Fraction of the Dark Current Carried by Ca2+ through Cgmp-Gated Ion Channels of Intact Rod and Cone Photoreceptors

doi:10.1085/jgp.116.6.735

Published 1 December 2000. doi:10.1085/jgp.116.6.735

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Original Article

Fraction of the Dark Current Carried by Ca²⁺ through Cgmp-Gated Ion Channels of Intact Rod and Cone Photoreceptors

Tsuyoshi Ohyama^a, David H. Hackos^a, Stephan Frings^b, Volker Hagen^c, U. Benjamin Kaupp^b, and Juan I. Korenbrot^a

^a Department of Physiology and Graduate Program in Biophysics, School of Medicine, University of California at San Francisco, San Francisco, California 94143
^b Institut für Biologische Informationsverarbeitung, Forschungszentrum Jülich, 52425 Jülich, Germany
^c Forschungs institut für Molekulare Pharmakologie, 10315 Berlin, Germany
Dept. of Physiology, School of Medicine, Box 0444, University of California at San Francisco, San Francisco, CA 94143.415-476-4929

juan{at}itsa.ucsf.edu

ABSTRACT

Top
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

The selectivity for Ca²⁺ over Na⁺, PCa/PNa, is higher in cGMP-gated(CNG) ion channels of retinal cone photoreceptors than in thoseof rods. To ascertain the physiological significance of thisfact, we determined the fraction of the cyclic nucleotide–gatedcurrent specifically carried by Ca²⁺ in intact rods and cones.We activated CNG channels by suddenly (<5 ms) increasingfree 8Br-cGMP in the cytoplasm of rods or cones loaded witha caged ester of the cyclic nucleotide. Simultaneous with theuncaging flash, we measured the cyclic nucleotide–dependentchanges in membrane current and fluorescence of the Ca²⁺-bindingdye, Fura-2, also loaded into the cells. The ratio of changesin fura-2 fluorescence and the integral of the membrane current,under a restricted set of experimental conditions, is a directmeasure of the fractional Ca²⁺ flux. Under normal physiologicalsalt concentrations, the fractional Ca²⁺ flux is higher in CNGchannels of cones than in those of rods, but it differs littleamong cones (or rods) of different species. Under normal physiologicalconditions and for membrane currents $≤$ 200 pA, the Ca²⁺ fractionalflux in single cones of striped bass was 33 ± 2%, and34 ± 6% in catfish cones. Under comparable conditions,the Ca²⁺ fractional flux in rod outer segments of tiger salamanderwas 21 ± 1%, and 14 ± 1% in catfish rods. FractionalCa²⁺ flux increases as extracellular Ca²⁺ rises, with a dependencewell described by the Michaelis-Menten equation. KCa, the concentrationat which Ca²⁺ fractional flux is 50% was 1.98 mM in bass conesand 4.96 mM in tiger salamander rods. Because Ca²⁺ fractionalflux is higher in cones than in rods, light flashes that generateequal photocurrents will cause a larger change in cytoplasmicCa²⁺ in cones than in rods.

Key Words: retina • phototransduction • ion selectivity

INTRODUCTION

Top
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

In rod and cone photoreceptors of the vertebrate retina, a continuousmembrane current flows into the outer segment in the dark thatlight suppresses. The dark current is carried by the simultaneousinward flux of Na⁺, Ca²⁺, and Mg²⁺ ions (Hodgkin et al. 1985;Cervetto et al. 1988) flowing through cyclic nucleotide–gated(CNG) ion channels. Understanding the fraction the dark currentspecifically carried by Ca²⁺ ions is important because Ca²⁺influx, as a component of the dark current, is in a dynamicbalance with its efflux through a Na⁺/Ca²⁺,K⁺ exchanger, andthis balance determines the free cytoplasmic Ca²⁺ in the outersegment of rods and cones (Yau and Nakatani 1985; Miller andKorenbrot 1987; Lagnado et al. 1992). Moreover, the quantitativefeatures of both influx and efflux differ between rods and cones,and these differences contribute to explaining the differencein transduction signals between the two photoreceptor types(Korenbrot 1995).

The fraction of the dark current carried by any given ion dependson the ion selectivity of the CNG channels and the concentrationand driving force of that ion. CNG channels in rods and conesare more permeable to Ca²⁺ than to Na⁺, but they differ in theirrelative selectivity of Ca²⁺ over Na⁺ (PCa/PNa). Under saturatingconcentrations of cGMP, when the probability of channel openingis $~$ 0.9, and in the presence of simple bionic solutions, PCa/PNain cones is $~$ 21.7, but in rods it is $~$ 6.5 (Picones and Korenbrot1995; Wells and Tanaka 1997; Hackos and Korenbrot 1999). Thedifference in PCa/PNa between CNG channels of rods and conesis also observed in recombinant channels formed from alpha subunitsalone (Frings et al. 1995). The value of PCa/PNa changes withchannel gating: at the cGMP concentrations expected in intactcells, when probability of channel opening is $~$ 0.03, PCa/PNain cones is $~$ 7.4x larger than that in rods (Hackos and Korenbrot1999).

To understand the functional significance of the differencesin ion selectivity between rod and cone CNG channels, the fractionof the dark current carried by Ca²⁺ under physiological solutionsneeds to be computed from the known values of PCa/PNa. Thistask, however, is complex. It may be accomplished through theoreticalmodels of ion permeation. For example, Wells and Tanaka 1997elegantly developed an Eyring-type permeation model for CNGchannels with three barriers, two wells, and four sites (eachfor Na⁺, K⁺ Ca²⁺, and Mg²⁺) that simulates fractional currentsand permeability ratios. A comparably complete computation hasnot been reported for cone CNG channels.

The fraction of the dark current carried by Ca²⁺ in intact rodhas been experimentally estimated using an indirect method.The method depends on measurements of a membrane current generatedby the electrogenic transport of cations by the Na⁺/Ca²⁺,K⁺exchanger, and requires the separation of this electrogeniccurrent from a changing conductive current. The method has limitationsthat have been thoroughly considered by those who have usedit (Nakatani and Yau 1988). Despite its possible limitations,the method in several hands has provided a reproducible estimatethat in rods, between 10 and 20% of the dark current is carriedby Ca²⁺ (Nakatani and Yau 1988; Lagnado et al. 1992; Gray-Kellerand Detwiler 1994; Younger et al. 1996). The Na⁺/Ca²⁺,K⁺ exchangerin cones also generates an electrogenic current. This current,however, is at least an order of magnitude faster than thatmeasured in rods (Nakatani and Yau 1989; Hestrin and Korenbrot1990; Perry and McNaughton 1991). Separating the electrogenicfrom the photocurrent, hence, is fraught with error (our unpublishedobservation) and analysis of the Ca²⁺ fractional current incones through this method is not entirely reliable.

Recently, Neher and his collaborators developed a method toassess the fraction of current carried specifically by Ca²⁺in several voltage- and ligand-gated channels (reviewed in Neher1995). The method depends on the simultaneous measurement ofmembrane current and cytoplasmic Ca²⁺ after synchronous activationof the channels of interest. We have previously extended thismethod to an investigation of the fractional Ca²⁺ flux in recombinantCNG channels formed by alpha subunits of olfactory, rod, andcone receptor cells (Dzeja et al. 1999; Frings et al. 2000).We report here on the application of this method to studiesin rod and cone photoreceptors that have allowed us to directlydetermine the fraction of the dark current carried by Ca²⁺ inintact cells isolated from several species.

MATERIAL AND METHODS

Top
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials
Striped bass (Morone saxitilis) and catfish (Ictalurus punctatus)were obtained from Professional Aquaculture Services and maintainedin the laboratory for up to 6 wk under 10:14-h dark:light cycles.Tiger salamanders (Ambystoma tigrinum) were received from CharlesSullivan and maintained in an aquarium at 6°C under 12:12-hdark:light cycles. Gecko (Gecko gecko) were obtained from localshops and maintained at ambient temperature under normal daylightcycles. The UCSF Committee on Animal Research approved protocolsfor the upkeep and killing of the animals.

Caged 8-Br-cGMP (8-bromoguanosine 3', 5'-cyclic monophosphate,4,5-dimethoxy-2-nitrobenzyl ester, dihydrate, axial isomer)was synthesized as previously described (Hagen et al. 1996,Hagen et al. 1998). Fura-2 was purchased from TefLabs. Enzymesfor tissue dissociation were obtained from Worthington Biochemical.All other chemicals were from Sigma-Aldrich.

Photoreceptor Isolation
Under infrared illumination and with the aid of a TV cameraand monitor, retinas were isolated from dark-adapted animalsand photoreceptors were dissociated as described in detail elsewhere(Miller and Korenbrot 1993, Miller and Korenbrot 1994). Singlecones were isolated by mechanical trituration of fish retinasbriefly treated with collagenase and hyaluronidase. Choppingthe retina with a blade isolated rod outer segments. Photoreceptorswere isolated and maintained in a Ringer's solution specificto each species studied. Solution composition is listed in Table .

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Table 1 Composition of Extracellular Ringers Solutions Used to Isolate and Perfuse Solitary Photoreceptors

Photoreceptors were dissociated in a Ringer's solution in whichglucose was replaced with 5 mM pyruvate. Suspended in this solution,cells were added to a recording chamber held on the stage ofan inverted microscope. The bottom of the recording chamberwas a glass coverslip derivatized with Concanavalin A (Piconesand Korenbrot 1992

). Solitary photoreceptors were firmly attachedto the coverslip, and after 5 min the bath solution was exchangedwith the normal, glucose-containing Ringer's.

Electrical Recording and Solutions
Photoreceptors in the recording chamber were observed usingan inverted microscope equipped with differential interferencecontrast optics and operated under infrared light (850 ±40 nm) with the aid of an IR-sensitive TV camera and monitor.We measured membrane currents under voltage clamp at room temperatureusing tight-seal electrodes in the whole-cell mode. Electrodeswere produced from aluminosilicate glass (1.5 mm o.d. x 1.0mm i.d., No. 1724; Corning Glassworks), and were sealed ontothe side of detached rod outer segments or the inner segmentof isolated single cones. Currents were measured with a patch-clampamplifier (Axopatch 1D; Axon Instruments, Inc.). Analogue signalswere low-pass filtered below 200 Hz with an eight-pole Besselfilter (Kronh-Hite), and then digitized on line at 1 kHz (FastLab;Indec).

