Photoreceptor Signals Research Articles

Light adaptation in Drosophila photoreceptors: II. Rising temperature increases the bandwidth of reliable signaling.

It is known that an increase in both the mean light intensity and temperature can speed up photoreceptor signals, but it is not known whether a simultaneous increase of these physical factors enhances information capacity or leads to coding errors. We studied the voltage responses of light-adapted Drosophila photoreceptors in vivo from 15 to 30 degrees C, and found that an increase in temperature accelerated both the phototransduction cascade and photoreceptor membrane dynamics, broadening the bandwidth of reliable signaling with an effective Q(10) for information capacity of 6.5. The increased fidelity and reliability of the voltage responses was a result of four factors: (1) an increased rate of elementary response, i.e., quantum bump production; (2) a temperature-dependent acceleration of the early phototransduction reactions causing a quicker and narrower dispersion of bump latencies; (3) a relatively temperature-insensitive light-adapted bump waveform; and (4) a decrease in the time constant of the light-adapted photoreceptor membrane, whose filtering matched the dynamic properties of the phototransduction noise. Because faster neural processing allows faster behavioral responses, this improved performance of Drosophila photoreceptors suggests that a suitably high body temperature offers significant advantages in visual performance.

Light adaptation in Drosophila photoreceptors: I. Response dynamics and signaling efficiency at 25 degrees C.

Besides the physical limits imposed on photon absorption, the coprocessing of visual information by the phototransduction cascade and photoreceptor membrane determines the fidelity of photoreceptor signaling. We investigated the response dynamics and signaling efficiency of Drosophila photoreceptors to natural-like fluctuating light contrast stimulation and intracellular current injection when the cells were adapted over a 4-log unit light intensity range at 25 degrees C. This dual stimulation allowed us to characterize how an increase in the mean light intensity causes the phototransduction cascade and photoreceptor membrane to produce larger, faster and increasingly accurate voltage responses to a given contrast. Using signal and noise analysis, this appears to be associated with an increased summation of smaller and faster elementary responses (i.e., bumps), whose latency distribution stays relatively unchanged at different mean light intensity levels. As the phototransduction cascade increases, the size and speed of the signals (light current) at higher adapting backgrounds and, in conjunction with the photoreceptor membrane, reduces the light-induced voltage noise, and the photoreceptor signal-to-noise ratio improves and extends to a higher bandwidth. Because the voltage responses to light contrasts are much slower than those evoked by current injection, the photoreceptor membrane does not limit the speed of the phototransduction cascade, but it does filter the associated high frequency noise. The photoreceptor information capacity increases with light adaptation and starts to saturate at approximately 200 bits/s as the speed of the chemical reactions inside a fixed number of transduction units, possibly microvilli, is approaching its maximum.

The Effector Enzyme Regulates the Duration of G Protein Signaling in Vertebrate Photoreceptors by Increasing the Affinity between Transducin and RGS Protein

The photoreceptor-specific G protein transducin acts as a molecular switch, stimulating the activity of its downstream effector in its GTP-bound form and inactivating the effector upon GTP hydrolysis. This activity makes the rate of transducin GTPase an essential factor in determining the duration of photoresponse in vertebrate rods and cones. In photoreceptors, the slow intrinsic rate of transducin GTPase is accelerated by the complex of the ninth member of the regulators of G protein signaling family with the long splice variant of type 5 G protein beta subunit (RGS9.Gbeta5L). However, physiologically rapid GTPase is observed only when transducin forms a complex with its effector, the gamma subunit of cGMP phosphodiesterase (PDEgamma). In this study, we addressed the mechanism by which PDEgamma regulates the rate of transducin GTPase. We found that RGS9.Gbeta5L alone has a significant ability to activate transducin GTPase, but its affinity for transducin is low. PDEgamma acts by enhancing the affinity between activated transducin and RGS9.Gbeta5L by more than 15-fold, which is evident both from kinetic measurements of transducin GTPase rate and from protein binding assays with immobilized transducin. Furthermore, our data indicate that a single RGS9.Gbeta5L molecule is capable of accelerating the GTPase activity of approximately 100 transducin molecules/s. This rate is faster than the rates reported previously for any RGS protein and is sufficient for timely photoreceptor recovery in both rod and cone photoreceptors.

