Interactions of Cyclic Nucleotide-Gated Channel Subunits and Protein Tyrosine Kinase Probed with Genistein

doi:10.1085/jgp.115.6.685

Published 1 June 2000. doi:10.1085/jgp.115.6.685

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Original Article

Interactions of Cyclic Nucleotide-Gated Channel Subunits and Protein Tyrosine Kinase Probed with Genistein

Elena Molokanova^a, Alexei Savchenko^a, and Richard H. Kramer^a

^a Department of Molecular and Cellular Pharmacology, University of Miami School of Medicine, Miami, Florida 33101
P.O. Box 016189, University of Miami School of Medicine, Miami, FL 33101.305-243-4555

rkramer{at}chroma.med.miami.edu

ABSTRACT

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cGMP sensitivity of cyclic nucleotide–gated (CNG)channels can be modulated by changes in phosphorylation catalyzedby protein tyrosine kinases (PTKs) and protein tyrosine phosphatases.Previously, we used genistein, a PTK inhibitor, to probe theinteraction between PTKs and homomeric channels comprised of ${alpha}$ subunits (RET ${alpha}$ ) of rod photoreceptor CNG channels expressedin Xenopus oocytes. We showed that in addition to inhibitingphosphorylation, genistein triggers a noncatalytic interactionbetween PTKs and homomeric RET ${alpha}$ channels that allostericallyinhibits channel gating. Here, we show that native CNG channelsfrom rods, cones, and olfactory receptor neurons also exhibitnoncatalytic inhibition induced by genistein, suggesting thatin each of these sensory cells, CNG channels are part of a regulatorycomplex that contains PTKs. Native CNG channels are heteromers,containing β as well as ${alpha}$ subunits. To determine the contributionsof ${alpha}$ and β subunits to genistein inhibition, we comparedthe effect of genistein on native, homomeric (RET ${alpha}$ and OLF ${alpha}$ ),and heteromeric (RET ${alpha}$ +β, OLF ${alpha}$ +β, and OLF ${alpha}$ +RETβ)CNG channels. We found that genistein only inhibits channelsthat contain either the RET ${alpha}$ or the OLFβ subunits. Thisfinding, along with other observations about the maximal effectof genistein and the Hill coefficient of genistein inhibition,suggests that the RET ${alpha}$ and OLFβ subunits contain bindingsites for the PTK, whereas RETβ and OLF ${alpha}$ subunits do not.

Key Words: cyclic guanosine monophosphate • protein tyrosine kinase • photoreceptor • olfactory receptor neuron

INTRODUCTION

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cyclic nucleotide–gated (CNG) channels are crucial forsensory transduction in rod and cone photoreceptors and olfactorysensory neurons. The cyclic nucleotide sensitivity of CNG channelscan be modulated by various intracellular signals includingCa²⁺/calmodulin (Chen et al. 1994; Grunwald et al. 1998) andphosphorylation (Gordon et al. 1992; Molokanova et al. 1997;Muller et al. 1998). We recently showed that the cyclic GMPsensitivity of CNG channels expressed in Xenopus oocytes, consistingof homomers of bovine rod ${alpha}$ subunits (RET ${alpha}$ ) can be modulated byprotein tyrosine kinases (PTKs) and phosphatases (PTPs) intrinsicto the oocyte (Molokanova et al. 1997, Molokanova et al. 1999b).These enzymes are constitutively active and remain associatedwith inside-out membrane patches for many minutes after excision,consistent with a relatively stable multimolecular complex includingCNG channels, PTKs, and PTPs. Similar complexes between ionchannels, protein kinases, and protein phosphatases have beenshown for several other channels (Levitan 1999) and may be therule rather than the exception.

We have probed the interaction between the rod CNG channel andthe oocyte PTK using the tyrosine kinase inhibitor genistein(Molokanova et al. 1999a). In addition to preventing PTK-catalyzedchanges in cGMP sensitivity when ATP is present, genistein alsoinhibits channel gating in the absence of ATP. Thus, genisteincan inhibit CNG channels even when the PTK is catalyticallyinactive. The simplest possible explanation would involve directbinding of genistein to the channel. However, genistein inhibitioncan be suppressed by agents that have no direct effect on CNGchannels, but that do inhibit PTKs. Erbstatin, a noncompetitiveinhibitor of the ATP binding site on PTKs (Imoto et al. 1987),noncompetitively prevents genistein inhibition. Adenylylimidodiphosphate(AMP-PNP), a nonhydrolyzable ATP analogue that competitivelyinhibits PTKs (Akiyama et al. 1987), competitively inhibitsgenistein inhibition. These results and other observations leadto the conclusion that genistein indirectly influences RET ${alpha}$ channelsby triggering a noncatalytic interaction between oocyte PTKsand the channel that allosterically inhibits channel gating.

