably [Na⁺] determines the magnitude of the magnesiuminhibition constant with the [Mg²⁺]_1/2 increasing with an increasein Na⁺ or Ca²⁺. In 10 µM Ca²⁺, for instance, [Mg²⁺]_1/2= 3.3 ± 0.12 mM, h = 1.1 ± 0.4. The complex interactionbetween these ions probably explains the paradox that, otherwise,the channel would be blocked in normal physiological conditionsgiven that sea water and PS contain 53 and 9.8 mM Mg²⁺, respectively(see METHODS). With PS on the extracellular face, the unitaryconductance of the channel is 23.4 ± 0.6 pS (n = 5) versus204 ± 7 pS (n = 7) in low-Ca²⁺ conditions. The activityof the SGC channels in physiologically relevant conditions hasbeen published earlier (Bobkov and Ache 2003).

Effect of pH on the channel

Acidification reversibly inhibits the channel (Fig. 2). Loweringthe pH of the solution bathing the extracellular face of outside-outpatches in which the channel was continuously activated by Na⁺(210 mM) in the pipette blocked the channel (Fig. 2A). Reducingthe extracellular pH from 8.0 to 7.0 almost completely blockedchannel activity (n = 11; Fig. 2B). The proton-mediated inhibitionhad an apparent inhibition constant, [H⁺]_1/2, of 2.67e-8 ±1.66e-9 M (corresponding to pH 7.57), with a cooperativity coefficient,h, of 4.0 ± 0.8, in good agreement with what we foundpreviously with inside-out patches (pH_1/2 = 7.3, h = 5) (Bobkovand Ache 2003). The proton effect presumably was not exclusivelyassociated with changing the affinity of the Ca²⁺ binding siteof the channel because acidification resulted in full blockadenot just blockage of the Ca²⁺-potentiated component. It is possiblethat protons additionally or alternately competed for the Na⁺binding site of the channel, although we did not attempt toidentify the mechanism of proton-mediated inhibition.

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FIG. 2. pH dependence of the SGC channel. A: increasing [H⁺]_out blocked the SGC channel. B: open probability of the SGC channel as function of the extracellular pH. Line, approximation by Hill equation ([H⁺]_1/2 = 2.67e-8 (pH,7.57) ±1.66e-9, h = 4.04 ± 0.8, (n = 5–11)]. The open probability was estimated assuming P = I/Ni. The analysis was corrected for changes in single channel amplitude and current baseline shift at increasing [Ca²⁺]. Experimental conditions: outside-out patch recording; HP, –70 mV; electrode solution, NaCl 210 mM + Ca²⁺ 10 nM. Application of solutions of different pH is shown by the line over the current trace. LiCl, 210 mM LiCl + 10 nM Ca²⁺; NaCl, 210 mM NaCl + 10 nM Ca²⁺.

Effect of other blockers on the channel

We then tested the potential effect of antagonists widely usedto block TRP channels by applying them to the inside face ofpatches containing the lobster channel. RR (10–20 µM),which also blocks the ryanodine receptor (RyR), inhibited theactivity of the channel (n = 7; Fig. 3A). The effect of RR wasreversible (data not shown). RR (10 µM) primarily ledto long-term closures, reducing the open probability (P_o) to0.12 ± 0.04 from 0.42 ± 0.1 in 10 nM Ca²⁺ andfrom 0.91 ± 0.08 in 10 µM Ca²⁺ (n = 3), but italso induced fast open channel block, as could be seen in theshort, burst-like episodes that occasionally interrupted thesustained closures (Fig. 3A, bottom). The latter effect wasvoltage dependent (data not shown).

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FIG. 3. Blockade of the SGC channel by cytosolic ruthenium red (A, 10 µM), SKF96365(B, 50 µM) and 2-aminoethoxydiphenyl borate (2-APB, C, 50 µM). Experimental conditions: inside-out patch recordings; HP, –70 mV; electrode solution, NaCl210 mM + Ca²⁺10 nM. Bar diagrams above current traces in B and C show time course of solution application. Time scales are different in all portions of the figure. LiCl in B and C—LiCl210 mM + Ca²⁺10 nM.

