Identification of a Long-Lasting Form of Odor Adaptation that Depends on the Carbon Monoxide/cGMP SecondMessenger System

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Volume 17, Number 8, Issue of April 15, 1997 pp. 2703-2712
Copyright ©1997 Society for Neuroscience

Identification of a Long-Lasting Form of Odor Adaptation that Depends on the Carbon Monoxide/cGMP SecondMessenger System

Frank Zufall and Trese Leinders-Zufall
Section of Neurobiology, Yale University School of Medicine, New Haven, Connecticut 06510

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The diffusible messenger carbon monoxide (CO) has been proposed to mediate endogenous cyclic guanosine 3 $'$ ,5 $'$ -monophosphate(cGMP) formation and sensory adaptation in vertebrate olfactoryreceptor neurons (ORNs). We have identified and characterizeda long-lasting form of odor response adaptation (LLA) that operatesat the level of isolated salamander ORNs and does not requireany interactions from other cells. Manifestations of LLA are seenin reduced amplitude and prolonged kinetics of the cAMP-mediatedexcitatory odor response and the generation of a persistent currentcomponent that lasts for several minutes and is attributable tocyclic nucleotide-gated (CNG) channel activation by cGMP. Becausethese effects can be mimicked by micromolar amounts of exogenouscGMP or CO, we applied various inhibitors of cGMP formation. LLAis abolished selectively by heme oxygenase inhibitors known toprevent CO release and cGMP formation in ORNs, whereas odor excitationremains unaffected. In contrast, blockers of nitric oxide synthaseare unable to eliminate LLA. Several controls rule out a contributionof nonspecific actions to the effects of CO inhibitors. The resultsindicate that endogenous CO/cGMP signals contribute to olfactoryadaptation and underlie the control of gain and sensitivity ofodor transduction. The findings offer a mechanism by which a single,brief odor stimulus can be translated into long-lasting intracellularchanges that could play an important role in the perceptual adaptationto odors, and explain the longstanding puzzle that the olfactoryCNG channels can be gated by both cAMP and cGMP.
Key words: olfactory receptor neuron; cyclic nucleotide-gated channel; carbon monoxide; nitric oxide; cAMP; cGMP; salamander; sensory adaptation; heme oxygenase inhibitors

INTRODUCTION

Carbon monoxide (CO) is a diffusible gas that, like nitric oxide (NO), activates soluble guanylyl cyclase (sGC) to stimulatecyclic guanosine 3 $'$ ,5 $'$ -monophosphate (cGMP) formation (Brüneand Ullrich, 1987; Furchgott and Jothianandan, 1991; Kharitonovet al., 1995). CO has been proposed to function as an endogenousmessenger molecule in the nervous system (Marks et al., 1991;Maines, 1993; Verma et al., 1993; Ingi and Ronnett, 1995; Leinders-Zufallet al., 1995a; Ingi et al., 1996a) and to play roles in long-lastingchanges of synaptic strength in hippocampus (Stevens and Wang,1993; Zhuo et al., 1993), modulation of the odor sensitivity ofolfactory neurons (Leinders-Zufall et al., 1996), regulation ofcarotid body sensory function (Prabhakar et al., 1995), and modulationof cerebellar neuronal activity (Nathanson et al., 1995).

Vertebrate olfactory receptor neurons (ORNs) are ideal for the dissection of CO action in modulating complex signaling cascadesand addressing the functional relevance of CO-mediated cGMP generation.ORNs contain high levels of the CO-producing enzyme heme oxygenase-2(HO-2) (Verma et al., 1993; Ingi and Ronnett, 1995; Ingi et al.,1996b) but no nitric oxide synthase (NOS) activity (Kishimotoet al., 1993; Bredt and Snyder, 1994; Kulkarni et al., 1994; Roskamset al., 1994), which could confound results. The primary responseof ORNs to odor ligands is a rapid rise in cAMP, which directlyopens Ca²⁺-permeable cyclic nucleotide-gated (CNG) ion channels (for review,see Lancet, 1986; Reed, 1992; Breer, 1993; Zufall et al., 1994).Interestingly, native olfactory CNG channels not only have beenshown to be gated by cAMP, but also have retained a high sensitivityto cGMP (Nakamura and Gold, 1987; Zufall et al., 1991a; Fringset al., 1992); hence, changes in cGMP concentration can be monitoredas ionic currents through CNG channels (Leinders-Zufall et al.,1995a, 1996).

Recently, several results have suggested that cGMP is part of the apparatus that mediates odor adaptation. (1) cGMP formationdepends on the stimulus strength and only occurs with strongerodor stimuli (Breer et al., 1992; Verma et al., 1993; Kroner etal., 1996). (2) Its buildup is slow, reaches only low levels,and can outlast the cAMP response for minutes (Breer et al., 1992).(3) Exogenous cGMP produces an adaptation-like effect lastingfor several minutes (Leinders-Zufall et al., 1996). (4) Only micromolaramounts of cGMP, known to occur in ORNs after stimulation withCO (Ingi and Ronnett, 1995; Leinders-Zufall et al., 1995a), arerequired for an adaptation effect. (5) The effect of cGMP canbe mimicked by CO (Leinders-Zufall et al., 1996), which is producedin an odor-dependent manner (Verma et al., 1993).

To test a possible involvement of the CO/cGMP cascade in olfactory adaptation, we have searched for long-lasting forms ofodor response adaptation. We have identified a form of olfactoryadaptation that operates on the time scale of minutes and thatwe term LLA. Analysis of LLA reveals that its properties are indistinguishablefrom the effects of exogenous cGMP or CO. We then use pharmacologicalagents with established effects on CO generation and cGMP levelsin ORNs to disrupt LLA.

