Magnitude of increase in retinal cGMP metabolic flux determined by 18O incorporation into nucleotide alpha-phosphoryls corresponds with intensity of photic stimulation

The property of cyclic nucleotide phosphodiesterases to catalyze 3'-P--O bond cleavage and the insertion of a single nonexchangeable atom of 18O from [18O]water into the phosphoryl of the 5'-nucleotide product has been utilized as a means for measuring the hydrolytic flux of cGMP and cAMP in isolated dark-adapted intact rabbit retinas. Without illumination 18O labeling of guanine nucleotide (GTP and GDP) alpha-phosphoryls proceeds linearly for at least 80 s at a rate of 3.3 nmol of 18O/s.g of retina (wet weight). This rate is estimated to be approximately 8 times greater in the rod outer segment layer where over 90% of retinal cGMP metabolic components reside. Photic stimulation during a 20-s incubation was provided by intermittent flashes of light representing 800 ms of total illumination. Light stimuli over a range of intensities of greater than 3 log units commencing with a minimally detectable intensity produce graded increments in the rate of 18O incorporation into guanine nucleotide alpha-phosphoryls to a maximum increase of 5-fold. On the basis of only the 800-ms period of illumination this maximum increase is 125-fold. Steady state levels of retinal cGMP are not altered appreciably over this greater than 3 log range of light intensities but a light stimulus exceeding this intensity range causes an approximate 50% decrease in retinal cGMP concentration and a relative decline in the maximal rate of 18O labeling of guanine nucleotide alpha-phosphoryls. No light-related increases were detected in 18O incorporation into adenine nucleotide alpha-phosphoryls nor the gamma-phosphoryls of GTP or ATP or Pi. These observations indicate that light stimuli over greater than 3 log of light intensity produce incremental increases in cGMP metabolic flux that result from comparable increases in the rates of both cGMP generation and cGMP hydrolysis. It is postulated that increases in cGMP metabolic flux rather than changes in cGMP steady state levels are integral to phototransduction by a mechanism that involves the coupling of cGMP synthesis and/or hydrolysis to either the release of calcium from disc membranes or the inhibition of Na+ conductance by the photoreceptor membrane. This is suggested to occur by an energy-linked process and/or the generation of protons.     

Changes in cGMP concentration correlate with some, but not all, aspects of the light-regulated conductance of frog rod photoreceptors

Cyclic GMP has been implicated in controlling the light-regulated conductance of rod photoreceptors of the vertebrate retina. However, there is little direct evidence correlating changes in cGMP concentration with the light-regulated permeability mechanism in living cells. A preparation of intact frog rod outer segments suspended in a Ringer's medium containing low Ca2+ has been used to demonstrate that initial changes in total cellular cGMP concentration parallel changes in the light-regulated membrane current over a wide range of light intensities. At light intensities bleaching from 160 to 5.6 X 10(6) rhodopsin molecules/rod/s, decreases in the response latency for the cGMP kinetics parallel decreases in the latent period of the electrical response. Further, changes in the rate of the cGMP decrease parallel the rate of membrane current suppression as the light intensity is varied. Up to 10(5) cGMP molecules are hydrolyzed per photolyzed rhodopsin, consistent with in vitro studies showing that each bleached rhodopsin can activate over 100 phosphodiesterase molecules. Addition of the Ca2+ ionophore, A23187, does not affect the initial kinetics of the cGMP decrease or of the electrical response, excluding a direct role for Ca2+ in the initial events of phototransduction. These results are consistent with cGMP being the intracellular messenger that links rhodopsin isomerization with changes in membrane permeability upon illumination. It is unlikely, however, that light-induced changes in total cGMP concentration are the sole regulators of membrane current. This is suggested by several observations: at bright light intensities, the subsecond light-induced cGMP decrease is essentially complete prior to complete suppression of membrane current; maximal light-induced decreases in cGMP concentration occur at all light intensities tested, whereas the extent of membrane current suppression varies over the same range of light intensities; changing the external Ca2+ concentration from 1 mM to 10 nM in the dark causes an increase in membrane current that is significantly more rapid than corresponding changes in cGMP concentration. Thus, light-induced changes in total cellular cGMP concentration correlate with some, but not all, aspects of the visual excitation process in vertebrate photoreceptors.     