SKF96365 (25–200 µM), a well known blocker of theCa²⁺ release-activated Ca²⁺ current (CRAC), completely inhibitedthe channel when applied to the inside face of the patch (n= 14; Fig. 3B). The effect was reversible. As can be seen fromthe constant current amplitude, the drug decreased the openprobability of the channel without affecting the single channelconductance. The effect of SKF96365developed relatively slowlyand was dependent on [Ca²⁺]_i such that increased [Ca²⁺]_i reducedthe drug efficacy (Fig. 3B). 100 µM Ca²⁺ completely abolishedthe SKF96365induced blockade (n = 7, data not shown).

2-APB (25–200 µM), a structurally unrelated TRPchannel blocker, also known to block IP₃Rs, completely inhibitedthe channel when applied to the inside face of the patch (n= 17; Fig. 3C). The effect was reversible. As with SKF963652-APB decreased the open probability of the channel withoutaffecting the single channel conductance, although the effectof 2-APB was more rapid (Fig. 3C).

The trivalent cations lanthanum (La³⁺), gadolinium (Gd³⁺) andaluminum (Al³⁺) also blocked the channel when applied to theintracellular face of cell-free patches containing the channel.We were careful to minimize possible confounding effects dueto chelation by EGTA, sulfate, or Tris (Caldwell et al. 1998)by not including these compounds in the solutions. The channelwas blocked completely by Gd³⁺ (100–200 µM, n =12), La³⁺ (100–200 µM, n = 23), and Al³⁺ (200 µM,n = 3, Fig. 4A). The lanthanides and aluminum appeared to blockprimarily by decreasing the open channel probability, althoughthere was some evidence in the records suggesting that theyalso altered the single channel conductance. The blocking effectof all three trivalent cations was not reversible itself butcould be fully reversed by application of a solution containingEGTA. The blocking effect of the trivalent cations was concentration-dependentin that decreasing [Gd³⁺] or [La³⁺] from 200 to 10 µMslowed the onset of the block, but the extent of the block (full)remained unchanged (n = 30; Fig. 4B). The actual time requiredfor 50% blockade in channel activity varied from patch to patchand experiment to experiment due, for example, to possible differencesin the size and geometry of the patch, so we elected not toquantify the concentration-dependent change in the rate of blockade.Lower concentrations (5 µM) of Gd³⁺ and La³⁺ were withouteffect 3–5 min postapplication (Fig. 4B, light traces).The blocking effect of the trivalent cations was voltage independent.Although positive holding potentials would be expected to acceleratethe rate of blockade by positively charged ions, the rate ofblockade, if anything, was actually slowed at more positiveholding potentials (Fig. 4B). There was no noticeable effectof Ca²⁺ on the effect of the trivalent cations in the rangeof 10–100 µM, even though one might expect La³⁺and Gd³⁺ would compete with Ca²⁺ ions to screen negative membranesurface charges and for Ca²⁺-binding sites.

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FIG. 4. Effect of trivalent cations on the SGC channel. A: La³⁺ (100 µM), Gd³⁺ (100 µM), Al³⁺ (200 µM) fully block the channel. Zero time corresponds to the moment of blocker application. Traces have different current scales. HP was –70 mV. B: different concentrations of Gd³⁺ (indicated above current traces) fully and irreversibly blocked the channels. Note: superfusion with Gd³⁺ 5 µM (light traces) for 3–5 min was without noticeable effect. To contrast kinetic parameters, the current traces were truncated and aligned relative to the moment of blocker application (0 time does not correspond to the start of the recordings). Note: blockade with Gd³⁺ and other trivalent cations is lost after incubation with chelating agents. La³⁺ and Al³⁺ had similar effects. Experimental conditions: inside-out recording; HPs, indicated on the plot; electrode solution, NaCl210 mM + Ca²⁺10 nM; superfusion solution, NaCl210 mM + Ca²⁺ 10 µM.

All of the preceding blockers were equally effective at blockingthe channel when applied to the outside face of the membranein outside-out patches in which the channel was activated byhaving Na⁺ and Ca²⁺ in the patch pipette. RR (20 µM, n= 2), SKF96365(100 µM, n = 3), 2-APB (100 µM, n= 5), Gd³⁺ (100 µM, n = 4), La³⁺ (100 µM, n = 7),and Al³⁺ (100 µM, n = 1) completely inhibited the channelfrom the outside face (data not shown).

