Putative ClC-2 chloride channel mediates inward rectification in Drosophila retinal photoreceptors.

We report that Drosophila retinal photoreceptors express inwardly rectifying chloride channels that seem to be orthologous to mammalian ClC-2 inward rectifier channels. We measured inwardly rectifying Cl(-) currents in photoreceptor plasma membranes: Hyperpolarization under whole-cell tight-seal voltage clamp induced inward Cl(-) currents; and hyperpolarization of voltage-clamped inside-out patches excised from plasma membrane induced Cl(-) currents that have a unitary channel conductance of approximately 3.7 pS. The channel was inhibited by 1 mM: Zn(2+) and by 1 mM: 9-anthracene, but was insensitive to DIDS. Its anion permeability sequence is Cl(-) = SCN(-)> Br(-)>> I(-), characteristic of ClC-2 channels. Exogenous polyunsaturated fatty acid, linolenic acid, enhanced or activated the inward rectifier Cl(-) currents in both whole-cell and excised patch-clamp recordings. Using RT-PCR, we found expression in Drosophila retina of a ClC-2 gene orthologous to mammalian ClC-2 channels. Antibodies to rat ClC-2 channels labeled Drosophila photoreceptor plasma membranes and synaptic regions. Our results provide evidence that the inward rectification in Drosophila retinal photoreceptors is mediated by ClC-2-like channels in the non-transducing (extra-rhabdomeral) plasma membrane, and that this inward rectification can be modulated by polyunsaturated fatty acid.

Coordinated gating of TRP-dependent channels in rhabdomeral membranes from Drosophila retinas.

Using a newly developed dissociation procedure, we isolated the specialized rhabdomeral membranes from Drosophila retinal photoreceptors. From these membranes, we have recorded spontaneous active currents in excised patch, voltage-clamp recordings. We observed rapid opening events that closely resembled those ascribed to one class of light-activated channels, TRP. All activity exhibited Ba(2+) permeability, little voltage dependence, and sensitivity to La(3+) block. Mutational analysis indicated that the spontaneous activity present in these membranes was TRP-dependent. Excised patches from wild-type rhabdomeral membranes exhibited a wide range of conductance amplitudes. In addition, large conductance events exhibited many conductance levels in the open state. Block of activity by La(3+) both developed and recovered in a stepwise manner. Our results indicate that TRP-dependent channels have a small unitary conductance and that many channels can be gated coordinately.

Rescue of excitation by inositol following Li(+)-induced block in Limulus ventral photoreceptors.

The phosphoinositide (PI) intracellular signaling pathway, which triggers Ca2+ release from intracellular stores, appears to be a central feature of phototransduction in most invertebrate species studied. Procedures designed to inhibit PI-pathway reactions cause suppression of excitation to dim lights. However, in Limulus photoreceptors, responses to bright stimuli are in fact enhanced by some of these procedures, suggesting that PI metabolism is not obligatory for light-induced excitation. Other studies, however, suggest that Ca2+ release is obligatory for excitation. We studied this issue by examining the effects of PI-pathway inhibitor, Li+, on electrophysiological responses to light in Limulus photoreceptors. Li+ is reported to cause depletion of intracellular PI-pathway intermediate, inositol; and it offers the pharmacological advantage that its block can be bypassed by introducing exogenous inositol. Introduction of Li+ caused a very slowly developing but complete suppression of responses to dim stimuli. In contrast, Li+ caused a rapidly developing but partial suppression of responses to bright stimuli. Li(+)-induced suppression was reversed by exogenous introduction of inositol. In addition, inositol prevented Li(+)-induced suppression of excitation. Li+ enhanced light adaptation (light-induced desensitization) but slowed response deactivation, indicating a difference in the processes underlying these phenomena. Li+ slowed dark adaptation, the recovery of sensitivity following light adaptation. All of these effects were prevented or rescued by extracellularly applied inositol, suggesting the presence of a transmembrane inositol transport system. The overall results suggest that PI-dependent signaling is central and obligatory for excitation in Limulus, at least for responses to dim to moderate illumination. The failure of Li+ to suppress bright light-induced excitation completely may be due to a failure of Li+ to block PI metabolism completely, as in other systems; however, it may point to a parallel, PI-independent excitation pathway possessing very low light sensitivity when PI metabolism is inhibited.

Current issues in invertebrate phototransduction. Second messengers and ion conductances.

