A Ca2+/Calmodulin-Dependent Protein Kinase Modulates Drosophila Photoreceptor K+ Currents: A Role in Shaping the Photoreceptor Potential

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The Journal of Neuroscience, November 15, 1998, 18(22):9153-9162

A Ca²⁺/Calmodulin-Dependent Protein Kinase Modulates Drosophila Photoreceptor K⁺ Currents: A Role in Shaping the Photoreceptor Potential
Asher Peretz¹^,², Ilane Abitbol¹, Alexander Sobko¹, Chun-Fang Wu², and Bernard Attali¹
¹ Neurobiology Department, Weizmann Institute of Science, Rehovot 76100, Israel, and ² Department of Biological Sciences, University of Iowa, Iowa City, Iowa 52442

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Light activation of Drosophila photoreceptors leads to the generation of a depolarizing receptor potential via opening oftransient receptor potential and transient receptor potential-likecationic channels. Counteracting the light-activated depolarizingcurrent are two voltage-gated K⁺ conductances, I_A and I_K, that are expressed in these sensoryneurons. Here we show that Drosophila photoreceptors I_A and I_Kare regulated by calcium-calmodulin (Ca²⁺/calmodulin) via a Ca²⁺/calmodulin-dependent protein kinase (CaM kinase), with I_K beingfar more sensitive than I_A. Inhibition of Ca²⁺/calmodulin by N-(6 aminohexyl)-5-chloro-1-naphthalenesulfonamideor trifluoperazine markedly reduced the K⁺ current amplitudes. Likewise, inhibition of CaM kinases by KN-93potently depressed I_K and accelerated its C-type inactivationkinetics. The effect of KN-93 was specific because its structurallyrelated but functionally inactive analog KN-92 was totally ineffective.In Drosophila photoreceptor mutant Sh^KS133, which allows isolation of I_K, we demonstrate by current-clamprecording that inhibition of I_K by quinidine or tetraethylammoniumincreased the amplitude of the photoreceptor potential, depressedlight adaptation, and slowed down the termination of the lightresponse. Similar results were obtained when CaM kinases wereblocked by KN-93. These findings place photoreceptor K⁺ channels as an additional target for Ca²⁺/calmodulin and suggest that I_K is well suited to act in concertwith other components of the signaling machinery to sharpen lightresponse termination and fine tune photoreceptor sensitivity duringlightadaptation.

Key words: potassium channels; phototransduction; calmodulin; light adaptation; photoreceptor; CaM kinase; Drosophila

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Phototransduction in vertebrates and invertebrates is a complex signal transduction cascade, based on rhodopsin-G-proteincoupling interactions (Hardie and Minke, 1995; Ranganathan etal., 1995; Baylor, 1996; Minke and Selinger, 1996; Zuker, 1996).The phototransduction process has the capacity to amplify singlephoton events into large electrical signals and to regulate thephotoresponse output in a broad dynamic range. Major advanceshave been made in characterizing the molecular components of phototransductionand the mechanisms of light adaptation and response termination(Baylor, 1996; Minke and Selinger, 1996; Zuker, 1996). However,the modulation of these latter processes is not yet fully understood.The powerful combination of molecular genetics and electrophysiologymakes Drosophila photoreceptors an exquisite preparation for studyingthese processes. In Drosophila, light activation of rhodopsinactivates phospholipase C via G-proteins, which hydrolyzes phosphatidylinositol-4,5-bisphosphateinto inositol trisphosphate (IP₃) and diacylglycerol (DAG). Thisprocess leads within a few tens of milliseconds to the openingof cation-selective channels encoded by the trp and trp-like genes(Hardie and Minke, 1995; Ranganathan et al., 1995; Minke and Selinger,1996). The feedback control of the activation process was recentlyshown to involve calcium-calmodulin (Ca²⁺/calmodulin), which tightly regulates the adaptation and terminationof the light response (Arnon et al., 1997a,b; Scott and Zuker,1997; Scott et al., 1997).

The photoreceptor potential has a complex waveform that arises from the opening of light-activated channels as well as fromvoltage-dependent conductances. Interestingly, Drosophila photoreceptorsare endowed with high densities of voltage-gated K⁺ channels (Hardie, 1991; Hardie et al., 1991). In neurons, K⁺ channels were recognized to regulate action potential duration,firing patterns, and resting membrane potential (Rudy, 1988; Hille,1992). A great diversity of K⁺ channel subtypes appear to underlie these pleiotropic functions(Pongs, 1992; Doupnik et al., 1995; Salkoff and Jegla, 1995; Wickmanand Clapham, 1995; Jan and Jan, 1997). Analysis of Drosophilamutants enabled the initial molecular characterization of severalclasses of K⁺ channels (Kamb et al., 1987; Tempel et al., 1987; Pongs et al.,1988). Four different voltage-sensitive K⁺ channel genes were initially identified in Drosophila: Shakerand Shal, encoding A-type K⁺ currents (I_A), and Shab and Shaw, encoding delayed-rectifierK⁺ currents (I_K) (Salkoff and Wymann, 1981; Wu and Haugland, 1985;Broadie and Bate, 1993; Tsunoda and Salkoff, 1995a,b). Subsequently,other classes of K⁺ channels were characterized molecularly in Drosophila (Warmkeet al., 1991; Goldstein et al., 1996; Titus et al., 1997; Wanget al., 1997).

Drosophila photoreceptors express both I_A and I_K currents, with the former mediated by subunits encoded by the Shaker locus(Hardie, 1991; Hardie et al., 1991). However, the genes encodingthe delayed-rectifier channel subunits have not yet been identified,and very little is known about I_K modulation. Although the functionalsignificance of I_A and I_K remains to be clarified in Drosophilaphototransduction, in Limulus and in the blowfly Calliphora vicinathey may regulate the gain and frequency response during lightand dark adaptation (Fain and Lisman, 1981; Weckstrom et al.,1991). In Drosophila photoreceptors, the sustained depolarizationgenerated by light activation of transient receptor potential(TRP) and transient receptor potential-like (TRPL) cationic channelsis expected to open voltage-gated K⁺ channels. One can predict that the subsequent hyperpolarizingK⁺ currents will oppose the light-induced depolarizing currentsto shape the photoreceptorpotential.