Effect of blocking the channel in situ

We used the preceding pharmacological profile to more rigorouslyimplicate the lobster SGC channel in the olfactory transductioncascade in situ. The rate and pattern of spontaneous and evokeddischarge of lobster ORNs in situ suggest the presence of severalfunctional subpopulations of cells that we are in the processof characterizing in more detail elsewhere. Here, we focus onlyon cells that are tonically active and comprise the predominantsubpopulation. These cells discharge spontaneously at 2.23 ±0.36 Hz (minimum = 0.125, maximum = 4.9, n = 48); odors phasicallyincrease the rate of discharge in a concentration-dependentmanner (Fig. 5A, top traces and plot).

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FIG. 5. Effects of removing Ca²⁺ on the excitability of lobster olfactory receptor neurons (ORNs) in situ. A: representative responses of a single lobster ORN to odorant pulses of increasing intensity in the presence (top and bottom traces and plots) and absence (middle traces and plot) of extracellular Ca²⁺ [Ca²⁺-free Panulirus saline (PS)]. Left: raster displays of actual discharge. Stimulus concentration increases from bottom to top, changed by increasing the duration of the odor pulse in 40-ms increments from t₁ = 40 ms (lines below traces). Time between successive sweeps, 60 s. Shaded area, 2-s peristimulus interval starting 0.34 s prior to stimulus onset during which mean discharge frequency was determined to generate the dose-response relationships shown in C and D. Right: plots of the instantaneous frequency (f = 1/t, where t = time between adjacent events) for each raster shown on the left. In Ca²⁺-free PS, Ca²⁺ was replaced with equimolar Mg²⁺. Total [Mg²⁺], 23.4 mM. EGTA (1 mM) added to avoid possible Ca²⁺ contamination. B: net Ca²⁺-dependent component of the odor-evoked discharge (bottom) obtained by subtracting the average of 8 responses to the same intensity stimulus (200 ms) in the presence and absence of Ca²⁺ (top). Bin width, 100 ms. C: activity of the same ORN as in A plotted as a function of stimulus intensity (duration, ms). F_max = 14.7, S_1/2 = 64, h = 3.1 (control conditions, solid line). D: the same type of data as in C collected from 3 different cells. The dose-response relation of each cell was normalized to F_max and S_1/2 in control conditions. Control conditions (light circles, Fc): F_max = 0.89, S_1/2 = 1, and h = 3.32. Ca²⁺ free conditions (dark circles, Fs): F_max = 0.56, S_1/2 = 3.07, and h = 2.53. Gray curve, gain coefficient (k) calculated as k = (Fc – Fs)/Fs.

As would be predicted from the single channel results, removingthe extracellular Ca²⁺ bathing the outer dendrites reversiblyreduced odor-evoked activity in the cells (Fig. 5A, middle andbottom traces and plots). The response intensity, calculatedas the mean frequency of discharge during a 2-s peristimulusinterval (shaded region, Fig. 5A) to saturating concentrationsof odorants was reduced by 46.9 ± 8% (n = 10). Therewas no noticeable difference in the rate of spontaneous discharge.To identify the Ca²⁺-dependent component of the response, wesubtracted the response following removal of extracellular Ca²⁺from that before (Fig. 5B). The effect of removing extracellularCa²⁺ persisted across the range of odor responsiveness of thecell (Fig. 5C). For three cells, in which the response intensitywas normalized by first fitting the Hill equation to their respectiveconcentration-response functions in control conditions {F =F_b + (F_max – F_b)/[1 +(S_1/2/S)^h], where F_b = spontaneousdischarge frequency, F_max = the maximal frequency of response,S_1/2 = duration (concentration) of stimulus required to elicithalf-maximal discharge, and h = Hill coefficient} and expressedas a ratio of F_max and S_1/2, the cells responded with F_max =0.89, S_1/2 = 1, and h = 3.32 in control conditions (Fc; Fig.5D, light circles), compared with F_max = 0.56, S_1/2 = 3.07,and h = 2.53 in Ca²⁺ free conditions (Fs; Fig. 5D, dark circles).To better visualize how Ca²⁺ substitution altered the gain ofthe output, we estimated the additional amplification (k) thatis attributable to the Ca²⁺-dependent component of the responseover the entire range of stimulus intensity using the equationk= (Fc – Fs)/Fs (Fig. 5D, light trace).

