Spectroscopic properties of porphyropsins

Enhancement of the long-wavelength sensitivity of optogenetic microbial rhodopsins by 3,4-dehydroretinal

Electrogenic microbial rhodopsins (ion pumps and channelrhodopsins) are widely used to control the activity of neurons and other cells by light (optogenetics). Long-wavelength absorption by optogenetic tools is desirable for increasing the penetration depth of the stimulus light by minimizing tissue scattering and absorption by hemoglobin. A2 retinal (3,4-dehydroretinal) is a natural retinoid that serves as the chromophore in red-shifted visual pigments of several lower aquatic animals. Here we show that A2 retinal reconstitutes a fully functional archaerhodopsin-3 (AR-3) proton pump and four channelrhodopsin variants (CrChR1, CrChR2, CaChR1, and MvChR1). Substitution of A1 with A2 retinal significantly shifted the spectral sensitivity of all tested rhodopsins to longer wavelengths without altering other aspects of their function. The spectral shift upon substitution of A1 with A2 in AR-3 was close to that measured in other archaeal rhodopsins. Notably, the shifts in channelrhodopsins were larger than those measured in archaeal rhodopsins and close to those in animal visual pigments with similar absorption maxima of their A1-bound forms. Our results show that chromophore substitution provides a complementary strategy for improving the efficiency of optogenetic tools.

Ontogenetic changes in color vision in the milkfish (Chanos chanos Forsskål, 1775)

The milkfish (Chanos chanos Forsskål, 1775) is a euryhaline fish widely distributed in tropical and subtropical Indo-Pacific waters. It is unique in having in the cephalic region adipose eyelid tissue that begins to develop in the larval stage and is completely formed by the Juvenile stage. The formation of the adipose eyelids coincides with the onset of active swimming ability. Larval and juvenile milkfish have different dietary modes and habitats. This study was aimed to investigate ontogenetic changes in color perception ability with the use of microspectrophotometry (MSP). Larval milkfish had rod cells and red, green, blue, and violet cone cells, while juvenile milkfish lost the violet cone cells, and the blue cones shifted to shorter wavelengths. Histological sections showed the presence of cone cells of the single type (but no double or twin types) in the retina, which implies that the milkfish may not have polarized vision.

Light responses in rods of vitamin A-deprived Xenopus

PURPOSE

Accumulation of free opsin by mutations in rhodopsin or insufficiencies in the visual cycle can lead to retinal degeneration. Free opsin activates phototransduction; however, the link between constitutive activation and retinal degeneration is unclear. In this study, the photoresponses of Xenopus rods rendered constitutively active by vitamin A deprivation were examined. Unlike their mammalian counterparts, Xenopus rods do not degenerate. Contrasting phototransduction in vitamin A-deprived Xenopus rods with phototransduction in constitutively active mammalian rods may provide new understanding of the mechanisms that lead to retinal degeneration.

METHODS

The photocurrents of Xenopus tadpole rods were measured with suction electrode recordings, and guanylate cyclase activity was measured with the IBMX (3-isobutyl-1-methylxanthine) jump technique. The amount of rhodopsin in rods was determined by microspectrophotometry.

RESULTS

The vitamin A-deprived rod outer segments were 60% to 70% the length and diameter of the rods in age-matched animals. Approximately 90% of its opsin content was in the free or unbound form. Analogous to bleaching adaptation, the photoresponses were desensitized (10- to 20-fold) and faster. Unlike bleaching adaptation, the vitamin A-deprived rods maintained near normal saturating (dark) current densities by developing abnormally high rates of cGMP synthesis. Their rate of cGMP synthesis in the dark (15 seconds(-1)) was twofold greater than the maximum levels attainable by control rods ( approximately 7 seconds(-1)).

CONCLUSIONS

Preserving circulating current density and response range appears to be an important goal for rod homeostasis. However, the compensatory changes associated with vitamin A deprivation in Xenopus rods come at the high metabolic cost of a 15-fold increase in basal ATP consumption.

Quantal noise from human red cone pigment

The rod pigment, rhodopsin, shows spontaneous isomerization activity. This quantal noise produces a dark light of approximately 0.01 photons s(-1) rod(-1) in human, setting the threshold for rod vision. The spontaneous isomerization activity of human cone pigments has long remained a mystery because the effect of a single isomerized pigment molecule in cones, unlike that in rods, is small and beyond measurement. We have now overcome this problem by expressing human red cone pigment transgenically in mouse rods in order to exploit their large single-photon response, especially after genetic removal of a key negative-feedback regulation. Extrapolating the measured quantal noise of transgenic cone pigment to native human red cones, we obtained a dark rate of approximately 10 false events s(-1) cone(-1), almost 10(3)-fold lower than the overall dark transduction noise previously reported in primate cones. Our measurements provide a rationale for why mammalian red, green and blue cones have comparable sensitivities, unlike their amphibian counterparts.