Are native CNG channels in sensory cells, like CNG channelsexpressed in oocytes, associated with PTKs? Our recent workshows that CNG channels in rod outer segments are subject tomodulation by changes in tyrosine phosphorylation, the finalstep in a biochemical cascade in which neuromodulators can alterthe rod light response (Savchenko, Kraft, Molokanova, Kramer,manuscript in preparation). Since genistein has been usefulin probing the interaction between the cloned RET ${alpha}$ channel andoocyte PTKs, we asked whether genistein would reveal a similarinteraction between native CNG channels and PTKs in sensorycells, namely rods, cones, and olfactory receptor neurons.

Both the native rod and olfactory CNG channels are heteromerscontaining ${alpha}$ and β subunits (Bradley et al. 1994; Chen etal. 1994, Liman and Buck 1994; Koerschen et al. 1995), namedRET ${alpha}$ and RETβ in rods and OLF ${alpha}$ and OLFβ in olfactoryneurons. Exogenous expression of ${alpha}$ subunits alone generates functionalCNG channels in oocytes. In contrast, β subunits do notform functional channels when expressed alone. However, coexpressionof ${alpha}$ and β subunits yields channels with properties thatmore closely resemble native rod and olfactory channels. Tobetter understand how ${alpha}$ and β subunits of CNG channels interactwith PTKs, we compared the effects of genistein on native, clonedhomomeric, and cloned heteromeric channels. Our results suggestthat all three native CNG channels (rod, cone, and olfactory)are indeed associated with PTKs. However, for the rod channel,the ${alpha}$ subunit is crucial for allowing interaction with the PTK,whereas in the olfactory CNG channel, the β subunit iscrucial.

MATERIALS AND METHODS

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Recording from Native CNG Channels
Water-phase tiger salamanders (Ambystoma tigrinum) maintainedin a temperature-controlled aquarium (4°C) on a 12/12 light/darkcycle were used in experiments at the same time of day. Animalswere dark-adapted for 1 h and anesthetized in an ice-cold solutioncontaining 1 g/liter of 2-amino benzoic acid for 20 min beforedecapitation and removal of eyes under dim red light. Eyes wereplaced in physiological saline containing (mM): 155 NaCl, 2.5KCl, 1 CaCl₂, 2 MgCl₂, 10 glucose, and 10 HEPES, pH 7.5. Retinaswere removed and gently triturated to yield isolated rods, cones,or rod outer segments. Borosilicate glass pipettes (3–5M ${Omega}$ ) were filled with standard patch solution containing (mM):115 NaCl, 5 EGTA, 1 EDTA, and 5 HEPES, pH 7.5 with NaOH, andwere used to obtain excised inside-out patches from outer segmentsof rods and cones.

Olfactory receptor neurons were acutely dissociated from theolfactory epithelium of land-phase tiger salamanders. Afterdissection, the epithelium was placed for 18–22 min at21°C in a tube containing 3 ml of physiological solution[(mM)148 NaCl, 4 KCl, 1.5 CaCl₂, 2 MgCl₂, 10 glucose, 10 HEPES,pH 7.4] containing 48 µl of cysteine-activated papain(Worthington Pharmaceuticals). The tissue was then continuouslywashed for 10 min in ice cold papain-free solution and gentlytriturated to isolate individual olfactory receptor neurons.Patch pipettes with resistances of 10–20 M ${Omega}$ were used forobtaining excised patches. Pipettes were filled with a solutioncontaining (mM): 150 NaCl, 4 KCl, 5 EGTA, 0.2 MgCl₂, 10 glucose,10 HEPES, pH 7.4. This also served as the bath solution andcGMP perfusion solution for experiments on olfactory neurons.

Expression and Recording from CNG Channels Expressed in Xenopus Oocytes
To generate homomeric channels, a cDNA clone encoding the ${alpha}$ subunitsof the bovine rod photoreceptor CNG channel (Kaupp et al. 1989)or the rat olfactory CNG channels (Dhallan et al. 1992) wereused for in vitro transcription of mRNA, which was injectedinto Xenopus oocytes (50 nl per oocyte at 1 ng/nl). After 2–7d, the vitelline membrane was removed from injected oocytes,which were then placed in a chamber for patch-clamp recordingat 21–24°C. Glass-patch pipettes (2–3 M ${Omega}$ ) werefilled with standard patch solution, which also served as thestandard bath solution and cGMP perfusion solution. After formationof a gigaohm seal, inside-out patches were excised and the patchpipette was quickly (<30 s) placed in the outlet of a 1-mmdiameter tube for application of cGMP and other agents. We useda perfusion manifold containing up to eight different solutionscapable of solution changes within 50 ms. Most patches contained100–200 channels.