Removal of extracellular Na⁺ was shown earlier to reduce theodor-evoked output of these cells (Zhainazarov et al. 1998).To compare the relative effect of removing extracellular Ca²⁺with that of removing Na⁺, we used the approach described aboveto quantify the effect of removing extracellular Na⁺. Substituting486 mM of the Na⁺ bathing the outer dendrites with Li⁺ reducedthe response to saturating concentrations of odors by 52.4 ±2% (n = 11). The cells (n = 4) responded with F_max = 0.84, S_1/2= 1, and h = 3.25 in control conditions (Fc; Fig. 6A, lightcircles), but with F_max = 0.45, S_1/2 = 2.78, and h = 2.09 inlow Na⁺ conditions (Fs; Fig. 6A, dark circles). Overall, theeffect of removing extracellular Na⁺ was similar to the effectof removing extracellular Ca²⁺ (Figs. 6A vs. 5D).

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FIG. 6. Effects of low sodium PS (Li-PS, A), acidification (low pH-PS, B) and La³⁺ (La³⁺ 300 µM, C) on the excitability of lobster ORNs in situ. Left: net component of the odor-evoked discharge after the respective treatments, obtained by subtracting the averaged response to the same intensity stimulus before and after treatment. Bin width, 100 ms. Right: plots of the activity as a function of stimulus concentration (duration) before and after the respective treatments. Data were collected, processed, and normalized using the same experimental paradigm as described above for Ca²⁺-free PS effects (Fig. 5). Hill equation approximation parameters (left-hand axis): A, the cells (n = 4) responded with F_max = 0.84, S_1/2 = 1, and h = 3.25 in control conditions (Fc, light circles), while with F_max = 0.45, S_1/2 = 2.78, and h = 2.09 in low-Na⁺ conditions (Fs, dark circles); B, the cells (n = 4) responded with F_max = 0.85, S_1/2 = 1, and h = 3.43 in control conditions (Fc, light circles), while with F_max = 0.53, S_1/2 = 2.08, and h = 2.8 in low-pH conditions (Fs, dark circles); C, the cells (n = 3) responded with F_max = 0.87, S_1/2 = 1, and h = 4.6 in control conditions (Fc, light circles), while with F_max = 0.5, S_1/2 = 2.1, and h = 3.2 in the presence of La³⁺ (Fs, dark circles). Gray curve in each plot is the gain coefficient estimated as k = (Fc – Fs)/Fs, where Fc is the activity of ORNs in control conditions expressed as relative discharge frequency and Fs is the activity of ORNs after treatment.

We then used the same approach to determine the effect of someof the antagonists of the channel on the odor-evoked outputof the cells. Acidification of the solution bathing the outerdendrites from pH 8.0 to 7.4 slightly increased the spontaneousrate of discharge in 6 of 22 cells from 2.2 ± 0.2 to3.4 ± 0.3 Hz, suggesting that acidification may alterion stasis in some cells. We therefore excluded these cellsfrom further analysis to avoid possible confounding effects.In the remaining 16 cells, lowering the pH to 7.4 reduced theodor-evoked response of the cells to saturating stimuli by 44.4± 5.2%. Lowering the pH to 7.4 (n = 4) reduced the responseto odors from F_max = 0.85, S_1/2 = 1, and h =3.43 in controlconditions (Fc; Fig. 6B, light circles), to F_max = 0.53, S_1/2= 2.08, and h = 2.8 in low pH conditions (Fs; Fig. 6B, darkcircles). The effect of acidification was reversible (data notshown).

La³⁺ (300 µM), tested as a representative trivalent cation,reduced the odor-evoked response to saturating concentrationsof odorant by 43.8 ± 3.6% (n = 9). The cells (n = 3)responded with F_max = 0.77, S_1/2 = 1, and h = 5.5 in controlconditions (Fc; Fig. 6C, light circles), while with F_max = 0.43,S_1/2 = 2.35, and h = 4.1 in the presence of La³⁺ (Fs; Fig. 6C,dark circles). In contrast to the effect of La³⁺ on the channel,however, lower concentrations of La³⁺ (10, 50, 100 µM)did not have any detectable effect on the odor-evoked activityof the cells in situ and effective concentrations (e.g., 300µM) of La³⁺ were reversible (n = 17). This finding suggeststhe outer dendritic compartment may possess some mechanism forchelating or otherwise eliminating trivalent cations, althoughthis possibility was not pursued further. High concentrationsof La³⁺ (0.5 mM) irreversibly altered the spontaneous discharge,causing irregular, sporadic but long-lasting bursts (n = 4;data not shown).