MATERIALS AND METHODS
Dissociation and recording from ORNs. ORNs were freshly isolated from the nasal epithelium of adult land-phase tiger salamanders(Ambystoma tigrinum) by methods described in detail previously(Firestein et al., 1991b; Zufall et al., 1991a). No enzymes wereused for the dissociation procedure. All of the cells used inthis study were clearly identifiable as ORNs by their characteristicmorphology, including a single thick dendrite ending in a knob-likeswelling from which emanated half a dozen or more moving cilia.Macroscopic currents were recorded at 22-25°C under voltage clampby applying the perforated patch technique with amphotericin Bto gain electrical access to the interior of the cells (Leinders-Zufallet al., 1995a, 1996). A main advantage of this approach is toensure the least possible disturbance of the internal milieu ofthe neurons and to prevent artificial Ca²⁺ buffering from influencing the results. We also found that amphotericinB recordings display very low levels in baseline noise (Leinders-Zufallet al., 1996), which is a prerequisite to detect reliably tonicshifts in the baseline current as low as 0.5 pA. Current recordings,command potential sequences, data acquisition, and on-line analysiswere controlled by an EPC-9 patch-clamp amplifier, in combinationwith Pulse software (HEKA Electronic) and a Macintosh computer.Continuous currents (low resolution) were filtered at 300 Hz ( $-$ 3dB, 8-pole low-pass Bessel) and digitally sampled at 5 msec perpoint. Single odor responses at expanded temporal resolution weresampled at 1 msec per point. The indifferent electrode consistedof a Ag-AgCl wire connected to the bath solution via an agar bridge.All data reported here have been corrected for junction potentials.The holding potential in all voltage-clamp experiments was $-$ 60mV. To measure the current-voltage (I-V) relationship of the CNGconductance in intact cells, we applied voltage ramps (slope,0.35 mV/msec). Ramps were digitized at 100 µsec per point.

All odor responses were elicited by brief, 100 msec odor pulses. For sequential, repetitive stimulation, we used relativelylong interstimulus intervals of $>=$ 30 sec to avoid early forms ofadaptation (Kurahashi and Shibuya, 1990). Our basic paradigm toestablish LLA was to elicit one conditioning pulse followed bya series of test pulses, all at fixed concentration. Before eachexperimental series, we gave a pulse of a relatively low cineoleconcentration (usually 10 µM). We found that cells that did notrespond with measurable currents to the 10 µM stimulus did notshow LLA, even when responses could be elicited at higher cineoleconcentrations (n = 39). These cells were rejected from the currentstudy but could be used for testing the effects of exogenous COand 8-bromo-cGMP (8-Br-cGMP) (Leinders-Zufall et al., 1996). Conversely,except for one case, all cells that were sensitive to 10 µM cineolepulses produced LLA (n = 33) and were used for further experimentsas described here.

Solutions and chemicals. Cells were held in a laminar flow chamber and continuously superfused at a rate of ~100 µl/sec withphysiological Ringer's solution containing (in mM): 115 NaCl,2.5 KCl, 1.0 CaCl₂, 1.5 MgCl₂, 4.5 HEPES, and 4.5 Na-HEPES, pH7.6, adjusted to 240 mOsm. For experiments with a lowered externalCa²⁺ concentration (Fig. 7), we used the following solution (in mM):105 NaCl, 2.5 KCl, 4.8 CaCl₂, 1.5 MgCl₂, 4.5 HEPES, 4.5 Na-HEPES,5 EGTA, pH 7.6 (NaOH). This solution results in a free Ca²⁺ concentration of 1 µM as measured with a Ca²⁺-sensitive electrode. Because of the limit of precision of ourCa²⁺-selective electrode in this concentration range, 1 µM Ca²⁺ should be regarded as an upper limit for the accurate value.An estimate for this value was calculated from the stability constants,giving 0.6 µM free Ca²⁺. The pipettes were filled with the following solution (in mM):17.7 KCl, 92.3 KOH, 82.3 methanesulfonic acid, 5.0 EGTA, 10 HEPES,pH 7.5 (KOH), adjusted to 220 mOsm.

Odorant solutions containing cineole (Sigma, St. Louis, MO) were prepared in Ringer's solution with <0.1% dimethyl sulfoxide(DMSO). Focal stimulation of olfactory cilia with well definedstimuli was obtained by pressure-ejecting the odorant solutionsfrom multibarrel glass pipettes that were placed within 5-10 µmfrom the cilia. Stimulus pipettes were located downstream fromthe cilia. Under these conditions, the solution switching timewas 30-40 msec as measured by the response to high K⁺ solutions. Odorant dose-response curves obtained with this methodwere in close agreement with cineole responses described previouslyin these cells (Firestein et al., 1993).

All metalloporphyrin solutions were made fresh each day. Zinc (II) protoporphyrin IX (ZnPP-9), zinc (II) deuteroporphyrinIX 2,4-bisglycol (ZnBG), and copper (II) protoporphyrin IX (CuPP-9)were obtained from LC Laboratories (Woburn, MA) and were initiallydissolved in 100% DMSO to give 1 mM stock solutions. The agentswere diluted to the final concentration immediately before use,sonicated, and applied by bath perfusion. Final concentrationsof the metalloporphyrin solutions contained <0.02% (vol/vol) DMSO.ORNs were preincubated for 20-30 min in these solutions beforetests were carried out. Because metal-loporphyrins are photoreactive(Vreman et al., 1993), solubilization, incubation, and recordingwere carried out at very low or zero ambient light to avoid breakdownand possible phototoxicity (Vreman et al., 1993; Meffert et al.,1994). The NO synthase blocker N^G-nitro-L-arginine (L-NOARG; Research Biochemicals International,Natick, MA) was dissolved in 0.1N HCl solution to give a 100 mMstock solution.

CO gas was obtained in research purity (Matheson, Gloucester, MA). We prepared CO stock solutions by bubbling the gas untilsaturation in distilled water, giving a concentration of 0.96mM CO (solubility of CO: 2.691 mg/100 gm H₂O at 23°C and 760 mmHg).This solution was immediately diluted to the desired concentrationin Ringer's solution and injected directly into the recordingchamber (Leinders-Zufall et al., 1995a, 1996). Other compounds,such as cadmium, W-7 (N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide),and LY83583 (6-(phenylamino)-5,8-quinolinedione; Research BiochemicalsInternational) were delivered directly to individual cells viaa multibarrel flow pipette apparatus. Unless otherwise stated,chemicals were obtained from Sigma.