The intracellular pupil mechanism and photoreceptor signal: noise ratios in the fly Lucilia cuprina

The function of the intracellular pupil mechanism is examined by comparing the responses of photoreceptors in normal flies with those from white-eyed flies that lack the pupil. In white-eyed flies the response to an intensity increment of fixed contrast decreases at high background intensities. There is a smaller decrease in noise amplitude so that the signal:noise ratio falls. The intensity dependence of the photoreceptor signal:noise ratio fits a simple model in which activated photopigment molecules compete for 3 X 10(4) transduction units. The signal:noise ratio decreases at high intensities because the transduction units are saturated. This model is supported by a noise analysis, which provides three estimates of the number of events generating photoreceptor responses. In white-eyed flies the event number saturates at high background intensities, suggesting that a maximum of 2 X 10(4) events can be simultaneously active. Wild-type flies do not exhibit saturation effects over the range of intensities studied. The signal:noise ratio rises with intensity to reach a stable asymptote, close to the maximum observed for white-eyed flies. Pupil attenuation is calculated from measurements of signal:noise ratio in white-eyed and wild-type flies. The pupil is progressively activated over a two log unit intensity range and when fully closed attenuates the effective intensity by 99%. The threshold of this pupil effect coincides with the threshold of pupil activation measured optically. We conclude that the intracellular pupil attenuates the light flux to prevent receptor saturation and to extend the range of intensities at which fly photoreceptors operate close to their maximum signal:noise ratio. This upper limit is determined by the number of transduction units generating a cell's response.     

Rapid declines in cyclic GMP of rod outer segments of intact frog photoreceptors after illumination

Considerable disagreement has resulted from experiments designed to test whether light-induced falls in cGMP in outer segment (OS) of photoreceptors precede their light-induced electrical responses. Different studies have reported initial declines at 50 ms, at s, or not at all for physiological stimuli. Such studies have employed whole retinas, isolated rod OS, or isolated rod OS with attached inner segments and involved a variety of techniques. We developed an apparatus that illuminates intact pieces of dark-adapted frog retinas at 22 degrees C for known brief durations and then rapidly (47 ms) presses their OS surface against a copper mirror cooled by liquid helium. Freezing occurs in less than 2 ms. Cyclic GMP was then assayed in cryostat sections of the OS layer. Six illumination intensities that bleached from 90 to 9 X 10(8) rhodopsin molecules per s were delivered for durations of 0.1-2 s. Compared to dark-adapted values, progressive losses of cGMP were seen with all illumination intensities. Because a significant loss in cGMP was seen after a 100 ms exposure to our dimmest stimulus, it appears that a loss of cGMP could play a role in rod visual transduction.     

The rate of rhodopsin phosphorylation in isolated rentinas of frog and cattle.

Phosphorylation of rhodopsin has been measured in isolated retinas incubated with 32P-phosphate under physiological conditions. The half-time of the light-induced phosphorylation was found to be approximately 2 min with frog retinas at 21 degrees C, and in the order of 1--2 min with cattle retinas at 36 degrees C. It is suggested by this slow rate that the phosphorylation reaction is not directly involved in the chain of events which lead from absorption of a photon to excitation of the photoreceptor cells but may perhaps have a regulatory function in controlling light/dark adaptation.     

Optical Imaging of Human Cone Photoreceptors Directly Following the Capture of Light