Light, photoreceptors, and circadian clocks

Research over the past decade has focused increasingly on the photoreceptor mechanisms that regulate the circadian system in all forms of life. Some of the results to emerge are surprising. For example, the rods and cones within the mammalian eye are not required for the alignment (entrainment) of circadian rhythms to the dawn-dusk cycle. There exists a population of directly light-sensitive ganglion cells within the eye that act as brightness detectors; these regulate both circadian rhythms and melatonin synthesis. An understanding of these "circadian photoreceptor" pathways, and the features of the light environment used for entrainment, have been and will continue to be heavily dependent on the appropriate use and measurement of light stimuli. Furthermore, if results from different laboratories, or species, are to be compared in any meaningful sense, standardized methods for light measurement and manipulation need to be adopted by circadian biologists. To this end, we describe light measurement in terms of both radiometric and photometric units and consider the appropriate use of light as a stimulus in circadian experiments. In addition, the construction of action spectra has been very helpful in associating photopigments with particular responses in a broad range of photobiological systems. Because the identity of the photopigments mediating circadian responses to light are often not known, we have also taken this opportunity to provide a step-by-step approach to conducting action spectra, including the construction of irradiance response curves, the calculation of relative spectral sensitivities, photopigment template fitting, and the underlying assumptions behind this approach. The aims of this chapter are to provide an accessible introduction to photobiological methods and explain why these approaches need to be applied to the study of circadian systems.

Spectral sensitivity of the perch (Perca fluviatilis) from the Danube

In spectral sensitivity studies, electroretinograms (ERG) were recorded from the in situ eyecup of immobilized perch (Perca fluviatilis) electrofished in the floodplain zone of the Danube River. It is shown that the ERG b-wave is a good indicator of spectral sensitivity, although it reflects the activity of photoreceptors indirectly. With a maximum around 542 mm, the scotopic spectral sensitivity of perch obtained using fitted amplitude-log intensity functions for threshold calculation and two models developed in our laboratory for computer-assisted fitting of spectral sensitivity curves did not differ from the sensitivity determined using the microspectrophotometric and isolated pigment methods (maximum around 541 nm).

Seasonal cycle in vitamin A1/A2-based visual pigment composition during the life history of coho salmon (Oncorhynchus kisutch)

Microspectrophotometry of rod photoreceptors was used to follow variations in visual pigment vitamin A1/A2 ratio at various life history stages in coho salmon. Coho parr shifted their A1/A2 ratio seasonally with A2 increasing during winter and decreasing in summer. The cyclical pattern was statistically examined by a least-squares cosine model, fit to the 12-month data sets collected from different populations. A1/A2 ratio varied with temperature and day length. In 1+ (>12 month old) parr the A2 to A1 shift in spring coincided with smoltification, a metamorphic transition preceding seaward migration in salmonids. The coincidence of the shift from A2 to A1 with both the spring increase in temperature and day length, and with the timing of seaward migration presented a challenge for interpretation. Our data show a shift in A1/A2 ratio correlated with season, in both 0+ (<12 months old) coho parr that remained in fresh water for another year and in oceanic juvenile coho. These findings support the hypothesis that the A1/A2 pigment pair system in coho is an adaptation to seasonal variations in environmental variables rather than to a change associated with migration or metamorphosis.

The thermal contribution to photoactivation in A2 visual pigments studied by temperature effects on spectral properties

Effects of temperature on the spectral properties of visual pigments were measured in the physiological range (5-28 degrees C) in photoreceptor cells of bullfrog (Rana catesbeiana) and crucian carp (Carassius carassius). Absorbance spectra recorded by microspectrophotometry (MSP) in single cells and sensitivity spectra recorded by electroretinography (ERG) across the isolated retina were combined to yield accurate composite spectra from ca. 400 nm to 800 nm. The four photoreceptor types selected for study allowed three comparisons illuminating the properties of pigments using the dehydroretinal (A2) chromophore: (1) the two members of an A1/A2 pigment pair with the same opsin (porphyropsin vs. rhodopsin in bullfrog "red" rods); (2) two A2 pigments with similar spectra (porphyropsin rods of bullfrog and crucian carp); and (3) two A2 pigments with different spectra (rods vs. long-wavelength-sensitive (L-) cones of crucian carp). Qualitatively, the temperature effects on A2 pigments were similar to those described previously for the A1 pigment of toad "red" rods. Warming caused an increase in relative sensitivities at very long wavelengths but additionally a small shift of lambdamax toward shorter wavelengths. The former effect was used for estimating the minimum energy required for photoactivation (Ea) of the pigment. Bullfrog rod opsin with A2 chromophore had Ea = 44.2 +/- 0.9 kcal/mol, significantly lower (one-tailed P < 0.05) than the value Ea = 46.5 +/- 0.8 kcal/mol for the same opsin coupled to A1. The A2 rod pigment of crucian carp had Ea = 42.3 +/- 0.6 kcal/mol, which is significantly higher (one-tailed P < 0.01) than that of the L-cones in the same retina (Ea = 38.3 +/- 0.4 kcal/mol), whereas the difference compared with the bullfrog A2 rod pigment is not statistically significant (two-tailed P = 0.13). No strict connection between lambdamax and Ea appears to exist among A2 pigments any more than among A1 pigments. Still, the A1 --> A2 chromophore substitution in bullfrog opsin causes three changes correlated as originally hypothesized by Barlow (1957): a red-shift of lambdamax, a decrease in Ea, and an increase in thermal noise.