Solutions used to fill tight-seal electrodes are listed in Table .Salt solutions were first passed over a Chelex-100 resin column(Bio-Rad Laboratories) to thoroughly remove all multivalentcations; MgCl₂ was then added. Fura-2 and caged 8Br-cGMP wereadded to the solutions immediately before use. Even in the dark,caged 8Br-cGMP hydrolyzes over time (Hagen et al. 1998). Therefore,electrode-filling solutions were kept in darkness and discardedafter 3 h.

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Table 2 Composition of Solutions Used to Fill Tight-seal Electrodes

Solutions used to measure cGMP-gated currents with Ca²⁺ as theexclusive net charge carrier are listed in Table . In thesesolutions, the permeant cations Na⁺ and Mg²⁺ were replaced bythe impermeant cations choline⁺ or tetramethylamonium⁺ (Hodgkinet al. 1985

). K⁺ was not replaced because its presence is requiredfor the function of the Na⁺/Ca²⁺,K⁺ exchanger. However, itsconcentrations were selected such that at –35 mV the holdingvoltage in the experiments, the net K⁺ current was zero.

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Table 3 Composition of Solutions Used to Measure f_max

Single-Cell Loading and Superfusion
Photoreceptors in the recording chamber were maintained in darknessunder Ringer's solution that was exchanged intermittently. Foreach cell type studied here, we determined the interval necessaryfor equilibration between electrode lumen and cytoplasmic spacesby (a) photometrically monitoring the rate of fura-2 loading,and (b) electrically monitoring the rate of change in holdingcurrent.

The extracellular solution was changed only around the cellunder investigation, using a micro-superfusion system. Testsolutions were selected with electronically controlled switchvalves and steady flow was maintained under a positive pressureof $~$ 10 cm H₂O. Solutions were delivered through a glass capillary100 µm in tip diameter placed within $~$ 300 µm of thecell.

Photometric Recording
Simultaneously with membrane current, we measured the fluorescenceof single fura 2–loaded photoreceptors. The instrumentdesigned for these studies is schematically illustrated in Fig. 1.Fluorescence excitation light at 380 nm (selected with a narrowband interference filter from a DC powered Xenon source (150W;Osram XBO) was delivered onto the cell through the microscopeobjective used to observe it (Fluor 40, 40x, 1.3 NA; Nikon).To this end, we designed an epi-illumination pathway consistingof a fiber-optic light scrambler that provided extremely uniformillumination to the back aperture of the objective (TechnicalVideo Ltd.) and a custom dichroic mirror that reflected >60%of light between 300 and 400 nm and transmitted >90% of lightbetween 750 and 950 nm (Chroma Technology). This pathway alsoincluded a shutter and an adjustable aperture to selectivelydeliver fluorescence excitation light to a limited section ofthe solitary photoreceptors.

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Figure 1 Schematic illustration of microfluorimeter designed to simultaneously measure membrane current and fluorescence from individual, solitary rod, and cone photoreceptors. The photoreceptors are observed under infrared differential interference contrast with the aid of a TV camera. Fluorescence excitation light from a Xe source is selected at 380 nm with interference filters and delivered onto the cell through an epi-illumination path consisting of a fiber-optic scrambler, a dichroic mirror, and a lens that permits an adjustable aperture to be focused onto selected areas of the cell. Uncaging light from a Xe flash source is selected below 400 nm with short pass filters and delivered onto the cell through an epi-illumination path consisting of a quartz beam splitter and a relay lens that permits an adjustable aperture to be focused onto selected areas of the cell. Fluorescence emission in the range between 400 and 600 nm is collected by a custom micro-objective (µ-objct) that focuses the image of the cell onto the end of an optical fiber. This fiber is part of a fiber optic bench that delivers the collected photons to a PMT operated in photon counting mode.

We designed a second epi-illumination pathway to deliver tothe cell brief, powerful flashes of light to uncage 8Br-cGMP.This pathway consisted of a Xenon flashlamp, able to deliver200 J with $~$ 170-µs half bandwidth (Chadwick-Helmuth Co.).Uncaging flashes were of light <400 nm, selected with theuse of short-pass optical filters (Hoya Optics Inc.). Uncaginglight was focused onto the cell through the microscope objectivewith the aid of a custom designed relay lens. With the use ofan adjustable aperture placed in this pathway, the uncaginglight could illuminate selected parts of the cell. In general,uniform uncaging flashes were delivered over the entire surfaceof detached rod outer segments, but were restricted to the outersegment alone in studies of cones.

The fluorescent light emitted by a solitary photoreceptor wascaptured with a custom micro-objective designed to efficientlycapture photons, while allowing electrical recording with microelectrodes(Optical Design Service). The micro-objective is a water immersion,multi-element lens 5.2 mm in diameter, 0.6 NA, and 2.8-mm workingdistance mounted on a micromanipulator. The lens produces awell-corrected image at a focal length of 10 mm with 0.18 NA.At the focal plane of the micro-objective, we placed the endof a multimode optical fiber (365 µm core, 400 µmclad, step index 0.22 NA). The other end of the fiber was focused,through a coupling lens, onto the photocathode of a photomultipliertube (PMT) (R943-02; Hamamatsu) operated at –20°Cand sampled in 50-ms counting bins using photon-counting instrumentation(Photochemical Research Associates).

The fiber-optic bench incorporated an interference filter toselect the emitted fluorescence in the range between 410 and600 nm (Omega Optical). A synchronized shutter in the benchwas used to insure that light from the uncaging Xe flash didnot reach the PMT. The fiber-optic bench also included a dichroicmirror and lens to focus the light from an IR laser diode (830nm) onto the back end of the transfer optical fiber (Oz Optics,Ltd.). This feature was essential because it allowed us to locateand focus the micro-objective onto the individual cell underinvestigation. The light from the IR laser diode, transferredthrough the optical fiber, was emitted by the micro-objective.The experimenter, observing through the microscope objective,could see this IR light and use it as a guide to accuratelyposition and focus the micro-objective.

Calibration
In every experiment, a calibrated photodiode (United DetectorTechnology) was used to measure the intensity of the 380-nmfluorescence excitation light at the position of the cells onthe microscope stage. Data presented here were measured at excitationintensities between 1.1 and 1.8 x 10⁸ photons µm^–2s^–1. To quantitate cell fluorescence intensity, at theend of each experiment, we measured the fluorescence emittedby individual fluorescent beads excited identically to the cells(Fluoresbrite^TM carboxy BB 4.1 ± 0.2 µm microspheres;Polyscience, Inc.). Fluorescence intensity of cells and beadswas corrected by subtracting from each the signal measured intheir absence and due to leakage of light between excitationand emission filter sets (cross talk). In each experiment, weaveraged the fluorescence of 10 different beads (units of countsin 50-ms bin per bead) and defined this intensity as one beadunit (bu). Cell fluorescence was expressed in bu by dividingthe intensity of each cell by the bead unit measured in thesame experiment.

Data Analysis
To calculate P_f, the fractional Ca²⁺ flux, we corrected thedata to analyze only the flash-dependent changes. To this end,we averaged the value of the holding current and fluorescencefor 1 s preceding the uncaging flash and subtracted this valuefrom the data; consequently, both the holding current and thefluorescence intensity preceding the flash had an average valueof zero. We then integrated the corrected current over the first15 s after the uncaging flash. Finally, we fit the integralof the current changes to the fluorescence changes.

Selected mathematical functions were fit to experimental datawith nonlinear, least square minimization algorithms (Origin;MicroCal Software). Dynamic simulations were carried out usingTutsim^TM software (Actuality Corp.). Statistical error throughoutis presented as SD. In some calculations of population mean,we included two, and only two, measurements from the same cell(as indicated in the text). To calculate errors on ratios ofmeans, we computed propagation of errors as described by Bevington1992:

Formula
where ${sigma}$ ² is the varianceof the mean of quantities a, u and v.

Theory
The fraction of the cGMP-dependent current carried by Ca²⁺ ionsin photoreceptors, here denominated P_f, can be determined bysimultaneously measuring total membrane current with patch-clampelectrodes, and Ca²⁺ concentration with the Ca²⁺-sensitive fluorescentdye, fura-2. Neher 1995 has reviewed this analytical methodand we have described in detail its application to studies ofCNG channels (Frings et al. 2000). In brief, cGMP-dependentcurrents are rapidly activated by the sudden intracellular applicationof 8Br-cGMP, achieved by photolysis of caged 8Br-cGMP molecules.Because the channels exhibit only limited ion selectivity, thecGMP-dependent membrane current in normal Ringer's solution,I_T, is composed of contributions from several ion species: Na⁺(I_Na), K⁺ (I_K), Mg²⁺ (I_Mg), and Ca²⁺ (I_Ca) ():

Formula 1 (1)

The Ca²⁺-free form of fura-2 is present in the outer segment'scytoplasm, where it binds the inflowing Ca²⁺. Binding Ca²⁺ causesa decrease in the intensity of fluorescence excited by 380 nmlight (F380). The extent of decline in F380 is proportionalto free Ca²⁺ concentration, but it measures the total amountof Ca²⁺ entering the cell if, and only if, a number of experimentalconditions are strictly met. (a) Ca²⁺ enters the cell only throughthe channels of interest. (b) All entering Ca²⁺ is bound byfree fura-2; none is sequestered or actively transported outof the cell. (c) Fura-2 outcompetes endogenous Ca²⁺ buffersbecause it is present at a concentration that exceeds that ofthe other buffers.

