On the Interaction Between Voltage-Gated Conductances and Ca2+ Regulation Mechanisms in Retinal Horizontal Cells

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On the Interaction Between Voltage-Gated Conductances and Ca²⁺ Regulation Mechanisms in Retinal Horizontal Cells

Yuki Hayashida and Tetsuya Yagi

Neurosystems Laboratory, Faculty of Computer Science and Systems Engineering, Kyushu Institute of Technology, Fukuoka 820-8502, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Hayashida, Yuki and Tetsuya Yagi. On the Interaction Between Voltage-Gated Conductances and Ca²⁺ Regulation Mechanisms in Retinal Horizontal Cells. J. Neurophysiol. 87: 172-182, 2002. The horizontal cell is a second-order retinal neuron that is depolarized in the dark and responds to light with graded potentialchanges. In such a nonspiking neuron, not only the voltage-gatedionic conductances but also Ca²⁺ regulation mechanisms, e.g., the Na⁺/Ca²⁺ exchange and the Ca²⁺ pump, are considered to play important roles in generating thevoltage responses. To elucidate how these physiological mechanismsinteract and contribute to generating the responses of the horizontalcell, physiological experiments and computer simulations weremade. Fura-2 fluorescence measurements made on dissociated carphorizontal cells showed that intracellular Ca²⁺ concentration ([Ca²⁺]_i) was maintained <100 nM in the resting state and increasedwith an initial transient to settle at a steady level of $sime$ 600nM during prolonged applications of L-glutamate (L-glu, 100 µM).A preapplication of caffeine (10 mM) partially suppressed theinitial transient of [Ca²⁺]_i induced by L-glu but did not affect the L-glu-induced steady[Ca²⁺]_i. This suggests that a part of the initial transient can beexplained by the Ca²⁺-induced Ca²⁺ release from the caffeine-sensitive Ca²⁺ store. The Ca²⁺ regulation mechanisms and the ionic conductances found in thehorizontal cell were described by model equations and incorporatedinto a hemi-spherical cable model to simulate the isolated horizontalcell. The physiological ranges of parameters of the model equationsdescribing the voltage-gated conductances, the glutamate-gatedconductance and the Na⁺/Ca²⁺ exchange were estimated by referring to previous experiments.The parameters of the model equation describing the Ca²⁺ pump were estimated to reproduce the steady levels of [Ca²⁺]_i measured by Fura-2 fluorescence measurements. Using the cablemodel with these parameters, we have repeated simulations so thatthe voltage response and [Ca²⁺]_i change induced by L-glu applications were reproduced. The simulationstudy supports the following conclusions. 1) The Ca²⁺-dependent inactivation of the voltage-gated Ca²⁺ conductance has a time constant of ~2.86 s. 2) The falling phaseof the [Ca²⁺]_i transient induced by L-glu is partially due to the inactivationof the voltage-gated Ca²⁺ conductance. 3) Intracellular Ca²⁺ is extruded mainly by the Na⁺/Ca²⁺ exchange when [Ca²⁺]_i is more than ~2 µM and by the Ca²⁺ pump when [Ca²⁺]_i is less than ~1 µM. 4) In the resting state, the Na⁺/Ca²⁺ exchange may operate in the reverse mode to induce Ca²⁺ influx and the Ca²⁺ pump extrudes intracellular Ca²⁺ to counteract the influx. The model equations of physiologicalmechanisms developed in the present study can be used to elucidatethe underlying mechanisms of the light-induced response of thehorizontal cell insitu.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Neurons generally have resting potentials of around $-$ 70 mV and can generate action potentials in response to stimuli. On theother hand, most of the outer retinal neurons of the vertebrateretina are depolarized in the dark and respond to light with gradedpotential changes. In such neurons, not only the voltage-gatedionic conductances but also the Ca²⁺ regulation mechanisms are thought to play important roles ingenerating the light-induced responses (Hayashida et al. 1998).

The horizontal cell is a second-order neuron of the vertebrate retina that is tonically depolarized in the dark by an excitatorytransmitter, probably L-glutamate, released from the photoreceptors(Cervetto and MacNichol 1972; Dowling and Ripps 1972; Murakamiet al. 1972). The membrane properties have been studied in enzymaticallydissociated horizontal cells and five types of voltage-gated ionicconductances were identified under the voltage-clamp condition(e.g., Kaneko 1987; Lasater 1991 for reviews; Lasater 1986; Picaudet al. 1998; Shingai and Christensen 1983, 1986; Tachibana 1983;Yagi and Kaneko 1988). Among these voltage-gated conductances,the Ca²⁺conductance was suggested to play a crucial role in maintainingthe membrane potential in the dark (Winslow 1989). More recently,some aspects concerning the Ca²⁺ regulation mechanisms were also revealed in dissociated horizontalcells by the optical measurement using the Ca²⁺-sensitive dyes (Hayashida et al. 1998; Linn and Christensen 1992;Micci and Christensen 1998; Okada et al. 1999). The Ca²⁺-regulation mechanisms are thought to affect the horizontal cellresponse because the voltage-gated Ca²⁺ conductance is known to be inactivated by intracellular Ca²⁺ (Tachibana 1981, 1983). Despite these previous experiments elucidatingthe electrochemical properties of individual physiological mechanisms,there are few quantitative analyses studying how these ionic conductancesand Ca²⁺-regulation mechanisms interact each other. In the present study,we used a cable model to quantitatively study how the physiologicalmechanisms identified in in vitro preparations operate togetherto generate physiological responses of horizontalcells.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Physiological experiments

Horizontal cells were dissociated from the retinae of carp, Cyprinus carpio (10- to 20-cm body length). The dissociation procedureand the cell preparation appeared in the previous study (Hayashidaet al. 1998). The dissociated cells were superfused continuouslywith a control solution using a "Y"-tube microflow system (Suzukiet al. 1990). The control solution contained (in mM) 120 NaCl,7.6 KCl, 2.5 CaCl₂, 1 MgCl₂, 10 glucose, 10 HEPES with 0.1 mg/mlBSA (pH adjusted to 7.3 with 1 M NaOH). A high concentration ofK⁺ was included in this control solution as was in previous studieson the dissociated cells of the cyprinid fish (Tachibana 1983,1985; Yagi 1989; Yagi and Kaneko 1988). The general conclusionsreached in the present study were not changed when a lower concentrationof K⁺ (2.6 mM) was used in the control solution (data not shown). Fora cobalt application, 1 mM CaCl₂ in the control solution was replacedby equimolar CoCl₂. For cadmium or caffeine application, 0.2 mMCdCl₂ or 10 mM caffeine was added to the control solution. Ca²⁺-free solution was made by removing CaCl₂ from the control solutionand, in some cases, adding 5 mM EGTA. When L-glutamate was appliedto the cell, sodium L-glutamate (100 µM) was dissolved in superfusates.Pharmacological agents were applied using the "Y"-tube microflowsystem, whose outlet (internal tip diameter, ~500 µm) was locatedwithin ~500 µm from the recordedcell.