In the present study, we show that Drosophila photoreceptor I_K and I_A channels are positively regulated by Ca²⁺/calmodulin via a Ca²⁺/calmodulin-dependent protein kinase (CaM kinase), with I_K beingmore sensitive than I_A. Using the current-clamp technique, wedemonstrate that inhibition of I_K with K⁺ channel blockers or with a CaM kinase inhibitor increases theamplitude and broadens the transient component of the photoreceptorpotential, weakens adaptation, and slows the termination of thelight response. We suggest that I_K represents an additional calmodulin-sensitivecomponent of Drosophilaphototransduction.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation. Wild-type (WT) Drosophila of the Canton S strain and of Sh^KS133 mutant (both red-eyed) were used for the experiments (Wu andGanetzky, 1992). The Sh^KS133 allele, which eliminates the I_A, is a missense point mutationin the pore-forming H5 region of the Shaker channel protein (Lichtinghagenet al., 1990). Ommatidia dissociated from stage p15 pupae (Bainbridgeand Bownes, 1981) were prepared as described previously (Hardie,1991; Peretz et al., 1994). Retinae were rapidly dissected inCa²⁺/Mg²⁺-free Ringer's solution, transferred to normal Ringer's solutionsupplemented with 10% fetal calf serum and 25 mM sucrose, andgently triturated with a fire-polished glass pipette of ~200-400µm tip diameter. During the dissociation procedure, which requiresno enzyme treatment, the surrounding pigment cells disintegrate,exposing the photoreceptor membrane. The dissection procedurewas performed under dim red light illumination (Schott OG630 filter).Dark-adapted ommatidia were used immediately after dissection,for whole-cell patch-clamprecording.

Electrophysiology. Aliquots (~10 µl) of ommatidia were allowed to settle in a small chamber onto a clean coverslip mountedon the stage of an Axiovert 35 inverted microscope (Carl Zeiss).Recordings were made at 22 ± 1°C, using patch pipettes pulledfrom borosilicate glass capillaries (fiber filled) with resistanceof 4-8 M $Omega$ . Whole-cell recordings were performed using standardtechniques (Hamill et al., 1981; Hardie, 1991; Peretz et al.,1994). In experiments investigating the light response, we appliedthe current-clamp mode of the whole-cell patch-clamp techniquein isolated Drosophila photoreceptors. The resting potential ofthe photoreceptors was adjusted to $-$ 60 mV by applying a constantcurrent. Series resistances were compensated by 85-90%. A tungstenhalogen lamp (20 V, 150 W; Olympus Highlight 3000), attenuatedby neutral density filters (1.5-2.0) via a Uniblitz shutter (VincentAssociates, Rochester, NY), provided illumination of photoreceptors.The peak transmission of the excitation and viewing filters was520 and 630 nm, respectively. Signals were amplified using anAxopatch 200A patch-clamp amplifier (Axon Instruments, FosterCity, CA), filtered below 2 kHz, via a four-pole Bessel filter.Data were sampled at 4-5 kHz and analyzed using pClamp 6.0.2 software(Axon Instruments) on an IBM-compatible 486 computer interfacedwith DigiData 1200 (Axon Instruments). Further data analysis wasperformed using Axograph 3.0 software (Axon Instruments) and Excel5.0 (MicroSoft) on an Apple Macintosh computer. All data wereleakage-subtracted off line by the Clampfit program of the pClampsoftware. Activation and steady-state inactivation data were fittedwith the Boltzmann distribution (assuming a reversal potentialV_K of $-$ 85 mV):

(1)

where V₅₀ is the voltage of half-maximal activation (at which I = 1/2 I_max), or the voltage at which half of the steady-stateinactivation was removed, and s is the slope of the curve. InWT photoreceptors, I_A was measured at the peak, whereas I_K wasmeasured at the end of the trace (~90 msec). All data were expressedas mean ± SEM. Statistically significant differences were assessedby Student's ttest.

Solutions. Bath Ringer's solution contained 120 mM NaCl, 5 mM KCl, 1.5 mM CaCl, 8 mM MgSO₄, and 10 mM N-tris[hydroxymethyl]methyl-2-aminoethanesulfonicacid (TES), pH 7.15. Stock solutions of KN-62, KN-92, and KN-93(Calbiochem, La Jolla, CA) were made in DMSO. N-(6 aminohexyl)-5-chloro-1-naphthalenesulfonamide(W7), trifluoperazine (TFP) TEA-Tetraethyfammonium, and quinidine(Sigma, St. Louis, MO) were added to the bath solution at thefinal concentrations indicated in text and figure legends. Thepipette solution contained 135 mM potassium gluconate, 2 mM MgCl,4 mM Mg-ATP, 0.5 mM Na-GTP, and 10 mM TES, pH 7.15.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Activation and inactivation characteristics of I_K and I_A in Drosophila photoreceptors

The whole-cell configuration of the patch-clamp technique (Hamill et al., 1981) was used to study the modulation of K⁺ currents in dissociated Drosophila ommatidia. As shown in Figure1, wild-type Drosophila photoreceptors are endowed with two mainvoltage-gated K⁺ conductances, the rapidly activating/inactivating I_A and theslowly inactivating I_K currents (Hardie, 1991). The delayed-rectifierI_K current has previously been shown to be composed of two kineticallydifferent components, I_Kf and I_Ks (Hardie, 1991). Using our activationprotocol (Fig. 1), we were unable to discriminate accurately betweenthese two I_K components, mainly because of the kinetic overlapof the various voltage-dependent rise times of activation. Wecould distinguish two different kinetic components of I_K in themutant allele Shaker KS133 (Sh^KS133) subjected to steady-state inactivation, when photoreceptor cellswere treated with CaM kinase inhibitors (in five of eight cells;see below and Fig. 5). However, for the sake of clarity we haveconsidered the delayed-rectifier K⁺ current as one I_K component, distinguishable from the I_A current.Representative traces are shown in Figure 1A (left). IsolatedI_K measurement was achieved by using the Sh^KS133 mutation, which eliminates I_A (Fig. 1B, left). Sh^KS133 is a missense point mutation in the H5 pore-forming region ofthe Shaker channel protein (Lichtinghagen et al., 1990). I_K wasalso measured in WT photoreceptors at the end of depolarizingpulses (~90 msec) after I_A has inactivated. The normalized current-voltage(I-V) relation of I_K as measured in WT or in Sh^KS133 photoreceptors showed that I_K activated above $-$ 40 mV and saturatedat potentials greater than +50 mV (Fig. 1C, left). In Sh^KS133, the normalized conductance during I_K activation was describedby a single Boltzmann function with V₅₀ = +12.5 ± 4.7 mV, slope= $-$ 12.3 ± 0.9 mV (n = 5) (Fig. 2; see Table 2). A slight negativeshift in the I_K current-voltage relation and normalized conductancecurves measured in WT was seen when compared with those measuredin Sh^KS133 (Figs. 1C, 2C,D). This could result from incomplete inactivationof I_A in WT at the end of the depolarizing pulse, although a majorpart of I_A inactivated in our protocol. Alternatively, there couldbe a modulation of I_K activity attributable to developmental hyperexcitabilityof the Sh^KS133 photoreceptors. Along this line, we found that I_K amplitude inSh^KS133 tends to be slightly higher than that measured in WT (Tables1, 3). Such compensatory mechanisms are observed sometimes intransgenic knock-out mice.