Capture of light in the photoreceptor outer segment initiates a cascade of chemical events that inhibit neurotransmitter release, ultimately resulting in vision. The massed response of the photoreceptor population can be measured non-invasively by electrical recordings, but responses from individual cells cannot be measured without dissecting the retina. Here we used optical imaging to observe individual human cones in the living eye as they underwent bleaching of photopigment and associated phototransduction. The retina was simultaneously stimulated and observed with high intensity visible light at 1 kHz, using adaptive optics. There was marked variability between individual cones in both photosensitivity and pigment optical density, challenging the conventional assumption that photoreceptors act as identical subunits (coefficient of variation in rate of photoisomerization = 23%). There was also a pronounced inverse correlation between these two parameters (p<10⁻⁷); the temporal evolution of image statistics revealed this to be a dynamic relationship, with cone waveguiding efficiency beginning a dramatic increase within 3 ms of light onset. Beginning as early as 2 ms after light onset and including half of cells by ∼7 ms, cone intensity showed reversals characteristic of interference phenomena, with greater delays in reversal corresponding to cones with more photopigment (p<10⁻³). The timing of these changes is argued to best correspond with either the cessation of dark current, or to related events such as changes in intracellular cGMP. Cone intensity also showed fluctuations of high frequency (332±25 Hz) and low amplitude (3.0±0.85%). Other groups have shown similar fluctuations that were directly evoked by light; if this corresponds to the same phenomenon, we propose that the amplitude of fluctuation may be increased by the use of a bright flash followed by a brief pause, to allow recovery of cone circulating current.     

Light and dark active phosphodiesterase regulation in salamander rods

We studied the activation of 3',5'-cyclic guanosine monophosphate (cGMP) phosphodiesterase (PDE) by using a cell-permeant enzyme inhibitor. Rods of Ambystoma tigrinum held in a suction electrode were jumped into a stream of 3-isobutyl-1-methylxanthine (IBMX), 0.01-1 mM. Initial transient light-sensitive currents fit the notion that dark and light-activated forms of PDE contributed independently to metabolic activity and were equivalently inhibited by IBMX (apparent Ki 30 microns). Inhibition developed within 50 ms, producing a step decrease of enzyme velocity, which could be offset by activation with flashes or steps of light. The dark PDE activity was equivalent to light activation of enzyme by 1,000 isomerization rod-1s-1, sufficient to hydrolyze the free cGMP pool (1/e) in 0.6 s. Steady light activated PDE in linear proportion to isomerization rate, the range from darkness to current saturation amounting to a 10-fold increase. The conditions for simultaneous onset of inhibitor and illumination to produce no net change of membrane current defined the apparent lifetime of light-activated PDE, TPDE* = 0.9 s, which was independent of both background illumination and current over the range 0-3 x 10(5) isomerization s-1, from 50 to 0 pA. Adaptation was a function of current rather than isomerization: jumps with different proportions of IBMX concentration to steady light intensity produced equal currents, and followed the same course of adaptation in maintained light, despite a 10-fold difference of illumination. Judged from the delay between IBMX- and light-induced currents, the dominant feedback regulatory site comes after PDE on the signal path. The dark active PDE affects the hydrolytic flux and cytoplasmic diffusion of cGMP, as well as the proportional range of the cGMP activity signal in response to light.     

The rate of rhodopsin phosphorylation in isolated retinas of frog and cattle

Phosphorylation of rhodopsin has been measured in isolated retinas incubated with ³²P-phosphate under physiological conditions. The half-time of the light-induced phosphorylation was found to be approximately 2 min with frog retinas at 21°C, and in the order of 1–2 min with cattle retinas at 36°C. It is suggested by this slow rate that the phosphorylation reaction is not directly involved in the chain of events which lead from absorption of a photon to excitation of the photoreceptor cells but may perhaps have regulatory function in controlling light/dark adaptation.     