Data analysis. All data analysis and calculations were performed using the Igor Pro software package (WaveMetrics) runningon Macintosh computers. With this program, user-defined functions,in combination with an iterative Levenberg-Marquardt nonlinearleast squares fitting routine, were applied to the data. If nototherwise stated, data are expressed as mean ± SD and number ofobservations (n). Statistical tests were performed using statisticalsoftware (SuperAnova version 1.1 and StatView version 4.0, AbacusSoftware, Berkeley, CA). Fisher's least significant difference(LSD) test was used as a post hoc comparison of the ANOVA.

RESULTS

Long-lasting adaptation of the odor response of olfactory receptor cells
Electrophysiological studies testing the effects of exogenous cGMP or CO on ORNs suggest that the following main steps arelikely to occur after the formation of cGMP (Leinders-Zufall etal., 1995a, 1996): (1) generation of a persistent inward currentwith small amplitude lasting for several minutes and attributableto activation of the CNG channels by cGMP; (2) sustained Ca²⁺ influx through tonic CNG channel activation; and (3) reductionof the gain of the primary cAMP second-messenger cascade causedby the Ca²⁺ entry. Manifestations of this effect should be evident in a long-lastingdecline of peak odor responses, a prolongation of the odor responsekinetics, and characteristic changes of the odorant dose-responsecurve (Leinders-Zufall et al., 1996). To identify the effectsof endogenous cGMP formation, we therefore searched for formsof olfactory adaptation with characteristics similar to the effectsof exogenous CO/cGMP. Odor responses were elicited by repeated100 msec pulses of the single odor ligand cineole at various concentrations(Firestein et al., 1993; Leinders-Zufall et al., 1996), and currentswere measured under voltage clamp by means of the perforated patchtechnique (Leinders-Zufall et al., 1996).

Under these experimental conditions, a time-dependent decrease in odor sensitivity resembling the effects of CO/cGMP occursregularly after exposure to odor stimuli of a given strength.An example is illustrated in Figure 1A, in which four identicalodor pulses at fixed concentration (10 µM cineole) produced transientinward currents with similar peak amplitudes, showing no signsof adaptation. An increase in the stimulus strength to 20 µM cineoleresulted in a larger initial response, an observation consistentwith the dose-response behavior of these cells, but subsequentodor responses elicited by the same 20 µM odor pulse progressivelydeclined until reaching a new equilibrium at a 5.7-fold lowerlevel (Fig. 1A). This adaptive effect is denoted here as long-lastingadaptation (LLA). LLA developed with a relatively slow onset timecourse, with a time constant of ~25 sec (n = 11) (Fig. 1A, dottedcurve). Figure 1B illustrates that LLA was fully reversible; aftera 6.5 min period without odor stimulation, the initial odor responserecovered spontaneously and, in response to further stimulation,readaptation proceeded with the same time course as in the controlmeasurement (Fig. 1B). By using the same stimulation paradigmas in Figure 1B and varying the interval (recovery time) duringthe two test series, we found that the time for full recoveryfrom LLA was between 6 and 8 min (Fig. 1C). To distinguish LLAfrom a decreased responsiveness attributable to the repetitionof the chemosensory stimuli, we increased the time interval betweenthe first and second odor pulse (n = 5) (Fig. 1D). The resultsindicate that a single 100 msec odor stimulus can be sufficientto fully establish LLA, and that LLA is not primarily caused bythe repetition rate of the stimulus. In fact, it appears thatLLA, once initiated, can proceed for several minutes with itsown intrinsic time course in the absence of continuous odor stimulation.
Fig. 1. LLA of the odor response of isolated olfactory neurons. A, Response of an individual ORN to four repeated 100 msec pulsesof the odor ligand cineole plotted at low time resolution. Interstimulusinterval was $>=$ 30 sec. Arrows indicate odor stimuli. Cells werevoltage-clamped by means of the perforated patch technique. Holdingpotential in all recordings was $-$ 60 mV. Stimulation with 10 µMcineole produces odor responses with peak amplitudes of $-$ 18.6± 0.6 pA (n = 4). An increase in stimulus strength to 20 µM cineoleresults in a larger initial peak response ( $-$ 80.0 pA) followedby a time-dependent decline in odor responsiveness to $-$ 14.1 ±0.6 pA (n = 3). The onset time course of LLA is fit with a singleexponential function giving $tau$ = 25.4 sec (indicated by the dottedline). B, LLA recovers spontaneously after a 6.5 min period inodor-free solution. On further stimulation, readaptation proceedswith the same onset time course as in the control measurement.C, Plot of recovery time versus peak odor responses. Current amplitudesare plotted in normalized form, I/I_control, where I_control isthe incremental peak response to the first test pulse in the controlseries, and I is the incremental peak response to the first testpulse in the second series. Same stimulation paradigm as in B.Data points are connected by eye. D, LLA does not depend directlyon the repetition rate of the stimuli. When the interval betweenthe first and second stimulus is increased to 1.3 min, LLA proceedswith a similar time course as in control measurements. This isindicated by the dotted curve representing the average onset timecourse ( $tau$ = 24 ± 4 sec) of LLA from 11 control cells stimulatedwith the pulse paradigm used in B. This experiment also demonstratesthat a single 100 msec stimulus of a given strength is sufficientto establish LLA.
[View Larger Version of this Image (23K GIF file)]