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Figure 1. Activation and inactivation characteristics of I_A and I_K in Drosophila photoreceptors. A, Representative wild-type (WT) whole-cell recordings of photoreceptor potassium currents using the activation (left) and inactivation (right) protocols. Usually, we can clearly differentiate the inactivating I_A component (arrowheads) separated from the slowly inactivating I_K. B, Representative whole-cell recordings of activation (left) and inactivation (right) protocols of the Shaker mutant allele Sh^KS133. C (left), The current density (pA/pF) is plotted against the voltage steps for WT () and Sh^KS133 ( $black-square$ ). The I_K component is characterized (Boltzmann fitting, assuming a reversal potential V_K = $-$ 85 mV) by I_max = 85.5 ± 4.1 pA/pF and 87.8 ± 5.6 pA/pF for WT (n = 11) and Sh^KS133 (n = 8), respectively. Right, Steady-state inactivation of I_K in WT () and Sh^KS133 ( $black-square$ ). For Boltzmann fitting parameters, see Table 2. D (left), The current density/voltage curve of I_A is presented (Table 1). I_A is characterized (Boltzmann fitting, measured at peak outward current, assuming a reversal potential V_K = $-$ 85 mV) by I_max = 92.3 ± 7.8 pA/pF (n = 11). Right, The Boltzmann fitting of I_A steady-state inactivation gave the values V₅₀ = $-$ 42.1 ± 1.0 mV and slope = 10.0 ± 0.8 (n = 4). In all voltage-clamp experiments throughout this study, the holding potential was $-$ 100 mV. For the activation protocol, cells were stepped from $-$ 100 mV to +60 mV in 10 mV increments, during a 100 msec test pulse (left column). In the steady-state inactivation protocol, the cell membrane was subjected to inactivating prepulses of 1 sec duration from $-$ 90 mV to +10 mV in 10 mV increments, before 80 msec test pulse to +30 mV (right column).

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Figure 2. Inhibition of the delayed-rectifier current (I_K) by the calmodulin antagonist W7. The activation protocol as in Figure 1 is used to detect the steady-state effect of the calmodulin antagonist W7 on I_K currents. Traces were recorded 3-4 min after drug treatment. A, Whole-cell potassium currents, recorded in WT photoreceptors, were inhibited by W7 in a concentration-dependent manner. In response to 2.5 µM W7, I_K was reduced by >50% (middle), whereas 25 µM W7 almost completely abolished the current (right), as compared with control (left). B, Similar results were obtained in the Sh^KS133 mutant, which lacks the I_A. C, D, The current density/voltage curve for WT (C, left) and Sh^KS133 (D, left) and their corresponding normalized conductance (C, D, middle) are shown for control (), 2.5 µM W7 ( $black-square$ ), and 25 µM W7 ( $bullet$ ) data. The steady-state inactivation protocol was the same as in Figure 1 (right; traces not shown). Because of almost complete inhibition of I_K, no steady-state inactivation curves could be determined after treatment with 25 µM W7. The curves were fitted by the Boltzmann distribution function. For fitting values see Tables 1 and 2.


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Table 1. W7 effect on the I_max in WT and Sh^KS133

As shown in the normalized I-V curve, I_A activated at potentials more negative than those required for I_K, above a thresholdof approximately $-$ 60 mV (Fig. 1D, left). The normalized conductanceof I_A activation was fitted with a single Boltzmann distributionof V₅₀ = $-$ 7.9 ± 2.9 mV and slope = $-$ 13.8 ± 0.3 mV (n = 5) (Fig.3; Table 2). Both currents inactivated in response to a depolarizingprepulse, with the I_A being inactivated at more hyperpolarizedpotentials. The steady-state inactivation of I_A and I_K could bedescribed by a V₅₀ = $-$ 42.1 ± 1.0 mV, slope = 10.0 ± 0.8 (n = 4),and V₅₀ = $-$ 18.9 ± 2.1 mV, slope = 11.0 ± 0.2 (n = 6), respectively(Figs. 1C,D, right, 3, right; Table 2). The V₅₀ values for I_Aactivation and steady-state inactivation of the present work aresignificantly shifted to more depolarized potentials (more than+10 mV) when compared with a recent study on a semi-intact retinapreparation (Hevers and Hardie, 1995). Differences in recordingconditions and solutions may account for these variations.

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Figure 3. The effect of W7 on I_A. The current density/voltage curve (left), their normalized conductance (middle), and the corresponding steady-state inactivation curves (right) are shown for control (), 2.5 µM W7 ( $black-square$ ), and 25 µM W7 ( $bullet$ ) data. Because little effect on I_A was observed in the presence of 2.5 µM W7, only the data obtained with 25 µM W7 were included in the normalized conductance and steady-state inactivation curves. All of the curves were fitted by Boltzmann distributions. For details of the fitting values, see Tables 1 and 2.


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Table 2. Effect of W7 on the steady-state activation and inactivation parameters in WT and Sh^KS133

Ca²⁺/calmodulin-dependent modulation of I_K

In view of the pivotal role played by Ca²⁺/calmodulin in adaptation and termination of the light response (Arnon et al., 1997a,b;Scott et al., 1997), we tested whether photoreceptor I_A and I_Kwould be subjected to modulation by Ca²⁺/calmodulin-dependent processes, and if so, to what extent itwould affect the light response. To examine the possible Ca²⁺/calmodulin-dependent modulation of I_K, we perfused the photoreceptorcells extracellularly with the calmodulin antagonist W7 at twodifferent concentrations. Similar results were obtained usingTFP, another calmodulin antagonist (data not shown). For all experiments,the currents were recorded on the same cell before and after applicationof the drug. Application of 2.5 µM W7 to WT photoreceptor cellsled to a reduction of ~62% of the maximal I_K current density (I_max),whereas exposure of 25 µM W7 produced an almost complete inhibitionof I_K (Fig. 2A,C; Table 1). The onset of W7 action was at ~1-2min, and the effect reached steady state within ~5-7 min. Similarresults were obtained when I_K was reordered in isolation in theSh^KS133 mutant, with 55% inhibition of I_K current density at 2.5 µM W7and an almost complete I_K suppression on exposure to 25 µM W7(Fig. 2B,D; Table 1). The normalized conductance of activationindicated that there was a small negative shift of V₅₀ in thepresence of 2.5 µM W7 (5.6 and 7 mV as measured in WT and Sh^KS133, respectively) (Fig. 2C,D; Table 2). Generally, the steady-stateinactivation properties of I_K did not change significantly inresponse to 2.5 µM W7, as measured either in WT or in Sh^KS133 mutant (Fig. 2C,D; Table 2).