Investigation of phototransduction in invertebrate photoreceptors has revealed many physiological and biochemical features of fundamental biological importance. Nonetheless, no complete picture of phototransduction has yet emerged. In most known cases, invertebrate phototransduction involves polyphosphoinositide and cyclic GMP (cGMP) intracellular biochemical signaling pathways leading to opening of plasma membrane ion channels. Excitation is Ca(2+)-dependent, as are adaptive feedback processes that regulate sensitivity to light. Transduction takes place in specialized subcellular regions, rich in microvilli and closely apposed to submicrovillar membrane systems. Thus, excitation is a highly localized process. This article focuses on the intracellular biochemical signaling pathways and the ion channels involved in invertebrate phototransduction. The coupling of signaling cascades with channel activation is not understood for any invertebrate species. Although photoreceptors have features that are common to most or all known invertebrate species, each species exhibits unique characteristics. Comparative electrophysiological, biochemical, morphological, and molecular biological approaches to studying phototransduction in these species lead to fundamental insights into cellular signaling. Several current controversies and proposed phototransduction models are evaluated.

Characterization of protein phosphatases type 1 and type 2A in Limulus nervous tissue: their light regulation in the lateral eye and evidence of involvement in the photoresponse.

The activities of both protein phosphatases and protein kinases are responsible for the transient changes in the levels of phosphorylation and probably the functions of protein intermediates involved in the biochemical and physiological mechanisms underlying the photoresponse in photoreceptor cells from both vertebrate and invertebrate organisms. Of the known protein serine/threonine phosphatases, various forms of type 1 (PP 1) and type 2A (PP 2A) protein phosphatases are responsible for dephosphorylating many of the known phosphoproteins including those involved in photoreceptor cell function. In this report, we provide biochemical evidence for both PP 1- and PP 2A-like activities in the visual and nonvisual tissue of the horseshoe crab, Limulus polyphemus, that membrane and soluble forms of both enzymes are present, and that the activities of both enzymes are greater in light- than in dark-adapted lateral eyes. These activities were characterized using glycogen phosphorylase a, a substrate for both PP 1 and PP 2A, and various protein phosphatase inhibitors, including okadaic acid. We also report that okadaic acid, at concentrations required to inhibit PP 1, inhibited physiological functions of photoreceptor cells from the ventral eye, causing a delayed reduction of the resting membrane, and slowing and reducing light responses.

The second messenger for visual excitation in invertebrate phototransduction.

Invertebrate visual transduction involves a second messenger cascade process that leads to an increase in membrane conductance. The identity of the second messenger that gates the light-dependent channels is presently a major focus of attention. Cyclic GMP, inositol trisphosphate and Ca2+ are the most likely candidates for being such a messenger in the species studied so far. Here we review the available evidence for each of these molecules.

The second messenger for visual excitation in invertebrate phototransduction

Invertebrate visual transduction involves a second messenger cascade process that leads to an increase in membrane conductance. The identity of the second messenger that gates the light-dependent channels is presently a major focus of attention. Cyclic GMP, inositol trisphosphate and Ca2+ are the most likely candidates for being such a messenger in the species studied so far. Here we review the available evidence for each of these molecules

Cyclic-GMP enhances light-induced excitation and induces membrane currents in Drosophila retinal photoreceptors.

Phototransduction in the Drosophila retina appears to require the phosphoinositide signaling cascade following receptor/G-protein activation. Subsequent opening of membrane cationic channels causes excitation. The biochemical events underlying channel opening and regulation of sensitivity remain largely unknown. Evidence is mounting that phototransduction in Drosophila and other invertebrate species may additionally involve the second messenger, cyclic-GMP (cGMP). We report that exogenous cGMP influenced Drosophila retinal phototransduction in two ways. In whole cell tight-seal voltage-clamp experiments, membrane permeant cGMP analog, 8-bromo-cyclic-GMP (8-Br-cGMP), induced membrane currents and dramatically enhanced light-induced currents. The currents induced by 8-Br-cGMP possessed reversal potentials similar to those induced by light. The magnitudes of cGMP-induced currents exhibited marked dependence on intensity of background illumination. Potential direct or modulatory roles of cGMP in Drosophila phototransduction are discussed.

Inhibitors of cyclic-GMP phosphodiesterase alter excitation of Limulus ventral photoreceptors in Ca(2+)-dependent fashion.