To generate heteromeric RET ${alpha}$ +β channels, mRNA encoding RET ${alpha}$ and RETβ (Koerschen et al. 1995) were coinjected into oocytes.The presence of heteromers in excised patches was confirmedby application of saturating (2 mM) cGMP in conjunction with10 µM L-cis diltiazem, which selectively blocks channelscontaining β subunits, but is ineffective at blocking homomericRET ${alpha}$ channels (Chen et al. 1993). Injection of a 1:8 (n = 6)or 1:10 (n = 14) ratio of RET ${alpha}$ to RETβ mRNA produced channelsthat were inhibited 78 and 80%, respectively, by 10 µML-cis diltiazem. In contrast, a 1:5 ratio generated channelsinhibited by 50%, suggesting that a RET ${alpha}$ :RETβ mRNA ratioof 1:10 is sufficient to saturate the RETβ contributionto heteromeric channels, consistent with previous results (Shammatand Gordon 1999). For expression of OLF ${alpha}$ +β heteromeric channels,OLF ${alpha}$ and OLFβ (Liman and Buck 1994) mRNAs were injectedat a ratio of 4:1, previously reported to saturate the contributionof OLFβ to olfactory heteromeric channels (Shapiro andZagotta 1998). In agreement with these earlier results, we foundthat injection of this ratio of mRNAs generated channels withincreased sensitivity to cAMP as compared with homomeric OLF ${alpha}$ channels [K_1/2 of 9.9 ± 0.8 µM (n = 11) and 130± 9 µM (n = 12), respectively].

For expression of hybrid OLF ${alpha}$ +RETβ channels, mRNAs encodingthe two subunits were co-injected into oocytes. The presenceof RETβ in hybrid channels was confirmed by applying 10µM L-cis diltiazem (Finn et al. 1998). This inhibitorblocked channels resulting from OLF ${alpha}$ to RETβ mRNA-injectionratios of 1:1.5 and 1:3 by 36.8 ± 2.9% (n = 3) and 32.8± 1.4% (n = 6), respectively. These results suggest thata OLF ${alpha}$ to RETβ injection ratio of 1:3 is sufficient to saturatethe contribution of RETβ to hybrid channels.

Analysis of Genistein Inhibition
Genistein and erbstatin (stable analogue) were purchased fromAlexis Corp. and were prepared as concentrated stock solutionsin DMSO. Aqueous solutions containing the final concentrationswere prepared for use as needed. The final concentration ofDMSO did not exceed 0.1%, which had no effect on CNG channelsor their modulation. Cyclic GMP and AMP-PNP were purchased fromSigma Chemical Co. Current responses through CNG channels wereobtained with an Axopatch 200A patch clamp (Axon Instruments,Inc.), digitized, stored, and later analyzed using pClamp 6.0software. Membrane potential was held at –75 mV in allexperiments. Current responses were normalized to the maximalCNG current (I_max), elicited by saturating (2 mM) cGMP. To estimatethe K_i for genistein, we used a modified Hill equation: I_b/I_max= [1 – (I_b(max)/I_max)]/[1 + (K_i/B)ⁿ] + I_b(max)/I_max, whereB is the concentration of blocker, I_b and I_b(max) are the currentsactivated by saturating cGMP in the presence of a given blockerconcentration, and a saturating blocker concentration, respectively.Genistein inhibition of closed and fully activated channelswas analyzed as described previously (Molokanova et al. 1999a).Variability among measurements is expressed as mean ±SEM.

RESULTS

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Genistein Inhibition of Native CNG Channels
Application of genistein on expressed homomeric rod channels(RET ${alpha}$ ) stabilizes the closed state of the channel, such thatpreapplication of genistein slows activation upon exposure tocGMP (Molokanova et al. 1999a). Fig. 1 shows that genisteinhas a similar effect on native channels in patches excised fromsalamander rod outer segments. Without genistein, saturatingcGMP (2 mM) rapidly activates CNG current (Fig. 1 A). However,if the channels are pretreated with genistein (Fig. 1 B), afraction of the CNG current activates very slowly ( ${tau}$ = 8.5 s),while the residual current activates over the normal rapid timecourse ( ${tau}$ = 20 ms). By examining these two components with differentconcentrations of genistein, we previously showed that the slowlyactivating current reflects channels inhibited by genistein,whereas the residual current reflects channels that are unaffectedby genistein. Genistein also inhibits channels after they havebeen maximally activated by saturating cGMP (Fig. 1 C), butthe extent of inhibition is less than for closed channels. Hence,genistein more effectively inhibits closed than open rod channels,as was observed previously for the expressed RET ${alpha}$ channel.