Retinal photoreceptors and visual pigments in Boa constrictor imperator

The photoreceptors of Boa constrictor, a boid snake of the subfamily Boinae, were examined with scanning electron microscopy and microspectrophotometry. The retina of B. constrictor is duplex but highly dominated by rods, cones comprising 11% of the photoreceptor population. The rather tightly packed rods have relatively long outer segments with proximal ends that are somewhat tapered. There are two morphologically distinct, single cones. The most common cone by far has a large inner segment and a relatively stout outer segment. The second cone, seen only infrequently, has a substantially smaller inner segment and a finer outer segment. The visual pigments of B. constrictor are virtually identical to those of the pythonine boid, Python regius. Three different visual pigments are present, all based on vitamin A(1.) The visual pigment of the rods has a wavelength of peak absorbance (lambda(max)) at 495 +/- 2 nm. The visual pigment of the more common, large cone has a lambda(max) at 549 +/- 1 nm. The small, rare cone contains a visual pigment with lambda(max) at 357 +/- 2 nm, providing the snake with sensitivity in the ultraviolet. We suggest that B. constrictor might employ UV sensitivity to locate conspecifics and/or to improve hunting efficiency. The data indicate that wavelength discrimination above 430 nm would not be possible without some input from the rods.

Eye function of Mysidacea (Crustacea) in the northern Baltic Sea

Eye spectral sensitivity, [S(lambda)], was measured in seven northern Baltic mysid species using an electroretinogram technique. Their S(lambda) curves were compared with the spectral distribution of underwater light at their normal habitats. In the littoral species Neomysis integer, Praunus flexuosus and Praunus inermis, the S(lambda) maxima, [S(lambda)(max)], were in the wavelength-bands of 525-535, 505-515 and 520-530 nm respectively. The neoimmigrant species Hemimysis anomala had a S(lambda)(max) around 500 nm and high sensitivity at 393 nm, possibly indicating UV-sensitivity. S(lambda) of the pelagic species Mysis mixta and Mysis relicta sp. II was at about 505-520 nm. M. relicta sp. I from Pojoviken Bay and fresh water humic Lake Pääjärvi had S(lambda)(max) at approximately 550 nm and 570 nm respectively. This is in accordance with a similar long-wavelength shift in light transmittance of the respective waters. The eyes of the latter population were also damaged by strong light. The pontocaspian neoimmigrant H. anomala is clearly adapted to waters transmitting more blue light.

Spectral tuning in salamander visual pigments studied with dihydroretinal chromophores

In visual pigments, opsin proteins regulate the spectral absorption of a retinal chromophore by mechanisms that change the energy level of the excited electronic state relative to the ground state. We have studied these mechanisms by using photocurrent recording to measure the spectral sensitivities of individual red rods and red (long-wavelength-sensitive) and blue (short-wavelength-sensitive) cones of salamander before and after replacing the native 3-dehydro 11-cis retinal chromophore with retinal analogs: 11-cis retinal, 3-dehydro 9-cis retinal, 9-cis retinal, and 5,6-dihydro 9-cis retinal. The protonated Schiff's bases of analogs with unsaturated bonds in the ring had broader spectra than the same chromophores bound to opsins. Saturation of the bonds in the ring reduced the spectral bandwidths of the protonated Schiff's bases and the opsin-bound chromophores and made them similar to each other. This indicates that torsion of the ring produces spectral broadening and that torsion is limited by opsin. Saturating the 5,6 double bond in retinal reduced the perturbation of the chromophore by opsin in red and in blue cones but not in red rods. Thus an interaction between opsin and the chromophoric ring shifts the spectral maxima of the red and blue cone pigments, but not that of the red rod pigment.

The photoreceptors and visual pigments in the retina of a boid snake, the ball python (Python regius)

The photoreceptors and visual pigments of Python regius were studied using microspectrophotometry and scanning electron microscopy. The retina contains rods and cones, with rods constituting at least 90 % of the photoreceptor population. The rods are of a single type with long, narrow outer segments and are tightly packed. The wavelength of maximum absorbance (λ max) of the visual pigment in the rods is in the region of 494 nm. Two distinct types of cone are present. The most common cone, with a stout but stubby outer segment, contains a visual pigment with λ max at approximately 551 nm. A relatively rare cone, with a long, slender outer segment, contains an ultraviolet-sensitive visual pigment with λ max at approximately 360 nm. All the visual pigments have chromophores based on vitamin A1. The results are discussed in relation to the behavior of P. regius.