[Ca²⁺]_i was ratiometrically measured by using the fluorescent Ca²⁺ indicator, Fura-2 (Grynkiewicz et al. 1985). Fura-2 fluorescencemeasurements from dissociated horizontal cells have been describedin a previous study (Hayashida et al. 1998). In brief, the isolatedcells were incubated in Fura-2/AM solution in the dark for 30-40min at room temperature. The Fura-2/AM solution was made by addingthe membrane-permeant analogue Fura-2 acetoxymethyl ester (Fura-2/AM)to the control solution to a final concentration of 5 µM (<0.1%vol/vol DMSO). The cells were then rinsed twice with control solutionand maintained in culture medium for >30 min to convert Fura-2/AMto the Ca²⁺-sensitiveform.

The 340- and 380-nm excitation light was used and the fluorescence emitted by cells was measured at 510 nm. The ratio of thefluorescence intensities elicited with the 340- and 380-nm excitationlight was calculated after subtracting the background fluorescence.[Ca²⁺]_i was calculated from the fluorescence ratio (R) according tothe following formula of Grynkiewicz et al. (1985)

[Ca2+]i=<IT>K</IT><IT>d</IT><IT>·</IT>(<IT>F</IT><IT>free</IT><IT>/</IT><IT>F</IT><IT>bound</IT>)<IT>·</IT>(<IT>R</IT><IT>−</IT><IT>R</IT><IT>min</IT>)<IT>/</IT>(<IT>R</IT><IT>max</IT><IT>−</IT><IT>R</IT>) (1)

Here K_d is the equilibrium dissociation constant for Fura-2 at 20°C (135 nM) (Grynkiewicz et al. 1985). In the present study,R_min was estimated as the ratio obtained when a cell was superfusedwith a Ca²⁺ ionophore, 4-Br-A23187 or A23187 (10 µM), in a Ca²⁺-free solution (10 mM EGTA and no Ca²⁺ added). The R_max value was determined as the ratio when a cellwas superfused with the Ca²⁺ ionophore in a high-Ca²⁺ solution (5 mM Ca²⁺). F_free and F_bound were determined as the fluorescence intensitiesat 380-nm excitation when a cell was superfused with the Ca²⁺ ionophore in the Ca²⁺-free solution and the high-Ca²⁺ solution, respectively. In the text, [Ca²⁺]_i values are given when the values of F_free, F_bound, R_min, andR_max were obtained for each cell at the end of the recording.Otherwise, only the R values are given (denoted as "fluorescenceratio" in the relevant textfigures).

In the voltage- and current-clamp experiments, the perforated-patch technique with the whole cell configuration was employedto minimize disruption of cytoplasmic constituents (Horn and Marty1988).

Computer simulations

Computer simulations were carried out using the simulation software NEURON (Hines and Carnevale 1997).

Since we preferentially used horizontal cells which have round-shaped somata and a few short thin dendrites in the presentexperiments, a hemi-spherical cable is considered to be appropriatefor modeling the dissociated horizontal cell. As shown in Fig.1, a dissociated horizontal cell was modeled by a hemi-sphericalcable with 15 µm of radius. This cable dimension mimicked a typicalshape of the dissociated horizontal cells used in the presentexperiments. The simulation was conducted with a single cylindricalcable model as well. The diameter and length of the cable were20 and 22.5 µm, respectively. The internal volume and surfacearea of the cable are the same as those of the hemi-sphericalcable. There is no distinguishable difference in simulation resultsbetween these two models. Therefore only the simulation resultsobtained with the hemi-spherical cable are described in this paper.

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Fig. 1. A hemi-spherical cable model for a dissociated horizontal cell. Radius of the cable is 15 µm. The cable is divided into 202 segments in the longitudinal direction, as indicated by seg. Internal space of each segment is divided into 101 shells in the radial direction, as indicated by j (see text for detail).

In the simulations, intracellular Ca²⁺ diffusion in the longitudinal direction was taken into account by dividing the cableinto 202 segments (Hines and Carnevale 2000). Intracellular Ca²⁺ diffusion in the radial direction was also taken into accountby dividing the each segment into 101 shells. The diffusion betweenneighboring shells is described by (Hines and Carnevale 2000)

[Ca2+]<IT>j</IT> <LIM><OP><ARROW>↔</ARROW></OP><UL><IT>D</IT><IT>Ca</IT><IT>·</IT><IT>a</IT><IT>j</IT><IT>,</IT><IT>j</IT><IT>+1</IT><IT>/</IT><IT>d</IT><IT>j</IT><IT>,</IT><IT>j</IT><IT>+1</IT></UL></LIM> [<IT>Ca2+</IT>]<IT>j</IT><IT>+1</IT>

Here, j is an integer from 0 to 100 representing the shell number; [Ca²⁺]_j is the Ca²⁺ concentration in the shell of j, e.g., j = 0 for the outer mostshell; a_j,j+1 and d_j,j+1 are the areaof the border and the distance between the shells of j and j +1; D_Ca is the diffusion constant for intracellular Ca²⁺ (units of µm²/s). D_Ca used in the present simulations was assumed to be 6 µm²/s and is in the range of the apparent diffusion constant of Ca²⁺ measured in a living cell (Kushmerick and Podolsky 1969).

The number of segments and shells were increased in the simulation to estimate the error of thecalculation.

A step of calculation time was 20-50 µs in allsimulations.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Physiological experiments

[CA²⁺]_i CHANGE INDUCED BY L-GLU. Figure 2A shows an example of the [Ca²⁺]_i change in response to a prolonged application of L-glu (100 µM) to an isolated horizontalcell. In this experiment, the cell was first superfused with thecontrol solution to measure [Ca²⁺]_i in the resting state. The resting potential of the isolatedhorizontal cell was more negative than $-$ 50 mV in the control solution[ $-$ 56.2 ± 6.0 (SD) mV, n = 5] (Hayashida et al. 1998; Tachibana1981). At this voltage, voltage-gated Ca²⁺ current was not detectable by the voltage-clamp experiments (Tachibana1983; Yagi and Kaneko 1988). [Ca²⁺]_i in the resting state was ~52 nM in this cell [75 ± 37 (SD)nM, n = 11]. The resting [Ca²⁺]_i was not affected by 200 µM Cd²⁺ (n = 5) as shown in Fig. 2B. Furthermore, application of 1 mMCo²⁺ did not have effects on [Ca²⁺]_i in the resting state (n = 4, data not shown). These observationsconfirm the results obtained by the voltage-clamp experiments.

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Fig. 2. [Ca²⁺]_i change measured in the isolated horizontal cell. A: 100 µM L-glutamate was applied for 324 s. The fluorescence ratio of Fura-2 was measured every 4 s ( $open circle$ ). [Ca²⁺]_i was calculated by measuring the calibration parameters for this cell at the end of this recording (METHODS). B: 200 µM Cd²⁺ was applied for 60 s and then 100 µM L-glutamate was applied for 9 s. A and B were obtained in different cells. The membrane potential was not clamped and was not recorded both in A and B.