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Figure 1 Effect of genistein on native rod CNG channels. (A) Activation of CNG channels by saturating cGMP without genistein. (B) Effect of genistein on closed channels. Response to saturating cGMP after pre-exposure to 100 µM genistein for 1 min. The broken line distinguishes the slowly activating current component inhibited by genistein and the rapidly activating residual current. (C) Effect of 100 µM genistein on fully activated channels, indicated by the broken line.

Genistein inhibition of the expressed RET ${alpha}$ channel is suppressedby coapplication of PTK inhibitors that have no direct effectson CNG channels (Molokanova et al. 1999a

). These include AMP-PNP,a nonhydrolyzable ATP analogue that competes with genisteinfor the ATP binding site on PTKs, and erbstatin, a noncompetitiveinhibitor of PTKs with respect to genistein. Fig. 2 shows thatboth AMP-PNP and erbstatin also reduce genistein inhibitionof the native rod channels. Thus, genistein inhibition of bothclosed (Fig. 2 A) and fully activated (B) native rod CNG channelsis markedly reduced by coapplication of AMP-PNP or erbstatin.AMP-PNP and erbstatin have no effect on the kinetics, cGMP sensitivity,or maximal current in the absence of genistein (n = 4). Theobservation that genistein inhibition is suppressed by two knownPTK inhibitors that have no direct effect on the rod channelstrongly suggests that, as in oocytes, genistein inhibits thenative rod channel indirectly, by first binding to a PTK.

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Figure 2 PTK inhibitors reduce the genistein inhibition. (A) Inhibition of closed rod photoreceptor CNG channels by 1 min pre-exposure to 100 µM genistein alone or together with PTK inhibitors (500 µM AMP-PNP or 100 µM erbstatin). Closed channels were activated by application of 2 mM cGMP (control). (B) Inhibition of fully activated channels by genistein alone or together with PTK inhibitors.

Native CNG channels differ in their sensitivity to genisteininhibition (Fig. 3). Genistein has a much larger effect on CNGchannels from rods and cones than on channels from olfactoryreceptor neurons. Maximal inhibition of closed channels by saturatingconcentrations of genistein (500 µM) was 61 ± 8%(n = 9) for rod, 50 ± 3% (n = 8) for cone, and 28 ±4% (n = 5) for olfactory channels (Fig. 3 A). As observed inhomomeric RET ${alpha}$ channels, genistein was less effective at inhibitingfully activated channels (Fig. 3 B) [inhibition of 31 ±4% (n = 5) for rod, 37 ± 3% (n = 4) for cone, and 11± 4% (n = 3) for olfactory channels]. Moreover, for rodand cone CNG channels, fully activated channels had a higherapparent K_i for genistein than did closed channels (Fig. 3 C),again consistent with previous observations. For olfactory CNGchannels, K_i values for genistein inhibition of closed and openchannels were not significantly different. Not only did genisteinhave a smaller maximal effect on olfactory channels, but theapparent K_i for genistein was also higher than values for channelsfrom rods or cones (Fig. 3 C).

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Figure 3 Comparison of genistein inhibition of native CNG channels. Dose-inhibition curves of the effect of genistein on native closed (A) and fully activated (B) CNG channels from rod and cone outer segments and olfactory receptor neurons. Continuous curves in A and B show fits of the data to the Hill equation (see MATERIALS AND METHODS). (C) Bar graph showing K_i values for genistein inhibition of closed and activated channels from rods, cones, and olfactory neurons. Data represents mean ± SEM for all of the individual experiments included in A and B.

Role of RET ${alpha}$ and RETβ Subunits in Genistein Inhibition of Rod CNG Channels
While inhibition of native rod channels is qualitatively similarto that of expressed homomeric RET ${alpha}$ channels, there are strikingquantitative differences. Thus, saturating genistein can completelysuppress activation of closed RET ${alpha}$ channels (inhibition of 98± 5%; n = 20), whereas activation of native channelsis maximally reduced by only 61 ± 8% (n = 9). Fig. 4shows that the RETβ subunit almost entirely accounts forthis difference. Thus, heteromeric RET ${alpha}$ +β channels behavein a manner very similar to native rod channels, with channelsin their closed state exhibiting a maximal genistein inhibitionof 53 ± 5% (n = 10) (Fig. 4 A). Moreover, the apparentK_i of heteromeric RET ${alpha}$ +β channels was 20 µM, a valuemuch higher than for homomeric RET ${alpha}$ channels (4 µM), butsimilar to that for native rod channels (19 µM) (Fig. 4B). The Hill coefficient also differs for native rod CNG channels( $~$ 1) and homomeric RET ${alpha}$ channels ( $~$ 2), but the value for heteromericRET ${alpha}$ +β channels ( $~$ 2) is indistinguishable from that for nativechannels.