The case for light-dependent magnetic orientation in animals

Light-dependent models of magnetoreception have been proposed which involve an interaction between the magnetic field and either magnetite particles located within a photoreceptor or excited states of photopigment molecules. Consistent with a photoreceptor-based magnetic compass mechanism, magnetic orientation responses in salamanders, flies and birds have been shown to be affected by the wavelength of light. In birds and flies, it is unclear whether the effects of light on magnetic orientation are due to a direct effect on a magnetoreception system or to a nonspecific (e.g. motivational) effect of light on orientation behavior. Evidence from shoreward-orienting salamanders, however, demonstrates that salamanders perceive a 90 degrees counterclockwise shift in the direction of the magnetic field under long-wavelength (&gt;=500 nm) light. A simple physiological model based on the antagonistic interaction between two magnetically sensitive spectral mechanisms suggests one possible way in which the wavelength-dependent effects of light on the salamander's magnetic compass response might arise. Assuming that the wavelength-dependent characteristics of the avian magnetic response can be attributed to an underlying magnetoreception system, we discuss several hypotheses attempting to resolve the differences observed in the wavelength-dependent effects of light on magnetic orientation in birds and salamanders. By considering the evidence in the context of photoreceptor- and non-photoreceptor-based mechanisms for magnetoreception, we hope to encourage future studies designed to distinguish between alternative hypotheses concerning the influence of light on magnetoreception.

The effects of temperature on the dark-adapted spectral sensitivity function of the adult zebrafish

In goldfish and other cold-blooded vertebrates, temperature can influence the rhodopsin/porphyropsin contributions to the rod photoreceptors. This study examined the effects of temperature on the spectral sensitivity function of the dark-adapted zebrafish. Zebrafish were housed in either a warm (28-30 degrees C) or cold (22-25 degrees C) tank prior to testing. Fish were dark-adapted for at least 1 h and electroretinogram (ERG) responses to 200 ms stimuli of various wavelengths and irradiances were obtained. Results show that water temperature affected the spectral sensitivity function of the ERG b-wave. Subjects housed in the warm temperatures had a spectral sensitivity consistent with the rhodopsin absorption curve; however, fish housed in the colder temperatures had a spectral sensitivity function that was the result of a rhodopsin/porphyropsin mixture. In addition, ultraviolet cones (lambda max: 362 nm) contributed to the dark-adapted spectral sensitivity function under both temperature conditions. Consistent with the results from other fish, the dark-adapted visual system of the zebrafish can be influenced by water temperature. The results of this study demonstrate the necessity of maintaining a stable environment when examining the contributions of the photoreceptors to the visual response.

Switch in rod opsin gene expression in the European eel, Anguilla anguilla (L.)

The rod photoreceptors of the European eel, Anguilla anguilla (L.), alter their wavelength of maximum sensitivity (lambda max) from c.a. 523 nm to c.a. 482 nm at maturation, a switch involving the synthesis of a new visual pigment protein (opsin) that is inserted into the outer segments of existing rods. We artificially induced the switch in rod opsin production by the administration of hormones, and monitored the switch at the level of mRNA accumulation using radiolabelled oligonuleotides that hybridized differently to the two forms of eel rod opsin. The production of the deep-sea form of rod opsin was detected 6 h after the first hormone injection, and the switch in rod opsin expression was complete within four weeks, at which time only the mRNA for the deep-sea opsin was detectable in the retinal cells. It is suggested that this system could be used as a tractable model for studying the regulatory control of opsin gene expression.

Spectral properties of turtle cones

Microelectrodes were used to record from red and green cones of the turtle Pseudemys scripta elegans. The purpose of this study was to determine the action spectra of the red and green cone photopigments, and to look closely for direct interactions between the two cone classes. An isolated retina preparation was employed so that cones could be stimulated from the outer segment side, thereby avoiding the oil droplets that reside in the inner segments of many cones and normally filter incident light. In agreement with some previous electrophysiological studies, we found little evidence for significant direct connections between red and green cones. Exceptions to this rule are noted and discussed. Measurements indicate that this result does not appear to be due to a general loss of cone connectivity in the isolated retina preparation. Action spectra of the cone photopigments differed markedly from action spectra reported for cones in the eyecup preparation. In contrast to cones in the eyecup, cones in the isolated retina showed higher short-wavelength sensitivity and had action spectra that were adequately described by photopigment nomograms. A model of cone optical properties suggests that in the eyecup up to about 40% of the light that reaches a cone outer segment may do so without first passing through an oil droplet.

An analysis of two spectral properties of vertebrate visual pigments

Spectral data are scrutinized on two properties: (1) the chromophore-induced wavelength shift, i.e. the variation in absorbance maximum (lambda max) upon exchanging the vitamin A1-based chromophore with one based on vitamin A2 in the same opsin; (2) the half-band width (HBW) variation as a function of the reciprocal of the peak absorbance (lambda max)-1. It is shown that in an extended spectral range that includes the UV and when data are plotted in wavenumbers, the chromophore-induced shifts can be approximated with a parabola, whose minimum occurs near 23,000 cm-1 (approximately 430 nm). Similarly, HBW variations can also be fitted with parabolas, however, these show maxima near 430 nm. The theoretical implications of the two phenomena concerning lambda max tuning in vertebrate visual pigments are discussed.