During the L-glu application, [Ca²⁺]_i transiently increased to the maximum level and then gradually decreased to reach a steadylevel of ~0.82 µM (0.59 ± 0.23 µM, n = 11). [Ca²⁺]_i changed little when L-glu (100 µM) was applied to the cellin the Ca²⁺-free solution (n = 6, data not shown). Ca²⁺ is known to enter the horizontal cell through the glutamate-gatedcation conductance (Hayashida et al. 1998

; Linn and Christensen1992

; Okada et al. 1999

) as well as the voltage-gated Ca²⁺ conductance. The relative amount of Ca²⁺ entering the isolated cell through these conductances was examinedby a voltage-clamp experiment shown in Fig. 3, A and B. We firstmeasured a change of [Ca²⁺]_i induced by L-glu (100 µM) when the membrane voltage was clampedat $-$ 75 mV (Fig. 3A). As shown in the figure, [Ca²⁺]_i was slightly increased by the L-glu application (indicatedby a). This increase of [Ca²⁺]_i is due to the Ca²⁺ influx through the glutamate-gated conductance because the voltage-gatedCa²⁺ conductance was not activated at this voltage. The increase of[Ca²⁺]_i, however, was much smaller than that induced by the depolarizationof membrane to $-$ 10 mV (b). Similar results were obtained for eightof nine cells examined. The membrane potential of the isolatedhorizontal cell was maintained at approximately $-$ 5 mV during theapplication of 100 µM L-glu (Hayashida et al. 1998

). When themembrane potential was clamped to $-$ 5 from $-$ 55 mV, [Ca²⁺]_i transiently increased and then gradually decreased to reacha steady level (Fig. 3B, b). At this steady level, L-glu (100µM) application induced a sustained inward current but only asmall increase of [Ca²⁺]_i was seen (indicated by a). Similar results were obtained forseven of eight cells examined. These observations suggest thatthe Ca²⁺ influx occurs mainly through the voltage-gated Ca²⁺ conductance during applications of 100 µM L-glu to isolated horizontalcell.

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Fig. 3. Relative contribution of the voltage-gated Ca²⁺ conductance and the glutamate-gated conductance to the L-glu-induced [Ca²⁺]_i change. A: L-glutamate (100 µM) was applied for 32 s during the voltage clamp in the perforated-patch configuration. The holding voltage was $-$ 75 mV (bottom) and then the membrane voltage was depolarized to $-$ 10 mV for 5 s. The whole cell membrane current (top) and the Fura-2 fluorescence ratio (middle) were simultaneously measured. · · · , the 0 pA level in the current trace. The fluorescence ratio was measured once every second. B: the holding voltage was $-$ 55 mV (bottom) and then the membrane voltage was depolarized to $-$ 5 mV for 800 s. L-Glutamate (100 µM) was applied for 240 s during the membrane potential was clamped at $-$ 5 mV. The whole cell membrane current (top) and the Fura-2 fluorescence ratio (middle) were simultaneously measured. · · · , the 0 pA level in the current trace. The fluorescence ratio was measured every 20 s.

INITIAL TRANSIENT OF [CA²⁺]_i INDUCED BY L-GLU. The transient increase of [Ca²⁺]_i shown in Fig. 2A was suppressed by a preapplication of caffeine (Fig. 4). L-Glu (100 µM) wasapplied to the cell repetitively as shown in the figure. In thesecond trial, 10 mM caffeine was applied immediately before theapplication of L-glu. [Ca²⁺]_i transiently increased and then decreased toward the restinglevel in response to the caffeine application (see inset). Thetransient increase of [Ca²⁺]_i induced by L-glu was partially suppressed to ~60% (61 ± 26%,mean ± SD, n = 7) when the caffeine was preapplied in seven ofnine cells examined. In the remaining two cells, the initial transientwas completely suppressed (Fig. 4B). The transient increase of[Ca²⁺]_i recovered in the third trial (A and B). The suppression ofthe transient increase of [Ca²⁺]_i by caffeine is likely to be due to a prolonged depletion ofCa²⁺ store. This observation suggests that a part of the initial transientof [Ca²⁺]_i can be explained by the Ca²⁺-induced Ca²⁺ release (CICR) from the caffeine-sensitive Ca²⁺ store (DISCUSSION). The remaining component of the initial transient,which was not blocked by the preapplication of caffeine (Fig.4A), is explained by the Ca²⁺-dependent inactivation of the voltage-gated Ca²⁺ conductance, which will be shown later with quantitative analysesusing the biophysical model of the isolated horizontal cell.

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Fig. 4. Initial transient of [Ca²⁺]_i change. L-Glutamate (100 µM) was applied repetitively for ~3 min with 2-min intervals. In the second trial, 10 mM caffeine was preapplied for ~10-20 s immediately before the L-glu application. The Fura-2 fluorescence ratio was measured every 3 s. The membrane potential was not clamped and was not recorded. A: partial suppression of the initial transient by the caffeine preapplication. The caffeine-induced Ca²⁺ release was shown in the inset with an expanded time scale. B: complete blockade of the initial transient by the caffeine preapplication.

In contrast to the initial transient, the steady levels of [Ca²⁺]_i during the prolonged L-glu application were not affected bythe preapplication of caffeine (indicated by a andb).

Biophysical model of the isolated horizontal cell

MODELS OF PHYSIOLOGICAL MECHANISMS. The physiological mechanisms relevant to calculate [Ca²⁺]_i were the glutamate-gated cation conductance, the voltage-gated Ca²⁺ conductance, the Na⁺/Ca²⁺ exchange, the Ca²⁺ pump, and Ca²⁺ buffering. These mechanisms were described by the followingequations.

Ca²⁺ influx through the glutamate-gated cation conductance has been reported in fish horizontal cells (Hayashida et al. 1998

;Linn and Christensen 1992

; Okada et al. 1999

). Within the rangeof membrane potential considered in the present study ( $-$ 60 to0 mV), the cation current through the glutamate-gated conductancedepends on the membrane potential almost linearly (Tachibana 1985

).Thus the glutamate-gated cation current was described by an equation

<IT>I</IT><SUB><IT>glu</IT></SUB><IT>=</IT><IT>g</IT><SUB><IT>glu</IT></SUB>(<IT>t</IT>)<IT>·</IT>(<IT>V</IT><SUB><IT>m</IT></SUB><IT>−</IT><IT>E</IT><SUB><IT>glu</IT></SUB>)

(2)

Here, V_m is the membrane potential; E_glu is the reversal potential of the cation current that is ~0 mV (Ishida and Neyton1985

; Ishida et al. 1984

; Murakami and Takahashi 1987

; Tachibana1985

); g_glu(t) is the glutamate-gated conductance (units of mS/cm²). The N-methyl-D-aspartate (NMDA)-type glutamate receptor hasbeen found in the catfish horizontal cell (O'Dell and Christensen1986

, 1989

), but not in the horizontal cell of cyprinid fish (Ishidaet al. 1984

; Lasater and Dowling 1982

). The spatial distributionof the glutamate receptors over the dissociated horizontal cellmembrane is thought to be almost homogeneous (Ishida et al. 1984

).Therefore the glutamate-gated cation conductance expressed byEq. 2 was distributed homogeneously over the entire lateral surfaceof the cable shown in Fig. 1. To simulate the response to a L-gluapplication, g_glu(t) was modulated with an equation