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Figure 4 Subunit dependence of genistein inhibition of closed rod CNG channels. (A) Dose-inhibition curves for genistein effect on closed native rod, homomeric RET ${alpha}$ , and heteromeric RET ${alpha}$ +β channels. (B) Bar graph showing K_i and Hill coefficient values for genistein inhibition curves. Data represents mean ± SEM for all individual experiments included in A.

The same is true of rod channels in their open state. Genisteininhibition of native rod channels more closely resembles inhibitionof heteromeric RET ${alpha}$ +β than of homomeric RET ${alpha}$ channels (Fig. 5A). In the presence of saturating cGMP (2 mM), genistein inhibitsnative, homomeric RET ${alpha}$ , and heteromeric RET ${alpha}$ +β channels by31 ± 4% (n = 5), 67 ± 4% (n = 18), and 37 ±3% (n = 9), respectively. Fig. 5 B shows that K_i values forgenistein on fully activated channels was $~$ 51 µM for native,82 µM for RET ${alpha}$ , and 53 µM for RET ${alpha}$ +β. The Hillcoefficient was similar for inhibition of each of the open channels,with values near 1 for each. However, while the Hill coefficientsfor inhibition of native and heteromeric RET ${alpha}$ +β are thesame for open and closed channels ( $~$ 1 for each), for homomericRET ${alpha}$ channels, the Hill coefficient changes from 2 when the channelsare closed to 1 when the channels are fully activated.

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Figure 5 Subunit dependence of genistein inhibition of fully activated rod CNG channels. (A) Dose-inhibition curves for genistein effect on native and homomeric RET ${alpha}$ , and heteromeric RET ${alpha}$ +β channels. All channels were fully activated with saturating (2 mM) cGMP before genistein application. (B) Bar graph showing K_i and Hill coefficient values for genistein inhibition curves. Data represents mean ± SEM for all individual experiments included in A.

The β subunit also accounts for differences in the kineticsof genistein inhibition. Genistein inhibition of open nativerod channels is relatively fast, with a time constant of 1.2s for fully activated channels (see Fig. 1 C). In contrast,the time course of genistein inhibition of open homomeric RET ${alpha}$ channels is much slower (Fig. 6 A), with a time constant of9 s. The kinetics of inhibition of heteromeric RET ${alpha}$ +β channels(Fig. 6 B) are similar to that of native channels with a timeconstant of $~$ 1 s. The kinetics of genistein inhibition are similarat a range of genistein concentrations from 25 to 1,000 µM.This suggests that the rate-limiting step in inhibition is notgenistein binding, but rather the interaction between the PTKand channel subunits.

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Figure 6 Kinetics of inhibition of fully activated homomeric RET ${alpha}$ (A) and heteromeric RET ${alpha}$ +β (B) channels by various concentrations of genistein.

Role of OLF ${alpha}$ and OLFβ Subunits in Genistein Inhibition of Olfactory CNG Channels
Like rod CNG channels, native olfactory CNG channels are heteromerscontaining OLF ${alpha}$ and OLFβ subunits, in addition to a splicevariant of the RETβ subunit (Sautter et al. 1998

; Bonigket al. 1999

). To determine whether OLF ${alpha}$ , like RET ${alpha}$ , is the primarytarget for genistein inhibition, we examined the effect of genisteinon homomeric OLF ${alpha}$ channels. Fig. 7 shows that genistein failsto inhibit both closed (A) and fully activated (B) OLF ${alpha}$ channels,at concentrations up to 500 µM (n = 4). In contrast, heteromericchannels, formed by coexpressing OLF ${alpha}$ and OLFβ subunitswere inhibited to an even greater extent than were native olfactorychannels.

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Figure 7 Subunit dependence of genistein inhibition of olfactory CNG channels. Dose-inhibition curves for genistein effect on closed (A) and fully activated (B) native (n = 3–5), homomeric OLF ${alpha}$ (n = 4), and heteromeric OLF ${alpha}$ +β (n = 6) channels.

Studies on hybrid RET+OLF channels
The observation that OLFβ is necessary for genistein inhibitionsuggests that the PTK responsible for indirectly conferringgenistein sensitivity can selectively associate with OLFβ,rather than with OLF ${alpha}$ subunits. Do the two RET subunits, RET ${alpha}$ and RETβ, also differ in their ability to interact withthe PTK and confer genistein inhibition? To address this question,we took advantage of the observation that OLF ${alpha}$ is apparentlyunable to interact with the PTK. If RETβ can interact withthe PTK, one might expect that hybrid heteromeric channels (OLF ${alpha}$ +RETβ)generated by coexpressing OLF ${alpha}$ with RETβ would be subjectto genistein inhibition. Expression of such hybrid channelswas confirmed by examining their sensitivity to L-cis diltiazem,which has a heightened affinity for blocking channels that containthe RETβ subunit. Fig. 8 shows that genistein has no effecton these hybrid channels, strongly suggesting that the RETβsubunit does not bind to the PTK responsible for genistein inhibition.Hence we propose that genistein inhibition of rod CNG channelsis mediated selectively by the interaction between the PTK andthe RET ${alpha}$ subunit.