A third, ultraviolet-sensitive, visual pigment in the Tokay gecko (Gekko gekko)

Numerous extraction and microspectrophotometric studies have shown that the nocturnal Tokay gecko (Gekko gekko), has two visual pigments: a "green" with lambda max at 521 nm and a "blue" at 467 nm. In addition, similar studies on other nocturnal gecko species have found only the same two classes of visual pigment. With the finding that some diurnal species of gecko have a third visual pigment class with lambda max peaking in the UV, doubts were raised concerning the presence of only two visual pigment classes in nocturnal forms. Therefore, a microspectrophotometric re-examination of the Tokay gecko was undertaken to look specifically for a UV visual pigment. A UV-absorbing pigment (364 nm lambda max) was found in approx. 20% of the thin outer segments of type C double rods, thought previously to contain only the 467 nm pigment. That this UV-absorbing pigment was truly a visual pigment was confirmed by its dichroism, behaviour following exposure to UV radiation and "nomogram" fit. It is suggested that this visual pigment had been seen in previous microspectrophotometric studies, but its similarity to known photoproducts peaking in the same spectral region resulted in a case of mistaken identity.

Spectral characteristics of visual pigments in rainbow trout (Oncorhynchus mykiss)

We investigated retina preparations of young rainbow trout (Oncorhynchus mykiss) with body wt 5-40 g. Rods, single and double cones were measured in side-on orientation by microspectrophotometry, identifying five spectrally distinct visual pigments (or photoreceptors containing mixtures of visual pigments). The mean wavelength of peak absorbance (lambda max) of the alpha-bands were 365 and 434 nm in single cones, 531 and 576 nm in double cones, and 521 nm in the rods. The half-band width (HBW) of the main absorption bands were broader than expected of retinal- (vitamin A1-) based visual pigments, and thus, they were indicative of a mixed chromophore pool derived from both the vitamin A1 and A2 forms. One consequence of the utilization of mixed chromophores is the broadening of the alpha-band absorption in each pigment type. And yet, we obtained exceptionally narrow HBW for the UV-type pigment, when compared with HBW values expected on the basis of the linear trend seen in visual pigments absorbing in the visible spectrum. We conclude that the UV pigment in rainbow trout has an unusually narrow HBW. Nevertheless, this species is not exceptional in this regard, for the UV-absorbing visual pigments in other vertebrate species also have narrow HBW.

Photoreceptor spectral absorbance in larval and adult winter flounder (Pseudopleuronectes americanus)

The habitat occupied by larval winter flounder (Pseudopleuronectes americanus) differs considerably in light regime from that of the adult. To understand how the visual system has adapted to such changes, photoreceptor spectral absorbance was measured microspectrophotometrically in premetamorphic and postmetamorphic specimens of winter flounder. Before metamorphosis, larval flounder retinas contain only one kind of photoreceptor which is morphologically cone-like with peak absorbance at 519 nm. After metamorphosis, the adult retina has three types of photoreceptors: single cones, double cones, and rods. The visual pigment in single cones has a peak absorbance at lambda max = 457 nm, the double cones at lambda max = 531 and 547 nm, and the rod photoreceptors at lambda max = 506 nm. Double cones were morphologically identical, but the two members contained either different (531/547 nm) or identical pigments (531/531 nm). The latter type were found only in the dorsal retina. The measured spectral half-bandwidths (HBW) were typical of visual pigments with chromophores derived from vitamin A1 with the possible exception of the long-wavelength absorbing pigment in double cones which appeared slightly broader. Because the premetamorphic pigment absorbance has a different lambda max than those of the postmetamorphic pigments, different opsin genes must be expressed before and after metamorphosis.

Visual pigments in the sea lamprey, Petromyzon marinus

We present microspectrophotometric evidence for the existence of two distinct visual pigments residing in two different morphological types of photoreceptor of the sea lamprey. In the upstream migrant Petromyzon marinus, the pigment found in short receptors has a wavelength of peak absorbance (lambda max) of 525 nm, whereas the pigment located in long receptors has a lambda max of 600 nm. Although the former appears to be pure porphyropsin, the latter is akin to visual pigments found in the red-absorbing cones of amphibian and teleost retinae. The kinship is more than superficial pertaining to lambda max, however, because the long receptor pigment, like the others, shows the typical sensitivity to the anionic milieu. Lampreys belong to the class Cyclostomata, which now becomes the sixth phylogenetic class of vertebrates with anion-sensitive as well as anion-insensitive visual pigments. This finding strengthens the hypothesis that sensitivity to anions is an integral property of all long-wavelength-absorbing vertebrate pigments and that these pigments form a distinct group in which an external Cl- ion is utilized in tuning the lambda max of the alpha-band absorbance to its native maximum value. The presence of an anion-sensitive and an anion-insensitive pigment in a retina implies the expression of two distinct opsin genes. We infer this from several examples of correlation between anion sensitivity and opsin sequence groupings. Moreover, the presence of two distinct opsin genes expressed throughout six vertebrate classes implies their existence in a common ancestor to all.