A Molecular Pathway for Light-Dependent Photoreceptor Apoptosis in Drosophila

Light-induced photoreceptor apoptosis occurs in many forms of inherited retinal degeneration resulting in blindness in both vertebrates and invertebrates. Though mutations in several photoreceptor signaling proteins have been implicated in triggering this process, the molecular events relating light activation of rhodopsin to photoreceptor death are yet unclear. Here, we uncover a pathway by which activation of rhodopsin in Drosophila mediates apoptosis through a G protein–independent mechanism. This process involves the formation of membrane complexes of phosphorylated, activated rhodopsin and its inhibitory protein arrestin, and subsequent clathrin-dependent endocytosis of these complexes into a cytoplasmic compartment. Together, these data define the proapoptotic molecules in Drosophila photoreceptors and indicate a novel signaling pathway for light-activated rhodopsin molecules in control of photoreceptor viability.

Binding of the cGMP-gated Channel to the Na/Ca-K Exchanger in Rod Photoreceptors

The intracellular Ca(2+) concentration in rod outer segments of vertebrate photoreceptors is controlled by Ca(2+) influx through cGMP-gated channels and by Ca(2+) efflux driven by Na/Ca-K exchangers. Previously, we suggested that channel and exchanger are associated (Bauer, P. J., and Drechsler, M. (1992) J. Physiol. (Lond. ) 451, 109-131). This suggestion has been thoroughly examined using a variety of biochemical approaches. First, we took advantage of the fact that cGMP-gated channels bind calmodulin (CaM). Using CaM affinity chromatographic purification of the channel in 10 mm CHAPS, a significant fraction of exchanger was co-eluted with the channel indicating a binding affinity between channel and exchanger. Binding of channel and exchanger was examined more directly by cross-linking of proteins in the rod outer segment membranes. Activation of the channel with cyclic 8-bromo-GMP lead to exposure of a cysteine, which allowed cross-linking of the channel to the exchanger with the thiol-specific reagent dl-1,4-bismaleimido-2,3-butanediol. Cleavage of the cross-links and electrophoretic analysis indicated that a cross-link between the alpha-subunit of the channel and the exchanger formed. Furthermore, a cross-link between two adjacent alpha-subunits of the channel was found, suggesting that the alpha-subunits of the native channel are dimerized. Further support for an interaction between alpha-subunit and exchanger was obtained by in vitro experiments. Specific binding of the exchanger to the alpha-subunit but not to the beta-subunit of the channel was observed in Western blots of purified channel incubated with purified exchanger. This study suggests that two exchanger molecules bind to one cGMP-gated channel and, more specifically, that binding of exchanger molecules occurs at the alpha-subunits, which in the native channel are dimerized. The implications of these findings regarding the possibility of local Ca(2+) signaling in vertebrate photoreceptors will be discussed.

Origin and functional impact of dark noise in retinal cones.

Spontaneous fluctuations in the electrical signals of the retina's photoreceptors impose a fundamental limit on visual sensitivity. While noise in the rods has been studied extensively, relatively little is known about the noise of cones. We show that the origin of the dark noise in salamander cones varies with cone type. Most of the noise in long wavelength-sensitive (L) cones arose from spontaneous activation of the photopigment, which is a million-fold less stable than the rod photopigment rhodopsin. Most of the noise in short wavelength-sensitive (S) cones arose in a later stage of the transduction cascade, as the photopigment was relatively stable. Spontaneous pigment activation effectively light adapted L cones in darkness, causing them to have a smaller and briefer dim flash response than S cones.