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Figure 8 Summary data for genistein inhibition of various expressed homomeric and heteromeric channels in closed (A) and fully activated (B) states. n = 5–8 for each channel type.

	DISCUSSION

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Multimolecular Complexes between CNG Channels and PTKs
There is a growing realization that ion channels do not existin isolation, but rather coexist with other proteins in macromolecularcomplexes. Protein partners of ion channels include cytoskeletalcomponents, anchored via PDZ and other domains (Sheng and Wyszynski1997

) and regulatory enzymes, such as protein kinases and phosphatases(Levitan 1999

). Biochemical evidence for such regulatory complexesincludes copurification or coimmunoprecipitation of variouskinases and phosphatases, including PTKs and PTPs, with ionchannels (Rehm et al. 1989

; Holmes et al. 1996

; Yu et al. 1997

;Tsai et al. 1999

). Electrophysiological evidence for regulatorycomplexes comes from the ability of ATP to modulate channelgating after isolation from the cytoplasmic environment, eitherby excising membrane patches or by reconstituting the channelsin artificial lipid bilayers. Moreover, modulation can be preventedby application of specific inhibitors of kinases and/or phosphatases(Biefeld and Jackson 1994

; Reinhart and Levitan 1995

; Molokanovaet al. 1997

; Wilson et al. 1998

). These studies suggest thatchannels, kinases, and phosphatases are often involved in anintimate, rather than just a casual relationship.

Our studies strongly suggest that CNG channels are part of aregulatory complex that contains PTKs and PTPs. The cGMP sensitivityof homomeric RET ${alpha}$ channels expressed in Xenopus oocytes increasesafter patch excision, owing to tyrosine dephosphorylation byPTPs (Molokanova et al. 1997). Conversely, application of ATPdecreases cGMP sensitivity, owing to tyrosine phosphorylationby PTKs. The observation that modulation can be elicited repeatedlywithout decrement, even many minutes after patch excision andsuperfusion, suggests that the PTKs and PTPs responsible formodulation are tightly associated with RET ${alpha}$ channels.

Application of PTP and PTK inhibitors to intact rods shows thatthe sensitivity of native rod CNG channels is also modulatedby changes in tyrosine phosphorylation (Molokanova et al. 1997).However, we have found that in the absence of Ca²⁺, CNG channelsin excised patches from rod outer segments do not exhibit spontaneouschanges in cGMP sensitivity and are unaffected by ATP application.In recent studies, we find that extrinsic growth factors, suchas IGF-1, can trigger changes in cGMP sensitivity by initiatinga cascade that ultimately activates PTPs in rods (Savchenko,Kraft, Molokanova, Kramer, manuscript in preparation). Henceit has been unclear whether the native rod CNG channels aretightly, or only loosely, associated with PTKs and PTPs.

We have used the PTK inhibitor genistein to probe the interactionbetween PTKs and CNG channels. In previous studies (Molokanovaet al. 1999a), we showed that genistein inhibits gating of expressedRET ${alpha}$ channels even in the absence of ATP, indicating that theinhibition does not require catalytic activity of PTKs. However,the genistein effect was suppressed by PTK inhibitors that donot directly interact with CNG channels (AMP-PNP and erbstatin),strongly suggesting that genistein does not directly bind tothe channel, but rather affects channel gating indirectly bybinding to a PTK. From these studies, we concluded that thePTK can allosterically influence channel gating even withoutcatalyzing phosphorylation. In this paper, we find characteristicsof genistein inhibition of native rod CNG channels that areentirely consistent with our previous results on expressed channels,supporting the notion that a similar macromolecular complex,including at least CNG channels and a PTK, must exist in rodouter segments. Since we observe at least some degree of genisteininhibition not only in rods, but also in cones and olfactoryneurons, CNG channels in all of these sensory cells may occurin macromolecular complexes with PTKs. The placement of regulatoryenzymes, such as PTKs and PTPs, in close apposition with substrateproteins, such as CNG channels, may be important for efficientand rapid signaling. We suggest that, in rods, a complex ofCNG channels, PTKs, and perhaps PTPs may be part of a larger"transducisome," also containing other proteins involved inphototransduction (Koerschen et al. 1999).