Two temporal phases of light adaptation in retinal rods

Vertebrate rod photoreceptors adjust their sensitivity as they adapt during exposure to steady light. Light adaptation prevents the rod from saturating and significantly extends its dynamic range. We examined the time course of the onset of light adaptation in bullfrog rods and compared it with the projected onset of feedback reactions thought to underlie light adaptation on the molecular level. We found that adaptation developed in two distinct temporal phases: (1) a fast phase that operated within seconds after the onset of illumination, which is consistent with most previous reports of a 1-2-s time constant for the onset of adaptation; and (2) a slow phase that engaged over tens of seconds of continuous illumination. The fast phase desensitized the rods as much as 80-fold, and was observed at every light intensity tested. The slow phase was observed only at light intensities that suppressed more than half of the dark current. It provided an additional sensitivity loss of up to 40-fold before the rod saturated. Thus, rods achieved a total degree of adaptation of approximately 3,000-fold. Although the fast adaptation is likely to originate from the well characterized Ca(2+)-dependent feedback mechanisms regulating the activities of several phototransduction cascade components, the molecular mechanism underlying slow adaptation is unclear. We tested the hypothesis that the slow adaptation phase is mediated by cGMP dissociation from noncatalytic binding sites on the cGMP phosphodiesterase, which has been shown to reduce the lifetime of activated phosphodiesterase in vitro. Although cGMP dissociated from the noncatalytic binding sites in intact rods with kinetics approximating that for the slow adaptation phase, this hypothesis was ruled out because the intensity of light required for cGMP dissociation far exceeded that required to evoke the slow phase. Other possible mechanisms are discussed.     

Light-induced decreases in cGMP concentration precede changes in membrane permeability in frog rod photoreceptors

This study examines whether changes in cGMP concentration initiated by illumination of frog rod photoreceptors occur rapidly enough to implicate cGMP as an intermediate between rhodopsin activation in the disc membrane and permeability changes in the plasma membrane. Previous studies using whole retinas or isolated outer segments have provided conflicting evidence on the role of cGMP in the initial events of phototransduction. The rod photoreceptor preparation employed in this work consists of purified suspensions of outer segments still attached to the mitochondria-rich ellipsoid portion of the inner segment. These photoreceptors are known to retain normal electrophysiological responses to illumination and have cGMP levels comparable to those measured in the intact retina. When examined under several different conditions, changes in cGMP concentrations were found to occur as rapidly or more rapidly than the suppression of the membrane dark current. Subsecond changes in cGMP concentration were analyzed with a rapid quench apparatus and confirmed by comparison with a rapid freezing technique. In a 1 mM Ca2+ Ringer's solution, cGMP levels decrease to 65% of their final extent within 200 ms after bright illumination; changes in membrane dark current follow a similar time course. When the light intensity is decreased to 8000 rhodopsins bleached per rod per s, the light-induced cGMP decrease is completed within 50 ms, with 7 X 10(5) cGMP molecules hydrolyzed per rhodopsin bleached. During this time the dark current has not yet begun to change. Thus, under physiological conditions it is clear that changes in cGMP concentration precede permeability changes at the plasma membrane. The correlation of rapid changes in cGMP levels with changes in membrane current leave open the possibility that changes in cGMP concentration may be an obligatory step in the reaction sequence linking rhodopsin activation by light and the resultant decrease in sodium permeability of the plasma membrane.     

A role for GCAP2 in regulating the photoresponse. Guanylyl cyclase activation and rod electrophysiology in GUCA1B knock-out mice

Cyclic GMP serves as the second messenger in visual transduction, linking photon absorption by rhodopsin to the activity of ion channels. Synthesis of cGMP in photoreceptors is supported by a pair of retina-specific guanylyl cyclases, retGC1 and -2. Two neuronal calcium sensors, GCAP1 and GCAP2, confer Ca(2+) sensitivity to guanylyl cyclase activity, but the importance and the contribution of each GCAP is controversial. To explore this issue, the gene GUCA1B, coding for GCAP2, was disrupted in mice, and the capacity for knock-out rods to regulate retGC and generate photoresponses was tested. The knock-out did not compromise rod viability or alter outer segment ultrastructure. Levels of retGC1, retGC2, and GCAP-1 expression did not undergo compensatory changes, but the absence of GCAP2 affected guanylyl cyclase activity in two ways; (a) the maximal rate of cGMP synthesis at low [Ca(2+)] dropped 2-fold and (b) the half-maximal rate of cGMP synthesis was attained at a higher than normal [Ca(2+)]. The addition of an antibody raised against mouse GCAP2 produced similar effects on the guanylyl cyclase activity in wild type retinas. Flash responses of GCAP2 knock-out rods recovered more slowly than normal. Knock-out rods became more sensitive to flashes and to steps of illumination but tended to saturate at lower intensities, as compared with wild type rods. Therefore, GCAP2 regulation of guanylyl cyclase activity quickens the recovery of flash and step responses and adjusts the operating range of rods to higher intensities of ambient illumination.     