The change in the mole amount of intracellular Ca²⁺ caused bythe cGMP-activated current over a time interval ${Delta}$ t, is givenby :

Formula 2 (2)
where F isFaraday's constant. If fura-2 is used to monitor cytoplasmicCa²⁺, intracellular Ca²⁺ may distribute among several competingpools: (a) free Ca²⁺, (b) Ca²⁺ bound to cytoplasmic buffers(CaB), (c) Ca²⁺ bound to fura-2 (CaFu), and (d) Ca²⁺ pumpedinto cellular organelles or out of the cell (P). Thus:

Formula 3 (3)
where ${Delta}$ n_free, ${Delta}$ n_CaFu, ${Delta}$ n_CaB, and ${Delta}$ n_P are the changes in mole amount of Ca²⁺ free, bound to fura-2,bound to cytoplasmic buffers, and pumped (or sequestered) outof the cytoplasm, respectively. Neher 1995 reasoned, and provedrigorously, that under certain experimental conditions, whenall entering Ca²⁺ is bound to the fura-2 present in the cell, can be simplified. These conditions are: (a) measurements areexecuted with high fura-2 concentrations, 1–5 mM. Underthis condition, the indicator dye, which is a very powerfulbuffer, outcompetes the endogenous Ca²⁺ buffers, rendering ${Delta}$ n_CaBnegligible. (b) The rapid rate of Ca²⁺ binding by fura-2 (fewmilliseconds) (Kao and Tsien 1988) allows a few seconds to besufficiently long for binding to the dye to be complete, butstill short relative to the time necessary to pump Ca²⁺ intoorganelles or out of the cell; this condition makes ${Delta}$ n_P negligible.(c) Fura-2 exists in its Ca²⁺-free form. Then, all enteringCa²⁺ is bound by the dye and ${Delta}$ n_free is negligible. Then, onlyunder these experimental conditions:

Formula 4 (4)

The Ca²⁺ binding capacity of fura-2, ${kappa}$ _Fu is defined as ():

Formula 5 (5)
where [Ca²⁺], [CaFu], and [Fu_tot]are the concentrations of free Ca²⁺, bound Ca²⁺, and total fura-2,respectively. K_d is the dissociation constant of the fura-Ca²⁺complex. With this definition, considering a small incrementalelevation in [Ca²⁺] and under the experimental conditions thathold true for , then:

Formula 6 (6)
where V_c is the accessible cytoplasmic volume. If we definethe emitted intensity of fura-2 fluorescence excited at 380nm (F₃₈₀) as the sum of the fluorescence of its two molecularforms, one Ca²⁺-free, S_Fu, and the other Ca²⁺-bound, S_CaFu,then:

Formula 7 (7)

This equation indicates that, under these conditions, the changein fluorescence is proportional to the total amount of Ca²⁺entering the cell, as the ion shifts the fraction of fura-2between its free and bound states. Combining , , and yields:

Formula 8 (8)

Let us define f as the ratio of the change in fluorescence, ${Delta}$ F₃₈₀, and the integral of the membrane current ():

Formula 9 (9)

Under conditions where Ca²⁺ is the exclusive current carrier;that is, when I_T = I_Ca, then f takes the value f_max.

Formula 10 (10)
and the fractionof the I_T current carried by Ca²⁺ under normal conditions, P_f,can be calculated if f and f_max are both measured in the samecell type.

Formula 11 (11)

RESULTS

Top
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

To determine P_f, the fraction of the total cGMP-dependent currentcarried by Ca²⁺ ions, we measured flash-generated changes inmembrane current under voltage clamp and fluorescence of individualrod and cone photoreceptors loaded with caged 8Br-cGMP and fura-2.We studied the cells with tight-seal electrodes filled withsolutions that lacked triphosphate nucleotides and, therefore,could not sustain endogenous synthesis of cGMP (Hestrin andKorenbrot 1987; Rispoli et al. 1993). At –35 mV holdingvoltage, the magnitude of the membrane current preceding theuncaging flash is a measure of the stability of the electricalrecordings and the completeness of diffusion exchange betweenelectrode lumen and the cytoplasm. When the cells' cytoplasmis fully equilibrated with the electrode lumen, the holdingcurrent, Ihold, at –35 mV should be zero for detachedrod outer segments (dROS) and outward for cones, which consistof both inner and outer segments. These expectations followfrom the fact that CNG channels are the only channels in thedROS and they should be closed (Baylor and Nunn 1986). In cones,and rods with an inner segment, in contrast, an outward currentcan be expected to flow through the voltage-dependent K⁺ channelsof the inner segment (Maricq and Korenbrot 1990; Barnes andHille 1989). The data presented here were measured in tigersalamander dROS no less than 4.5 min after going into whole-cellmode and while Ihold was –4.6 ± 2.7 pA (n = 17);striped bass single cones at no less than 3 min after goinginto whole-cell mode and while Ihold was 21.1 ± 12.3pA (n = 35); catfish cones at no less than 3 min after goinginto whole-cell mode and while Ihold was 14.3 ± 8.3 pA(n = 11), and catfish rods (which retain a portion of theirinner segment) at no less than 4 min after going into whole-cellmode and while Ihold was 46.2 ± 16.7 pA (n = 12). Cellfluorescence of fura-2 also confirmed that, at the times indicated,equilibration between cell cytoplasm and the electrode was complete.

Typical current and fluorescence changes generated by uncagingflashes in dROS of tiger salamander and single cones of stripedbass are illustrated in Fig. 2. In both receptor types, theuncaging flash activated a transient, inward current and, simultaneously,caused a decrease in fluorescence intensity. The current increasereflects the transient opening of cGMP-gated channels, whilethe loss of fluorescence arises from the entry of Ca²⁺ ions,which subsequently bind to fura-2. Shown are repeated measurementsin the same cell generated by flashes of increasing intensity.Photoreceptors recovered to their initial conditions in betweenflashes, provided that at least 3 min elapsed between the flashes.The peak current amplitude increased with flash intensity andso did the extent of fluorescence change. Since the intensityof the flash is correlated with the amount of released 8Br-cGMP,the results indicate that current amplitude and Ca²⁺ influxare dependent on the cyclic nucleotide concentration. SinceCNG channels in rods are more sensitive to 8Br-cGMP than thoseof cones (Hackos and Korenbrot 1997), it is not surprising thatuncaging flashes of comparable intensity caused larger currentchanges in rods than in cones.

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Figure 2 Membrane currents and fluorescence measured simultaneously in individual photoreceptor cells loaded with 2 mM fura-2 and 50 µM caged 8Br-cGMP. (Left) Data measured in a dROS from a tiger salamander. The dROS was held at –35 mV and the holding current was –5 pA. Uncaging flashes of varying intensity were presented at various times after achieving whole-cell mode. Each flash caused an inward, transient current and a decrease in fluorescence excited at 380 nm. In between uncaging flashes, both current and fluorescence intensity recovered to their initial values. Peak currents (and time after attaining whole-cell mode) were: 710 pA (12.5 min), 172 pA (15 min), 1,175 pA (25 min), and 362 pA (28 min). (Right) Data measured in a single cone from a striped bass. The cone was held at –35 mV and the holding current was +38 pA. Uncaging flashes also activated inward, transient currents proportional to the intensity of the flash. Peak currents measured (and time after achieving whole-cell mode) were: 179 pA (8.5 min), 79 pA (10.5 min), and 565 pA (12.5 min). Associated with the change in current, there also was a decrease in fluorescence excited at 380 nm. Fluorescence intensity, measured in 50-ms bins, is expressed in bead units. 1 bu is the fluorescence intensity of a single fluorescent bead (Fluoresbrite^TM carboxy BB microsphere) measured in the same experiment and under the same conditions used to measure cell fluorescence.

The rapid rise of the flash-generated current (time to peak $≤$ 100 ms) (Fig. 2) is consistent with the rate of photolysis ofthe caged 8Br-cGMP (Hagen et al. 1998

) and the rapid activationof channels by the free nucleotide (Karpen et al. 1988

). However,the rapid decline from a peak towards the starting value issurprising. We observed this feature in every cell and everyspecies we studied. The time course of the current decay fromits peak was well described by a single exponential. In tigersalamander dROS, the mean decay time constant was 0.84 ±0.23 s (range 0.61–1.27, n = 13 for peak currents $≤$ 200pA). In striped bass cones, the mean decay time constant was0.89 ± 0.38 s (range 0.54–1.77 s, n = 9 for peakcurrents $≤$ 200 pA). Experimental results detailed in the suggestthat the rapid current decline arises primarily from the bindingof free 8Br-cGMP to specific binding sites in the outer segment.The existence of cGMP-binding sites in rod outer segments hasbeen inferred from analysis of cGMP diffusion kinetics (Olsonand Pugh 1993

; Koutalos et al. 1995

) and measured biochemically(Cote and Brunnock 1993

). Although comparable data do not existfor cones, the similarity in decay kinetics suggests that cGMP-bindingsites are not different in rods and cones.

Experimental Conditions Required to Determine the Value of P_f Are Met in Isolated Photoreceptors
To calculate P_f, it is crucial to establish that the experimentalconditions necessary to apply the analytical theory describedabove indeed hold.

Ca²⁺ enters the cell only through the channels of interest.
In dROS, CNG are the only ion channels present in the plasmamembrane (Baylor and Nunn 1986; Hestrin and Korenbrot 1987).In cones, and rods with an inner segment, Ca²⁺ could potentiallyenter through voltage-gated Ca²⁺ channels in the inner segment.We assured that voltage-gated Ca²⁺ channels are inactive byconducting all experiments under voltage clamp at –35mV holding potential, a condition under which the known Ca²⁺channels in rod and cone inner segments are inactive (Coreyet al. 1984; Maricq and Korenbrot 1988).

All Ca²⁺ that enters the cell through the CNG channels in the outer segment binds to fura-2.
In cones or rods with an inner segment, Ca²⁺ entering the outersegments can flow into the inner segment through the ciliumthat connects them. Flow between outer and inner segment canbe expected for any diffusible molecule. Evidence of this flowis presented in Fig. 3. When 8Br-cGMP was released in the innersegment only, by restricting uncaging light to this part ofthe cell, currents were nonetheless generated in the outer segment.The currents, however, exhibited a delay of a magnitude wellpredicted for the aqueous diffusion of 8Br-cGMP from the innersegment to the outer segment. To minimize errors that may arisefrom intracellular Ca²⁺ flow, data in cone photoreceptors weremeasured by restricting uncaging light to the outer segmentalone, but sampling fura-2 fluorescence over the entire cell.Under these conditions, cGMP-dependent Ca²⁺ entry occurs onlyin the outer segment, but it is fully sampled even if it flowsto the inner segment.