Microspectrophotometric determinations of rod visual pigments in some adult and larval Australian amphibians

Visual pigments from the red rods of adults of eight species of Australian anuran amphibians, from a variety of habitats, were analyzed by microspectrophotometry. The lambda max in all cases fell between 502 nm and 506 nm, and the absorption spectra were well fitted by an A1-based visual pigment template curve. Red rod pigments were also analyzed for a number of tadpoles. In some cases the data were best fitted with an A1-based visual pigment template, in other cases with an A2-based template, and finally some tadpoles appeared to have mixtures of the two pigments.

The frequency of isomerization-like 'dark' events in rhodopsin and porphyropsin rods of the bull-frog retina

1. The dark current and responses to dim flashes were recorded with the suction pipette technique from single rods in pieces of bull-frog retina taken from either the dorsal porphyropsin or the ventral rhodopsin field. 2. The composition of visual pigment in the rods was determined by microspectrophotometry. Rods from the dorsal pieces contained 70-88% porphyropsin523 mixed with rhodopsin502. The ventral rods contained almost pure rhodopsin, any possible admixture of porphyropsin being below the level of detectability (less than 5%). 3. In most cells, the responses to dim flashes were well fitted by a four-stage linear filter model, with no systematic differences in the response kinetics of porphyropsin and rhodopsin rods. The amplitude of saturated responses varied between 8 and 55 pA and that of responses to single isomerizations between 0.4 and 3.5 pA. 4. In porphyropsin rods, discrete events similar to the response to one photoisomerization were clearly seen in complete darkness. The dark current amplitude histogram was fitted by a convolution of the probability densities for the Gaussian continuous noise component and the averaged dim-flash response waveform. This allows estimation of the frequency and amplitude of discrete events and the standard deviation of the continuous component. The mean frequency of discrete dark events thus obtained from six porphyropsin cells was 0.057 rod-1 s-1 at 18 degrees C. 5. In rhodopsin rods, the dark current amplitude histogram appeared completely symmetrical, indicating that the frequency of discrete events must be lower than 0.005 rod-1 s-1 (except in one rod where it was 0.006 events rod-1 s-1). Per molecule of rhodopsin, the events are then at least 5 times rarer than reported for toad rhodopsin rods at the same temperature. 6. The low rate of isomerization-like 'dark' events in bull-frog rhodopsin rods shows, firstly, that results cannot be generalized across species even for rhodopsins which appear spectrally identical. Secondly, it suggests that these events need not (in an evolutionary sense) constitute an irreducible noise factor which must set the ultimate limit to the sensitivity of dark-adapted vision. 7. The difference between porphyropsin and rhodopsin rods shows that, given (presumably) the same opsin, the pigment utilizing retinal2 and absorbing maximally at longer wavelengths produces more noise. The signal/noise ratio attained in the photoreceptor may be an important factor in the natural selection of visual pigments.

The presence of a porphyropsin-based visual pigment in the juvenile lemon shark (Negaprion brevirostris)

The visual pigment from the juvenile lemon shark has been extracted and is a homogeneous vitamin A2-based porphyropsin with maximum absorption at 522 nm. This is the first report of a porphyropsin visual pigment extracted from the retina of an elasmobranch. In contrast, the visual pigment from the adult lemon shark yields a homogeneous vitamin A1-based rhodopsin with maximum absorption at 501 nm. We conclude that the porphyropsin of the juvenile lemon shark changes over to a rhodopsin as the animal matures.

The visual pigment basis for cone polymorphism in the guppy, Poecilia reticulata

Long-wavelength visual pigment polymorphism, similar to that found in primates, was found in the guppy using microspectrophotometry (MSP). Guppies have a rod pigment with a wavelength of maximal absorbance (lambda max) at 501 nm and cone pigments with peak absorbance at 408 and 464 nm. In addition individuals may have one, two or three cone classes in the yellow-green region of the spectrum with mean lambda max values of 533, 543 and 572 nm. Unlike primates this variation is not sex-linked and may be based on only two visual pigments which occur either on their own in outer-segments of the 533 nm and 572 nm cone classes or as a mixture in the 543 nm cone class.

Interspecific variation in the visual pigments of deep-sea fishes

Visual pigments in the rods of 38 species of deep-sea fish were examined by microspectrophotometry. 33 species were found to have a single rhodopsin with a wavelength of maximum absorbance (lambda max) in the range 470-495 nm. Such visual pigments have absorbance maxima close to the wavelengths of maximum spectral transmission of oceanic water. 5 species, however, did not conform to this pattern and visual pigments were found with lambda max values ranging from 451 nm to 539 nm. In 4 of these species two visual pigments were found located in two types of rod. Some 2-pigment species which have unusual red sensitivity, also have red-emitting photophores. These species have both rhodopsin and porphyropsin pigments in their retinae, which was confirmed by HPLC, and the two pigments are apparently located in separate rods in the same retinal area. In deep-sea fishes the occurrence of 'unusual' visual pigments seems to be correlated with aspects of the species' depth ranges. In addition to ecological influences we present evidence, in the form of lambda max spectral clustering, that indicates the degree of molecular constraint imposed on the evolution of visual pigments in the deep-sea.