The Ca²⁺ dependence of SKF96365made it impractical to test thedrug in physiologically relevant conditions, so this antagonistwas not tested on the cells in situ. RR and 2-APB are also knownto target IP₃Rs, which have been implicated in the activationof lobster ORNs (Munger et al. 2000). These probes, too, werenot tested on the cells in situ to avoid possible confoundingeffects. We found that RR (Fadool and Ache 1992) and 2-APB (datanot shown) blocked odor-evoked responses in these cells, andthis blockage could potentially be ascribed to the IP₃R.

DISCUSSION

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The general properties of the lobster SGC channel studied here,specifically the characteristics of the Na⁺, Ca²⁺, and voltagedependencies of its activation, were identical to those reportedearlier for the channel (e.g., Bobkov and Ache 2003). We assume,therefore that the present results serve to extend our previousunderstanding of this channel.

As a nonselective cation channel, the lobster SGC channel potentiallyis a member of the growing family of TRP channels (review: Minkeand Cook 2002). Although there is no specific pharmacologicalprofile that serves to identify TRP channels, the lobster SGCchannel was blocked by drugs known to block and commonly usedto characterize TRP channels in other systems. Specifically,the lobster SGC channel was blocked by RR, known to block channelsof the TRPV and TRPM subfamilies (reviewed by Gunthorpe et al.2002; Patapoutian et al. 2003); SKF96365 known to block membersof TRPC subfamily (Halaszovich et al. 2000; Inoue et al. 2001;Zhu et al. 1998); and 2-APB, known to block store operated/TRPchannels (Bootman et al. 2002; Clapham et al. 2001; Lucas etal. 2003; Ma et al. 2001). The effect of common organic blockersof known TRP channels on the lobster SGC channel is consistentwith the latter being a member of the TRP family.

The lack of specific organic blockers for TRP channels has precipitatedthe use of differential sensitivity to the lanthanides, La³⁺and Gd³⁺, to discriminate TRP channels (rev. Minke and Cook2002; Zitt et al. 2002), even though lanthanides are known tononspecifically block other (e.g., mechanosensitive) (Hamilland McBride 1996; Yang and Sachs 1989) channels and have otherconfounding effects (Caldwell et al. 1998). The ability of La³⁺and Gd³⁺ to block the lobster SGC channel therefore furthersupports the interpretation that the lobster channel is a memberof the TRP family. Two characteristics of the blockade of thelobster channel by lanthanides, however, to our knowledge havenot been reported previously. The slow, irreversible onset,building over as much as 30 s in a concentration-dependent manner,although unusual, may reflect the gradual adsorption of lanthanidesto high-affinity binding sites on the channel itself or othermembrane constituents, including possibly membrane lipids. Lanthanidebinding to phospholipids alters various physical propertiesof lipid bilayers, which presumably would alter channel behavior(Awayda et al. 2004; Ermakov et al. 2001). Alternately, lanthanidebinding could sequester lipids essential for channel functionbecause phosphoinositides activate the SGC channel (Zhainazarovand Ache 1999). A similar interpretation has been proposed toexplain the interaction between polyvalent cations, includinglanthanides, and membrane or membrane-associated proteins inother systems (Hilgemann and Ball 1996; McDonald and Mamrack1995; Verstraeten and Oteiza 2002). Indeed, the effects of lanthanideson ion channels could be predictive of sensitivity to anionicpolyphosphoinositides. Second, the effect "stepped" from nothingto full blockade over <5 µM Gd³⁺, suggesting a steepdependency of steady-state channel activity (P_o) on trivalentcation concentration, with a potential Hill coefficient in excessof 8. Although such a high level of cooperativity might seemto be unusual, and to our knowledge has not been determinedpreviously for TRP channels, Gd³⁺-induced inhibition of a stretch-activatednonselective cation channel in Xenopus oocytes shows a similarlysteep dose-dependency (Yang and Sachs 1989).