Biochemical mechanism of light adaptation in vertebrate photoreceptors.

Vertebrate photoreceptors can adjust their sensitivity to a wide range of light intensities spanning several orders of magnitude, the phenomenon of which is called light adaptation. Electrophysiological and biochemical studies have revealed that calcium can serve as an intracellular transmitter of light adaptation under the control of cGMP metabolism. After illumination, the cytoplasmic calcium concentration of a photoreceptor decreases, which in turn strongly activates photoreceptor guanylate cyclase. This calcium-dependent effect is mediated by a novel calcium-binding protein (recoverin) and leads to the restoration of the depleted cGMP pool after illumination.     

Rod sensitivity and visual pigment concentration in Xenopus

Xenopus larvae were raised on a vitamin A-free diet under constant illumination until their visual pigment content had decreased to between 8% of normal and an undetectably low level. After the intramuscular injection of 2.1 X 10(13-2.1 X 10(16) molecules of [3H]vitamin A, ocular tissue showed a rapid rate of uptake of label which reached a maximum level of incorporation by 48 h. Light- microscopic autoradiography revealed that the retinal uptake of label was concentrated within the receptor outer segments. Spectral transmissivity measurements at various times after injection were made upon intact retinas and upon digitonin extracts. They showed that visual pigment with a lambdamax of 504 nm was formed in the retina and that the amount formed was a function of incubation time and the magnitude of the dose administered. Electrophysiological measures of photoreceptor light responses were obtained from the PIII component of the electroretinogram, isolated with aspartate. The quantal flux required to elicit a criterion response was determined and related to the fraction of visual pigment present. The results showed that rod sensitivity varied linearly with the probability of quantal absorption.     

Light Adaptation in the Ventral Photoreceptor of Limulus

Light adaptation in both the ventral photoreceptor and the lateral eye photoreceptor is a complex process consisting of at least two phases. One phase, which we call the rapid phase of adaptation, occurs whenever there is temporal overlap of the discrete waves that compose a light response. The recovery from the rapid phase of adaptation follows an exponential time-course with a time constant of approximately 75 ms at 21°C. The rapid phase of adaptation occurs at light intensities barely above discrete wave threshold as well as at substantially higher light intensities with the same recovery time-course at all intensities. It occurs in voltage-clamped and unclamped photoreceptors. The kinetics of the rapid phase of adaptation is closely correlated to the photocurrent which appears to initiate it after a short delay. The rapid phase of adaptation is probably identical to what is called the "adapting bump" process. At light intensities greater than about 10 times discrete wave threshold another phase of light adaptation occurs. It develops slowly over a period of ½ s or so, and decays even more slowly over a period of several seconds. It is graded with light intensity and occurs in both voltage-clamped and unclamped photoreceptors. We call this the slow phase of light adaptation.     

Dopaminergic amacrine neurons of rat retinas with photoreceptor degeneration continue to respond to light

Exposure of albino rats to continuous light of low intensity (350–700 lux) for 4 months produces massive degeneration of the photoreceptor segments and cell bodies of the outer nuclear layer of the retina. Only a few heterochromatic, receptor cell nuclei remain, and no photoreceptor segments are present. On the other hand, the inner layers of these retinas remain morphologically intact. The inner nuclear layer of the normal rat retina contains a group of amacrine cells which contain the putative neurotransmitter, dopamine (DA). Short term exposure to light (30 or 60 min) markedly stimulates the rate of DA turnover in these cells in normal, previously dark-adapted rats. Such enhancement of the rate of neurotransmitter turnover in the brain has been correlated with an increase in nerve impulse activity. The present study was undertaken to determine if the dopaminergic amacrine cells of the inner nuclear layer were still responsive to light in the retinas of rats whose photoreceptors were previously destroyed by long term exposure to continuous illumination. One week before sacrifice, the animals which had been housed in continuous light for 4 months were returned to normal 14 hr light: 10 hr dark lighting conditions. At the end of this time they and a group of control rats which had been housed in cyclic lighting conditions for the entire 4 months were dark adapted for approximately 15 hr. Then the rate of retinal DA turnover was estimated from the depletion of DA following inhibition of DA synthesis by α methyl para-tyrosine. The turnover of DA in the dark-adapted retinas of the control rats and of experimental rats with photoreceptor degeneration was dramatically enhanced 2–4 fold by short term exposure (up to 1 hr) to light. Since rats are nocturnal and avoid light, we tested the light aversion of another group of rats which had been exposed to light for 4 months and then returned to cyclic lighting conditions for one week. These rats and control animals which had been maintained in cyclic lighting conditions for 4 months both chose the dark side of a light-dark box over 80% of the time. This behavior of the rats with retinal degeneration was taken as a crude indication of their continued ability to detect light. The light-induced increase in DA activity in retinas with photoreceptor degeneration may play a role in the continued ability of these rats to perceive light.     