Adaptation of a deep-sea cephalopod to the photic environment. Evidence for three visual pigments

Watasenia scintillans, a bioluminescent deep-sea squid, has a specially developed eye with a large open pupil and three visual pigments. Photoreceptor cells (outer segment: 476 micron; inner segment: 99 micron) were long in the small area of the ventral retina receiving downwelling light, whereas they were short (outer segment: 207 micron; inner segment: 44 micron) in the other regions of the retina. The short photoreceptor cells contained the visual pigment with retinal (lambda max approximately 484 nm), probably for the purpose of adapting to their environmental light. The outer segment of the long photoreceptor cells consisted of two strata, a pinkish proximal area and a yellow distal area. The visual pigment with 3-dehydroretinal (lambda max approximately 500 nm) was located in the pinkish proximal area, giving high sensitivity at longer wavelengths. A newly found pigment (lambda max approximately 471 nm) was in the yellow distal area. The small area of the ventral retina containing two visual pigments is thought to have a high and broad spectral sensitivity, which is useful for distinguishing the bioluminescence of squids of the same species in their environmental downwelling light. These findings were obtained by partial bleaching of the extracted pigment from various areas of the retina and by high-performance liquid chromatographic analysis of the chromophore, complemented by microscopic observations.

Light adaptation of rod and cone luminosity horizontal cells of the retina of the goldfish

Intracellular recordings from rod horizontal cells and luminosity external horizontal cells of the goldfish retina were obtained, and the process of light adaptation induced by steady, full-field background illumination was investigated. Rod horizontal cells had remarkably steep response vs intensity (rvi) functions when dark-adapted. Background illumination reduced the sensitivity of these cells primarily due to response compression, with intense backgrounds resulting in eventual response saturation. Increment threshold functions for these cells were non-linear, and increment saturation was evident when 500-nm backgrounds exceeded 10.5 log photons s-1 cm-2. Cone luminosity cells displayed broad response operating functions when dark-adapted. Light adaptation resulted in substantial narrowing of the rvi function, as well as a shift in the operating function to greater intensities. Response compression played only a minor role in the loss of sensitivity of these cells.

Application of an invariant spectral form to the visual pigments of crustaceans: implications regarding the binding of the chromophore

Visual pigment absorption spectra were measured in single photoreceptors of a stomatopod, a crayfish, a hermit crab, and five species of brachyuran crab. All fitted a Mansfield (1985) invariant form for visual pigment, the form also fitted by vertebrate retinal-based visual pigments. This is consistent with a theoretical model based on the structure of visual pigment molecules (Greenberg et al., 1975; Honig et al., 1976) which predicts that spectral bandwidth decreases as lambda max increases. The conformation to the invariant form implies that for any given chromophore bandwidth times lambda max is a constant.

Interaction of visual pigment with G-protein: effects of bleaching in native and reconstituted ROS preparations

Native and reconstituted preparations of bullfrog rod outer segment (ROS) membranes were analysed for the binding of the alpha and beta subunits of G-protein. Following incubation at 22-28 degrees C under varying conditions of illumination and chemical treatment, preparations were chilled and extracted with hypotonic medium lacking-vs.-containing GTP (H and HG extracts, respectively). The extent of binding of G alpha,beta ('percentage G bound') was determined by measurement of the relative abundance of G alpha, beta in the H and HG extracts. The addition of G to unbleached, G-depleted membranes (D-ROS) yielded relatively little binding of the G (14 +/- 13%). G reintroduced at congruent to 1 min vs. congruent to 90 min after major bleaching yielded, respectively, levels of binding of 88 +/- 8% and 24 +/- 8%. Native G, extracted at congruent to 90 min post-bleach and added to freshly bleached D-ROS, exhibited binding exceeding that in the parent (bleached +90 min) sample. Supplementation of reconstituted suspensions with all-trans retinal, and subsequent incubation in darkness, yielded 30-35% G-binding; similar treatment with 11-cis retinal yielded binding in the range of 0-32%. Upon irradiation, suspensions previously supplemented with either isomer exhibited approximately 60% binding. Incubation with 11-cis retinal had no substantial effect on the condition of tight binding observed shortly after bleaching. The data are discussed in relation to previous studies of visual pigment bleaching and regeneration.