We have examined the hypothesis that Ca(2+)-dependent cyclic-GMP metabolism may play a role in visual transduction in Limulus photoreceptors. Although phosphoinositide hydrolysis is central to phototransduction and phosphoinositide-dependent Ca(2+)-mobilization seems to be required for transduction, the subsequent steps leading to ion channel gating (the immediate cause of excitation) are not understood. Channels normally opened in response to light can be opened in excised membrane patches by cGMP but not by Ca2+, suggesting that cGMP acts as a channel ligand in excitation. Using phosphodiesterase inhibitors, we investigated whether changes in cGMP metabolism could affect excitation. We report that zaprinast and IBMX increased the amplitudes and retarded the kinetics of physiological light responses. These effects were maximal for brightest stimuli. The effects were markedly enhanced in low Ca2+ conditions. In contrast, excitation induced by direct IP3-injection and by direct Ca(2+)-injection were inhibited. These observations suggest that PI-induced excitation is dependent on cGMP metabolism in a Ca(2+)-dependent manner, and they support the possibility that transduction involves modification of cGMP metabolism by Ca(2+)-release resulting from phosphoinositide hydrolysis.

The Drosophila dgq gene encodes a G alpha protein that mediates phototransduction.

We examined the roles of the Drosophila Gq alpha proteins (DGq) in the phototransduction pathway. The DGq proteins immunolocalized to the ocelli and all eight retinular photoreceptor cell rhabdomeres. An affinity-purified anti-DGq alpha immunoglobulin blocked the light-dependent GTP hydrolysis activity associated with Drosophila head membranes in vitro, suggesting that rhodopsin stimulated DGq. Dominantly active DGq1 mutants exhibited a light-independent GTPase activity and abnormal electrophysiological light responses, such as reduced retinal sensitivity and slow response kinetics compared with wild-type flies. Dominant DGq2 mutants exhibited a light-independent GTPase activity with normal electrophysiological light responses. Retinas of double mutants of DGq1, but not DGq2, with the light-dependent retinal degeneration mutant rdgB degenerated even in the dark. DGq1 stimulation of rdgB retinal degeneration in the dark was norpA-dependent. These results indicate that DGq1 mediates the stimulation by light-activated rhodopsin of the norpA-encoded phospholipase C in the visual transduction cascade.

Pertussis toxin expression in Drosophila alters the visual response and blocks eating behaviour.

Pertussis toxin inactivates certain G-proteins by introducing an ADP-ribose group near the carboxyl-terminus of the alpha-subunit. The major pertussis toxin substrate in Drosophila tissues is Go alpha. We introduced a pertussis toxin gene under control of the hsp70 heat-shock promoter into the Drosophila genome. When heat-shocked, transformed flies produce active pertussis toxin which ADP-ribosylates endogenous Go alpha. Pertussis toxin is expressed in photoreceptors, in the lamina of the eye and in epithelial cells lining the gut. As expected from the absence of Go alpha in photoreceptors, pertussis toxin does not affect the photoreceptor component of the Drosophila visual response. However, it abolishes light on- and off-transients in the electroretinogram. These transients normally arise from the lamina, a tissue where Go alpha transcripts have been detected. Pertussis toxin expression also blocks embryonic development and shortens the lifetime of adult Drosophila. Following heat-shock, transformed adults are active, but they fail to take up nutrients because they stop eating. High energy metabolites are significantly depleted shortly after pertussis toxin expression is induced and the flies die within 48 h.

Inward rectification in Limulus ventral photoreceptors.

We examined inward rectification in Limulus ventral photoreceptors using the two-microelectrode voltage clamp. Hyperpolarization in the dark induced an inward current whose magnitude was distinctly dependent on extracellular K+ concentration, [K+0]. The [K+0] dependence resembled the characteristic [K+0] dependence of other inward rectifiers. The inward current was not dependent on extracellular Ca2+ or Na+, and it was unaffected by intracellular injection of Cl-. The hyperpolarization induced currents had two phases, an early nearly instantaneous phase and a slowly developing late phase. The currents were sensitive to extracellular barium and cesium. In voltage-pulse experiments, the magnitudes of the inwardly rectifying currents were variable from cell to cell, with some cells exhibiting negligible inward currents. Large hyperpolarizations (to membrane potentials more negative than about -140 mV) caused unstable inward current recordings, irreversible desensitization, and irreversible elevation of intracellular Ca2+ concentration. The inward rectifier provides negative feedback by tending to depolarize the cell (with inward current) in response to hyperpolarization. We suggest that the inward rectifier reduces the amount of hyperpolarization that would otherwise be generated by electrogenic processes. This feature would restrict the dynamic voltage range of the photoreceptors at very hyperpolarized potentials.

Effects of external lithium on the physiology of Limulus ventral photoreceptors.