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Figure 3 Membrane currents measured in a single cone from striped bass loaded with 2 mM fura-2 and 50 µM caged 8Br-cGMP. Superimposed are currents measured in the same cell at –35 mV holding voltage in response to uncaging flashes delivered 4 min (A) or 11 min (B) after achieving whole cell mode. The holding current was +12 pA. Identical flashes were delivered through an aperture that restricted uncaging light to a 20-µm circle centered either on the inner segment (A) or the outer segment (B), approximately as indicated in the drawing (top right). Generating free 8Br-cGMP in the outer segment caused a large, transient inward current without detectable delay relative to the presentation of the flash (B). Generating a similar amount of free 8Br-cGMP in the inner segment also caused an inward current, but smaller in amplitude and slower in time course than that generated by illuminating the outer segment (A). Importantly, this current exhibited a significant delay relative to the moment of presentation of the uncaging flash. The delay was $~$ 400 ms and is consistent with the expected transit time for a small molecule diffusing over a distance of $~$ 20 µm. The inner segment is $~$ 25-µm long.

In photoreceptor outer segment, entering Ca²⁺ is cleared bya Na⁺/Ca²⁺,K⁺ exchanger and the rate of clearance is fasterin cones than in rods (reviewed in Korenbrot 1995

). To investigatewhether this transport interferes with P_f determination, wemeasured currents and fluorescence in a bass single cone inthe presence and absence of extracellular Na⁺, conditions underwhich Ca²⁺ clearance through the Na⁺/Ca²⁺,K⁺ exchanger shouldbe active or inactive, respectively. Typical results are illustratedin Fig. 4. Similar observations were made in four other cells.In the presence of normal Ringer, the uncaging flash activateda transient, inward current and caused a decrease in fluorescence.3 min later, the same cell was superfused with a solution inwhich all Na⁺ was iso-osmotically replaced by guanidinium⁺.Guanidinium⁺ permeates CNG channels indistinguishably from Na⁺and, therefore, the flash-activated currents, as expected, werenearly identical under both ions. Guanidinium⁺ does not replaceNa⁺ in the Na⁺/Ca²⁺,K⁺ exchange, which, therefore, is inactive.The initial decrease in fluorescence was indistinguishable inthe presence of the two cations, but $~$ 12 s after the uncagingflash, the time course of fluorescence distinctly diverged.It was nearly stationary in the presence of Na⁺, but continuedto decline in the presence of guanidinium⁺ (Fig. 4). It wasnecessary to return to Na⁺ Ringer for the fluorescence to recoverits initial value. These results indicate that, in the presenceof an active exchanger, 2 mM fura-2 in the cytoplasm retainsthe entering Ca²⁺ for the first 10 s or so after channel opening.At longer times, a combination of binding saturation of fura-2and the activity of the exchanger compromises the retentionof Ca²⁺ by the fluorescent dye. The method of analysis presentedhere was applied only to data recorded over the first 6–8s after the uncaging flash.

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Figure 4 Membrane currents and fluorescence measured simultaneously in a single cone from striped bass loaded with 2 mM fura-2 and 50 µM caged 8Br-cGMP. Superimposed are currents measured in the same cell at –35 mV holding voltage in response to identical uncaging flashes delivered 6.5 min (Na⁺) or 8.5 min (Guanidinium⁺) after achieving whole-cell mode. The Na⁺ tracing was measured in the presence of the normal Ringer's solution, while the Guanidinium⁺ tracing was measured starting 15 s after switching the medium superfusing the cell from normal Ringer's to one in which Na⁺ was iso-osmotically replaced by guanidinium⁺. The holding current in the presence of Na⁺ was +22 pA, but it changed to –44 pA in the presence of guanidinium⁺. Currents were corrected to have their holding value be zero preceding the flash. Fluorescence intensity before the flash was the same. The flash-activated currents under both ionic conditions were essentially indistinguishable. The associated decrease in fluorescence were also indistinguishable at first, but began to diverge $~$ 12 s after the flash.

Fura-2 is at a sufficient concentration to outcompete endogenous buffers.
We verified that 2 mM fura-2 is a sufficient concentration bycomparing the P_f results obtained in the presence of 1 and 4mM fura-2. In both rods and cones, P_f data gathered under eitherconcentration were the same (data not shown, but see Fringset al. 2000

), indicating that the experimental condition holds.The same conclusion has been reached in previous studies withCNG channels expressed in mammalian cells (Frings et al. 1995

;Dzeja et al. 1999

P_f in Rod Outer Segments of Tiger Salamander
To determine the value of f, we measured cGMP-activated changesin current and fluorescence in dROS of tiger salamander in thepresence of the solutions listed in Table and Table . To determineP_f, it was also necessary to measure f_max, the value of f whenI_T = I_Ca (). To do so, we carried out experiments using thesame protocols used to measure f, but we exposed the cells tothe solutions listed in Table . Cells were maintained in normalRinger's and exposed only for $~$ 60 s to the extracellular testsolution to determine f_max. Extracellular Na⁺ and Mg²⁺ werereplaced by the impermeant cation choline, while maintainingCa²⁺ at the normal 1 mM. Intracellular Mg²⁺ and most of theK⁺ ions were also replaced with choline. A small amount of K⁺was retained in the intracellular test solutions to assure thatthe Na⁺/Ca²⁺,K⁺ exchanger operated in normal, Na⁺ Ringer's.At the intracellular K⁺ concentration selected and at –35mV holding voltage, the net K⁺ current was zero. Under f_maxconditions, Ca²⁺ is the only net charge carrier through theCNG channels.

In Fig. 5 are shown typical measurements of f and f_max in tigersalamander dROS. In the standard Ringer's at –35 mV, theholding current before the uncaging flash was essentially zeroand the flash caused a transient inward current and a decreasein fluorescence from its initial value. In the Ringer's, whereCa²⁺ ions are the only net charge carriers, the uncaging flashalso generated a transient inward current and a decrease influorescence intensity in dROS. Also shown in Fig. 5 are flash-inducedchanges in fluorescence and the integral of the current changes.These two data sets superimpose over a span of $~$ 5 s after theflash (Fig. 5, bottom). Superimposition is evidence that theconditions necessary to calculate f (see above) are met overthis restricted time span. We determined the singular valueof f, the ratio of the change in fluorescence to the currentintegral only over this restricted time span (f, bu/pC).

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Figure 5 Determination of the values of f and f_max in detached rod outer segments from tiger salamander. (Left and right) Records from different cells. (Top) Membrane currents and fluorescence measured simultaneously in rods loaded with 2 mM fura-2 and 50 µM caged 8Br-cGMP. Uncaging flashes activated transient, inward currents and a decrease in cell fluorescence. To analyze the data, currents were integrated over the time shown and the resulting charge is shown as a continuous line (pC, bottom). The flash-activated change in fluorescence was shifted to assign its average holding value preceding the flash to be zero (bottom). f is the ratio of the change in fluorescence to the integral of the change in current, measured over the time interval where the two scaled parameters superimpose fully. The value of f was measured under the normal physiological solution (Na⁺ Ringers). The value of f measured under experimental conditions designed to have Ca²⁺ be the exclusive, net charge carrier through the CNG ion channels (Choline⁺ Ringers), is defined as f_max. For the rods shown, under Na⁺ Ringers, the holding current was –4 pA, the peak current was 408 pA measured 10 min after achieving whole cell mode, and f was 0.00237. Under Choline⁺ Ringers, the holding current was –4 pA, the peak current was 159 pA measured 7 min after achieving whole cell mode, and f_max was 0.01154.

The mean peak photocurrent amplitude in tiger salamander rodsis $~$ 70 pA (Miller and Korenbrot 1994

). To determine the valueof P_f under conditions similar to those expected in the functionalretina, we restricted analysis to data sets in which uncagingflashes generated peak current amplitudes $≤$ 200 pA, with a meanvalue of 115 ± 53. The average value of f_max was 0.0112± 0.0019 bu/pC (13 measurements in eight different cells,range 0.0101–0.0130). The average value of f was 0.00238± 0.0009 bu/pC (n = 17). Hence, under these conditions,the average value of P_f (

) in tiger salamander rods is: 0.21± 0.01

We also measured P_f in dROS of gecko because the Ca²⁺ homeostasisof this organelle has been carefully and thoroughly studied(Gray-Keller and Detwiler 1994; Gray-Keller et al. 1999). Westudied this species less extensively than others and we pooleddata measured in cells over a much wider range of peak currentamplitudes. For currents between 210 and 1,048 pA in peak amplitude,the average f value was 0.0044 ± 0.0012 bu/pC (n = 4).Given f_max of 0.022 for these cells, the average value of P_fin gecko rods is 0.19 ± 0.05.

P_f in Single Cones of Striped Bass
In Fig. 6 are shown typical measurements of f and f_max in singlecones of striped bass. Shown are electrical and photometricdata both in standard Ringers solution and in one designed tohave Ca²⁺ ions as the only net charge carrier. The experimentaldata are qualitatively similar to that in dROS, uncaging flashescause a transient inward current and a decrease in fluorescence.We analyzed the experimental data to determine the values off and f_max as described above. For currents <200 pA in peakamplitude, the average value of f_max was 0.0098 ± 0.0014bu/pC (range 0.008–0.0125, n = 9). The average value off was 0.0032 ± 0.0011 bu/pC (n = 40). Hence, under theseconditions, the average value of P_f () in striped bass singlecones is 0.33 ± 0.02.

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Figure 6 Determination of the values of f and f_max in single cones from striped bass. (Top) Membrane currents and fluorescence measured simultaneously in cones loaded with 2 mM fura-2 and 50 µM caged 8Br-cGMP. Uncaging flashes activated transient, inward currents and a decrease in cell fluorescence. To analyze the data, both currents and fluorescence were shifted to have their average holding value be zero preceding the uncaging flash. Currents were integrated starting from this zero value (bottom, continuous line) and the integral was scaled and superimposed on the flash-generated change in fluorescence (bottom). f is the ratio of the current integral to the fluorescence over the time interval that the two superimpose. In different cells, we measured f under physiologic solutions (Na⁺ Ringers) and f_max under experimental conditions designed to have Ca²⁺ be the exclusive, net charge carrier through the CNG ion channels (Choline⁺ Ringers). For the cones shown, under Na⁺ Ringers, the holding current was 22 pA, the peak current was 75 pA measured 9 min after achieving whole cell mode, and f was 0.00382. Under Choline⁺ Ringers, the holding current was 0 pA, the peak current was 56 pA measured 4 min after achieving whole cell mode, and f_max was 0.01017.