Role of ${alpha}$ and β Subunits in Genistein Inhibition
Since homomeric RET ${alpha}$ channels are strongly inhibited by genistein,it appears that the RET ${alpha}$ subunit alone is sufficient for bindingthe PTK. For heteromeric RET ${alpha}$ +β channels, genistein hasa lower apparent affinity, smaller maximal effect, and a smallerHill coefficient for inhibition of closed channels. These observationsare consistent with the possibility that genistein inhibitionof RET ${alpha}$ +β channels is solely mediated by interaction betweenthe PTK and the RET ${alpha}$ subunit, with the RETβ subunit unableto bind. However, it also possible that the PTK binds to bothsubunits, but in the context of the heteromeric RET ${alpha}$ +β channel,binding of the PTK to each subunit is less favorable. The observationthat genistein has no effect on hybrid OLF ${alpha}$ +RETβ channelshelps distinguish between these possibilities. Thus, the RETβsubunit is unable to confer genistein sensitivity when coexpressedwith OLF ${alpha}$ subunits, which by itself is insensitive. The OLFβsubunit does confer genistein sensitivity when coexpressed withOLF ${alpha}$ , indicating that OLF ${alpha}$ is not simply "dominant negative" forgenistein inhibition. Hence, we conclude that genistein inhibitionof rod channels is exclusively mediated by an interaction betweenthe PTK and the RET ${alpha}$ subunit. The RETβ subunit does appearto alter the kinetics of this interaction (Fig. 6), perhapsthrough an allosteric influence on RET ${alpha}$ subunits.

The situation is different for olfactory CNG channels. HomomericOLF ${alpha}$ channels are unaffected by genistein, whereas heteromericOLF ${alpha}$ +β channels are inhibited, suggesting that the OLFβsubunit, rather than the OLF ${alpha}$ , interacts with the PTK. Hence,whereas the ${alpha}$ subunit interacts with the PTK in rod CNG channels,the β subunit interacts with the PTK in olfactory CNG channels.It should be noted that the nomenclature of CNG channel subunits( ${alpha}$ vs. β) is not based on sequence homology, but ratheris based on the chronology of subunit cloning, such that thefirst cloned subunits were named " ${alpha}$ " and the second named "β."In fact, the two subunits that are unable to interact with thePTK (OLF ${alpha}$ and RETβ) share a homologous domain in the NH₂terminus that enables these subunits to interact with Ca²⁺/calmodulin(Chen et al. 1994; Liu et al. 1994). It remains to be determinedwhether this region somehow inhibits PTK binding to these subunits,rendering them genistein insensitive. It also remains to bedetermined whether the RET ${alpha}$ and OLFβ subunits share regionsthat allow interaction with the PTK, enabling genistein inhibition.In addition, it should be noted that native olfactory CNG channelsappear to contain not only OLF ${alpha}$ and OLFβ subunits, but alsoa splice variant of the RETβ subunit (Sautter et al. 1998;Bonigk et al. 1999). In our expressed heteromeric OLF ${alpha}$ +βchannels (Fig. 8), the lack of RETβ subunit, which apparentlydoes not bind PTK, may account for the greater degree of genisteininhibition as compared with native olfactory channels.

Stoichiometry of Interactions between PTKs and CNG Channel Subunits
Fig. 9 A presents one possible mechanism for how PTKs mightinteract with the subunits of CNG channels. The Hill coefficientfor genistein inhibition of closed homomeric RET ${alpha}$ channels is2. If this accurately reflects the number of genistein bindingsites, it would suggest that two PTKs are involved in channelinhibition. Since the homomeric channel contains four identicalsubunits, it is possible that each PTK simultaneously interactswith two neighboring subunits (Fig. 9 A, left). Many receptor-typePTKs, such as growth factor receptors, either contain repeatingdomains or are dimeric proteins (Fantl et al. 1993), providinga possible structural basis for PTK binding to identical siteson adjacent channel subunits. However, it is possible that theHill coefficient underestimates the number of genistein bindingsites. Thus, more than two PTKs (e.g., four PTKs) may underliegenistein inhibition, with each subunit individually inhibitedby its own enzyme. To illustrate the uncertainty in the numberof PTKs involved (two or four), the illustrated PTKs are dividedin half with a dotted line.

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Figure 9 Schematic diagram of genistein inhibition. Homomeric and heteromeric RET and OLF channels and their interactions with PTKs, symbolized with the shaded crescent symbol. Genistein (G) is depicted bound to the PTK. In the closed state of the homomeric RET ${alpha}$ channel (A), two PTKs, and thus two genistein molecules, are required to completely inhibit the channel. cGMP triggers channel opening, which functionally dimerizes RET ${alpha}$ subunits. With the PTK spanning two functional dimers, only one PTK, and therefore one genistein, is sufficient to inhibit the channel, although two are still able to bind. In addition, the affinity of the closed channel for the PTK is higher than for the open channel, hence a tighter fit between the channel and the PTK symbol is depicted for the closed channel. For the RET ${alpha}$ +β channel (B), only the RET ${alpha}$ binds the PTK. Hence there is no change in the number of PTK required to blocked the closed and open channels. The homomeric OLF ${alpha}$ channel (C) is unaffected by genistein because OLF ${alpha}$ subunits do not contain PTK binding sites. The heteromeric OLF ${alpha}$ +OLFβ (D) channel binds one PTK, via the binding sites on the OLFβ subunits.