We have examined some of the physiological effects associated with the replacement of extracellular Na+ with Li+ in nominally Ca(2+)-free saline in the ventral photoreceptors of the horseshoe crab Limulus polyphemus. We observed that replacement of Na+ saline with Li+ saline induced larger voltage-activated inward currents with similar voltage dependence. These currents were absent in Tris+ saline. Anode-break excitation was maintained in Li+ saline but blocked in Tris+ saline. Regenerative events associated with quantum bumps in dark-adapted cells illuminated with dim lights were maintained in Li+ saline. Regenerative events associated with responses to moderately bright illumination were also maintained in Li+ saline. The post-illumination hyperpolarization associated with the Na+/K(+)-exchange pump (Brown & Lisman, 1972) was present after brief exposure to Li+ saline but disappeared after longer exposure. Following return to Na+ saline, the post-illumination hyperpolarization reappeared. We conclude that (1) Li+ permeates the voltage-dependent Na+ channel, GNa(V), in the photoreceptor plasma membrane; (2) Li+ supports voltage-activated physiological events normally mediated by Na+; and (3) Li+ substitution briefly supports and later inhibits the electrogenic effects of the Na+/K(+)-exchange pump. The effects of external Li+ on cellular physiology have implications for the interpretation of other studies employing Li+ extracellularly.

Physiological roles of Na+/Ca2+ exchange in Limulus ventral photoreceptors.

In previous work we have presented evidence for electrogenic Na+/Ca2+ exchange in Limulus ventral photoreceptors (1989. J. Gen. Physiol. 93:473-492). This article assesses the contributions to photoreceptor physiology from Na+/Ca2+ exchange. Four separate physiological processes were considered: maintenance of resting sensitivity, light-induced excitation, light adaptation, and dark adaptation. (a) Resting sensitivity: reduction of [Na+]o caused a [Ca2+]o-dependent reduction in light sensitivity and a speeding of the time courses of the responses to individual test flashes; this effect was dependent on the final value to which [Na+]o was reduced. The desensitization caused by Na+ reduction was dependent on the initial sensitivity of the photoreceptor; in fully dark-adapted conditions no desensitization was observed; in light-adapted conditions, extensive desensitization was observed. (b) Excitation: Na+ reduction in fully dark-adapted conditions caused a Ca2+o-dependent depolarizing phase in the receptor potential that persisted beyond the stimulus duration and was evoked by a bright adapting flash. (c) Light adaptation: the degree of desensitization induced by a bright adapting flash was Na+o dependent, being larger with lower [Na+]o. Na+ reduction enhanced light adaptation only at intensities brighter than 4 x 10(-6) W/cm2. In addition to being Na+o dependent, light adaptation was Ca2+o dependent, being greater at higher [Ca2+]o. (d) Dark adaptation: the recovery of light sensitivity after adapting illumination was Na+o dependent. Dark adaptation after bright illumination in voltage-clamped and in unclamped conditions was faster in normal-Na+ saline than in reduced Na+ saline. The final sensitivity to which photoreceptors recovered was lower in reduced-Na+ saline when bright adapting illumination was used. The results suggest the involvement of Na+/Ca2+ exchange in each of these physiological processes. Na+/Ca2+ exchange may contribute to these processes by counteracting normal elevations in [Ca2+]i.

Fused rhabdomeres (fur) in Drosophila: an eye mutation that alters rhabdomere morphology and retinal function.

In the Drosophila compound eye, the photoreceptor cells are organized in highly precise units, the ommatidia. In each photoreceptor cell, the primary photopigment, opsin, is contained in the rhabdomere, an ordered array of densely packed microvilli. A genetic and phenotypic analysis of a new X-linked. P element-induced mutation, fur, (fused rhabdomeres) is presented. Light and electron microscope studies show that mutations at the fur locus result in the fusion of the adjacent rhabdomeres in the developing eye and the fusion takes place during the pupal stage of eye development. Electrophysiological experiments indicate that the fur mutant photoreceptors have reduced sensitivity to light and lack a PDA (prolonged depolarizing afterpotential), a response characteristic of normal photoreceptor cells. Recombination and deficiency mapping localize fur to the proximal region of the X chromosome. Reversion analysis indicates the fur mutant is the result of a P element insertion. These studies suggest that the fur locus encodes a gene that has specific roles in rhabdomere morphogenesis and retinal function.

Evidence for electrogenic Na+/Ca2+ exchange in Limulus ventral photoreceptors.