P_f in Single Cones and Rods of Catfish
The two species described above, tiger salamander and stripedbass, are the ones in which most of the electrical studies ofion selectivity have been conducted. The rod versus cone differencesdescribed, however, could represent differences between species,rather than between photoreceptor types. This is unlikely sincerod/cone differences are also found in alpha subunit channelsof bovine photoreceptors (Frings et al. 1995

; Dzeja et al. 1999

).Nonetheless, we investigated the value of P_f in rods and conesof the same species.

In Fig. 7 are shown typical measurements in rods and cones ofcatfish. In this species, unlike tiger salamander or gecko,the detached rod outer segment includes a small portion of thecell's ellipsoid. Consequently, at –35 mV, the holdingcurrent preceding the uncaging flash was outward both in thedROS and the single cones. In both cell types, the uncagingflash caused an inward current and a decrease in fluorescence.For uncaging flashes of the same intensity, the amplitude ofthe inward currents (and its concomitant change in fluorescence)was always smaller in cones than in rods. This almost certainlyreflects the fact that the sensitivity for cGMP is higher inchannels of rods than in those of cones (Haynes and Yau 1990;Rebrik and Korenbrot 1998).

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Figure 7 Determination of the values of f in single cones and rods from catfish under physiologic solutions. (Top) Membrane currents and fluorescence measured simultaneously in photoreceptors loaded with 2 mM fura-2 and 50 µM caged 8Br-cGMP. Uncaging flashes activated transient, inward currents and a decrease in cell fluorescence. To analyze the data, both currents and fluorescence were shifted to have their average holding value be zero preceding the uncaging flash (bottom). Currents were integrated starting from this zero value (bottom, continuous line) and the integral was scaled and superimposed on the flash-generated change in fluorescence. f is the ratio of the current integral to the fluorescence, over the time interval that the two superimpose. For the cone shown, the holding current was 11 pA, the peak current was 85 pA measured 4 min after achieving whole cell mode, and f was 0.0031. For the rod shown, the holding current was 45 pA, the peak current was 97 pA measured 11 min after achieving whole cell mode and f was 0.0022.

We determined the values of f (Fig. 7) and f_max (data not shown)for rods and cones of the catfish.

Cones.
For currents <75 pA in peak amplitude (range 30–75pA), the average value of f_max was 0.0087 ± 0.0031 bu/pC(nine determinations in six cells). For currents <200 pAin peak amplitude, the average f value was 0.00295 ±0.0013 bu/pC (17 determinations in 11 cells). Under these conditions,the average value of P_f was 0.34 ± 0.06.

Rods.
For currents <50 pA in peak amplitude (range 13–40pA), the average value of f_max was 0.0124 ± 0.0028 bu/pC(seven determinations in four cells). For currents <220 pAin peak amplitude, the average f value was 0.00174 ±0.0005 bu/pC (19 determinations in 12 cells). Under these conditions,the average value of P_f was 0.14 ± 0.01.

The values of P_f at –35 mV holding voltage, for cGMP-dependentcurrents <200 pA in amplitude and in the presence of 1 mMexternal Ca²⁺ for the species studied here, are compared inFig. 8. The differences in Ca²⁺ fractional current between rodsand cones are thus features preserved across species.

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Figure 8 Mean (± SD) of the fractional Ca²⁺ flux (P_f) measured in rods and cones of several species under normal Ringers solutions. The data were pooled from measurements in cells held at –35 mV, in the presence of 1 mM external Ca²⁺ and for cGMP-dependent currents $≤$ 200 pA in peak current amplitude.

Interaction between Ca²⁺ and CNG Channels Are Reflected in the Value of P_f and Differs Between Channels of Rods and Cones
We measured the current and fluorescence changes caused by identicalflashes delivered to the same cell bathed in varying amountsof Ca²⁺ (Table ). Cells were superfused with test solution beginning15 s before the flash and for the course of the measurement(30 s). Otherwise, cells were maintained in the normal Ringer's.We waited 2–3 min between flashes, time sufficient forcells to recover to their starting conditions. We analyzed onlydata in which these starting values differed by <10%. Wetested various Ca²⁺ concentrations in random sequence, but alwaysstarted at the normal 1 mM Ca²⁺.

In Fig. 9 are shown typical data measured in striped bass singlecones and tiger salamander dROS. We illustrate fluorescencechanges and the integral of the current scaled to optimallyfit the changes in fluorescence. For both photoreceptor types,the data shown were measured at 3-min intervals in the samecell bathed with varying external Ca²⁺ concentrations. The signal-to-noiseratio in the photometric cone data is significantly less thanin those of rods because bass cone outer segments are only aboutone tenth the volume of the tiger salamander's rod outer segments.In cones, the average f values we measured were: at 0.5 mM Ca²⁺,0.00129 ± 0.00018; at 1 mM Ca²⁺, 0.00295 ± 0.00049;at 1.5 mM Ca²⁺, 0.00383 ± 0.00113; at 2 mM Ca²⁺, 0.00421± 0.0015; at 2.5 mM Ca²⁺, 0.00518 ± 0.0021; andat 5 mM Ca²⁺, 0.00952 ± 0.00603. Data were measured ina total of 10 cells, with any one concentration sampled in 3–10cells. Thus, fractional Ca²⁺ current increased steeply withCa²⁺ concentration. The dependence of P_f on Ca²⁺ was well describedby the Michaelis-Menten function:

Formula 12 (12)

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Figure 9 Dependence of fractional Ca²⁺ flux (P_f) on external Ca²⁺ concentration. (Top) Data measured in a tiger salamander dROS (left) and a striped bass single cone (right). For each photoreceptor type, data shown were measured in the same cell in the presence of Ringers containing different Ca²⁺ concentrations, as labeled. Shown are the flash-activated changes in fluorescence and the integral of the flash-activated changes in current (continuous line) scaled to match. For the dROS shown, Ihold throughout was –4 pA. At 1 mM Ca²⁺ (4 min after achieving whole-cell mode), Ipeak = 690 pA; at 2.5 mM Ca²⁺ (6 min), Ipeak = 354; at 5 mM Ca²⁺ (8 min), Ipeak = 300. For the cone shown, at 1 mM Ca²⁺ (4 min), Ihold = 20 pA, Ipeak = 162 pA; at 1.5 mM Ca²⁺ (8 min), Ihold = 12 pA, Ipeak = 97 pA; at 2 mM Ca²⁺ (10 min), Ihold = 20 pA, Ipeak = 162 pA. (Bottom) Mean value of P_f as a function of Ca²⁺. The continuous line is an optimum fit to the experimental data of the Michaelis-Menten function (

). For cones, the best fit was obtained with KCa = 1.98 mM, and for rods KCa = 4.96 mM.

KCa is the value at which P_f = 0.5. We obtained the best fitto the mean of the data with KCa = 1.98 mM.

In rods, the fractional Ca²⁺ current also increased with externalCa²⁺, but much less steeply than in cones and, even at 10 mM,external Ca²⁺ carries only about half the current (Fig. 9).The average f values we measured were: at 1 mM Ca²⁺, 0.00286± 0.000883; at 2.5 mM Ca²⁺, 0.003812 ± 0.00098;at 5 mM Ca²⁺, 0.005713 ± 0.004314; and at 10 mM Ca²⁺,0.00668 ± 0.000496. Data were measured in a total ofnine cells, with any one concentration sampled in four to ninecells. We note that in this data set, the mean value of P_f at1 mM Ca²⁺ was 0.25 ± 0.043. This value is slightly largerthan the mean value presented above because the data set includedpeak 8Br-cGMP-dependent current of amplitude $≤$ 1,000 pA, witha mean value of 454 ± 347 pA. The mean value of P_f issmaller for currents $≤$ 200 pA because selectivity is linked togating in rod CNG channels (Hackos and Korenbrot 1999). Thebest fit of the Michaelis-Menten function () to the mean ofthe rod data was obtained with KCa = 4.96 mM (Fig. 9).

DISCUSSION

Top
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have directly measured the fraction of the cGMP-gated currentcarried by Ca²⁺ in the outer segment of intact rods and cones.Ca²⁺ carries 14–20% of the dark current in rods and 32–34%in cones. The differences in fractional Ca²⁺ flux between rodsand cones are maintained across several species.

Our results in rods are similar to those of indirect measurementspreviously reported by others, and based on an analysis of thecurrent generated by the electrogenic transport activity ofNa⁺/Ca²⁺,K⁺ exchangers in the outer segment membrane (Nakataniand Yau 1988; Lagnado et al. 1992; Gray-Keller and Detwiler1994; Younger et al. 1996). Such analyses require the unambiguousseparation of the exchanger current from the photocurrent, aswell as assumptions about transport stoichiometry. The indirectstudies have set the value of P_f in rods anywhere between 0.10and 0.18. The similarity of present and past results in rodsconfirms the accuracy of the indirect method and extends theobservation to several species.

Our results in cones are in quantitative disagreement with thosereported by Perry and McNaughton 1991, based on analysis ofthe electrogenic exchanger currents in tiger salamander cones.Perry and McNaughton 1991 correctly recognized that the fractionof the dark current carried by Ca²⁺ current is higher in conesthan in rods. Their estimate of this fraction, however, is smallerthan the results we have found. They estimated that P_f is 0.12in rods and 0.21 in cones. This difference likely reflects theuncertainty in separating the exchanger from the conductivecurrents. The exchanger current in rods of lower vertebratesdecays with an exponential time course of several hundred millisecondsor seconds time constant (Nakatani and Yau 1988; Lagnado etal. 1992; Gray-Keller and Detwiler 1994; Younger et al. 1996).In cones, in contrast, the exponential decay of the exchangercurrent has a time constant of tens of milliseconds duration(Hestrin and Korenbrot 1990; Perry and McNaughton 1991).