The antagonistic effect of lowering the extracellular pH from8.0 to 7.4 on the lobster SGC channel is particularly interesting.The effect was relatively dramatic, and to our knowledge, apH change in this range is not known to effectively block othertypes of ion channels in lobster ORNs. Thus proton blockadein this range could potentially serve as a selective probe forthe SGC channel. If indeed the lobster SGC channel proves tobe a member of the TRP family, proton blockage in this rangecould potentially serve as a selective probe for one or moreclasses of TRP channels. Although the present findings do notallow us to tentatively assign the lobster SGC channel to aparticular class of TRP channels, the blockade by lanthanidestogether with its Ca²⁺-dependent activation and its involvementin chemosensory transduction would be consistent with the lobsterchannel being a member of the TRPC/M family of TRP channels(Liu and Liman 2003; Lucas et al. 2003; Perez et al. 2002; Prawittet al. 2003; Reuss et al. 1997). It will be interesting to seeif TRPC/M channels are subject to proton blockade in this range.

Because all the antagonists also acted from the extracellularface of the membrane, we were able to use them in conjunctionwith the agonists Na⁺ and Ca²⁺ to more rigorously implicatethe channel in the transduction cascade of the cells in situwith the exception of those noted earlier to have potentialconfounding effects by their ability to also target InsP₃Rs.All the antagonists tested, as well as removing extracellularNa⁺ and Ca²⁺, had essentially the same effect on both the magnitudeand time course of the odor-evoked response; they decreasedthe maximum response and increased the stimulus intensity neededfor half-maximal response. In particular, they had the sameeffect on the Ca²⁺-dependent component of the odor-evoked responseas determined by our subtractive protocol. The similarity oftheir collective effect on the odor-evoked response argues stronglythat the pharmacological probes are targeting the same effector,the SGC channel. Their similar collective action cannot be deemedto be definitive proof because we cannot eliminate the possibilitythat some or all of the probes had nonspecific effects on otherchannels and/or elements of the signaling cascade that resultedin a similar overall effect. Nonetheless, the similarity ofthe collective effect of the various probes on the cells iscompelling.

The effect of blocking the channel in situ supports the earlierproposal based on the replacement of extracellular Na⁺ thatthe channel serves to amplify the receptor current (Zhainazarovet al. 1998). If the lobster SGC serves to amplify the receptorcurrent, its role in the phosphoinositide-signaling cascadein the lobster cells may be functionally similar to that proposedfor the Ca⁺-activated Cl^– channel in the cyclic nucleotidesignaling cascade that mediates olfactory transduction in vertebrateolfactory receptor cells. In the latter case, Ca⁺ entering thecell through the primary effector, the cyclic nucleotide-gatedcation channel, is thought to secondarily activate a Ca²⁺-activatedCl channel (Kleene and Gesteland 1991; Kurahashi and Yau 1993),which serves to amplify the primary signal (Lowe and Gold 1993;Reisert et al. 2003). This analogy raises the question of whatchannel would function as the primary effector in lobster ORNs.One possibility might be the IP₃R, which these cells expressin the plasma membrane of the outer dendrite (Munger et al.2000). Activation of the IP₃R presumably would allow Ca²⁺ toenter the cell, in this case from extracellular "stores" becausethere are no known intracellular stores in the fractional micrometer-diameterolfactory outer dendrites (Grunert and Ache 1988). The factthat the antagonists tested had the same effect on the Ca²⁺-dependentcomponent of the odor-evoked response would be consistent withthis interpretation. Other scenarios certainly are possible,however, and currently we are exploring the detailed sequenceof events leading to activation of the lobster SGC channel inthe intact cell.

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This work was supported by National Institute of Deafness andOther Communication Disorders Grant DC-01655.

ACKNOWLEDGMENTS

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We thank J. Tulsian for preparation of the cultured cells andL. Milstead for assistance with the illustrations.

FOOTNOTES

The costs of publication of this article were defrayed in partby the payment of page charges. The article must therefore behereby marked "advertisement" in accordance with 18 U.S.C. Section1734 solely to indicate this fact.

Address for reprint requests and other correspondence: Y. V. Bobkov, Whitney Laboratory for Marine Bioscience, University of Florida, 9505 Ocean Shore Blvd, St. Augustine, FL 32080-8610 (E-mail: bobkov{at}whitney.ufl.edu)

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