Ca²⁺/calmodulin regulation of I_A

Qualitatively, similar results were obtained for W7 action on I_A, except that the effects on I_max were much weaker. Furthermore,the effect of W7 on I_A might be slightly overestimated becauseof a minor contribution of the I_K rise. At 2.5 µM W7, currentdensity at the peak of I_A was not significantly altered, witha decrease of <10% (Fig. 3; Table 1). At 25 µM W7, maximal I_Awas substantially reduced (by 67%). The voltage dependence ofactivation and steady-state inactivation were significantly affectedby W7. The V₅₀ of I_A activation was negatively shifted from $-$ 7.9± 2.9 mV to $-$ 19.8 ± +1.7 mV (n = 5) in response to 25 µM W7. Inaddition, there was a negative shift of the steady-state inactivationfrom V₅₀ = $-$ 42.1 ± 1.0 mV to V₅₀ = $-$ 48.8 ± 2.5 mV in responseto 25 µM W7 (n = 4) (Fig. 3; Table 2).

A CaM kinase, identified as a calmodulin-dependent modulator of photoreceptor K⁺ channels

The next question we asked was what type of calmodulin-dependent process was involved in the regulation of the photoreceptorK⁺ currents. To examine this issue, we used the specific CaM Kinaseinhibitors KN-93 (Sumi et al., 1991) and KN-62 (Tokumitsu et al.,1990). Only the data of KN-93 are presented here, because essentiallythe same results were obtained with KN-62 (data not shown). Wefocused on the I_K current because it proved to be more sensitiveto W7. For this purpose, we used the Sh^KS133 mutant to exclude any I_A contamination. Although I_K inactivatedvery little in the range of 100 msec (Fig. 1B, left), it underwentC-type inactivation (Hoshi et al., 1990) in a longer stimulationrange (1 sec), and its inactivation could reach >50% (Figs. 4D,5). We measured I_K amplitudes both at the peak and at the endof the pulse (plateau). After exposure to 5 µM KN-93, the amplitudesof the peak and plateau components of I_K were reduced by 62% (from107.1 ± 6.8 pA/pF to 40.7 ± 6.1 pA/pF) and 85% (from 65.7 ± 6.3pA/pF to 10.1 ± 1.2 pA/pF), respectively (n = 6) (Fig. 4A,D, toptraces; Table 3). The effect of KN-93 was very specific becausethe application of its structurally related but functionally inactiveanalog KN-92 (5 µM) did not produce any effect on I_K even afterlonger exposure (>15 min) (Fig. 4D). Furthermore, to exclude thepossibility that KN-93 could act as an open-channel blocker, weused a train protocol. KN-93 inhibition was obtained at the firstpulse (+60 mV) after a 5 min exposure to the drug, and the effectdid not significantly increase further after subsequent stimulations.The onset of KN-93 inhibitory action was at ~2 min after application,and it peaked at ~5-6 min. Because KN-93 was delivered along withthe carrier DMSO at a final concentration of 0.1%, we checkedfor possible effects of the solvent carrier. We found that DMSOalone affected neither I_K nor the light response (data not shown).KN-93 caused a significant change in the voltage dependence ofactivation. The normalized conductance curves indicated a negativeshift of the V₅₀ by 11.5 and 8.7 mV for the peak and plateau components,respectively (Fig. 4B; Table 3). KN-93 also caused the I_K toinactivate at more negative potentials. The V₅₀ of steady-stateinactivation was shifted from $-$ 12.7 ± 0.6 mV to $-$ 22.3 ± 2.4 mV(n = 6) (Fig. 4C; Table 3), an effect not seen in response toW7 treatment (see Discussion).

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Figure 4. Modulation of I_K by the CaM kinase inhibitor KN-93 in the Sh^KS133 mutant. The specific CaM kinase inhibitor KN-93 modulates the peak and plateau components of I_K in the Sh^KS133 mutant. In the experiments, the currents were recorded on the same cell before and after 6 min application of the drug. Except for C, the cells were stepped from $-$ 100 to +60 mV in 10 mV increments, and the peak and plateau currents were measured during the 1 sec pulse. The curves were fitted by a single Boltzmann distribution. Results were obtained from six pupae. A, The current density/voltage curve is shown for control () and in response to 5 µM KN-93 ( $black-square$ ) at the peak (left) and plateau (right) of I_K. B, The normalized conductance curves are shown for the peak (left) and plateau component (right) of I_K. The same symbols were used as in A. For the fitting values, see Table 3. C, The steady-state inactivation curve of I_K is shown. Here the inactivation protocol was the same as in Figure 1. For detailed Boltzmann fitting values see Table 3. D (top traces), Representative example of the KN-93 (5 µM) effect on I_K. From a holding potential of $-$ 100 mV, a step to +60 mV (1 sec) was given before and after (9 min) drug application. Bottom traces, Cell stepped from a holding potential of $-$ 100 to +60 mV (100 msec) before and 10 min after KN-92 treatment (5 µM).


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Table 3. Effect of KN-93 on I_max, normalized conductance and steady-state inactivation of I_K in Sh^KS133