Previous electrical studies had established that the selectivityof Ca²⁺ over Na⁺, PCa/PNa, measured from reversal potentialsis higher in CNG channels of cones than in those of rods (Fringset al. 1995; Picones and Korenbrot 1995). These measurements,however, are conducted under simple ionic solutions, with onlyCa²⁺ and Na⁺ present. Extending them to determine the fractionalCa²⁺ flux under normal physiological solutions is complex andrequires application of a specific model of ion permeation.Wells and Tanaka 1997 have developed a plausible model basedon Eyring rate theory that successfully simulates PCa/PNa, I-Vcurves and the Ca²⁺ fractional flux in rod CNG channels. Themodel presumes the existence of three barriers, two wells, andfour sites that interact electrostatically (each for Na⁺, K⁺Ca²⁺ and Mg²⁺). Similar but less elaborate models were firstformulated and analyzed by Zimmerman and Baylor 1992. A comparablycomplete computation has not been reported for cone CNG channels.However, a simpler Eyring-type model consisting of one barrierand two wells has been successfully used to analyze monovalentcation selectivity in cone CNG channels (Picones and Korenbrot1992; Haynes 1995).

An indirect conclusion supported by our results is that strongbuffering sites for cyclic nucleotides operate in intact rodand cone outer segments of all species tested. The sites arerelatively fast in kinetics, their K_d is high and they are activein the cyclic nucleotide concentration range expected undernormal operating conditions in the cell. Biochemical analysissuggests that, in rods, the cGMP binding sites are noncatalyticsites on phosphodiesterase (Cote and Brunnock 1993). The sitesare not functionally different in rods and cones.

There are significant physiological consequences to accuratelyknowing the value of P_f. Cytoplasmic Ca²⁺ homeostasis in thephotoreceptor outer segment arises from the dynamic balanceof influx, efflux, and buffering by endogenous sites, with norole recognized for transport in or out of intracellular compartments.Knowing the value of P_f, therefore, is crucial to understandingCa²⁺ dynamics. This is made particularly clear by computationalmodels developed to explain in molecular detail the phototransductionprocess. Particularly detailed and thorough models have beenput forward (Forti et al. 1989; Sneyd and Tranchina 1989; Torreet al. 1990; Nikonov et al. 1998). Every one of these modelsincludes an explicit term for P_f, and the value assigned tothis parameter strongly affects the performance of the model.

The difference in P_f between rod and cone channels implies thatlight-dependent changes in Ca²⁺ concentration caused by equalamplitude currents will be larger in cones than in rods. Thisfact, added to the known difference in the clearance rate ofCa²⁺ from the outer segment indicates that, for a given currentresponse, Ca²⁺ concentration changes will be larger and fasterin cones than in rods. These differences contribute to explainingthe dissimilarity in the photosensitivity, kinetics, and light-and dark-adaptation characteristics of the two photoreceptortypes.

Differences in P_f between rod and cone channels reflect differencesin the molecular interaction between the cation and the channelprotein. Seifert et al. 1999 studied homomeric channels formedfrom ${alpha}$ subunits of CNG channels cloned from olfactory neurons,rod, and cone photoreceptors and Drosophila. They discoveredthat the interaction between extracellular Ca²⁺ and the channelsdiffers among channels cloned from different cell types (rodversus cone versus olfactory), but not among channels clonedfrom the same cell type in different species (bovine versuschicken versus rabbit). Again, a unique CNG channel structure/functionis associated with a specific cell type, regardless of the animalspecies in which the cell is found.

Mutagenesis analysis has demonstrated than in recombinant homomericalpha CNG channels, Ca²⁺ interacts with a glutamate residuewithin the pore loop of the channel (E363) (Root and Mackinnon1993; Eismann et al. 1994). Although the same residue existsin the pore of all CNG alpha channels, the thermodynamics ofthe interaction between Ca²⁺ and glutamate E363 differs amongCNG channels. For example, the extracellular Ca²⁺ concentrationthat blocks channel conductance by 50% at –70 mV is 7µM in rods, but 68 µM in cones (Seifert et al. 1999).Thus, structural features of E363 alone cannot explain the characteristicsof the interaction between Ca²⁺ and the CNG channels. Recentwork has demonstrated that the Ca²⁺/E363 interaction changeswith the state of protonation of the residue, which, in turn,is controlled by structural features of the regions of the proteinadjacent to the pore, the S5 and S6 loops (Seifert et al. 1999).The S5-pore-S6 "structural module" differs among recombinantalpha channels depending on the cellular source of the cDNA(Seifert et al. 1999).

The molecular view of the interaction between Ca²⁺ and the S5-pore-S6structural module obtained from experiments with recombinanthomomeric alpha CNG channels cannot simply be extended to thestructure of the native photoreceptor channels. Native channelsin both rods and cones are formed from alpha and beta subunits.Rod channels are formed by two alpha and two beta subunits,although the sequence of these subunits is controversial (Shammatand Gordon 1999; He et al. 2000). Two striking differences existbetween native and recombinant alpha channels with respect totheir Ca²⁺ fractional currents. (a) In the presence of 1 mMexternal Ca²⁺, P_f in native cone channels is about twice thatin rods, but in alpha recombinant channels this is reversed:P_f in rods is about three times larger than that in cones. (b)The Ca²⁺ dependence of P_f is extremely steep in rod alpha recombinantchannels, but remarkably shallow in native rod channels. Inrecombinant channels, the Ca²⁺ concentration at which P_f = 0.5is 0.4 mM and P_f is essentially 1 when Ca is only 1 mM (Dzejaet al. 1999). In the native channel, P_f is 0.2 at 1 mM Ca²⁺and even when Ca²⁺ is 10 mM, P_f is still only $~$ 0.5.

A structural understanding of the differences between recombinantalpha and native channels is not at hand, but, if we extendthe information gained from the structural studies of Seifertet al. 1999, the functional differences likely reflect differencesin the dielectric environment surrounding the pore glutamate.Differences in dielectric environment can arise from two possiblesources or their combination. The obvious first possibilityis that the beta subunits, which have a glycine instead of aglutamate in the pore loop, create a pore sufficiently unlikethat in alpha channels as to explain the difference. A secondpossibility is that the dielectric environment is changed byMg²⁺ ions. The results reported here were all measured in thepresence of 1 mM external Mg²⁺ and 0.5 mM free cytoplasmic Mg²⁺.The studies of alpha recombinant channels were conducted inthe absence of external Mg²⁺ and with 0.27 mM free cytoplasmicMg²⁺ (Dzeja et al. 1999). Because the channels bind Mg²⁺ almostas well as Ca²⁺, the presence of Mg²⁺ must influence the interactionbetween Ca²⁺ and the channel (Wells and Tanaka 1997). The roleof these two possible mechanisms needs to be resolved experimentally.

It is notable that, whereas the dependence of P_f on outsideCa²⁺ differs significantly between native and recombinant rodchannels, this is not the case for cone channels. In both nativeand recombinant cone channels, the Michaelis-Menten functiondescribes well the dependence of P_f on Ca²⁺, with KCa = 1.38mM in alpha recombinant channels (Dzeja et al. 1999) and KCa= 1.98 mM in native ones. This characteristic of the channelsis similar despite the fact that measurements were conductedin the absence of Mg²⁺ in recombinant proteins and with 1 mMoutside Mg²⁺ in the native cells. If the presence of beta subunitsis important in defining the interaction of divalent cationswith native channels, our results suggest that the alpha/betasubunit interactions differ in rods and cones. Future work shouldprovide information on the mechanisms of this difference.

We investigated possible mechanisms to explain the surprisinglyrapiddecay of the outer segment current generated by uncaging8Br-cGMP(2). If 8Br-cGMP were not processed within the outersegment,it would be reasonable to expect a slow decay in currentafterthe uncaging flash due to equilibration of freed 8Br-cGMPbetweencytoplasm and electrode lumen. To determine the rateof thisequilibration, we used tight-seal electrodes filledwith theusual solution () containing, in addition, 30 µM8Br-cGMP,and we monitored the membrane current after membraneruptureto attain whole-cell mode. 10 illustrates a typicalresult inbass single cones at –35-mV holding voltage.After membranerupture, an inward current developed withoutdetectable delaythat reached a maximum in $~$ 52 s. In eight differentcells, themean time to the maximum was 73.6 ± 22.3 s.Since currentdecay after an uncaging flash is much, much faster(above),its time course cannot be explained by the rate ofcell/electrodeequilibration.

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Figure 10 (Top) Rate of 8Br-cGMP loading of a bass single cone by equilibration between the cell and the lumen of a tight-seal electrode. (WCR) The moment the membrane under the electrode tip was ruptured. Inward current (at –35 mV holding voltage) is activated by the continuously rising concentration of 8Br-cGMP in the cone outer segment. A maximum current is reached in $~$ 52 s. The transients on the membrane current at the earliest times after attaining WCR are currents generated by 200-ms duration, 5-mV voltage steps applied to ascertain cell integrity. (Bottom) Hydrolysis of free cyclic nucleotide by PDE does not explain the decay of current generated by uncaging light flashes. (Bottom, left) Membrane current measured at –35 mV in a single cone loaded with 50 µM caged cGMP in the presence of 0.1 mM IBMX added to the bathing Ringers solution. A brief, bright flash uncaged the nucleotide and caused an inward current that reached peak in $~$ 30 ms, and then decayed exponentially with a 0.24 s time constant. The same behavior is observed in the absence of the PDE blocker. (Bottom, right) Membrane current measured at –35 mV in a single cone loaded with 15 µM free 8Br-cGMP. An uncaging flash was delivered at the moment indicated by the arrow. The flash caused a rapid transient, an artifact due to the discharge of the Xenon lamp, but the current was otherwise unchanged, indicating that light-activated PDE did not hydrolyze 8Br-cGMP at this concentration.