LLA could not be elicited in every ORN responsive to cineole (cf. Leinders-Zufall et al., 1996). In an attempt to addresswhether a given cell would produce LLA, we found that the abilityto initiate LLA was strongly correlated with the sensitivity ofthat cell for the odor ligand. Previous experiments have shownthat each salamander ORN can respond to different odor molecules,but that each ORN responsive for a given odor ligand displaysa characteristic range and K_1/2 value of the dose-response curvefor that ligand (Firestein et al., 1993; Leinders-Zufall et al.,1996). The latter feature may reflect the specific tuning propertiesof odor receptor molecules for that stimulus (cf. Shepherd, 1994;Mori and Yoshihara, 1995). Here, we found that ORNs that displayeda heightened sensitivity to cineole or, in other words, thosewith the lowest K_1/2 values [K_1/2 = 33.6 ± 8.2 µM (n = 10); range,21.4-42.9 µM] exhibited LLA, whereas ORNs with high K_1/2 valuesdid not [K_1/2 = 76.8 ± 19.2 µM (n = 10); range, 42-110 µM; Spearmanrank correlation: R_s = $-$ 0.87; p < 0.001; n = 20]. By contrast,there was no correlation between LLA and the maximal amplitudeof odor currents in a given cell at saturating cineole concentrations(R_s = 0.35; p = 0.13; n = 20). As a result of these observations,a simple test was performed with each ORN before an experimentalseries (see Materials and Methods) that enabled us to predictin all but one case whether LLA would occur.

Long-lasting adaptation is indistinguishable from the effects of cGMP or CO
The characteristics of LLA as seen in Figure 1 are strikingly similar to the adaptation effect produced by exogenous cGMPor CO (Leinders-Zufall et al., 1996). More detailed analysis ofLLA provides additional evidence for this notion. As with theeffects of CO/cGMP, LLA is associated with the generation of apersistent background current. Figure 2A illustrates that stimulationof an ORN with a single odor ligand resulted in the activationof two different types of ionic currents: large transient inwardcurrents (termed primary odor response) and relatively small,sustained inward currents. Examination of the current traces athigher resolution (Fig. 2Ab,Ad) revealed the time course and temporalrelation of the sustained currents with respect to the transientodor currents and the development of LLA (Fig. 2Aa,Ac). Smallnet inward currents, reaching an amplitude of approximately $-$ 2pA on average, were generated upon odor stimulation and recoveredback to baseline ~3-4 min after the last odor stimulus of a testseries. This effect was repeatable upon stimulation in a secondtest series (Fig. 2Ab,Ad) and was seen in all cells that producedLLA (n = 33). These background currents developed immediatelyafter the first primary odor current of a test series. Hence,activation of the background current is secondary to the cAMP-mediatedodor response, but precedes the decline of the primary odor responses,suggesting that the tonic background current may underlie thereduced odor sensitivity observed here (Leinders-Zufall et al.,1996). Like odor-induced cGMP formation, activation (induction)of the background currents was dependent on the stimulus strength.Low odor concentrations insufficient to elicit LLA failed to inducebackground currents (n = 21). Conversely, all cells that respondedto a specific stimulus strength with LLA also generated a backgroundcurrent at the same stimulus intensity (n = 33). This providesfurther evidence that the background currents were causal to LLA.
Fig. 2. LLA is associated with the generation of a persistent background current. A, Temporal relation between persistent inward currentand diminished responsiveness of primary odor currents. Same experimentas shown in Figure 1B. Aa, To facilitate viewing of the wholeexperiment, odor responses are replotted at low-amplitude resolution.Ab, With higher resolution, the generation of small sustainedinward currents of approximately $-$ 1.3 pA becomes evident. Thesebackground currents are activated on odor stimulation after thefirst test pulse and recover spontaneously back to baseline 3-4min after the last odor pulse. Ac, To quantify the time-dependentreduction in odor responsiveness, peak odor responses are plottedin normalized form with respect to the incremental peak amplitudeof the first odor response of the experiment. Ad, Time courseof the background current. Each plotted data point representsthe mean of 651 data points. Data points representing transientodor currents are omitted from the plot. B, A single 100 msecpulse of cineole (80 µM) (arrow) results in the activation ofa transient odor current followed by the persistent backgroundcurrent. Rapid addition of Cd²⁺ (3 mM) blocked the persistent current. This effect can be reversedon washout of Cd²⁺. C, I-V analysis of odor-stimulated background current (fromvoltage ramps; see Materials and Methods) at three different conditions:(1) after induction of the background current; (2) in the presenceof 3 mM Cd²⁺ in the bath solution; and (3) after washout of Cd²⁺. Ramp currents taken under control conditions have been subtracted.D, Effect of the CNG channel inhibitors Cd²⁺, W-7, and LY83583 on the amplitude of odor-stimulated backgroundcurrents yielding the following data: $-$ 1.7 ± 0.6 pA (n = 10) (control); $-$ 0.05 ± 0.15 pA (n = 3) (3 mM Cd²⁺); $-$ 0.02 ± 0.07 pA (n = 3) (100 µM W-7); and 0.03 ± 0.08 pA (n= 3) (20 µM LY83583). Experiments were performed as in B.
[View Larger Version of this Image (24K GIF file)]

Several ionic and pharmacological tests were carried out to examine whether the background currents were mediated by CNG channelactivation. Figure 2B illustrates an experiment in which a single100 msec pulse of cineole (arrow) resulted in the activation ofa transient odor current followed by the persistent backgroundcurrent. Rapid addition of Cd²⁺ (3 mM) blocked the persistent current. This effect was fullyreversible upon washout of Cd²⁺, consistent with previous results showing that millimolar dosesof Cd²⁺ block the ionic pore of CNG channels but not the underlying second-messengercascade (Zufall and Firestein, 1993; Ahmad et al., 1994; Leinders-Zufallet al., 1995a,b). I-V analysis (Fig. 2C) revealed that the backgroundcurrents were caused by a conductance increase ranging from 38to 266 pS (n = 10). Like the persistent currents through CNG channelsactivated by exogenous CO/cGMP (Leinders-Zufall et al., 1996)(Table 1), odor-induced background currents could be abolishedreversibly by other CNG channel inhibitors besides Cd²⁺, such as the calmodulin inhibitor W-7 (100 µM) (Fig. 2D) (Kleene,1994; Leinders-Zufall et al., 1995a). Furthermore, establishedbackground currents were inhibited by LY83583 (20 µM) (Fig. 2D),which is known as a guanylyl cyclase inhibitor (Leinders-Zufallet al., 1995a) but acts also as an open channel blocker of theCNG channels themselves, with a K_1/2 of 1.4 µM (Leinders-Zufalland Zufall, 1995). A detailed comparison of the properties ofcurrents through CNG channels induced by exogenous 8-Br-cGMP withthe tonic odor-stimulated background currents demonstrates thatboth had closely similar properties (see Table 1). Collectively,these results indicate that the persistent currents, like thelarge transient odor responses, were caused primarily by the activationof CNG channels.