CaM kinase inhibition accelerated I_K inactivation kinetics

It is known that K⁺ channels exhibit two different mechanisms of inactivation, referred to as N- and C-type inactivations (Hoshiet al., 1990; Choi et al., 1991; Yellen et al., 1994). AlthoughN-type inactivation is a fast process involving the occlusionof the inner mouth of the channel pore by the amino terminus (balland chain model), C-type inactivation is a slower process occurringafter prolonged depolarization and involving conformational changesat the external mouth of the pore and the S6 transmembrane domain.As shown in Figure 5, after step depolarization of 1 sec durationfrom $-$ 100 mV to +60 mV, I_K underwent a slow C-type inactivationprocess by >50%. In Figure 5A,B, the traces have been normalizedto compare the kinetics. After 6 min of 5 µM KN-93 applicationon Sh^KS133 photoreceptor cells, I_K decreased in amplitude and inactivatedwith faster kinetics when compared with control (Fig. 5A). Similarresults were obtained with 10 µM W7 application (Fig. 5B). Aftera 5 min W7 washout, there was a partial recovery in terms of bothamplitude and kinetics. Note that neither the deactivation kinetics[as reflected by the tail current decay (Fig. 5A, inset)] northe rising phase of current activation was changed in the presenceof W7 or KN-93 (Fig. 5A, right). I_K inactivation kinetics wasbest fitted with two exponentials. In response to 5 µM KN-93,the decay time constants were significantly reduced from $tau$ ₁ =86 ± 10 msec and $tau$ ₂ = 767 ± 29 msec to $tau$ ₁ = 30 ± 3 msec and $tau$ ₂= 514 ± 34 msec (n = 6, p < 0.005). Regarding the activation kinetics,we have considered the photoreceptor I_K to be one component. Asmentioned earlier, it was suggested by Hardie (1991) that theDrosophila delayed-rectifier currents are composed of two conductances,I_Kf and I_Ks, with fast and slow activation kinetic components.Results consistent with this suggestion were obtained in KN-93-treatedSh^KS133 photoreceptors by using a steady-state inactivation protocol(Fig. 5C). In the control traces, it was difficult to discriminatebetween the two kinetic components (Fig. 5C, left). However, whenphotoreceptor cells (in four of seven cells) were exposed to 5µM KN-93 for 6 min (Fig. 5C, right), it became obvious that afast component was more sensitive to inactivating prepulse potentials,as compared with a slower activating component that inactivatedmore weakly at the same prepulses. Similar results were obtainedwith W7 in seven of eight cells recorded. Nevertheless, it wasdifficult to distinguish between these two components when fittingthe steady-state inactivation curve (Fig. 4C). Thus, it is possiblethat inhibition of CaM kinase affects differently the two kineticcomponents of C-type inactivation, thereby reflecting the existenceof two different I_K conductances. However, we cannot exclude thepossibility that these kinetic components represent differentconformational kinetic transitions of the same channel complex.

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Figure 5. Changes in I_K kinetics in response to W7 and KN-93. Using the Sh^KS133 mutant, photoreceptor cells were stepped from $-$ 100 to +60 mV for 1 sec to allow the C-type inactivation of I_K to occur. A (left), The currents were recorded before (control) and after 6 min application of 5 µM KN-93. Traces have been normalized for kinetic comparison. Right, The same normalized traces are shown at a smaller time scale. Inset, The normalized tail currents are shown. The C-type inactivation kinetics are well described by two exponential fits. In response to 5 µM KN-93, the fast and slow time constants ( $tau$ 1 and $tau$ 2) decreased from 86 ± 10 to 30 ± 03 msec and from 767 ± 29 to 514 ± 34 msec, respectively (n = 6, p < 0.01). B (left), Similar results were obtained in response to 2 min exposure of 10 µM W7, with a partial recovery 5 min after washout of the drug. Right, Another experiment demonstrates the same phenomena at a smaller time scale and higher sampling rate. C, Steady-state inactivation traces, before and 5 min after application of 5 µM KN-93. The same steady-state inactivation protocol was used as in Figure 1.

Inhibition of I_K reduced the light adaptation and delayed the response termination

To test whether photoreceptor K⁺ currents oppose the light-induced depolarizing currents and shape the light response, we investigatedtheir role in phototransduction by pharmacological means usingthe current-clamp technique in isolated photoreceptors of theWT and the Drosophila mutant Sh^KS133, which eliminates I_A. To quantitatively estimate the drug effectson photoreceptor potential waveform, we used the quotient Q₅₀defined as a ratio value (Q₅₀ = T_D/T_C) of the measurements madein the presence (T_D) and absence (T_C) of the drug. T_D and T_C aretemporal parameters (in milliseconds) measuring the width of thelight response at 50% of the maximal receptor potential amplitudeevoked by illumination. First, we studied in WT photoreceptorsthe voltage light response before and after CaM kinase inhibitionby application of 5 µM KN-93 (Fig. 6A). After a 10 msec flashstimulus, KN-93 (6 min preincubation) significantly increasedthe light response amplitude and markedly delayed its termination,as compared with control with a Q₅₀ = 1.84 ± 0.15 (p < 0.05, n= 4) (Fig. 6A, left). To evaluate the effects of KN-93 on thelight adaptation process, a 500 msec light stimulus was givenbefore and after application of the drug. As shown in Figure 6A(right), KN-93 not only increased the amplitude of the receptorpotential but also broadened the transient component of the lightresponse and weakened the dip between the peak and the plateau(Q₅₀ = 1.99 ± 0.17, n = 4, p < 0.05). To focus on the K⁺ channel contribution, we investigated the effects of two differentK⁺ channel blockers, TEA and quinidine (Fig. 6B). After a 10 msecflash stimulus, there was an enhancement of the receptor potentialamplitude and a marked slowing of light response termination inthe presence of the general K⁺ channel blocker TEA (20 mM) (Q₅₀ = 1.76 ± 0.36, n = 6, p < 0.05).Similar results were obtained with 0.2 mM quinidine, previouslyshown to block delayed-rectifier K⁺ channels in Drosophila (Singh and Wu, 1989), with a Q₅₀ = 2.12± 0.17 (n = 4, p < 0.05). After a 500 msec light stimulus, quinidine(0.2 mM) strongly inhibited the light adaptation process witha much broader transient and an almost complete elimination ofthe plateau (Q₅₀ = 2.21 ± 0.33, n = 5, p < 0.01) (Fig. 6B, right).Figure 6C illustrates to what extent quinidine (0.2 mM) preferentiallyblocked I_K currents in WT photoreceptors (compare with Sh^KS133 in Fig. 7C). However, we noticed that at this concentration (0.2mM), quinidine also reduced by ~20% the I_A currents in WT cells(Fig. 6C).

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Figure 6. Effect of K⁺ channel blockers and a CaM kinase antagonist on the light response of WT photoreceptors. A, B, Whole-cell current-clamp recordings of the light response were performed in WT photoreceptors. In the current-clamp mode the resting potential was adjusted to $-$ 60 mV. The resting potential before adjustment ranged between $-$ 35 and $-$ 45 mV. Left, A light flash (10 msec, arrow) was given to dark-adapted photoreceptors (>2 min), and the light response was recorded before and 4 min after exposure of 5 µM KN-93 or 3 min after application of 20 mM TEA. Traces shown are representative of four similar experiments. Right, The same procedure was used except the light stimulus duration was 500 msec. Effects of the I_K channel blocker quinidine (0.2 mM, five experiments) and of the CaM kinase inhibitor KN-93 (5 µM, five experiments) are shown in representative traces. C, Whole-cell voltage-clamp recordings of cells before (control, left) and 2 min after application of 0.2 mM quinidine (right). The activation protocol was the same as in Figure 1.