Rapid current decay could reflect hydrolysisof free 8Br-cGMPby phosphodiesterase (PDE) activated by theuncaging flash.This is plausible because, while 8Br-cGMP is $~$ 100-fold less effectivethan cGMP as a substrate of rod PDE(Zimmerman et al. 1985

),it can, if present at a sufficientlyhigh concentration, behydrolyzed by activated PDE. Indeed,bright lights generatephotocurrents in rods loaded with highconcentrations of 8Br-cGMP(0.5–1 mM) (Cameron and Pugh1990

). To test whether currentinactivation reflects 8Br-cGMPhydrolysis by PDE, we conductedtwo control experiments. Inthe first one, we measured in singlecones the current generatedby uncaging cGMP in the continuouspresence of 0.1 mM 3-isobutyl-1-methylxanthine(IBMX), an effectiveblocker of cone PDE (Gillespie and Beavo1989

). The currentrapidly reached a peak and, in spite of thepresence of IBMX,it decayed with an exponential time coursesimilar to that measuredin the absence of the blocker (10).In a second control experiment,we tested whether the uncagingflash generated a photoresponsein single cones loaded with15 µM 8Br-cGMP. We do notknow the exact concentrationof free 8Br-cGMP generated by theuncaging flash, but consideringthat K_1/2, the nucleotide concentrationthat half activatesthe maximum CNG current in the intact conein the absence ofCa²⁺, is $~$ 15 µM (Rebrik and Korenbrot1998

), the concentrationnecessary to generate 200 pA currentis $~$ 5.5 µM. Even inthe presence of 15 µM 8Br-cGMP,the flash did not causea photocurrent (10). We can, therefore,reject the hypothesisthat current decay is caused by 8Br-cGMPhydrolysis.

Ca²⁺modulates ligand sensitivity of CNG channels in both rods(Hsuand Molday 1993; Gordon et al. 1995; Sagoo and Lagnado1996;Bauer 1996) and cones (Rebrik and Korenbrot 1998). Therefore,itis possible that current decay reflects a decrease in CNGchannelsensitivity to free ligand, caused by a rise in cytoplasmicCa²⁺associated with the enhanced current. Such modulation,however,is unlikely to occur under our experimental conditionsbecausechanges in cytoplasmic free Ca²⁺ are vanishingly smallin thefirst 6–8 s after the uncaging flash due to thepresenceof 2 mM fura-2.

We propose that the rapid current declinearises from bindingof free 8Br-cGMP to specific sites in rodand cone outer segments.The existence of cGMP-binding sitesin rod outer segments hasbeen inferred from analysis of cGMPdiffusion kinetics (Olsonand Pugh 1993; Koutalos et al. 1995)and measured biochemically(Cote and Brunnock 1993). These sitesare presumed to be theknown noncatalytic nucleotide bindingsites on PDE molecules(Hebert et al. 1998). To test this hypothesis,we carried outa competition experiment in the intact cell.The noncatalyticbinding site in the rod PDE binds cIMP (3'-5'cyclic inosinemonophosphate) with $~$ 20-fold higher affinity than8Br-cGMP (Hebertet al. 1998). On the other hand, the ligandsensitivity of therod CNG channels for cIMP is $~$ 0.006-fold thatfor 8Br-cGMP. K_1/2is $~$ 8 µM for 8Br-cGMP, but $~$ 1.2 mM forcIMP (Tanaka et al.1989). Based on these quantities, simplecalculations indicatethat 20 µM cIMP should not activatethe CNG channels (<0.003%),but should significantly reducebinding of free 8Br-cGMP tothe PDE. If 8Br-cGMP binding isreduced by cIMP, this shouldbe apparent by a slowdown in thekinetics of binding of 8Br-cGMPin the presence of cIMP, whencompared to the kinetics of bindingin the absence of cIMP.This is indeed the case (11).

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Figure 11 Kinetics of membrane currents in tiger salamander dROS activated by uncaging 8Br-cGMP in the presence of 20 µM cIMP added to the cytoplasm. (Top) Currents measured in the same cell at –35 mV holding voltage and generated by uncaging flashes of varying intensity presented at the moment indicated by the vertical arrow. Each flash caused an inward, transient current that did not fully recover its starting value in between flashes. Peak currents (and time after attaining whole-cell mode) were 710 pA (6 min), 172 pA (8 min), and 1,175 pA (10 min). The currents decayed from their peak at a rate well described by a single exponential, yet this rate of decay was slower than that measured under similar conditions but in the absence of cIMP. (Bottom) Flash-activated currents of similar peak amplitude measured in two different dROS. The ordinate scales for the two currents shown are adjusted to match the current's peak amplitude. The continuous trace was measured in the presence of 20 µM cIMP, while the dotted trace was measured in a different dROS in the absence of cIMP.

We measured in tiger salamanderdROS the current activated byuncaging 8Br-cGMP in the presenceof 20 µM cIMP. We filledtight-seal electrodes with thestandard solution containingcaged 8Br-cGMP and fura-2 (

) withan additional 20 µMcIMP. The mean holding current wasunaffected, indicating that,as expected, cIMP at this concentrationdid not activate CNGchannels. An uncaging flash caused a transientinward currentof peak amplitude dependent on the intensityof the uncagingflash (11). The current activated rapidly, andthen declinedfrom the peak towards its starting value. Therate of decline,however, was much slower than in the absenceof cIMP (11, alsocompare with 2). The time course of the currentdecay from itspeak was well described by a single exponentialwith a meandecay time constant of 2.34 ± 1.1 s (range1.32–3.98,n = 10). The decay time constant in the absenceof cIMP was $~$ 0.84 s (see RESULTS). On average, then, the rateof decay ofcurrents activated by uncaging 8Br-cGMP was aboutthreefoldslower in the presence of 20 µM cIMP than inits absence(11). Mathematical simulations of binding kineticsof the nucleotideto a single site (not shown) indicate thatthe slowdown in currentis consistent with cIMP having reducedthe number of availablesites for 8Br-cGMP binding by $~$ 70%. Ourexperimental resultsare consistent with the proposition thatfree 8Br-cGMP bindsto specific sites in the photoreceptor outersegment and thatthese sites select cIMP over 8Br-cGMP in amanner similar tothat described for rod PDE (Hebert et al.1998

). Data on nucleotidebinding are not available for coneouter segments (or cone PDE),but binding is likely quantitativelysimilar to that in rodssince current decay after the uncagingflash was nearly thesame in the two photoreceptor types.

Dr. Hackos' present address is Molecular Physiology and BiophysicsUnit, National Institute of Neurological Disease and Stroke,National Institutes of Health, Bethesda, MD 20892.116

Abbreviations used in this paper: bu, bead unit; CNG, cyclicnucleotide–gated; dROS, detached rod outer segment; IBMX,3-isobutyl-1-methylxanthine; PDE, phosphodiesterase; PMT, photomultipliertube.

Submitted: 18 July 2000
Revised: 30 August 2000
Accepted: 2 October 2000

REFERENCES

Top
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

Barnes S. & Hille B.. Ionic channels of the inner segment of tiger salamander cone photoreceptors, J. Gen. Physiol, 94, 1989, 719–743.[Abstract/Free Full Text]

Bauer P.J.. Cyclic GMP-gated channels of bovine rod photoreceptorsaffinity, density and stoichiometry of Ca(2+)-calmodulin binding sites, J. Physiol, 494, 1996, 675–685.[Abstract/Free Full Text]

Baylor D.A. & Nunn B.J.. Electrical properties of the light-sensitive conductance of rods of the salamander Ambystoma tigrinum, J. Physiol, 371, 1986, 115–145.[Abstract/Free Full Text]

Bevington P., Data reduction and error analysis for the physical sciences, 1992, McGraw-Hill Inc, New Yorkpp. 336 p.

Cameron D.A. & Pugh E.N. Jr.. The magnitude, time course and spatial distribution of current induced in salamander rods by cyclic guanine nucleotides, J. Physiol, 430, 1990, 419–439.[Abstract/Free Full Text]

Cervetto L., Menini A., Rispoli G. & Torre V.. The modulation of the ionic selectivity of the light-sensitive current in isolated rods of the tiger salamander, J. Physiol, 406, 1988, 181–198.[Abstract/Free Full Text]

Corey D.P., Dubinsky J.M. & Schwartz E.A.. The calcium current in inner segments of rods from the salamander (Ambystoma tigrinum) retina, J. Physiol, 354, 1984, 557–575.[Abstract/Free Full Text]

Cote R.H. & Brunnock M.A.. Intracellular cGMP concentration in rod photoreceptors is regulated by binding to high and moderate affinity cGMP binding sites, J. Biol. Chem, 268, 1993, 17190–17198.[Abstract/Free Full Text]

Dzeja C., Hagen V., Kaupp U.B. & Frings S.. Ca²⁺ permeation in cyclic nucleotide-gated channels, EMBO (Eur. Mol. Biol. Organ.) J, 18, 1999, 131–144.[Medline]

Eismann E., Muller F., Heinemann S.H. & Kaupp U.B.. A single negative charge within the pore region of a cGMP-gated channel controls rectification, Ca²⁺ blockage, and ionic selectivity, Proc. Natl. Acad. Sci. USA, 91, 1994, 1109–1113.[Abstract/Free Full Text]

Forti S., Menini A., Rispoli G. & Torre V.. Kinetics of phototransduction in retinal rods of the newt Triturus cristatus, J. Physiol, 419, 1989, 265–295.[Abstract/Free Full Text]

Frings S., Hackos D.H., Dzeja C., Ohyama T., Hagen V., Kaupp U.B. & Korenbrot J.I.. Determination of fractional calcium ion current in cyclic nucleotide–gated channels, Methods Enzymol, 315, 2000, 797–817.[Medline]

Frings S., Seifert R., Godde M. & Kaupp U.B.. Profoundly different calcium permeation and blockage determine the specific function of distinct cyclic nucleotide–gated channels, Neuron, 15, 1995, 169–179.[Medline]

Gillespie P.G. & Beavo J.A.. Inhibition and stimulation of photoreceptors phosphodiesterase by dipyridamole and M&B 22,948, Mol. Pharmacol, 36, 1989, 773–781.[Abstract]

Gordon S.E., Downing-Park J. & Zimmerman A.L.. Modulation of the cGMP-gated ion channel in frog rods by calmodulin and an endogenous inhibitory factor, J. Physiol, 486, 1995, 533–546.[Abstract/Free Full Text]

Gray-Keller M., Denk W., Shraiman B. & Detwiler P.B.. Longitudinal spread of second messenger signals in isolated rod outer segments of lizards, J. Physiol, 519, 1999, 679–692.[Abstract/Free Full Text]

Gray-Keller M.P. & Detwiler P.B.. The calcium feedback signal in the phototransduction cascade of vertebrate rods, Neuron, 13, 1994, 849–861.[Medline]