The human eye: structure and function

A brief history of eyes. Part 1 Ocular systems: formation of the human eye ocular geometry and topography the orbit the extraocular muscles the nerves of the eye and orbit blood supply and drainage the eyelids and the lacrimal system. Part 2 Components of the eye: the cornea and the sclera the limbus and the anterior chamber the iris and pupil the cillary body and choroid the lens and vitreous retina I - photoreceptors and functional organization retina II - editing photoreceptor signals retina III - regional variation and spatial organization the retina in vivo and the optic nerve. Epilogue - time and change.

Phytochromes, cryptochromes, phototropin: photoreceptor interactions in plants.

In higher plants, natural radiation simultaneously activates more than one photoreceptor. Five phytochromes (phyA through phyD), two cryptochromes (cry1, cry2) and phototropin have been identified in the model species Arabidopsis thaliana. There is light-dependent epistasis among certain photoreceptor genes because the action of one pigment can be affected by the activity of others. Under red light, phyA and phyB are antagonistic, but under far-red light, followed by brief red light, phyA and phyB are synergistic in the control of seedling morphology and the expression of some genes during de-etiolation. Under short photoperiods of red and blue light, cry1 and phyB are synergistic, but under continuous exposure to the same light field the actions of phyB and cry1 become independent and additive. Phototropic bending of the shoot toward unilateral blue light is mediated by phototropin, but cry1, cry2, phyA and phyB positively regulate the response. Finally, cry2 and phyB are antagonistic in the induction of flowering. At least some of these interactions are likely to result from cross talk of the photoreceptor signaling pathways and uncover new avenues to approach signal transduction. Experiments under natural radiation are beginning to show that the interactions create a phototransduction network with emergent properties. This provides a more robust system for light perception in plants.

Light Evokes Ca2+ Spikes in the Axon Terminal of a Retinal Bipolar Cell

Bipolar cells in the vertebrate retina have been characterized as nonspiking interneurons. Using patch-clamp recordings from goldfish retinal slices, we find, however, that the morphologically well-defined Mb1 bipolar cell is capable of generating spikes. Surprisingly, in dark-adapted retina, spikes were reliably evoked by light flashes and had a long (1–2 s) refractory period. In light-adapted retina, most Mb1 cells did not spike. However, an L-type Ca2+ channel agonist could induce periodic spiking in these cells. Spikes were determined to be Ca2+ action potentials triggered at the axon terminal and were abolished by 2-amino-4-phosphonobutyric acid (APB), an agonist that mimics glutamate. Signaling via spikes in a specific class of bipolar cells may serve to accelerate and amplify small photoreceptor signals, thereby securing the synaptic transmission of dim and rapidly changing visual input.

Localization of natriuretic peptides and their activation of particulate guanylate cyclase and nitric oxide synthase in the retina

In the vertebrate retina, cyclic guanosine monophosphate (cGMP) mediates photoreceptor signal transduction and modulates ion channel and gap junction conductivity. Although most previous studies have focused on its synthesis by nitric oxide (NO)-sensitive soluble guanylate cyclase, cGMP is also synthesized by NO-insensitive particulate guanylate cyclases (pGC). Natriuretic peptides and their associated pGC-coupled receptors have been reported in retina, but few studies have localized these natriuretic peptides or pGCs to specific retinal cells or demonstrated that activation of pGCs by natriuretic peptides increases cGMP synthesis. In this study, we immunocytochemically localized atrial, brain, and C-type natriuretic peptide-like immunoreactivity (ANP-LI, BNP-LI, and CNP-LI, respectively) in turtle retina by using isoform specific antisera, and determined the ability of each natriuretic peptide isoform to increase cGMP-like immunoreactivity (cGMP-LI) in retinal cells. ANP-LI and CNP-LI were localized in sparsely distributed amacrine cells with thin, intermittently varicose processes in the inner plexiform layer. BNP-LI was localized to abundant somata in the inner nuclear and ganglion cell layers and in specific amacrine and horizontal cells. Stimulation of turtle eyecups with each of these natriuretic peptides increased cGMP-LI in multistratified amacrine cells by means of NO-independent mechanisms in the central retina, and in select amacrine and bipolar cells in the peripheral retina by a nitric oxide-dependent mechanism. These results indicate that natriuretic peptides can modulate the synthesis of cGMP in select retinal neurons by two distinct signal transduction pathways in a regionally specific manner.