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Figure 7. Effect of K⁺ channel blockers on the light response of Sh^KS133 photoreceptors. A, B, Whole-cell current-clamp recordings of the light response were performed in Sh^KS133 photoreceptors. A, Voltage responses to light stimuli (500 msec) recorded in WT (right; representative of seven cells) and Sh^KS133 (left; representative of six cells) photoreceptors. B, Voltage responses of Sh^KS133 photoreceptors to a 10 msec flash in the absence and presence of 0.2 mM quinidine (left; representative of five cells) and 20 mM TEA (right; representative of four cells). C, Whole-cell voltage-clamp recordings of Sh^KS133 photoreceptors before (control, left) and 2 min after application of 0.2 mM quinidine (right). The activation protocol was the same as in Figure 1.

To evaluate the contribution of I_A in light response adaptation and termination, we performed the same experiments in Sh^KS133 photoreceptor cells (Fig. 7). The photoreceptor potential waveformwas very similar in Sh^KS133 mutants as compared with WT photoreceptors after either a 10msec flash or a 500 msec light stimulus (Figs. 6, 7A,B). The Sh^KS133 mutation affected neither the light adaptation nor the voltagewaveform, including the transient, the dip, and the plateau phases(Fig. 7A). As compared with WT cells, essentially the same effectsof TEA and quinidine were obtained in Sh^KS133 photoreceptors, with an increased amplitude and a broadeningof the photoreceptor potential as well as a slowing down of theturn-off responses to flash stimuli (Fig. 7B). After a 10 msecflash, the Q₅₀ of TEA (20 mM) and quinidine (0.2 mM) was 1.41± 0.04 (n = 5, p < 0.001) and 2.00 ± 0.26 (n = 4, p < 0.05), respectively.Similar results were obtained with KN-93 (data not shown). Figure7C shows that quinidine (0.2 mM) blocked virtually all I_K currentsin Sh^KS133photoreceptors.

Finally, we investigated the possible modulation of I_K by light. We compared I_K in dark-adapted cells and during a 10-100msec flash stimulus that generates an approximately +10 mV depolarization.I_K was measured under voltage-clamp by stepping cells for 100msec from $-$ 80 mV to $-$ 10 mV. After subtracting the light-inducedcurrent, we found no significant effects on I_K kinetics or amplitude(<10%) (data notshown).

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

For what functional purpose are Drosophila photoreceptors endowed with high densities of voltage-gated K⁺ channels (Hardie, 1991; Hevers and Hardie, 1995)? Given theirmagnitude, voltage operating range, and kinetics, it was crucialto elucidate whether these K⁺ conductances are subject to modulation and to evaluate theirfunctional significance in phototransduction. The present workshows that Drosophila photoreceptor K⁺ channels are modulated by a CaM kinase, and as such may act inconcert with other calmodulin-sensitive components to play a rolein the feedback control of the lightresponse.

Drosophila photoreceptor neurons have evolved an exquisitely sophisticated signaling machinery to turn on the light response.This leads to the opening of TRP and TRPL cationic channels andgenerates a depolarizing receptor potential (Ranganathan et al.,1995; Minke and Selinger, 1996; Zuker, 1996) that is expectedto activate the voltage-gated K⁺ channels. On light stimulation, photoreceptor cells are likelyto operate within potentials ranging from approximately $-$ 60 mVto +10 mV. Considering the voltage operating range values we foundfor I_A and I_K (Figs. 1, 3; Table 2), it is reasonable to assumethat these K⁺ conductances will be operative within the voltage limits of photoreceptoractivity.

Our data show that photoreceptors I_K and I_A are specifically inhibited by different Ca²⁺/calmodulin antagonists such as W7 or TFP, with I_K being far moresensitive than I_A. Interestingly, this modulation was mimickedby two selective CaM kinase antagonists, KN-62 and KN-93. Theinability of KN-92 (inactive structural analog of KN-93) to affectI_K demonstrates the specificity of KN-93 action. The mechanismswhereby I_K and I_A are depressed after exposure to CaM kinase inhibitorsare not elucidated yet, but may involve either a direct channelphosphorylation or an indirect modulation. With respect to indirectregulation, it is possible that the CaM kinase mediates its effectvia the eag channel subunit, as suggested previously (Zhong andWu, 1993). A striking consequence of CaM kinase inhibition wasthe accelerated C-type inactivation kinetics of I_K as revealedby exposure of Sh^KS133 photoreceptors to KN-93 or W7. Blockade of CaM kinase-mediatedphosphorylation may alter the local charge distribution in a specificchannel domain, thereby affecting directly or allosterically thekinetics of C-type inactivation, through long-range electrostaticinteractions. A very similar modulation by CaM kinase has beenreported recently for Kv1.4 K⁺ channels (Roeper et al., 1997). Blockade of CaM Kinase II byKN-93 was found to accelerate the Kv1.4 inactivation rate constantsby 5- to 10-fold, suggesting that CaM kinase phosphorylation islikely to affect the interplay between N- and C-type inactivation(Roeper et al., 1997). The origin of the shift toward negativepotentials (~10 mV) in steady-state activation of I_K and I_A evokedby KN-93 and W7, respectively, is unclear. However, blockade ofCaM kinase-mediated phosphorylation may alter the net charge inthe vicinity of the channel voltage sensor and thus affect thevoltage-dependent gating (Perozo and Bezanilla, 1990). It is worthnoting that W7 did not produce a substantial leftward shift inthe steady-state activation and inactivation curves of I_K (Fig.2), suggesting that the Ca²⁺/calmodulin effects may not be mediated solely by a CaMkinase.

Our results indicate that I_K is more sensitive than I_A to modulation by a CaM kinase in photoreceptor cells. A similar highersensitivity of I_K as compared with I_A with regard to CaM kinasemodulation was recently found in cultured Drosophila neurons (W.-D.Yao and C.-F. Wu, personal communication). The channel subunitgating the I_A current in Drosophila photoreceptors was found tobe encoded by the Shaker locus (Hardie et al., 1991). Althoughthe native oligomeric structure of I_A is not known, Hardie etal. (1991) suggested previously that it is encoded by some ofthe Shaker isoforms, possibly ShA1, ShA2, ShG1, or ShG2. The situationis even more complex for the identity of I_K. We found by PCR thatShab 1 and Shab 2 isoforms as well as Shaw transcripts are expressedin Drosophila retina (our unpublished data), indicating that Shaband Shaw gene products could possibly be direct or indirect substratesof CaM kinase regulation. In this regard, it is worth noting thatthe Shab channel subunit contains four consensus sites for phosphorylationby CaM kinase [XRXXS (Pearson and Kemp, 1991)] at its intracellularamino and Ctermini.