<IT>g</IT><SUB><IT>glu</IT></SUB>(<IT>t</IT>)<IT>=</IT><FENCE><AR><R><C>0</C><C>for <IT>t</IT><IT>≤</IT><IT>t</IT><SUB><IT>on</IT></SUB></C></R><R><C><OVL><IT>g</IT><SUB><IT>glu</IT></SUB></OVL><IT>·</IT>{<IT>1−exp</IT>(−(<IT>t</IT><IT>−</IT><IT>t</IT><SUB><IT>on</IT></SUB>)<IT>/&tgr;<SUB>glu</SUB></IT>)}</C><C>for <IT>t</IT><SUB><IT>on</IT></SUB><IT><</IT><IT>t</IT><IT>≤</IT><IT>t</IT><SUB><IT>off</IT></SUB></C></R><R><C><OVL><IT>g</IT><SUB><IT>glu</IT></SUB></OVL><IT>·</IT>{<IT>1−exp</IT>(−(<IT>t</IT><SUB><IT>off</IT></SUB><IT>−</IT><IT>t</IT><SUB><IT>on</IT></SUB>)<IT>/&tgr;<SUB>glu</SUB></IT>)}<IT>·</IT>{<IT>exp</IT>(−(<IT>t</IT><IT>−</IT><IT>t</IT><SUB><IT>off</IT></SUB>)<IT>/&tgr;<SUB>glu</SUB></IT>)}</C><C>for <IT>t</IT><IT>></IT><IT>t</IT><SUB><IT>off</IT></SUB></C></R></AR></FENCE>

(3)

Here, is the maximum conductance activated by the application of 100 µM L-glu; L-glu is applied at t_on andremoved at t_off; $tau$ _glu reflects two time constants, the activationtime constant of glutamate channels and the time constant of glutamateincrease by the "Y"-tube microflow system (METHODS). Because theactivation time constant of the channels is expected to be muchfaster than the time constant of glutamate increase by the "Y"-tubesystem, $tau$ _glu is considered to mainly represent the time constantof glutamate increase. was estimated from the dataobtained by Tachibana (1985)

. $tau$ _glu was selected to be 100 ms tosimulate the time course of activation of the glutamate-gatedcurrent induced by L-glu applications with the present method.The ratio of the current carried by Ca²⁺ to I_glu through the glutamate-gated conductance was assumed tobe 1% and is in the range of the fractional Ca²⁺ current through AMPA-receptor channels (Jonas and Burnashev 1995

The high-threshold and sustained voltage-gated Ca²⁺ conductance was found in the isolated goldfish horizontal cell (Tachibana1983

; Yagi and Kaneko 1988

). A transient type of Ca²⁺ conductance has been identified in the horizontal cells of whitebass (Sullivan and Lasater 1992

) but not in the horizontal cellof cyprinid fish. Therefore Ca²⁺ current through the voltage-gated Ca²⁺ conductance in the present case was described by

<IT>I</IT><SUB><IT>Ca</IT></SUB><IT>=</IT><OVL><IT>g</IT><SUB><IT>Ca</IT></SUB></OVL><IT>·</IT><IT>m</IT><SUB><IT>Ca</IT></SUB><IT>·</IT><IT>h</IT><SUB><IT>Ca</IT></SUB><IT>·</IT>(<IT>V</IT><SUB><IT>m</IT></SUB><IT>−</IT><IT>E</IT><SUB><IT>Ca</IT></SUB>)

(4)

<FR><NU>d<IT>m</IT><SUB><IT>Ca</IT></SUB></NU><DE><IT>d</IT><IT>t</IT></DE></FR><IT>=&agr;</IT><SUB><IT>m</IT><SUB><IT>Ca</IT></SUB></SUB><IT>·</IT>(<IT>1−</IT><IT>m</IT><SUB><IT>Ca</IT></SUB>)<IT>−&bgr;</IT><SUB><IT>m</IT><SUB><IT>Ca</IT></SUB></SUB><IT>·</IT><IT>m</IT><SUB><IT>Ca</IT></SUB>

<IT>h</IT><SUB><IT>Ca</IT></SUB><IT>+&tgr;<SUB>Ca</SUB> </IT><FR><NU><IT>d</IT><IT>h</IT><SUB><IT>Ca</IT></SUB></NU><DE><IT>d</IT><IT>t</IT></DE></FR><IT>=</IT><IT>K</IT><SUP><IT>n</IT><SUB><IT>Ca</IT></SUB></SUP><SUB><IT>Ca</IT></SUB><IT>/</IT>(<IT>K</IT><SUP><IT>n</IT><SUB><IT>Ca</IT></SUB></SUP><SUB><IT>Ca</IT></SUB><IT>+</IT>[<IT>Ca<SUP>2+</SUP></IT>]<SUP><IT>n</IT><SUB><IT>Ca</IT></SUB></SUP><SUB><IT>j</IT><IT>=0</IT></SUB>)

(5)

Here, E_Ca is the reversal potential of Ca²⁺; g_Ca is the maximum conductance (units of µS/cm²); m_Ca and h_Ca are the activation and the inactivation variables,respectively. $alpha$ _mCa and $beta$ _mCa are forward andbackward rate coefficients, respectively (units of 1/ms) and arefunctions of the membrane potential as shown in Table 1. Theinactivation variable is known to be dependent on intracellularCa²⁺ (Tachibana 1981

, 1983

) and was expressed as a function of [Ca²⁺]_j=0, which is the Ca²⁺ concentration in the shell just below the membrane. In a steadystate in which dh_Ca/dt = 0, the conductance is half inactivatedwhen [Ca²⁺]_i is equal to K_Ca. n_Ca is the Hill coefficient. $alpha$ _mCa, $beta$ _mCa and were selected to fit the voltage-dependentproperties of the conductance obtained by Tachibana (1983)

. K_Caand n_Ca of Eq. 5 were evaluated from the following observations.

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Table 1. Parameter values of the model equations for the Ca^2⁺-related physiological mechanisms

In Fig. 5, the inactivation curve in the steady state was plotted as a function of [Ca²⁺]_i with different K_Ca and n_Ca. As shown in the figure, the inactivationcurve shifts along the horizontal axis with K_Ca (a, c, and e)and the slope of curve changes with n_Ca (b, c, and d). As wasshown in the previous section, [Ca²⁺]_i of the isolated horizontal cell was ~75 nM in the resting state.We assumed that 98% of the conductance was not inactivated atthis resting [Ca²⁺]_i (indicated by rest). In the L-glu-induced sustained depolarization,on the other hand, [Ca²⁺]_i was ~0.59 µM and a few picoamps of inward Ca²⁺ current remained (Hayashida et al. 1998

). The Ca²⁺ current is ~100 pA before the inactivation at this voltage (Tachibana1983

), and therefore ~95% of the conductance was thought to beinactivated in this state (indicated by depo). For the steadystate inactivation curve described by Eq. 5 to meet these conditions,n_Ca needs to be larger than 4 and K_Ca is found to be ~300 nM.Accordingly, n_Ca was taken to be 4 because it is consistent withrecent observations (Ehlers and Augustine 1999

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Fig. 5. Inactivation curve of the voltage-gated Ca²⁺ conductance with different values of K_Ca and n_Ca. a, c, and e illustrate the curve with K_Ca = 150, 300, and 600 nM, respectively (n_Ca = 4). b, c, and d indicate the curve with n_Ca = 2, 4, and 6, respectively (K_Ca = 300 nM). rest and depo indicate the [Ca²⁺]_i in the resting state and in the L-glu-induced sustained depolarization, respectively.