Hackos D.H. & Korenbrot J.I.. Calcium modulation of ligand affinity in the cGMP-gated ion channels of cone photoreceptors, J. Gen. Physiol, 110, 1997, 515–528.[Abstract/Free Full Text]

Hackos D.H. & Korenbrot J.I.. Divalent cation selectivity is a function of gating in native and recombinant cyclic nucleotide–gated ion channels from retinal photoreceptors, J. Gen. Physiol, 113, 1999, 799–818.[Abstract/Free Full Text]

Hagen V., Dzeja C., Frings S., Bendig J., Krause E. & Kaupp U.B.. Caged compounds of hydrolysis-resistant analogues of cAMP and cGMPsynthesis and application to cyclic nucleotide–gated channels, Biochemistry, 35, 1996, 7762–7771.[Medline]

Hagen V., Dzeja C., Bendig J., Baeger I. & Kaupp U.B.. Novel caged compounds of hydrolysis-resistant 8-Br-cAMP and 8-Br-cGMPphotolabile NPE esters, J. Photochem. Photobiol. B, 42, 1998, 71–78.[Medline]

Haynes L.W.. Permeation of internal and external monovalent cations through the catfish cone photoreceptor cGMP-gated channel, J. Gen. Physiol, 106, 1995, 485–505.[Abstract/Free Full Text]

Haynes L.W. & Yau K.-W.. Single channel measurement from the cGMP-activated conductance of catfish retinal cones, J. Physiol, 429, 1990, 451–481.[Abstract/Free Full Text]

He Y., Ruiz M. & Karpen J.W.. Constraining the subunit order of rod cyclic nucleotide-gated channels reveals a diagonal arrangement of like subunits, Proc. Natl. Acad. Sci. USA, 97, 2000, 895–900.[Abstract/Free Full Text]

Hebert M.C., Schwede F., Jastorff B. & Cote R.H.. Structural features of the noncatalytic cGMP binding sites of frog photoreceptor phosphodiesterase using cGMP analogs, J. Biol. Chem, 273, 1998, 5557–5565.[Abstract/Free Full Text]

Hestrin S. & Korenbrot J.I.. Effects of cyclic GMP on the kinetics of the photocurrent in rods and in detached rod outer segments, J. Gen. Physiol, 90, 1987, 527–551.[Abstract/Free Full Text]

Hestrin S. & Korenbrot J.I.. Activation kinetics of retinal cones and rodsresponse to intense flashes of light, J. Neurosci, 10, 1990, 1967–1973.[Abstract]

Hodgkin A.L., McNaughton P.A. & Nunn B.J.. The ionic selectivity and calcium dependence of the light-sensitive pathway in toad rods, J. Physiol, 358, 1985, 447–468.[Abstract/Free Full Text]

Hsu Y.T. & Molday R.S.. Modulation of the cGMP-gated channel of rod photoreceptor cells by calmodulin, Nature, 361, 1993, 76–79.[Medline]

Kao J.P. & Tsien R.Y.. Ca²⁺ binding kinetics of fura-2 and azo-1 from temperature-jump relaxation measurements, Biophys. J, 53, 1988, 635–639.[Medline]

Karpen J.W., Zimmerman A.L., Stryer L. & Baylor D.A.. Gating kinetics of the cyclic-GMP-activated channel of retinal rodsflash photolysis and voltage-jump studies, Proc. Natl. Acad. Sci. USA, 85, 1988, 1287–1291.[Abstract/Free Full Text]

Korenbrot J.I.. Ca²⁺ flux in retinal rod and cone outer segmentsdifferences in Ca²⁺ selectivity of the cGMP-gated ion channels and Ca²⁺ clearance rates, Cell Calc, 18, 1995, 285–300.[Medline]

Koutalos Y., Brown R.L., Karpen J.W. & Yau K.W.. Diffusion coefficient of the cyclic GMP analog 8-(fluoresceinyl) thioguanosine 3',5' cyclic monophosphate in the salamander rod outer segment, Biophys. J, 69, 1995, 2163–2167.[Medline]

Lagnado L., Cervetto L. & McNaughton P.A.. Calcium homeostasis in the outer segments of retinal rods from the tiger salamander, J. Physiol, 455, 1992, 111–142.[Abstract/Free Full Text]

Maricq A.V. & Korenbrot J.I.. Calcium and calcium-dependent chloride currents generate action potentials in solitary cone photoreceptors, Neuron., 1, 1988, 503–515.[Medline]

Maricq A.V. & Korenbrot J.I.. Potassium currents in the inner segment of single retinal cone photoreceptors, J. Neurophysiol, 64, 1990, 1929–1940.[Abstract/Free Full Text]

Miller D.L. & Korenbrot J.I.. Kinetics of light-dependent Ca fluxes across the plasma membrane of rod outer segmentsa dynamic model of the regulation of the cytoplasmic Ca concentration, J. Gen. Physiol, 90, 1987, 397–425.[Abstract/Free Full Text]

Miller J.L. & Korenbrot J.I.. Phototransduction and adaptation in rods, single cones, and twin cones of the striped bass retinaa comparative study, Vis. Neurosci, 10, 1993, 653–667.[Medline]

Miller J.L. & Korenbrot J.I.. Differences in calcium homeostasis between retinal rod and cone photoreceptors revealed by the effects of voltage on the cGMP-gated conductance in intact cells, J. Gen. Physiol, 104, 1994, 909–940.[Abstract/Free Full Text]

Nakatani K. & Yau K.W.. Calcium and magnesium fluxes across the plasma membrane of the toad rod outer segment, J. Physiol, 395, 1988, 695–729.[Abstract/Free Full Text]

Nakatani K. & Yau K.W.. Sodium-dependent calcium extrusion and sensitivity regulation in retinal cones of the salamander, J. Physiol, 409, 1989, 525–548.[Abstract/Free Full Text]

Neher E.. The use of fura-2 for estimating Ca buffers and Ca fluxes, Neuropharmacology, 34, 1995, 1423–1442.[Medline]

Nikonov S., Engheta N. & Pugh E.N. Jr.. Kinetics of recovery of the dark-adapted salamander rod photoresponse, J. Gen. Physiol, 111, 1998, 7–37.[Abstract/Free Full Text]

Olson A. & Pugh E.N. Jr.. Diffusion coefficient of cyclic GMP in salamander rod outer segments estimated with two fluorescent probes, Biophys. J, 65, 1993, 1335–1352.[Medline]

Perry R.J. & McNaughton P.A.. Response properties of cones of the retina of the tiger salamander, J. Physiol, 433, 1991, 561–587.[Abstract/Free Full Text]

Picones A. & Korenbrot J.I.. Permeation and interaction of monovalent cations with the cGMP-gated channel of cone photoreceptors, J. Gen. Physiol, 100, 1992, 647–673.[Abstract/Free Full Text]

Picones A. & Korenbrot J.I.. Permeability and interaction of Ca²⁺ with cGMP-gated ion channels differ in retinal rod and cone photoreceptors, Biophys. J, 69, 1995, 120–127.[Medline]

Rebrik T.I. & Korenbrot J.I.. In intact cone photoreceptors, a Ca²⁺-dependent, diffusible factor modulates the cGMP-gated ion channels differently than in rods, J. Gen. Physiol, 112, 1998, 537–548.[Abstract/Free Full Text]

Rispoli G., Sather W.A. & Detwiler P.B.. Visual transduction in dialysed detached rod outer segments from lizard retina, J. Physiol, 465, 1993, 513–537.[Abstract/Free Full Text]

Root M.J. & Mackinnon R.. Identification of an external divalent cation-binding site in the pore of a cGMP-activated channel, Neuron, 11, 1993, 459–466.[Medline]

Sagoo M.S. & Lagnado L.. The action of cytoplasmic calcium on the cGMP-activated channel in salamander rod photoreceptors, J. Physiol, 497, 1996, 309–319.[Abstract/Free Full Text]

Seifert R., Eismann E., Ludwig J., Baumann A. & Kaupp U.B.. Molecular determinants of a Ca²⁺-binding site in the pore of cyclic nucleotide-gated channelsS5/S6 segments control affinity of intrapore glutamates, EMBO (Eur. Mol. Biol. Organ.) J, 18, 1999, 119–130.[Medline]

Shammat I.M. & Gordon S.E.. Stoichiometry and arrangement of subunits in rod cyclic nucleotide-gated channels, Neuron, 23, 1999, 809–819.[Medline]

Sneyd J. & Tranchina D.. Phototransduction in conesan inverse problem in enzyme kinetics, Bull. Math. Biol, 51, 1989, 749–784.[Medline]

Tanaka J.C., Eccleston J.F. & Furman R.E.. Photoreceptor channel activation by nucleotide derivatives, Biochemistry., 28, 1989, 2776–2784.[Medline]

Torre V., Forti S., Menini A. & Campani M.. Model of phototransduction in retinal rods, Cold Spring Harbor Symp.Quant. Biol, 55, 1990, 563–573.

Wells G.B. & Tanaka J.C.. Ion selectivity predictions from a two-site permeation model for the cyclic nucleotide–gated channel of retinal rod cells, Biophys. J, 72, 1997, 127–140.[Medline]

Yau K.W. & Nakatani K.. Light-induced reduction of cytoplasmic free calcium in retinal rod outer segment, Nature, 313, 1985, 579–582.[Medline]

Younger J.P., McCarthy S.T. & Owen W.G.. Light-dependent control of calcium in intact rods of the bullfrog Rana catesbeiana, J. Neurophysiol, 75, 1996, 354–366.[Abstract/Free Full Text]

Zimmerman A.L., Yamanaka G., Eckstein F., Baylor D.A. & Stryer L.. Interaction of hydrolysis-resistant analogs of cyclic GMP with the phosphodiesterase and light-sensitive channel of retinal rod outer segments, Proc. Natl. Acad. Sci. USA, 82, 1985, 8813–8817.[Abstract/Free Full Text]

Zimmerman A.L. & Baylor D.A.. Cation interactions within the cyclic GMP-activated channel of retinal rods from the tiger salamander, J. Physiol, 449, 1992, 759–783.[Abstract/Free Full Text]

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