Table 1. Evidence that odor-induced background currents are mediated by CNG channel activation

Odor-induced background current CNG channel current activated by 8-Br-cGMP

Amplitude (pA) $-$ 1.7 ± 0.6 $-$ 1.2 ± 0.5

  (1 mM external Ca²⁺) (n = 10) (n = 3)

Reversal potential (mV) $-$ 27.4 ± 9.5 $-$ 29.0 ± 3.6

  (1 mM external Ca²⁺) (n = 10) (n = 3)

Amplitude (pA) $-$ 19.5 ± 8.4 $-$ 15.0 ± 4.5

  (external Ca²⁺ reduced) (n = 3) (n = 3)

Reversal potential (mV) +7.6 ± 12.1 $-$ 3.8 ± 8.1

  (external Ca²⁺ reduced) (n = 3) (n = 3)

Cd²⁺ (3 mM) Complete block Complete block

LY83583 (20 µM) Complete block Complete block

W-7 (100 µM) Complete block Complete block

Currents through CNG channels were measured with the use of the perforated patch-clamp technique as described previously (Leinders-Zufallet al., 1995a, 1996). A concentration of 1 µM 8-Br-cGMP was usedin these experiments because this cGMP level can be produced byphysiological concentrations of CO (Leinders-Zufall et al., 1995a).For the analysis of the effect of low external Ca²⁺ (0.6 µM) on established odor-induced background currents, cellswere first exposed to normal 1 mM external Ca²⁺ and stimulated with an odor pulse as shown in Figure 2B. Afterthe background current was fully activated, rapid switching tolow Ca²⁺ solution was performed. The shift in reversal potential underlow Ca²⁺ presumably reflects a contribution of secondary, Ca²⁺-dependent conductances to the net inward currents observed here.

Figure 3 illustrates another characteristic feature of LLA shared with the effects of exogenous CO/cGMP on odor responses,i.e., a specific alteration of the odor response kinetics (Leinders-Zufallet al., 1996). A plot of the odor responses at higher temporalresolution, both as original currents (Fig. 3A) and in normalizedform (Fig. 3B), reveals that both the rising and the decayingkinetics of the currents were markedly prolonged after inducingLLA. The time-to-peak increased from 630 ± 130 msec (n = 10) undercontrol conditions to 790 ± 150 msec (n = 10) during LLA. Thedecay time course was fitted with single exponential functionsgiving time constants of $tau$ = 510 ± 130 msec (n = 10) (control)and $tau$ = 630 ± 250 msec (n = 10) (LLA). Thus, LLA reduced the amplitudeand increased the time-to-peak and recovery time of the odor response.In addition to these effects, it is evident from Figure 3 thatLLA also markedly decreased the initial slope of the rising phaseof the response. These results thus constitute a powerful setof constraints for the future identification of the downstreammolecular sites mediating long-lasting odor adaptation (cf. Detwilerand Gray-Keller, 1996).
Fig. 3. Effect of LLA on odor response kinetics. A, Comparison of the time course of the primary odor responses (50 µM cineole) atincreased time resolution under control conditions (control) andafter the initiation of LLA (adapted). Timing of the odor stimulusis indicated by the traces above the currents. LLA results ina decrease of the peak odor current [ $-$ 32.5 pA (adapted), $-$ 108.6pA (control)], a more prolonged time-to-peak [870 msec (adapted),550 msec (control)], and an increased decay time course. The decaytime course was fitted with monoexponentials giving time constantsof $tau$ = 591 msec (control) and $tau$ = 649 msec (adapted). B, To facilitateviewing of the kinetic effects, odor currents from A are rescaledto give identical peak amplitudes.
[View Larger Version of this Image (12K GIF file)]

Collectively, the data of Figures 1, 2, 3 demonstrate that LLA is virtually indistinguishable from the effects caused by lowmicromolar amounts of CO or cGMP on ORNs. These results thereforesuggest a model in which LLA is induced by the endogenous formationof cGMP.