It has been reported in the bipolar cell that the inactivation process has a slow time constant (2-5 s) (vonGersdorff andMatthews 1996

). The Ca²⁺ current of isolated horizontal cells also inactivates with aslow time course (see Fig. 3A of Tachibana 1983

). Therefore thetime constant $tau$ _Ca was introduced in Eq. 5. The time course ofthe Ca²⁺-dependent inactivation in the horizontal cell will be elucidatedto estimate $tau$ _Calater.

The Na⁺/Ca²⁺ exchange current of the isolated horizontal cell was found to fit the following equation (Hayashida et al. 1998

)

<IT>I</IT><SUB><IT>ex</IT></SUB><IT>=</IT><IT>k</IT><SUB><IT>ex</IT></SUB>{[<IT>Na<SUP>+</SUP></IT>]<SUP><IT>n</IT></SUP><SUB><IT>i</IT></SUB>[<IT>Ca<SUP>2+</SUP></IT>]<SUB><IT>out</IT></SUB><IT> exp</IT>((<IT>n</IT><IT>−2</IT>)<IT>rV</IT><SUB><IT>m</IT></SUB><IT>F</IT><IT>/</IT><IT>R</IT><IT>/</IT><IT>T</IT>)

(6)

<IT>−</IT>[<IT>Na<SUP>+</SUP></IT>]<SUP><IT>n</IT></SUP><SUB><IT>out</IT></SUB>[<IT>Ca<SUP>2+</SUP></IT>]<SUB><IT>j</IT><IT>=0</IT></SUB><IT> exp</IT>(−(<IT>n</IT><IT>−2</IT>)(<IT>1−</IT><IT>r</IT>)<IT>V</IT><SUB><IT>m</IT></SUB><IT>F</IT><IT>/</IT><IT>R</IT><IT>/</IT><IT>T</IT>)}

Here, k_ex is a scaling coefficient (units of pA/cm²/mM⁴), which is relevant to a density of exchanger molecules in the membrane;[Na⁺]_i and [Na⁺]_out are concentrations of Na⁺ inside and outside the cell, respectively; [Ca²⁺]_out is the extracellular Ca²⁺ concentration; n is the stoichiometry for Na⁺ and Ca²⁺; r is related to the position of an energy barrier in the plasmamembrane defined by the rate-theory; F, R, and T are the Faradayconstant, the gas constant and the absolute temperature, respectively.The values of k_ex, n, and r of Eq. 6 were estimated to be 60 pA/cm²/mM⁴, 3 and 0.59, respectively (Hayashida et al. 1998

). [Na⁺]_out and [Ca²⁺]_out correspond to the concentrations of the bath solution usedin the experiment. In rod outer segments, K⁺ is co-transported with Ca²⁺ by the Na⁺/Ca²⁺, K⁺ exchange and a stoichiometry for Na⁺ is 4 (Cervetto et al. 1989

). However, K⁺ dependency of the Na⁺/Ca²⁺ exchange was not found in the horizontal cell (Hayashida et al.1998

). Therefore the ratio of exchange was assumed to be Na⁺:Ca²⁺ = 3:1 and therefore the current carried by Ca²⁺ is equal to $-$ 2 × I_ex.

The Ca²⁺ efflux by the Ca²⁺ pump was described by (Zador et al. 1990

)

flux<SUB>pump</SUB>=<IT>A</IT><SUB><IT>pump</IT></SUB><IT>·</IT>[<IT>Ca<SUP>2+</SUP></IT>]<SUB><IT>j</IT><IT>=0</IT></SUB><IT>/</IT>(<IT>K</IT><SUB><IT>pump</IT></SUB><IT>+</IT>[<IT>Ca<SUP>2+</SUP></IT>]<SUB><IT>j</IT><IT>=0</IT></SUB>)

(7)

Here, flux_pump is an amount of Ca²⁺ efflux (units of pmol/cm²/s); A_pump is the maximum pumping rate (units of pmol/cm²/s); K_pump is the dissociation constant. In the present study,the current carried by Ca²⁺ pump was not taken into account, forsimplicity.

Ca²⁺ regulation by a Ca²⁺ buffer was described by a single binding site model

[Ca<SUP>2+</SUP>]<SUB><IT>j</IT></SUB><IT>+</IT>[<IT>Buffer</IT>]<SUB><IT>j</IT></SUB> <LIM><OP><IT>⇌</IT></OP><LL><IT>b</IT></LL><UL><IT>f</IT></UL></LIM> [<IT>CaBuffer</IT>]<SUB><IT>j</IT></SUB>

[CaBuffer]<SUB>total</SUB>=[Buffer]+[CaBuffer], <IT>K</IT><SUB><IT>buf</IT></SUB><IT>=</IT><IT>b</IT><IT>/</IT><IT>f</IT>

(8)

Here, [Buffer]_j and [CaBuffer]_j are concentrations of the free buffer and the buffer binding Ca²⁺, respectively; f and b are the rates of the binding and unbindingreactions, respectively (units of µM¹s¹ for f and s¹ for b). In the present study, the values of f and b were assumedto be 19 µM¹s¹ and 0.95 s¹, respectively (Lee et al. 2000

The Ca²⁺ store was not taken into account in the present simulation (DISCUSSION).

To calculate the membrane potential of the isolated cell, the voltage-gated K⁺ conductances found in the goldfish horizontal cell, i.e., theanomalous rectifier, the delayed rectifier and the transient A-typeconductances were also taken into account (Tachibana 1983

). Eachof these voltage-gated K⁺ currents were described by equations

<IT>I</IT><SUB><IT>x</IT></SUB><IT>=</IT><OVL><IT>g</IT><SUB><IT>x</IT></SUB></OVL><IT>·</IT><IT>m</IT><SUP><IT>p</IT><SUB>x</SUB></SUP><SUB>x</SUB><IT>·</IT><IT>h</IT><SUP><IT>q</IT><SUB><IT>x</IT></SUB></SUP><SUB><IT>x</IT></SUB><IT>·</IT>(<IT>V</IT><SUB><IT>m</IT></SUB><IT>−</IT><IT>E</IT><SUB><IT>K</IT></SUB>)

<FR><NU>d<IT>m</IT><SUB><IT>x</IT></SUB></NU><DE><IT>d</IT><IT>t</IT></DE></FR><IT>=&agr;</IT><SUB><IT>m</IT><SUB><IT>x</IT></SUB></SUB><IT>·</IT>(<IT>1−</IT><IT>m</IT><SUB><IT>x</IT></SUB>)<IT>−&bgr;</IT><SUB><IT>m</IT><SUB><IT>x</IT></SUB></SUB><IT>·</IT><IT>m</IT><SUB><IT>x</IT></SUB>

<FR><NU>d<IT>h</IT><SUB><IT>x</IT></SUB></NU><DE><IT>d</IT><IT>t</IT></DE></FR><IT>=&agr;</IT><SUB><IT>h</IT><SUB><IT>x</IT></SUB></SUB><IT>·</IT>(<IT>1−</IT><IT>h</IT><SUB><IT>x</IT></SUB>)<IT>−&bgr;</IT><SUB><IT>h</IT><SUB><IT>x</IT></SUB></SUB><IT>·</IT><IT>h</IT><SUB><IT>x</IT></SUB>

(9)

Here, is the maximum conductance (units of µS/cm²); m_x and h_x are the activation and inactivation variables, respectively;p_x and q_x are integers; E_K is the reversal potential of K⁺. $alpha$ _mx ( $alpha$ _hx) and $beta$ _mx ( $beta$ _hx)are forward and backward rate constants, respectively (units of1/ms). These are functions of the membrane potential and expressedby the equations shown in Table 2. The parameters included inpreceding equations were estimated to fit previous experiments(Tachibana 1983

) and are shown in Table 2.