Contributions of short-wavelength cones to goldfish ganglion cells

There are conflicting reports about the existence and nature of a short-wavelength cone (S-cone) contribution to ganglion cells in the goldfish retina. The present study sought to resolve these discrepancies by examining the S-cone contribution while recording from single ganglion cells in the excised, isolated goldfish retina. The effect of variations in the retinal preparation (gas content and type of background lighting during recording) on the S-cone input was also examined. Cells were classified into one of three types based on the responses at light onset and offset, when responses were driven only by the long-wavelength cone system (L-cones) of the receptive field's center (L+/-(on-excitation/off-inhibition), L-/+, and L+/+). With rare exceptions, the threshold spectral sensitivities of the centers and surrounds of cells that possessed opposite on and off responses (L+/- and L-/+) exhibited S-cone contributions, either prior to and/or during chromatic adaptation of the middle- and long-wavelength cones; the S-cone response was antagonistic to the L-cone input. The L+/+ center cells also contained a S-cone input, but it was synergistic to the L-cone input at suprathreshold intensities. These findings were robust across all of the retinal preparations employed. The discrepancies in the previous work were probably due to the incomplete classification of cells because of the use of threshold responses only.

Morphological and physiological studies of rod-driven horizontal cells with special reference to the question of whether they have axons and axon terminals

Rod-driven (intermediate) horizontal cells were examined in the carp retina to determine whether they bear axons and axon terminals. These cells were injected with HRP after physiological identification of the response type; which consisted of a higher sensitivity to light and a slower response time course than cone-driven (external) horizontal cells, and spectral sensitivity peaking at 520 nm. The labeled cells were further identified morphologically by tracing their dendrites to rod photoreceptors by light and electron microscopy. About two-thirds of the labeled cells (18/30) had a slender, axonlike process (less than 1 micron in diameter, 70-300 micron in length) running horizontally from the soma. No axonlike process was found in the remaining cells. Unlike the axons of external horizontal cells, this axonlike process was short and did not form a long fusiform expansion. No membrane specialization was found along the axonlike process. Since it has been reported that the syncytium made of axon terminals of external horizontal cells serves as a signal bypass of the syncytium made of the somata, it was asked, in separate experiments, whether the intermediate horizontal cells also had such a double syncytial layer. Response amplitudes to a slit of light were measured by placing the slit at various distances from the recording electrode. The response amplitude decayed with distance with a single exponential function, indicating that the syncytium of intermediate horizontal cells consists of a monolayer. These physiological data are consistent with the morphological observations.

Separation and light adaptation of rod and cone signals in the retina of the goldfish

The aspartate-isolated fast P III response was used to monitor the responses of goldfish photoreceptors at varying intensities of steady background illumination. When the retina contained the normal complement of rods and cones, light adaptation consisted of response compression, a shift of the response curve to more intense stimuli (cellular adaptation), and responses to decrements as well as increments of light. Rod and cone contributions to the fast P III response were separated by taking advantage of photomechanical movements of the photoreceptors to produce "all-rod" and "all-cone" retinae. Rods employ response compression as their primary adaptation mechanism. Rods show little cellular adaptation or responses to decremental flashes. However, cones do not show response compression, but continue to respond at bright backgrounds due to cellular adaptation.

3-Dehydroretinal in the eye of a bioluminescent squid, Watasenia scintillans

3-Dehydroretinal was found in the retina of a bioluminescent squid, Watasenia scintillans. The possible vitamin A2-visual pigment was localized in the ventral part of the eye and its proportion was about 15% of the total visual pigment.

Competition between retinal and 3-dehydroretinal for opsin in the regeneration of visual pigment

Rhodopsin regenerated faster than porphyropsin in all preparations of bullfrog opsin, bullfrog rod outer segment membrane and cattle opsin. When opsin was incubated with excess amount of an equimolar mixture of 11-cis-retinal and 11-cis-3-dehydroretinal, the composition of the regenerated pigment was simply dependent on the ratio of regeneration rates of rhodopsin and porphyropsin. This result can provide a mechanism to account for the discrepancy in vitamin A1/A2 composition between the retina and the pigment epithelium. The property of opsin preferring retinal to 3-dehydroretinal may be one of the basic factors affecting vitamin A1/A2 visual pigment systems.

Conversion of retinol to 3,4-didehydroretinol in the tadpole

The conversion of retinol to 3,4-didehydroretinol in bullfrog tadpoles was studied by injecting [3H] all-trans retinol into the peritoneal cavity. The specific activities of retinoids in the eye and the rest of the body at various time intervals after the injection were then determined by HPLC (high-performance liquid chromatography). Radioactivity was observed in ocular 3,4-didehydroretinyl esters after 2 days and their specific activity increased throughout the 2 weeks of experiment. This demonstrates that tadpoles can convert retinol to its 3,4-didehydro derivative. In vitro experiments performed on isolated eye cups also suggested that the ocular tissues could convert retinol to 3,4-didehydroretinol. In the eye, the specific activity of porphyropsin or all-trans 3,4-didehydroretinal (extracted by the denaturing solvent acetone) exceeded that of the all-trans 3,4-didehydroretinyl esters in storage. This suggests that the main ocular store of 3,4-didehydroretinyl esters does not constitute a precursor pool for porphyropsin synthesis.