The retina

The retina

Molecular mechanisms of the effects of sildenafil (VIAGRA).

The molecular mechanisms of the effects of sildenafil, a specific inhibitor of cyclic guanosine monophosphate (cGMP) phosphodiesterases are briefly reviewed. The second messenger cGMP as well as its molecular targets (with the exception of the photoreceptor signal transduction machinery) have long played an underdog role compared with cyclic adenosine monophosphate and other signalling molecules such as inositoltrisphosphate. The same holds for guanylyl cyclase, which, albeit being the main effector molecule of the gaseous neurotransmitters carbon monoxide and nitric oxide (NO), has received much less attention relative to its activators and their synthases. Stimulation of the arginine --> NO --> cGMP pathway by bypassing NO-synthase is a well-established pharmacological principle in the treatment of cardiovascular disorders. In contrast, local application of NO-donors or oral feeding of excessive amounts of precursor amino acid L-arginine to treat erectile dysfunction were met with variable success or failure. The advent of a new principle, amplification of the NO-signaling cascade by means of target organ selective phosphodiesterase inhibition, has renewed interest in phosphodiesterases and cGMP.

Cloning of a retinally abundant regulator of G-protein signaling ( RGS-r/ RGS16): genomic structure and chromosomal localization of the human gene

Regulators of G-protein signaling (RGS) constitute a family of GTPase-activating proteins with varying tissue-specific expression patterns and G-protein alpha subunit specificities. Here, we describe the molecular cloning of the human RGS-r/RGS16 cDNA, encoding a predicted polypeptide of 23 kDa that shows 86% identity to mouse RGS-r. Northern blot analysis shows that, like the mouse Rgs-r message, hRGS-r mRNA is abundantly expressed in retina, with lower levels of expression in most other tissues examined. Characterization of the genomic organization of the hRGS-r gene shows that it consists of five exons and four introns. We have also mapped the human RGS-r /RGS16 gene to chromosome 1q25–1q31 by fluorescence in situ hybridzation. Analysis of human ESTs reveals that at least five members of the RGS gene family map to chromosome 1q, suggesting that at least part of the RGS family arose through gene duplication. The chromosomal location, retinal abundance, and presumed function of the human RGS-r protein in desensitizing photoreceptor signaling make the RGS-r/RGS16 locus a candidate for mutations responsible for retinitis pigmentosa with para-arteriolar preservation of retinal pigment epithelium (RP-PPRE or RP12), an autosomal recessive disorder previously mapped to 1q31.

Anatomical evidence for rod input to the parvocellular pathway in the visual system of the primate.

The question whether midget bipolar cells in macaque monkey retina receive input from rods was investigated using double-label immunocytochemistry. Flat midget bipolar cells (labelled with antibodies against recoverin) were found to be pre- and postsynaptic to All amacrine cells (labelled with antibodies against calretinin). These results support physiological evidence that rod photoreceptor signals could reach the parvocellular pathway at an early stage of visual processing.

Effects of horizontal cell network architecture on signal spread in the turtle outer retina. experiments and simulations