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Table 2. Parameter values of the model equations for the voltage-gated K^⁺ conductances and the passive properties

To construct a biophysical model of the isolated horizontal cell, the physiological mechanisms explained above were incorporatedinto the cable shown in Fig. 1. All the physiological mechanismsexpressed by Eqs. 2-9 except for Eq. 8 (Ca²⁺ buffer) were incorporated into the lateral surface of the cable(Fig. 1, indicated by shadow). These mechanisms were not includedin the bottom and the top surface at the ends of the cable. Thepassive leakage conductance and the membrane capacitance (Yagi1989

) were also incorporated in the lateral but not in the bottomand top surfaces of the cable. The Ca²⁺ buffer was distributed evenly in the internal space of the cable.Diffusion of the Ca²⁺ buffer was neglected in the presentsimulations.

The physiological mechanisms, i.e., the glutamate-gated conductance, the voltage-gated ionic conductances, the Ca²⁺ efflux mechanisms, the passive leakage conductance and the membranecapacitance were assumed to distribute homogeneously over theentire lateral surface of thecable.

Estimation of parameter values of Ca²+ pump

To conduct physiologically plausible simulations, values of the parameters in the model equations describing the physiologicalmechanisms require appropriate estimation. As was explained inthe previous section, some parameters can be directly estimatedreferring to previous experiments. We used the following logicto estimate parameter values that cannot be explicitly found fromprevious experiments. Steady state was assumed in the restingstate as well as the prolonged application of L-glu for all physiologicalmechanisms. All cytoplasmic Ca²⁺ sequestration sites, i.e., Ca²⁺buffers and Ca²⁺ stores were also at steady state (no net release or storing ofCa²⁺ taking place). Therefore the efflux of Ca²⁺ by the Na⁺/Ca²⁺ exchange and the Ca²⁺ pump counterbalances the influx through the glutamate-gated cationand the voltage-gated Ca²⁺ conductances both in the resting state and in the L-glu-induceddepolarization. Figure 6 illustrates how such steady states wereachieved in the horizontal cell. The efflux of Ca²⁺ by each Ca²⁺ regulation mechanism was plotted as a function of [Ca²⁺]_i for the resting (A) and the L-glu-induced depolarized states(B). The total flux was plotted with a thick line (indicated bynet). [Ca²⁺]_i in each steady state corresponds to a point where there isno net flux. The Ca²⁺ flux induced by the Na⁺/Ca²⁺ exchange (NaCa) becomes inward when [Ca²⁺]_i decreases below a value at which the electrochemical gradientreverses. Based on previous experiments, the parameters includedin the glutamate-gated cation conductance, the voltage-gated Ca²⁺ conductance and the Na⁺/Ca²⁺ exchange were estimated. We selected parameter values for theCa²⁺ pump, i.e., A_pump and K_pump of Eq. 7, so that the [Ca²⁺]_i was reproduced in the resting state (~52 nM) as well as inthe prolonged L-glu application (~818 nM). The estimated valueswere 1.3 pmol/cm²/s for A_pump and 400 nM for K_pump.

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Fig. 6. Relationships between the Ca²⁺ flux and [Ca²⁺]_i in the steady states. ggcc, vgcc, NaCa and pump indicate the Ca²⁺ flux through the glutamate-gated cation conductance, voltage-gated Ca²⁺ conductance, Na⁺/Ca²⁺ exchanger, and Ca²⁺ pump, respectively. The Ca²⁺ flux was calculated with Eqs. 2 and 3 for ggcc, Eqs. 4 and 5 for vgcc, Eq. 6 for NaCa, and Eq. 7 for pump. The parameters shown in Table 1 were used for the calculations and area of the cell membrane was assumed to be 1.4 × 10⁵cm². net indicates the net flux of Ca²⁺ across the membrane. Upward deflection shows the efflux. A: the Ca²⁺ flux was calculated for the resting state in which the membrane voltage is about $-$ 56 mV. B: the Ca²⁺ flux were calculated for the L-glu-induced depolarized state in which the membrane voltage is about $-$ 5 mV.

Inactivation of Ca²+ current

The time course of the Ca²⁺-dependent inactivation observed in the isolated horizontal cell was analyzed by the model to estimate $tau$ _Ca of Eq. 5. The inactivation time course of voltage-gated Ca²⁺ current during the voltage clamp was calculated with differentvalues of $tau$ _Ca using the model as shown in Fig. 7. The model includesthe voltage-gated Ca²⁺ conductance, the Na⁺/Ca²⁺ exchange, the Ca²⁺ pump, the Ca²⁺ buffer, and the Ca²⁺ diffusion, and therefore the simulation mimics satisfactorilythe physiological experiments conducted on the isolated horizontalcell. The experimental data ( $open circle$ ) were replotted from Fig. 6 ofTachibana (1983), in which the membrane currents were measuredin the isolated goldfish horizontal cell with the micro electrode.All the voltage-gated K⁺ currents were blocked and the current induced by clamping thevoltage from $-$ 61 to 0 mV was measured in the absence (indicatedby exp:control) and the presence of 4 mM Co²⁺ (indicated by exp:Co²⁺). The calculated current illustrates the Co²⁺-sensitive current that is composed of those through the voltage-gatedCa²⁺ conductance and the Na⁺/Ca²⁺ exchange. The calculated current decayed much faster than experimentaldata when $tau$ _Ca was removed (indicated by a and middle trace inthe inset). [Ca²⁺]_j=0, the Ca²⁺ concentration just below the membrane, increases quickly afterthe activation of voltage-gated Ca²⁺ conductance by the depolarization (bottom trace in the inset)and immediately inactivates the conductance if $tau$ _Ca were negligiblysmall. The time course of calculated current provided a reasonablefit to the experimental data (indicated by b), when $tau$ _Ca is 2.86s. The experimental data could not be fitted by changing the diffusionconstant of intracellular Ca²⁺.