Ca²⁺/calmodulin is known to regulate various downstream targets, including CaM kinase as well as additional components involvedin phototransduction (Arnon et al., 1997a,b; Scott et al., 1997).Modulation of I_K mediated by CaM kinase thus represents one ofthe effects of Ca²⁺/calmodulin on receptor potential. Considering that photoreceptorcells were recorded in the dark, our data imply that in restingdark-adapted conditions there is a marked basal phosphorylationof K⁺ channels by CaM kinase. Resting cytoplasmic free Ca²⁺ levels in the dark (in the presence of 1.5 mM external Ca²⁺) range within 130 and 180 nM (Hardie, 1996). These values areapparently sufficient to elicit substantial CaM kinase activityin the dark (Friedman et al., 1986; Braun and Schulman, 1995;Soderling, 1996). Within the operating window of the photoreceptorpotential ( $-$ 60 mV to +10 mV), the activation of I_K and I_A is stillfar from saturation, leaving many K⁺ channels to be recruited by increased CaM kinase activity afterlight stimulation. However, we could not detect a significantupregulation of I_K by light. This result does not exclude a rolefor CaM kinases in regulating I_K activity during light stimulation.Indeed, under our experimental conditions light stimulation couldalso activate Ca²⁺/calmodulin-dependent phosphatases (e.g., calcineurin), whichmay tightly interact with the channel complex leaving a steady-statephosphorylation almost unchanged. Thus, I_K channel activity maybe accounted for by a fine tuning of Ca²⁺/calmodulin-dependent kinases and phosphatases. Interestingly,a recent report described the existence of a signaling complexconsisting of the stable association of the protein phosphatasePP2A with CaM kinase IV (Westphal et al., 1998). PP2A dephosphorylatesCaM kinase IV and functions as a negative regulator of CaM kinaseIV signaling (Westphal et al., 1998).

From a functional point of view, our current-clamp data show for the first time in Drosophila that voltage-gated K⁺ channels play a significant role in adaptation and terminationof the light response. Similar observations were reported in photoreceptorsof the blowfly C. vicina (Weckstrom et al., 1991), in which K⁺ channels were suggested to reduce the membrane time constant,thus enabling the photoreceptors to code high frequencies in light-adaptedcells. Previous work performed in Limulus suggested that the dipbetween the transient and the plateau phase of the photoreceptorpotential could be accounted for by the I_A channel activity (O'Dayet al., 1982). This dip was consistently observed in the voltagelight response recorded from Sh^KS133 photoreceptors (Fig. 7A), excluding a significant contributionof I_A to this phase of the receptor potential waveform. Furthermore,inhibition of CaM kinase by KN-93 or blockade of I_K channels byquinidine and TEA reproduced the same effects on either Sh^KS133 mutant or WT photoreceptors. Although we did not notice majordifferences in the potential waveforms between WT and Sh^KS133 mutants, we cannot totally exclude a possible role of I_A in thelight response. Clearly, the decreased light adaptation and theslowing down of the turn-off kinetics produced by TEA and quinidinepoint to I_K as the main K⁺ conductance involved in the regulation of the light response.It is worth noting that KN-93 broadened the transient componentof the light response but did not reduce the plateau phase aselicited by K⁺ channel blockers. A likely explanation is that 5 µM KN-93 didnot completely abolish I_K (Fig. 4; Table 3), whereas 0.2 mM quinidinealmost totally suppressed I_K in Sh^KS133 photoreceptors (Fig. 7).

The gating mechanisms of light-activated channels remain a matter of controversy. It has been proposed that calcium releasefrom internal stores is required for activation of phototransductionand that the TRP channel functions as a store-operated channel.In this view, TRP is gated by the depletion of internal stores(Minke and Selinger, 1996; Arnon et al., 1997a,b). However, recentstudies challenged this hypothesis and suggest that IP₃ receptorsand internal stores are not required for the activation of thelight response (Scott et al., 1997). However, Ca²⁺/calmodulin was recently found to tightly control the light responseby modulating the various components previously established inthe Drosophila phototransduction process. Ca²⁺/calmodulin was shown to mediate light adaptation through itsnegative feedback on IP₃- and ryanodine-sensitive stores, therebydampening the Ca²⁺-induced Ca²⁺ release amplification process (Arnon et al., 1997a,b). Likewise,Ca²⁺/calmodulin was found to control termination of the light responsevia its inhibitory action on TRPL channels and its positive regulationof arrestin activity (Scott et al., 1997). For example, arrestinI (also called phosrestin I in photoreceptors) undergoes light-inducedphosphorylation on a subsecond time scale, via CaM kinase II activity(Matsumoto et al., 1994; Kahn and Matsumoto, 1997). A recent studyin Limulus photoreceptors showed that Ca²⁺/calmodulin could even exert its control via inhibition of phospholipaseC, and this may also apply to the Drosophila phototransductionprocess (Richard et al., 1997). The modulation of I_K by CaM kinasesupports the notion that K⁺ channels represent an additional calmodulin-sensitive componentof the negative feedback control of the light response. We suggestthat I_K acts in concert with other Ca²⁺/calmodulin-sensitive elements of the transduction cascade toregulate the gain, to control the waveform of the light-activatedreceptor potential, and to extend the operating range ofphotoreceptors.

  FOOTNOTES

Received Aug. 5, 1998; accepted Aug. 26, 1998.