Inhibition of the CO/cGMP pathway eliminates long-lasting adaptation
To test the hypothesis that LLA is caused by endogenous cGMP production, we analyzed the effects of pharmacological inhibitorsof the cGMP second-messenger system. Figure 4A schematizes theproposed role of cGMP in odor transduction (Leinders-Zufall etal., 1996). According to this model, excitation and long-lastingadaptation are attributable to the activation of distinct, parallelsecond-messenger pathways, i.e., the cAMP cascade leading to transientactivation of the CNG channels and the cGMP system resulting inpersistent CNG channel activity. If this model is correct, thenselective blockade of the cGMP pathway should prevent inductionof the sustained background currents, as well as LLA, but shouldnot affect the primary excitation process.
Fig. 4. LLA is abolished by pharmacological blockade of the CO/cGMP system. A, Model for the proposed role of the cGMP second-messengersystem in olfactory transduction, based on previous results (Leinders-Zufallet al., 1996). According to this model, the processes leadingto excitation and long-lasting adaptation are attributable tothe activation of distinct, parallel second-messenger pathways,i.e., the cAMP cascade leading to transient activation of theCNG channels and excitation, and the cGMP system resulting inpersistent CNG channel activity and long-lasting adaptation. R,Odor receptor; G_olf, stimulatory G_s-like G-protein;AC, adenylyl cyclase type III. B, Plot of the onset time courseof LLA under control conditions. Data are from six cells (shownwith different symbols). Cells are stimulated with 300 µM cineole.Odor responses of a given cell are normalized to (I $-$ I_LLA)/(I_control $-$ I_LLA), so that the incremental peak response under control conditions(I_control) is set to the value 1, and the mean equilibrium peakresponse after producing LLA (I_LLA) is given the value 0. Continuousline is a best fit of the data with a single exponential functiongiving a time constant $tau$ = 24 sec. Insets are representative waveformsof transient odor-induced currents taken before LLA (large response)and after LLA was established (small response). C, Effect of ZnPP-9(100 nM, n = 4) on LLA demonstrating that LLA is abolished afterZnPP-9 treatment in all tested cells. Solid line was computedby regression analysis. Insets demonstrate that the characteristicproperties of the cAMP-mediated response remain unchanged duringZnPP-9 treatment and that there is no response decrement overtime (second response was taken 12 min after the first odor response).D, Lack of LLA after ZnBG treatment (300 nM, n = 3). Same analysisas in C. E, CuPP-9 (100 nM) is unable to abolish LLA (n = 3).There is, however, a slight increase in the onset time constantof LLA ( $tau$ = 98 sec) during CuPP-9 treatment compared with controlmeasurements of B, presumably reflecting the nonspecific effectsof CuPP-9. The characteristic waveform of odor currents beforeand after producing LLA is unaltered by CuPP-9. F, L-NOARG (100µM) is unable to prevent LLA (n = 3), but slightly increases theonset time constant of LLA ( $tau$ = 82 sec) without altering the characteristicwaveform of odor currents before and after establishing LLA.
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To inhibit cGMP production, we attempted to block the CO-generating enzyme HO-2. Previous work has shown that ORNs containhigh levels of HO-2 but lack NOS activity; therefore, it has beenproposed that CO may function as an endogenous activator of olfactorysGC (Verma et al., 1993; Ingi and Ronnett, 1995). In culturedORNs, release of CO and cGMP formation can be inhibited effectivelyby ZnPP-9 (Ingi and Ronnett, 1995), a potent inhibitor of hemeoxygenase activity (Maines, 1981). We therefore preincubated theORNs in ZnPP-9 (100 nM). Consistent with the proposed model (Fig.4A), this treatment abolished LLA (n = 4), even when very highodor concentrations were applied (300 µM cineole) and odor currentswere monitored over long recording times (up to 15 min) (Fig.4C). Furthermore, induction of the persistent background currentwas suppressed in the presence of ZnPP-9 (n = 4) (Fig. 5A), givingadditional support to the notion that it results from activationof CNG channels by cGMP signals. In contrast, the excitatory cAMP-mediatedresponse was not altered by ZnPP-9 (see Fig. 4C, insert), providingan important internal control concerning the pathway selectivityof the treatment.
Fig. 5. Effect of pharmacological inhibitors of the cGMP second-messenger system on activation (induction) of odor-stimulated backgroundcurrent. The following data are obtained: $-$ 1.7 ± 0.6 pA (control,n = 10); $-$ 0.12 ± 0.16 pA (100 nM ZnPP-9, n = 4); $-$ 0.14 ± 0.14pA (300 nM ZnBG, n = 3); $-$ 1.54 ± 0.34 pA (100 nM CuPP-9, n = 3), $-$ 1.48 ± 0.59 pA (100 µM L-NOARG, n = 3); $-$ 1.50 ± 0.31 pA (100µM L-NMMA, n = 3).
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Because of concerns about the specificity of ZnPP-9 as an inhibitor of heme oxygenase function (Meffert et al., 1994) a seriesof control experiments was carried out. First, we tested anotherinhibitor of HO-2, ZnBG (300 nM) (Vreman et al., 1991), and foundthat it also abolished LLA and left the excitation process unchanged(n = 3) (Fig. 4D). The slightly smaller potency of ZnBG comparedwith ZnPP-9 resembles the potencies of these two agents on cGMPproduction in cultured ORNs (Ingi and Ronnett, 1995). To assesspotential nonspecific effects of the metalloporphyrin inhibitors,we examined CuPP-9 (100 nM), which does not inhibit HO-2 (Yoshinagaet al., 1982; Prabhakar et al., 1995). CuPP-9 at a dose comparableto ZnPP-9 failed to prevent LLA (n = 3) (Fig. 4E). More importantly,a specific inhibitor of NOS, L-NOARG (100 µM), did not eliminateLLA (n = 3) (Fig. 4F) even when used at 1000-fold higher concentrationsthan ZnPP-9. The same result was obtained with N^G-monomethyl-L-arginine (L-NMMA; 100 µM), another inhibitor ofNOS (n = 3) (not shown). The result that NOS inhibitors are ineffectivein preventing LLA strongly argues against a role of NO in thisprocess and is consistent with reports that known isoforms ofNOS are absent from adult vertebrate ORNs (Kishimoto et al., 1993;Bredt and Snyder, 1994; Kulkarni et al., 1994; Roskams et al.,1994) and that NOS inhibitors fail to prevent CO release and cGMPformation in these cells (Verma et al., 1993; Ingi and Ronnett,1995).

Inhibitors of the CO/cGMP system not only abolished LLA, but also prevented induction of the secondary odor-stimulated backgroundcurrents. Figure 5 illustrates that the pharmacological profileof the background currents was identical to that obtained forLLA in Figure 4. All agents that abolished LLA, such as ZnPP-9and ZnBG, also suppressed activation of the background currents.Conversely, compounds that were ineffective in eliminating LLA,such as CuPP-9, L-NOARG, and L-NMMA, failed to suppress activationof the background current (Fig. 5). These results are fully consistentwith the predictions from the model outlined in Figure 4A.