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Fig. 7. The time course of Ca²⁺-dependent inactivation of the voltage-gated Ca²⁺ current. The experimental data were replotted from Fig. 6 of Tachibana (1983)

and were illustrated with $open circle$ . The membrane voltage of the model was depolarized from $-$ 61 to 0 mV to simulate the voltage-clamp experiment. A Co²⁺-sensitive current, composed of the voltage-gated Ca²⁺ current and the Na⁺/Ca²⁺ exchange current, was calculated with the cell model. a and b indicate the Co²⁺-sensitive current calculated with $tau$ _Ca = 0 and $tau$ _Ca = 2.86 s, respectively. The other parameters used for the calculations are shown in Table 1. Inset: the Co²⁺-sensitive current and the Ca²⁺ concentration just below the membrane ([Ca²⁺]_j=0) calculated with $tau$ _Ca = 0 s.

Simulation of L-glu-induced [Ca²+]_i change

Using the parameter values estimated in the previous sections, we simulated the experiments shown in Fig. 2A. The densitiesof each physiological mechanism in the cell model, i.e., g_glu,g_Ca, k_ex, A_pump, [Buffer]_total, and D_Ca were adjusted to reproducethe profile of Fig. 2A. Fig. 8A shows the L-glu-induced [Ca²⁺]_i change calculated with the cell model ( $---$ ). Note that the cellmodel includes all the membrane conductances, the membrane capacitance,and the Ca²⁺-related physiological mechanisms introduced in the present study.In this figure, the average concentration of intracellular Ca²⁺ of the cable was illustrated to be compared with the Fura-2 fluorescencemeasurement. The profile of [Ca²⁺]_i change calculated with the cell model provides an appropriatefit to the experimental data ( $open circle$ ) except for the initial transient.The initial transient of [Ca²⁺]_i estimated by the experiment, however, exceeded the measurablerange of Fura-2 (higher than a few µM) (Grynkiewicz et al. 1985)and is likely to include a large error. The discrepancy betweenthe experiment and the simulation probably reflects the errorof the Fura-2 fluorescence measurement in such high [Ca²⁺]_i. Another possibility to explain the discrepancy is the lackof Ca²⁺ store in the model. The Ca²⁺ store was suggested to contribute to the initial transient ofthe [Ca²⁺]_i increase as shown in Fig. 4.

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Fig. 8. Simulation of L-glu-induced [Ca²⁺]_i change using the cable model of isolated horizontal cell. The parameters shown in Tables 1 and 2 were used for the calculations. The glutamate-gated conductance incorporated in the cable surface was calculated with Eq. 3, where g_glu = 232 mS/cm² and $tau$ _glu = 100 ms. A: the average [Ca²⁺]_i of the whole cable was calculated ( $---$ ). $open circle$ , the [Ca²⁺]_i change shown in Fig. 2A. B: the Ca²⁺ flux through the Ca²⁺ regulation mechanisms was calculated. ggcc, vgcc, NaCa, and pump indicate the Ca²⁺ flux through the glutamate-gated cation conductance, voltage-gated Ca²⁺ conductance, Na⁺/Ca²⁺ exchanger, and Ca²⁺ pump, respectively. The traces of Ca²⁺ flux are enlarged from the inset (- - -). Upward deflections show the efflux.

The amount of Ca²⁺ flux induced by each physiological mechanism was illustrated separately to examine each mechanism's contributionto the control of [Ca²⁺]_i (Fig. 8B). In this figure, the vertical axis measures the amountof Ca²⁺ extruded from the cell. When L-glu is applied, a large influxof Ca²⁺ occurs through the voltage-gated Ca²⁺ conductance that increases [Ca²⁺]_i to 9.2 µM from 52 nM transiently. The Ca²⁺ efflux mechanisms are activated simultaneously to counteractthe influx. At a high [Ca²⁺]_i seen in the initial phase, Ca²⁺ is extruded mainly by the Na⁺/Ca²⁺ exchange because the Ca²⁺ extrusion rate of the Na⁺/Ca²⁺ exchange increases monotonically as [Ca²⁺]_i, yet that of the Ca²⁺ pump saturates. The influx of Ca²⁺ through the voltage-gated Ca²⁺ conductance decreases after reaching a peak ( $-$ 70 pA, inset) becauseof the Ca²⁺-dependent inactivation. The efflux through the Na⁺/Ca²⁺ exchange and the Ca²⁺ pump also decreases as [Ca²⁺]_i decreases. As a consequence, [Ca²⁺]_i reaches a steady level of 0.82 µM. These are the fundamentalCa²⁺ regulatory mechanisms of [Ca²⁺]_i in the isolated horizontal cell during the L-glu applicationimplied by themodel.

In the present model, the Ca²⁺ flux by the Na⁺/Ca²⁺ exchange is inward in the resting state. The difference of Ca²⁺ regulation properties between the Ca²⁺ pump and the Na⁺/Ca²⁺ exchange may suggest the functional difference in regulating[Ca²⁺]_i between them (DISCUSSION).

When the time constant of Ca²⁺-dependent inactivation of the voltage-gated Ca²⁺ conductance is removed from Eq. 5, the influx through the voltage-gatedCa²⁺ conductance decreases with a faster time course than that shownin the inset and a transient increase of [Ca²⁺]_i does not appear (data not shown). Therefore a part of the fallingphase of [Ca²⁺]_i transient during the L-glu application can be explained bythe Ca²⁺-dependent inactivation of the voltage-gated Ca²⁺conductance.

Simulation of voltage response to L-glu application

The voltage response to the L-glu application calculated with the cell model was compared with the experimental data as shownin Fig. 9; $---$ shows the calculated membrane potential and $open circle$ showthe measured voltage with the perforated-patch electrode. As shownin the figure, the membrane potential of the cell model was depolarizedfrom $-$ 56 to $-$ 5 mV in response to the L-glu application, whichis similar to the experiment. It is notable that the transientovershoot seen in the experiment is well reproduced by the model.As was shown in the previous section, the decline of the overshootis explained by the Ca²⁺-dependent inactivation of voltage-gated Ca²⁺ current. Therefore the transient depolarization seen at the initialphase is a Ca²⁺ spike induced by the L-glu application.

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Fig. 9. The voltage response to a L-glu application. The membrane voltage change was calculated with the cable model ( $---$ ). The parameters shown in Tables 1 and 2 were used for the calculation. The glutamate-gated conductance was calculated with Eq. 3, where g_glu = 232mS/cm² and $tau$ _glu = 100 ms. The membrane voltage of the isolated horizontal cell was measured under the current-clamp in the perforated-patch configuration and was shown with $open circle$ . L-Glutamate (100 µM) was applied for 74 s.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Computer simulation models of solitary horizontal cells with ionic currents have been previously developed (Usui et al. 1996;Winslow 1989). The biophysical model was developed in the presentstudy based on not only electrophysiological experiments but alsooptical measurements. Although there are various physiologicalparameters to be estimated in the model, the ranges of these parametervalues were determined by elucidating the results from both electrophysiologicaland optical measurements. Therefore the present model is physiologicallyrealistic especially in terms of the cooperative activities ofthe voltage-gated conductances and the Ca²⁺ regulationmechanisms.