In the Pseudemys turtle retina five functionally distinct, electrically coupled networks of horizontal cells distribute signals in the outer plexiform layer. These networks differ significantly in their architecture, as determined by intracellular labeling with Neurobiotin after physiological recording and identification. The density of H1 horizontal cells is highest, ranging around 1800 cells/mm 2 at approximately 2.3 mm eccentricity. H1 horizontal cell somata are connected via 6–10 thin, short dendrites. The H1 horizontal cell axon terminal network is composed of thick axon terminals, forming a three-dimensional, sheath-like structure. Networks of coupled H2 and H3 horizontal cells have cell densities of around 210 cells/mm 2 and 350 cells/mm 2 respectively, at the same eccentricity of 2.3 mm. Cell bodies are connected with 6–12 long, thin dendrites. Here we report for the first time H4 horizontal cell networks. Cell density is approximately 970 cells/mm 2 at 2 mm eccentricity, and cell bodies are connected with 6–10 thin, short dendrites. General properties of passive voltage spread were compared for three of these horizontal cell networks using NeuronC. Realistic network architectures were obtained by digitizing the intracellularly labeled networks, respectively. One network obtained from coupled H1 horizontal cell bodies, one from coupled H1 horizontal cell axon terminals, and one from H2 horizontal cells were simulated. These three realistic networks were compared with an artificial, electrically coupled regular triangular network. Passive signal spread in these networks strongly depended on the exact network architecture using otherwise identical parameters. Changes in coupling strength affected signal spread in these networks differently. As in the experimental situation, changes in synaptic conductance influenced signal spread. Some principal effects of extensively coupled horizontal cells on photoreceptor signal processing were simulated with one type of photoreceptor connected by telodendria, synapsing onto an underlying triangular network and receiving feedback synapses. Under certain conditions, spatial information is coded in single photoreceptors. This was also the case in the experimental situation. In the simulation, spatial filter adjustment for optimal spatial coding in photoreceptors can be achieved by changing coupling strength in the horizontal cell network.

Modulation of ganglion cell activity in the pineal gland of the rainbow trout: effects of cholinergic, catecholaminergic, and GABAergic receptor agonists.

Second order neurons within intact isolated pineal glands of the rainbow trout were explored by extracellular recordings to investigate modulatory effects of putative intrapineal neurotransmitters. Acetylcholine, dopamine, and norepinephrine were found to increase ganglion cell activity in a majority of cells tested. The excitatory effects of acetylcholine, dopamine, and norepinephrine were mimicked by muscarinic, dopamine D2, and beta-adrenergic receptor agonists and significantly increased with the applied light intensity, resulting in an attenuation of the ganglion cell response to light. GABA decreased discharge activity in most cells tested. This effect, which could be mimicked with the GABAA receptor agonist piperidine, was independent from the adaptive status. Acetylcholine and GABA were still active if applied during synaptic blockade with low Ca++ high Mg(++)-perfusion medium, whereas dopamine and norepinephrine exhibited no effects if applied during synaptic blockade, suggesting a differential cellular distribution of neurotransmitter receptors in the trout pineal gland. These data demonstrate that ganglion cell activity in the trout pineal gland is under the influence of several neurotransmitters, including acetylcholine, dopamine, norepinephrine, and GABA, which is in contrast to the originally proposed simple bineuronal transduction pathway from photoreceptors onto ganglion cells. Since the above-mentioned neurotransmitters are believed to be released from pineal interneurons, we may conclude that ganglion cell activity in the teleost pineal gland is, similarly to the retina, the product of photoreceptor signals and a modulatory active interneuronal system.

Adaptation to Variegated Scenes and Colour Constancy

For a visual system to possess colour constancy across varying illumination, chromatic signals from a scene must remain constant at some neural stage. We found that photoreceptor and opponent-colour signals from a large sample of natural and man-made objects under one kind of natural daylight were almost perfectly correlated with the signals from those objects under every other spectrally different phase of daylight. Therefore, in scenes consisting of many objects, the effect of illumination changes on specific colour mechanisms can be simulated by shifting all chromaticities by an additive or multiplicative constant along a theoretical axis. When the effect of the illuminant change was restricted to specific colour axes, thresholds for detecting a change in the perceived colours in a scene were significantly elevated in the presence of spatial variations along the same axis. Probe-flash threshold curves revealed that adaptation to variegated scenes is qualitatively different from independent adaptation to the constituents or to the space-average, but is similar to adaptation to prolonged temporal modulation (Shapiro and Zaidi, 1992 Vision Research32 2065 – 2076), which would be caused by small eye-movements across object boundaries. The data are consistent with a ‘response equalisation’ model, which modifies the response function of each mechanism to match the cumulative frequency distribution of its inputs (Zaidi and Shapiro, 1993 Biological Cybernetics69 415 – 428). In a variegated scene, correlations between spatially local chromatic signals across illuminants, and adaptation caused by eye movements across spatial variations, help the visual system to attenuate the perceptual effects due to changes in illumination.