Long-lasting adaptation can be restored in the presence of heme oxygenase inhibitors
ZnPP-9 is believed to inhibit heme oxygenase by acting as a pseudosubstrate for heme (iron protoporphyrin IX) (Maines, 1981;Vreman et al., 1989). Previous reports have shown that ZnPP-9sometimes can also alter the activity of other heme-containingenzymes besides heme oxygenase such as sGC (Ignarro et al., 1984;Luo and Vincent, 1994). Further controls were performed to assessthe possibility that ZnPP-9 blocked the cGMP pathway downstreamfrom HO-2. In Figure 6A, whole-cell currents through CNG channelsresulting from stimulation of sGC by known concentrations of exogenousCO (Leinders-Zufall et al., 1995a) were generated in the presenceand absence of ZnPP-9 (250 nM). This experiment was performedusing a CO concentration (2.4 µM) close to the K_1/2 value of theCO dose-response curve (Leinders-Zufall et al., 1995a). No significantdifference was found between the ability of CO to stimulate CNGchannel activation in the presence or absence of ZnPP-9 (Student'st test; p = 0.62) (Fig. 6A). Therefore, we conclude that ZnPP-9,at least in the low concentrations used in this study, had nosignificant effect on olfactory sGC, which is consistent withprevious biochemical work (Ingi and Ronnett, 1995). Furthermore,other downstream components of the cGMP pathway were not alteredsignificantly by ZnPP-9 (Fig. 6B). In the presence of ZnPP-9,LLA could be restored in a concentration-dependent manner by addingthe membrane-permeant cGMP analog 8-Br-cGMP (Fig. 6B) (n = 3).A similar result was obtained by adding exogenous CO (1 µM) (notshown). These data demonstrate that the molecular components downstreamfrom HO-2 needed to produce LLA were functionally intact in thepresence of ZnPP-9. Collectively, the results provide strong evidenceto conclude that ZnPP-9 acted at the level of HO-2 in these experimentsand that LLA was caused by the endogenous release of CO leadingto stimulation of sGC and subsequent cGMP formation.
Fig. 6. A, Analysis of currents through CNG channels stimulated by known concentrations of exogenous CO (2.4 µM) in the absence andpresence of ZnPP-9 (250 nM). This experiment was performed underwhole-cell recording conditions as described previously (Leinders-Zufallet al., 1995a). Control, $-$ 161.3 ± 54.6 pA (n = 6); ZnPP-9 (250nM), $-$ 151.9 ± 41.8 pA (n = 5). Note that there is no significantdifference between the two results (Student's t test; p = 0.62),indicating that ZnPP-9 has no significant effect on olfactorysGC activation at concentrations used here. B, In the presenceof ZnPP-9 (250 nM), LLA can be restored in a concentration-dependentmanner by supplying various concentrations of the membrane-permeantcGMP analog 8-Br-cGMP. Odor responses are elicited by identicalpulses of 300 µM cineole (arrows).
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DISCUSSION
Although much progress has been made in identifying the molecular components mediating odor detection and excitation in thevertebrate olfactory system in past years, the mechanisms underlyingolfactory adaptation remained elusive. Here we have identifieda form of odor adaptation that operates at the level of individualORNs and does not require any cooperative interactions from othercells. A single brief exposure (100 msec) of a given amount ofthe odor ligand cineole to isolated ORNs produced a progressive,reversible, and relatively long-lasting decline of the responseto that stimulus. This phenomenon is denoted LLA because completerecovery from its effect occurred after 6-8 min, sharply distinguishingit from early forms of olfactory adaptation (Getchell and Shepherd,1978; Kurahashi and Shibuya, 1990; Zufall et al., 1991b). It seemslikely that LLA is related to forms of long-lasting odor adaptationdescribed previously at the cellular and systems level in humans(Ekman et al., 1967; Murphy, 1987), amphibia (Baylin and Moulton,1979; Getchell, 1986), insects (Zack-Strausfeld and Kaissling,1986; Marion-Poll and Tobin, 1992), crustaceans (Voigt and Atema,1990), and nematodes (Colbert and Bargmann, 1995).

Alternative second messengers mediate distinct olfactory functions
The most striking result of the present study is that LLA can be uncoupled from excitation and completely abolished by exposureof the cells to the metalloporphyrin inhibitors ZnPP-9 and ZnBG,both at nanomolar concentrations. This treatment results in ahighly specific action, because the properties of the cAMP-mediatedtransduction cascade remain unaltered by these agents, and a structurallynearly identical porphyrin analog, CuPP-9, is ineffective in preventingLLA. Thus, the results demonstrate that odorant excitation andLLA are attributable to the activation of distinct biochemicalprocesses. In light of the current interest for the role of multiplesecond-messenger systems in ORNs (Breer, 1993; Dionne, 1994; Zhainazarovand Ache, 1995; Brunet et al., 1996; Restrepo et al., 1996), ourstudy provides some of the first clear evidence that differentfunctions of olfactory transduction, such as excitation and LLA,are caused by the activity of different, parallel second-messengercascades. This result is in close agreement with conclusions drawnfrom a recent study in Caenorhabditis elegans, in which the mutationof specific genes affected the adaptation process but did notdiminish the ability of unadapted animals to respond to odors(Colbert and Bargmann, 1995). Hence, it appears that common strategiesto produce long-term forms of odor adaptation could have evolvedin phylogenetically diverse nematodes and amphibia.

A role for cGMP in odor adaptation
Our results strongly support the proposal that cGMP contributes to olfactory adaptation by modulating the signaling propertiesof ORNs, thereby controlling the gain and sensitivity of the excitatorycAMP cascade (Breer and Shepherd, 1993; Kroner et al., 1996; Leinders-Zufallet al., 1996). Detailed analysis of LLA reveals that its temporalbehavior and dependence on stimulus strength are fully compatiblewith the properties of odor-stimulated cGMP generation. More importantly,LLA is indistinguishable from the adaptation effect produced byexogenous cGMP (Leinders-Zufall et al., 1996).