The Ca2+ indicator photoprotein, aequorin, was used to estimate and monitor intracellular Ca2+ levels in Limulus ventral photoreceptors during procedures designed to affect Na+/Ca2+ exchange. Dark levels of [Ca2+]i were estimated at 0.66 +/- 0.09 microM. Removal of extracellular Na+ caused [Ca2+]i to rise transiently from an estimated 0.5-0.6 microM in a typical cell to approximately 21 microM; [Ca2+]i approached a plateau level in 0-Na+ saline of approximately 5.5 microM; restoration of normal [Na+]o lowered [Ca2+]i to baseline with a time course of 1 log10 unit per 9 s. The apparent rate of Nao+-dependent [Ca2+]i decline decreased with decreasing [Ca2+]i. Reintroduction of Ca2+ to 0-Na+, 0-Ca2+ saline in a typical cell caused a transient rise in [Ca2+]i from an estimated 0.36 microM (or lower) to approximately 16.5 microM. This was followed by a decline in [Ca2+]i approaching a plateau of approximately 5 microM; subsequent removal of Cao2+ caused [Ca2+]i to decline slowly (1 log unit in approximately 110 s). Intracellular injection of Na+ in the absence of extracellular Na+ caused a transient rise in [Ca2+]i in the presence of normal [Ca2+]o; in 0-Ca2+ saline, however, no such rise in [Ca2+]i was detected. Under constant voltage clamp (-80 mV) inward currents were measured after the addition of Nao+ to 0-Na+ 0-Ca2+ saline and outward currents were measured after the addition of Cao2+ to 0-Na+ 0-Ca2+ saline. The results suggest the presence of an electrogenic Na+/Ca2+ exchange process in the plasma membrane of Limulus ventral photoreceptors that can operate in forward (Nao+-dependent Ca2+ extrusion) or reverse (Nai+-dependent Ca2+ influx) directions.

Octopamine enhances dark-adaptation in Limulus ventral photoreceptors.

Limulus ventral photoreceptors receive synaptic input from fibers that emerge from the brain and that appear to use octopamine as a transmitter. Exogenous application of octopamine has been shown to increase levels of intracellular cAMP in ventral photoreceptors, but the resulting physiological effects have been unclear. In this report, we show that octopamine increases the rate of dark-adaptation following a bright light. Since a similar increase in the rate of dark-adaptation is produced by IBMX (1 mM) and forskolin (100 microM), drugs shown previously to raise the concentration of cAMP, the octopamine effect may be mediated by cAMP. Our results suggest that dark-adaptation, a fundamental process of photoreceptors, is under efferent neural control.

Functional significance of voltage-dependent conductances in Limulus ventral photoreceptors.

The influence of voltage-dependent conductances on the receptor potential of Limulus ventral photoreceptors was investigated. During prolonged, bright illumination, the receptor potential consists of an initial transient phase followed by a smaller plateau phase. Generally, a spike appears on the rising edge of the transient phase, and often a dip occurs between the transient and plateau. Block of the rapidly inactivating outward current, iA, by 4-aminopyridine eliminates the dip under some conditions. Block of maintained outward current by internal tetraethylammonium increases the height of the plateau phase, but does not eliminate the dip. Block of the voltage-dependent Na+ and Ca2+ current by external Ni2+ eliminates the spike. The voltage-dependent Ca2+ conductance also influences the sensitivity of the photoreceptor to light as indicated by the following evidence: depolarizing voltage-clamp pulses reduce sensitivity to light. This reduction is blocked by removal of external Ca2+ or by block of inward Ca2+ current with Ni2+. The reduction of sensitivity depends on the amplitude of the pulse, reaching a maximum at or approximately +15 mV. The voltage dependence is consistent with the hypothesis that the desensitization results from passive Ca2+ entry through a voltage-dependent conductance.

Voltage-dependent conductances in Limulus ventral photoreceptors.

The voltage-dependent conductances of Limulus ventral photoreceptors have been investigated using a voltage-clamp technique. Depolarization in the dark induces inward and outward currents. The inward current is reduced by removing Na+ or Ca2+ and is abolished by removing both ions. These results suggest that both Na+ and Ca2+ carry voltage-dependent inward current. Inward current is insensitive to tetrodotoxin but is blocked by external Ni2+. The outward current has a large transient component that is followed by a smaller maintained component. Intracellular tetraethylammonium preferentially reduces the maintained component, and extracellular 4-amino pyridine preferentially reduces the transient component. Neither component is strongly affected by removal of extracellular Ca2+ or by intracellular injection of EGTA. It is concluded that the photoreceptors contain at least three separate voltage-dependent conductances: 1) a conductance giving rise to inward currents; 2) a delayed rectifier giving rise to maintained outward K+ current; and 3) a rapidly inactivating K+ conductance similar to the A current of molluscan neurons.