Positive and negative tropic curvature induced by microbeam irradiation of protonemal tip cells of the moss Ceratodon purpureus

The photoreceptor phytochrome mediates tropic responses in protonemata of the moss Ceratodon purpureus. Under standard conditions the tip cells grow towards unilateral red light, or perpendicular to the electrical vector of polarized light. In this study the response of tip cells to partial irradiation of the apical region was analysed using a microbeam apparatus. The fluence response curve gave an unexpected pattern: whereas a 15-min microbeam with light intensities around 3 micro mol m (-2) s (-1) induced a growth curvature towards the irradiated side, higher light intensities around 100 micro mol m (-2) s (-1) caused a negative response, the cells grew away from the irradiated side. This avoidance response is explained by two effects: the light intensity is high enough to induce photoconversion into the active Pfr form of phytochrome, not only on the irradiated but also on the non-irradiated side by stray light. At the same time, the strong light on the irradiated side acts antagonistically to Pfr. As a result of this inhibition, the growth direction is moved to the light-avoiding side. Such a Pfr-independent mechanism might be important for the phototropic response to distinguish between the light-directed and light-avoiding side under unilateral light.     

In situ cGMP phosphodiesterase and photoreceptor potential in gecko retina

The possible involvement of phosphodiesterase (PDE) activation in phototransduction was investigated in gecko photoreceptors by comparing the in situ PDE activity with the photoreceptor potential. In the dark, intracellular injection of cGMP into a gecko photoreceptor caused a long-lasting depolarization. An intense light flash given during the depolarization phase repolarized the cell with a short latency comparable to that of the light-evoked hyperpolarizing response, which indicates that the activation of PDE in situ is rapid enough to generate the photoreceptor potential. PDE activity in situ was estimated quantitatively from the duration of the cGMP-induced depolarization, since it was expected that the higher the PDE activity, the shorter the duration. Under steady illumination, the enzyme exhibited a constant activity. On exposure to a light flash, PDE became activated, but recovered in the dark with a time course that was dependent on the intensity of the preceding stimulus. When PDE activity and photoreceptor sensitivity to light were measured in the same cell after a light flash, both recovery processes showed similar kinetics. Theoretical analysis showed that the parallelism in the recovery time courses could be explained if cGMP is the transduction messenger. These results suggest that PDE activation is involved not only in the generation but also in the adaptation mechanisms of the photoreceptor potential.     

Proper function of the Drosophila trp gene product during pupal development is important for normal visual transduction in the adult

The response of invertebrate photoreceptors consists of the summation of quantum bumps, each representing the response to a single photon. The bumps adapt depending on the intensity of the stimulus: their average size is relatively large in dim light and small in bright light. The rate of occurrence of the bumps varies proportionally with light intensity. In the Drosophila mutant trp, unlike in the wild type, the rate does not increase with increasing light intensity and the bumps do not adapt. Here we report an analysis of the trp gene and its expression in normal and mutant flies. Our results suggest that the trp protein is a novel photoreceptor membrane-associated protein, that this protein is not required for the occurrence of bumps but is necessary for adaptation, and that proper function of the trp gene product during pupal development is important for normal visual transduction in the adult.