The horizontal cell in situ has a membrane potential of around $-$ 30 mV and responds to light with a graded potential change.Among the ionic conductances found in the horizontal cell, thevoltage-gated Ca²⁺ conductance drastically changes in this voltage range and stronglyaffects the response of the horizontal cell. The Ca²⁺ conductance is known to be activated around $-$ 40 mV and increasesprominently until ~0 mV in the horizontal cell of the lower vertebrates(Lasater 1986; Shingai and Christensen 1983, 1986; Tachibana 1983).Therefore a small amount of voltage change produces a significantchange in the Ca²⁺ influx. In other outer retinal neurons, i.e., photoreceptorsand bipolar cells, the Ca²⁺-activated K⁺ and Ca²⁺-activated Cl currents are thought to counteract the inward Ca²⁺ current to suppress Ca²⁺ spikes (e.g., Bader et al. 1982; Barnes and Hille 1989; Yagiand MacLeish 1994 for photoreceptors; Kaneko and Tachibana 1985;Karschin and Wässle 1990 for bipolar cells). In the horizontalcells, however, such Ca²⁺-activated outward currents were not observed (Tachibana 1983;Ueda et al. 1992) or too small to suppress the Ca²⁺ spikes (unpublished data). Our previous experiments on isolatedhorizontal cells have demonstrated that [Ca²⁺]_i is maintained at a high level and the voltage-gated Ca²⁺ conductance is inactivated to a large extent during the L-gluapplication (Hayashida et al. 1998) (see also Fig. 2A). Thesesuggest that the feed-back control of the voltage-gated Ca²⁺ conductance by the intracellular Ca²⁺ is expected to play an essential role in stabilizing the membranepotential of the horizontal cell in situ. It was suggested thatthe inactivation of the voltage-gated Ca²⁺ conductance as well as the tonic synaptic input from the photoreceptorsare required to account for the membrane potential in the darkand light-induced hyperpolarizing responses of horizontal cells(Winslow 1989). The quantitative analyses in the present studyclearly demonstrated the underlying mechanisms to control [Ca²⁺]_i and the membranepotential.

Previous studies showed that a caffeine-sensitive Ca²⁺ store exists in horizontal cells (Linn and Christensen 1992; Micci andChristensen 1998; Yasui 1988). In the L-glu-induced sustaineddepolarization as well as the resting state, the Ca²⁺ store is considered to be at steady state and no net release(or uptake) of Ca²⁺ by the store takes place. In the present study, we mainly focusedon the regulatory mechanism of [Ca²⁺]_i in the steady states. Therefore the Ca²⁺ store was not taken into account in the presentmodel.

The preapplication of caffeine suppressed the transient increase of [Ca²⁺]_i induced by the L-glu application (Fig. 4), suggesting a contributionof the Ca²⁺ store to the transient phase of the L-glu-induced [Ca²⁺]_i increase in the isolated horizontal cell. The release as wellas the uptake of Ca²⁺ by the Ca²⁺ store is likely to occur transiently by an abrupt Ca²⁺ influx. In the isolated horizontal cell, this abrupt Ca²⁺ influx was induced by a quick application of high concentrationof L-glu or by an instantaneous voltage clamp from the restingpotential to the potential in which the Ca²⁺ conductance is almost fully activated. This is not consideredto be a normal physiological condition in situ. The Ca²⁺ store, however, could contribute to the depolarizing phase afterthe cell was fully hyperpolarized by brightlight.

A possible contribution of the caffeine-sensitive Ca²⁺ store to the inactivation of the L-type Ca²⁺ channel on a long time scale has been demonstrated in rod photoreceptors(Krizaj et al. 1999). The caffeine-sensitive Ca²⁺ store in the horizontal cell might play a functional role insuch inactivation of the voltage-gated Ca²⁺ conductance. The effect of caffeine on the L-glu-induced steady[Ca²⁺]_i level was examined in the isolated horizontal cell. The L-glu-induced[Ca²⁺]_i level was lowered when caffeine (2-10 mM) was applied to thecell (n = 5, data not shown). Further experiments, however, areneeded to clarify the role of the Ca²⁺ store in the horizontalcell.

In horizontal cells, both the Na⁺/Ca²⁺ exchange and the Ca²⁺ pump operate together (Hayashida et al. 1998). The present simulationsindicated that Ca²⁺ was extruded mainly by the Ca²⁺ pump when [Ca²⁺]_i was lower than 1 µM, but the Na⁺/Ca²⁺ exchange became dominant as [Ca²⁺]_i increased further. These two transporters cooperate to controlintracellular Ca²⁺ over a wide range of concentrations. The level of [Ca²⁺]_i, however, might be different at different sites in the horizontalcell in situ. Therefore it is possible that these mechanisms controldifferent cellular functions. The present simulation suggestedthat the Na⁺/Ca²⁺ exchange may operate in the reverse mode when the cell is inthe resting state (Fig. 8B). This is consistent with the Ca²⁺ influx via the Na⁺/Ca²⁺ exchange demonstrated in the isolated catfish horizontal cell(Micci and Christensen 1998). Such a small amount of Ca²⁺ influx in the resting state might play an important role in loadingand/or unloading the Ca²⁺ store (Blaustein 1993; Micci and Christensen 1998). Ca²⁺ possibly enters the cell through a leakage conductance. Therefore[Ca²⁺]_i at the resting state might be maintained by the balance betweenthe efflux through the Ca²⁺ pump and the influx through the reversed Na⁺/Ca²⁺ exchange and/or the leakageconductance.

Na⁺ continuously enters the cell through the glutamate-gated cation conductance during the application of L-glu (Ishida etal. 1984; Tachibana 1985) and is assumed to be extruded by theNa⁺/K⁺ pump (Shimura et al. 1998; Yasui 1987, 1988). Therefore [Na⁺]_i is likely to be as dynamically changing and controlled as [Ca²⁺]_i. [Na⁺]_i affects the regulation of [Ca²⁺]_i via the Na⁺/Ca²⁺ exchange. In the present simulation, [Na⁺]_i was assumed to be constant (8 mM) to calculate the Na⁺/Ca²⁺ exchange current. The role of the Na⁺/K⁺ pump as well as the other Na⁺ transporters are to be studiedfurther.

The present study revealed fundamental mechanisms to explain Ca²⁺ regulation in the horizontal cell in vitro. Further studies withexperimental and computational analyses are needed to elucidatethe underlying mechanisms of the light-induced response of thehorizontal cell in situ. The model equations of physiologicalmechanisms developed in the present study are useful, when suchstudies areconducted.

	ACKNOWLEDGMENTS

The authors are grateful to H. Ohno for technical assistance with the computer simulations and to Dr. M. Hines for instructionson the use of NEURON. The authors thank K. H. Sienko for correctingthe English of the earlier version of the manuscript and A. T.Ishida for comments on themanuscript.

This work was partially supported by the Japan Society for the Promotion of Science, Grant-in-Aid for Research for the FutureProgram, JSPS-RFTF 97 I00101 (Principal Investigator: T. Yamakawaof Kyushu Institute ofTechnology).

	FOOTNOTES

Present address and address for reprint requests: T. Yagi, Graduate School of Engineering, Osaka University, Yamada-Oka 2-1,Suita, Osaka 565-0871, Japan (E-mail: yagi{at}ele.eng.osaka-u.ac.jp).

Received 30 October 2000; accepted in final form 14 September 2001.

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