This research was supported by grants from the Israel Academy of Science, the Minerva Foundation, and the Dominic EinhornFoundation (B.A). Dr. A. Peretz was supported by a Weizmann Institutepostdoctoral fellowship (Koret fund) and by the Human FrontierScience Program. B.A. is an incumbent of the Philip Harris andGerald Ronson Career Development chair. We thank Drs. Vivian Teichberg,Baruch Minke, and Eitan Reuveni for critical reading of this manuscriptand helpful discussions. We are grateful to Emily Levine for carefulreading of this manuscript. We also thank Wei-Dong Yao for communicationof unpublishedwork.
Correspondence should be addressed to Dr. Bernard Attali, Department of Neurobiology, The Weizmann Institute of Science, Rehovot76100,Israel.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Arnon A, Cook B, Montell C, Selinger Z, Minke B (1997a) Calmodulin regulation of calcium stores in phototransduction of Drosophila. Science 275:1119-1121[Abstract/Free Full Text].
Arnon A, Cook B, Gilo B, Montell C, Selinger Z, Minke B (1997b) Calmodulin regulation of light adaptation and stored-operated dark current in Drosophila photoreceptors. Proc Natl Acad Sci USA 94:5894-5899[Abstract/Free Full Text].
Bainbridge SP, Bownes M (1981) Staging the metamorphosis of Drosophila melanogaster. J Embryol Exp Morphol 66:57-80[ISI][Medline].
Baylor D (1996) How photons start vision. Proc Natl Acad Sci USA 93:560-565[Abstract/Free Full Text].
Braun AP, Schulman H (1995) The multifunctional calcium/calmodulin dependent protein kinase: from form to function. Annu Rev Physiol 57:417-445[ISI][Medline].
Broadie KS, Bate M (1993) Development of larval muscle properties in the embryonic myotubes of Drosophila melanogaster. J Neurosci 13:167-180[Abstract].
Choi KL, Aldrich RW, Yellen G (1991) Tetraethylammonium blockade distinguishes two inactivating mechanisms in voltage-activated K⁺ channels. Proc Nat Acad Sci USA 88:5092-5095[Abstract/Free Full Text].
Doupnik CA, Davidson N, Lester HA (1995) The inward rectifier potassium channel family. Curr Opin Neurobiol 5:268-277[ISI][Medline].
Fain GL, Lisman JE (1981) Membrane conductances of photoreceptors. Prog Biophys Mol Biol 37:91-147[ISI][Medline].
Friedman Y, Henricks L, Poleck T, Levasseur S, Burke G (1986) Calcium-activated, calmodulin-dependent protein kinase activity in bovine thyroid cytosol. Biochem Biophys Res Commun 140:120-127[ISI][Medline].
Goldstein SA, Price LA, Rosenthal DN, Pausch MH (1996) ORK1, a potassium-selective leak channel with two pore domains cloned from Drosophila melanogaster by expression in Saccharomyces cerevisiae. Proc Natl Acad Sci USA 93:13256-13261[Abstract/Free Full Text].
Hamill OP, Marty A, Neher E, Sakmann B, Sigworth FJ (1981) Improved patch-clamp techniques for high resolution current recording from cells and cell free membrane patches. Pflügers Arch 391:85-100[ISI][Medline].
Hardie RC (1991) Voltage-sensitive potassium channels in Drosophila photoreceptors. J Neurosci 11:3079-3095[Abstract].
Hardie RC (1996) INDO-1 measurements of absolute resting and light-induced Ca²⁺ concentration in Drosophila photoreceptors. J Neurosci 16:2924-2933[Abstract/Free Full Text].
Hardie RC, Minke B (1995) Phosphoinositide-mediated phototransduction in Drosophila photoreceptors: the role of Ca²⁺ and trp. Cell Calcium 18:256-274[ISI][Medline].
Hardie RC, Voss D, Pongs O, Laughlin SB (1991) Novel potassium channels encoded by the Shaker locus in Drosophila photoreceptors. Neuron 6:477-486[ISI][Medline].
Hevers W, Hardie RC (1995) Serotonin modulates the voltage dependence of delayed rectifier and Shaker potassium channels in Drosophila photoreceptors. Neuron 14:845-856[ISI][Medline].
Hille B (1992) In: Ionic channels of excitable membranes. Sunderland, MA: Sinauer.
Hoshi T, Zagotta WN, Aldrich RW (1990) Biophysical and molecular mechanisms of Shaker potassium channel inactivation. Science 250:533-538[Abstract/Free Full Text].
Jan LY, Jan YN (1997) Cloned potassium channels from eukaryotes and prokaryotes. Annu Rev Neurosci 20:91-123[ISI][Medline].
Kahn ES, Matsumoto H (1997) Calcium/calmodulin-dependent kinase II phosphorylates Drosophila visual arrestin. J Neurochem 68:169-175[ISI][Medline].
Kamb A, Iverson LE, Tanouye MA (1987) Molecular characterization of Shaker, a Drosophila gene that encodes a potassium channel. Cell 50:405-413[ISI][Medline].
Lichtinghagen R, Stocker M, Wittka R, Boheim G, Stuhmer W, Ferrus A, Pongs O (1990) Molecular basis of altered excitability in Shaker mutants of Drosophila melanogaster. EMBO J 9:4399-4407[ISI][Medline].
Matsumoto H, Kurien BT, Takagi Y, Kahn ES, Kinumi T, Komori N, Yamada T, Hayashi F, Isono K, Pak WL (1994) Phosrestin I undergoes the earliest light-induced phosphorylation by a calcium/calmodulin-dependent protein kinase in Drosophila photoreceptors. Neuron 12:997-1010[ISI][Medline].
Minke B, Selinger Z (1996) The role of TRP and calcium in regulating photoreceptor function in Drosophila. Curr Opin Neurobiol 6:459-466[ISI][Medline].
O'Day PM, Lisman JE, Goldring M (1982) Functional significance of voltage-dependent conductances in Limulus ventral photoreceptors. J Gen Physiol 79:211-232[Abstract/Free Full Text].
Pearson RB, Kemp BE (1991) Protein kinase phosphorylation site sequences and consensus specificity motifs, tabulations. Methods Enzymol 201:62-81.
Peretz A, Suss-Tobby E, Rom-Glas A, Arnon A, Payne R, Minke B (1994) The light response of Drosophila photoreceptors is accompanied by an increase in cellular calcium: effects of specific mutations. Neuron 12:1257-1267[ISI][Medline].
Perozo E, Bezanilla F (1990) Phosphorylation affects voltage gating of the delayed rectifier K⁺ channel by electrostatic interactions. Neuron 5:685-690[ISI][Medline].
Pongs O (1992) Molecular biology of voltage-dependent potassium channels. Physiol Rev 72:69-88.
Pongs O, Kecskemethy N, Muller R, Krahjentgens I, Baumann A, Kitz HH, Canal I, Liamazares S, Ferrus A (1988) Shaker encodes a family of putative potassium channel proteins in the nervous system of Drosophila. EMBO J 7:1087-1096[ISI][Medline].
Ranganathan R, Malicki DM, Zuker CS (1995) Signal transduction in Drosophila photoreceptors. Annu Rev Neurosci 18:283-317[ISI][Medline].
Richard AR, Ghosh S, Lowenstein JM, Lisman LE (1997) Ca²⁺/calmodulin-binding peptides block phototransduction in Limulus ventral photoreceptors: evidence for direct inhibition of phospholipase C. Proc Natl Acad Sci USA 94:14095-14099[Abstract/Free Full Text].
Roeper J, Lorra C, Pongs O (1997) Frequency-dependent inactiv