What accounts for the curious decrease in the value of the Hillcoefficient from two to one as RET ${alpha}$ channels go from closed toopen during activation? Recent studies suggest that rather thanacting independently or in a completely concerted manner, thefour subunits of some CNG channels may function as a pair ofindependent dimers. Thus, for each functional dimer, the twoparticipating channel subunits cooperatively bind cyclic nucleotideand activate in a concerted manner (Liu et al. 1998

; Shammatand Gordon 1999

). We propose that functional dimerization ofRET ${alpha}$ subunits is dependent on binding of cyclic nucleotide. Hence,whereas all the RET ${alpha}$ subunits are equivalent when the channelis closed, cGMP binding and/or channel opening triggers associationof adjacent channel subunits, allowing them to function as adimer. The minimal number of genistein molecules required toinhibit a channel containing such a pair of functional dimersis 1. This assumes that the PTK preferentially interacts "perpendicularly"with respect to the functional dimers; that is, by binding toRET ${alpha}$ subunits on two distinct functional dimers (Fig. 9 A, right).Since the PTK can bind to the channels in their closed state,binding of the PTK to two adjacent RET ${alpha}$ subunits may actuallydetermine which RET ${alpha}$ subunits functionally dimerize, namely theRET ${alpha}$ subunits that are not already joined by a PTK. In this scenario,PTK-dependent subunit linkage between subunits and cGMP-dependentfunctional dimerization are mutually exclusive.

In the heteromeric RET ${alpha}$ +β channel (Fig. 9 B), only the RET ${alpha}$ subunits are capable of binding the PTK. Hence, if the channelstoichiometry is indeed RET ${alpha}$ ₂, RETβ₂, a single PTK dimercould interact with adjacent RET ${alpha}$ subunits, fully accountingfor genistein inhibition because the RETβ subunits appearto be immune to genistein inhibition. This scenario is consistentwith our observed Hill coefficient for genistein inhibitionof 1, and also accounts for the reduced maximal effect of genistein.Moreover, the proposed subunit arrangement is supported by recentstudies by Shammat and Gordon 1999, who established that ${alpha}$ subunitsin heteromeric RET channels are adjacent rather than diagonallyopposed.

The role of ${alpha}$ and β subunits with respect to genistein inhibitionis reversed in the OLF channel. Homomeric OLF ${alpha}$ channels are unaffectedby genistein, suggesting that the OLF ${alpha}$ subunit cannot interactwith the PTK (Fig. 9 C). However, the OLFβ subunit confersgenistein sensitivity, suggesting that OLFβ subunits containa PTK binding site. The Hill coefficient of heteromeric OLF ${alpha}$ +βchannels is one for both closed and fully activated channels,consistent with PTK spanning two functional dimers via interactionwith two adjacent β subunits (Fig. 9 D).

These diagrams are speculative and are only a starting pointfor considering the stoichiometric relationships between PTKsand subunits of CNG channels. Estimates of stoichiometries basedon Hill coefficients need to be confirmed with more direct biochemicalexperiments. Various factors, including heterogeneous populationsof channels (Ruiz et al. 1999) and positive or negative cooperativitybetween channel subunits could alter Hill coefficients, leadingto an over or under estimate of the number of receptor sites.

Differences in the ability of ${alpha}$ and β subunits of rod andolfactory CNG channels to interact with PTKs has implicationsbeyond genistein inhibition. It is likely that susceptibilityto genistein inhibition is related to a channel's ability tobe modulated by tyrosine phosphorylation. Thus, channels containingonly subunits that are insensitive to genistein (e.g., OLF ${alpha}$ homomers)might be insensitive to neuromodulators that signal throughPTPs or PTKs, whereas channels that contain genistein-sensitivesubunits would be susceptible to such neuromodulators. Biochemicaland electrophysiological studies show that expression of olfactoryCNG channel subunits is especially widespread, in the nervoussystem and elsewhere, but channels in different locations maydiffer in their subunit compositions (Berghard et al. 1996;Wiesner et al. 1998), potentially providing for differentialmodulation by PTKs.

Dr. Savchenko's present address is Affymax Research Institute,Palo Alto, CA 94304.

Abbreviations used in this paper: AMP-PNP, adenylylimidodiphosphate;CNG, cyclic nucleotide-gated; PTK, protein tyrosine kinase;PTP, protein tyrosine phosphatase.

Submitted: 31 December 1999
Revised: 31 March 2000
Accepted: 11 April 2000

   REFERENCES

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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