How might odor-stimulated cGMP signals be generated? Given that adult vertebrate ORNs contain some of the highest levels ofHO-2, whereas NO synthase is absent from these cells (see introductoryremarks), and that HO-2 is colocalized with sGC in olfactory cilia(Ingi and Ronnett, 1995), interest has focused on a potentialrole of CO as an endogenous activator of olfactory sGC, thus mediatingodor-stimulated cGMP formation (but see Breer et al., 1992). Additionalsupport for CO came from the finding that ORNs are surprisinglysensitive to CO; submicromolar amounts of CO are sufficient toregulate the activity of CNG channels in a cGMP-dependent manner(Leinders-Zufall et al., 1995a). A specific function for CO wassuggested by the finding that CO can mimic the adaptation effectproduced by exogenous cGMP (Leinders-Zufall et al., 1996). Inthe present study, we tested for the involvement of endogenousCO in olfactory adaptation by examining the effects of pharmacologicalinhibitors of CO and NO production. The data clearly reveal thatmetalloporphyrins with established effects on the release of COfrom ORNs (Ingi and Ronnett, 1995) completely abolish LLA, whereastwo specific inhibitors of NOS, used at 1000-fold higher concentrations,are unable to eliminate LLA. The effects of ZnPP-9 cannot be explainedby its direct actions on sGC because CuPP-9, which is as potentas ZnPP-9 on sGC but does not inhibit heme oxygenase (Yoshinagaet al., 1982; Prabhakar et al., 1995), fails to eliminate LLA.Several other controls rule out that ZnPP-9 influences the cGMPsystem downstream from HO-2. Therefore, we conclude that LLA iscaused by the endogenous release of CO and subsequent cGMP formation.

Although it remains unclear why ORNs would use a diffusible messenger to produce adaption in the same cell in which the diffusiblemessage is generated, it is likely that CO has additional functionsbesides self-adaptation (e.g., in regulating the odor sensitivityof neighboring cells, thus contributing to an effect known ascross-adaptation) (Breer and Shepherd, 1993; Leinders-Zufall etal., 1995a; Broillet and Firestein, 1996). This could enhancefurther the spatial contrast of odor signals in the olfactoryepithelium. Further support for this notion comes from our resultthat only those ORNs with heightened sensitivity for cineole exhibitLLA.

How does cGMP formation lead to LLA?
An important result of the present study is that odor adaptation affects steps in the activation and recovery phase of thecAMP-mediated odor response (Fig. 3). This effect is cGMP-dependentbecause it can be eliminated by selective blockade of the cGMPsystem (Fig. 4). It is currently not fully understood how cGMPformation leads to odor adaptation. It has been suggested thatcGMP acts in ORNs through a cGMP-dependent protein kinase leadingto reduced cAMP generation (Kroner et al., 1996). An alternativepathway by which cGMP can influence adaptation is through gatingof CNG channels, resulting in long-lasting Ca²⁺ entry (Leinders-Zufall et al., 1996). Although the relative contributionof each of these steps to odor adaptation remains to be investigated,it is clear from previous results that cGMP is unable to mediateodor adaptation under conditions in which Ca²⁺ movements across the cellular membrane are reduced (Leinders-Zufallet al., 1996). This result argues that cGMP-dependent Ca²⁺ entry is a critical step in LLA and leads to the proposal thatcGMP, through CNG channel activation, initiates Ca²⁺-dependent feedback regulation of odor transduction; several Ca²⁺-dependent steps in the cAMP cascade have been described thatare consistent with this hypothesis and the kinetic changes ofthe odor responses identified here (see Discussion in Leinders-Zufallet al., 1996). The current study provides more evidence for thisview demonstrating that odor stimulation results in the generationof two distinct ionic currents, i.e., a transient inward currentattributable to activation of the cAMP system (Firestein et al.,1991a) and a persistent inward current of small amplitude, whichis denoted background current. Results from several tests (Figs.2, 5, Table 1) indicate that the background currents are mediatedby activation of CNG channels and depend on the cGMP cascade.Finally, the data indicate that the background currents are causalto LLA because they are always generated before the expressionof LLA. Conversely, LLA is absent under conditions in which thegeneration of the background currents is suppressed.

Functional implications and relevance
In summary, our results support the concept that cAMP and cGMP signals are active for different periods of time after briefodor stimuli and that cGMP reaches much lower levels in ORNs comparedwith cAMP. We suggest that these differences provide the physiologicalbasis for different functions in olfactory excitation and adaptation.We propose that cAMP and cGMP, at least under the conditions ofbrief odor stimulation, produce distinctly different Ca²⁺ signals through CNG channel activation, being transient in thecase of cAMP and more persistent in the case of cGMP. Our preliminaryanalysis of Ca²⁺-mediated fluorescence changes in olfactory cilia supports thishypothesis (Zufall et al., 1996). The results should be significantwith respect to the recent development that CNG channels are notonly expressed in sensory neurons but are also found in many otherneurons of the nervous system (Ahmad et al., 1994; Leinders-Zufallet al., 1995b; Kingston et al., 1996). The form of olfactory adaptationidentified in this study provides a mechanism that can translatea brief neuronal activation into long-lasting intracellular changes,which determine the odor sensitivity of olfactory neurons forminutes, based on previous exposure to odor ligands. Because thereis increasing evidence that slow cGMP second-messenger signalsmay control the odor sensitivity not only in vertebrates but alsoin insects (Ziegelberger et al., 1990; Zufall and Hatt, 1991;Boekhoff et al., 1993), long-term adaptation could reflect a generalprinciple of diverse chemosensory systems in dealing with thediscontinuous, nonspatial nature of olfactory stimuli.

FOOTNOTES

Received Dec. 2, 1996; revised Jan. 21, 1997; accepted Jan. 31, 1997.

This work was supported by Grant RO1-DC-02227 from the National Institute of Deafness and Other Communications Disorders toF.Z. We gratefully thank Gordon Shepherd, Charles Greer, and PaulKingston for critically reading earlier versions of this manuscriptand Steve Siegelbaum for a stimulating discussion.

Correspondence should be addressed to Dr. Frank Zufall, Section of Neurobiology, Yale University School of Medicine, 333 CedarStreet, New Haven, CT 06510.

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Zufall F, Leinders-Zufall T, Rand MN, Shepherd GM, Greer CA (1996) Odor-stimulated calcium signaling in cilia and dendrites of olfactory receptor neurons. Soc Neurosci Abstr 22:259.

Copyright ©1997 Society for Neuroscience   0270-6474/1997/172703-10$05.00/0

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