Optimal Sets of Color Receptors and Color Opponent Systems for Coding of Natural Objects in Insect Vision

Model calculations are used to find an optimal color vision system for the coding of natural objects. The criteria to assess the quality of color vision are (a) discriminability between all colors of a given set; (b) discriminability between nearest neighbors (only the most similar colors of a set); and (c) detectability (color difference between target and background). The colored objects investigated are several sets of flower colors, one set of green foliage colors, and one set of fruit colors. A large variety of hypothetical color vision systems was generated by varying both the wavelength positions of photoreceptors and the weights of color opponent processes used to evaluate the receptor inputs. It is shown that the set of spectral receptor types in flower visiting bees (λmax=340, 430 and 540 nm) is close to optimal for the discrimination of several sets of sympatric and simultaneously blooming flower colors, as well as for discrimination of green foliage, but not for fruit coloration. For two sets of objects, the illuminant was varied, which changed the results only marginally. Detectability of flowers against background is likewise optimal. The optimal wavelength positions of photoreceptors are largely independent of the particular color opponent mechanisms used to evaluate the photoreceptor signals. Optimal color opponent systems are all those which comprise two opponent processes with weighting factors differing strongly form one another. The evolutionary implications of these findings are discussed against the background of a recent phylogenetic study which showed that wavelength tuning of insect photoreceptors likely predated the evolution of flower color.

γ-Aminobutyric acid enhances the light response of ganglion cells in the trout pineal organ

Electrical recordings from achromatic second order neurons of intact superfused pineal organs of the rainbow trout were used to investigate the role of γ-aminobutyric acid (GABA) in the transmission of photoreceptor signals onto centrally projecting ganglion cells. Bath-applied GABA decreased the spike discharge rate of 98% of achromatic ganglion cells in a dose-dependent manner. GABA was also active if applied during synaptic blockade, demonstrating the presence of GABAergic receptors at the ganglion cell level. Responsiveness of ganglion cells to light was reversibly enhanced by GABA. The light response curve of ganglion cells, which was obtained by plotting spike rate versus light intensity, was significantly shifted to lower frequencies by GABA, indicating that GABA is an important inhibitory modulator of ganglion cell activity in the trout pineal organ.

Retinal degeneration in transgenic mice with photoreceptor-specific expression of a dominant-negative fibroblast growth factor receptor

Mutant cDNAs coding for dominant-negative forms of the fibroblast growth factor receptors 1 (FGFR-1) and 2 (FGFR-2) that lack tyrosine kinase activity were ligated to a 2.2 kb DNA fragment containing the bovine rhodopsin promoter and used to generate transgenic mice. Six independent lines were generated with the FGFR-1 construct, and five were generated with the FGFR-2 construct. Five of the six FGFR-1 mutant lines and all five FGFR-2 mutant lines showed transgene expression in the retina by reverse transcription-PCR. By both in situ hybridization and immunohistochemistry, mutant FGFRs were found to be expressed specifically in photoreceptors of transgene-positive FGFR-1 and FGFR-2 mice. Lines expressing the FGFR-2 mutant showed progressive photoreceptor degeneration; the retinas showed minimal or no abnormalities at 1 month, but by 2 months they showed focal areas of thinning of the outer nuclear layer and disruption of photoreceptors. By 2-4 months, areas of complete loss of photoreceptors were seen. These abnormalities were not seen in control littermates not expressing the transgene. Mice from two FGFR-1 mutant lines showed focal areas of thinning of the outer nuclear layer and numerous photoreceptors with fragmented chromatin, whereas the other FGFR-1 lines showed minimal or no abnormalities. These data indicate that perturbation of FGF signaling in photoreceptors is associated with progressive photoreceptor degeneration, suggesting that one or more of the FGFs may act as a survival factor for photoreceptor cells.