Sensitivity of regenerating and degenerating planarian photoreceptors to osmium fixation

Summary The microvillous border of normal, developing and degenerating planarian retinal clubs was examined using osmium and glutaraldehyde fixation. Well-developed normal photoreceptors contained well preserved microvilli both after osmium and glutaraldehyde fixation. Osmium-fixed regenerating and degenerating retinal clubs showed serried vesicles and anastomosing tubules at the site of the microvillous border. After glutaraldehyde fixation, chains of vesicles were absent and the photoreceptor consisted of a regular array of microvilli. This difference indicates the selective sensitivity of the photoreceptor membranes in regenerating and degenerating retinal clubs to the action of osmium tetroxyde.     

Effects of continuous light and darkness on the eyes of the troglobitic salamander Typhlotriton spelaeus

Larval Typhlotriton spelaeus collected from five caves in Pulaski Co., Missouri, were kept as larvae or induced to transform in darkness or continuous fluorescent illumination. Larvae maintained in darkness for 215 and 279 days had smaller eyes, smaller rod inner and outer segments, and fewer metaphase figures in the genninative zone of the neural retina than comparable larvae maintained in light (258 lux). Except for visual cell size, differences were small and for each characteristic exceptions were observed. One larva kept in light showed early retinal degeneration comparable to that in transformed adults of T. spelaeus. All larvae exhibited optomotor behavior both before and after the experiment. Among animals induced to transform by L-thyroxin and maintained in darkness 111 to 366 days, visual cell and pigment epithelium degeneration was more extensive and more frequent than in animals kept for the same length of time in light (237-298 lux). In darkness the frequency of animals with retinal degeneration increased between 111 and 366 days. In light some animals exhibited pigment epithelium reduction with normal visual cells, and others had free, pigmented cells in the subretinal space. These effects were not comparable to degeneration in darkness. Eyelids covered the eyes of only a few animals in both light and dark treatments. The extent of eyelid encroachment over the eye was greater in darkness than in light. Most animals exhibited optomotor responses after experiments, but responses of animals kept in darkness were impaired in comparison to those of animals kept in light.     

The influence of functional alteration on monoamine oxidase and catechol-O-methyl transferase in the visual pathway of rats

—Rats were reared in complete darkness or under chronic stimulation with flashing light from birth to the age of 7 weeks. Light deprivation caused a significant increase in monoamine oxidase activity (measured with [¹⁴C]serotonin) of about 30 per cent in the structures of the visual pathway. Chronic stimulation with flashing light had no influence on the activity of monoamine oxidase in either visual or non-visual structures. The activity of catechol-O-methyl transferase in the brain areas of light-deprived rats was reduced, in light-stimulated rats it was slightly increased. In mother rats kept together with their litters in either complete darkness or flashing light for 5 weeks no change in monoamine oxidase activity was observed. The activity of catechol-O-methyl transferase in mother rats kept in darkness was significantly decreased in all brain regions studied; in light-stimulated animals the enzyme activity was not affected.     

Rhabdom breakdown in the eye of Cirolana borealis (Crustacea) caused by exposure to daylight

Summary The effect of daylight on the compound eye was investigated in the deep-water crustacean isopod Cirolana borealis Lilljeborg. The animals were captured and fixed at night (dark-exposed, i.e. not exposed to light) and day (daylight-exposed), respectively. Changes in light and darkness have an effect on the retinula cells; the ultrastructure of dark-exposed eyes is characterized by well-preserved organelles and cytoplasm. The photoreceptor membranes covering the microvilli are regularly aligned, and the outline of the villi is smooth. Electron-dense pigment granules are evenly distributed in the cytoplasm of the retinula cell outside the rhabdom. Daylight-exposed eyes differ from the dark-exposed eyes in the following aspects: (i) the microvilli are disrupted, (ii) retinula-cell pigment is found in the rhabdom, and (iii) the cytoplasm of retinula cells is vesiculated. These results are interpreted as retinal damage caused by excess exposure to light.     

Effect of optic chiasmotomy upon serotonin concentration in the pineal gland of the monkey

The concentration of serotonin within the pineal gland of the monkey exhibits a 24-hour rhythm, being higher during the hours of light and falling during the hours of darkness. Chiasmotomies were performed upon male cynomolgus monkeys (Macaca irus) to ascertain whether the intrapineal concentration of serotonin is dependent upon information passing from the eyes by means of nerve fibers that cross in the optic chiasma. After two weeks, the operated animals, whether killed in the light or the dark, showed a significant reduction in intrapineal serotonin compared with controls; however, the concentration of serotonin in operated animals killed during hours of light was comparable with that of control animals killed during the corresponding hours of darkness. The results indicate that the intrapineal concentration of serotonin is dependent upon information transmitted from the eyes by means of nerve fibers which cross in the optic chiasma; it is possible that these fibers are also components of the accessory optic tracts. It also is suggested that during hours of light, uncrossed fibers of retinal origin may participate in the regulation of the intrapineal serotonin concentration of this monkey.     

The ultrastructure of the sense organs of some turbellaria rhabdocoela. I. The eyes of Polycystis naegelii Kölliker (Eukalyptorhynchia Polycystididae)

Summary Each pigment-cup eye of Polycystis naegelii consists of two retinal clubs and a single pigmented cell. The latter is divided into two cavities by a septum. Under bright illumination the photoreceptor process appears as a disk containing membranous laminar whorls; under faint illumination the latter are replaced by numerous straight, closely packed, microvilli. This morphological variation is correlated with the intensity of the photoreceptor's exposure to light. The lenticular structures described by previous light microscopists have not been observed.This work was supported by a grant from the Italian National Research Council (C.N.R.)     

Light pulse effect on the locomotor activity rhythm of Talitrus saltator (Montagu) (Crustacea,Amphipoda)

The locomotor activity rhythm of the sandhopper Talitrus saltator (Amphipoda Talitridae) was investigated in Madfoun beach. The rhythm was monitored in individual and group animals during 21 days at constant temperature. During the first two weeks, animals were kept under light–dark cycle (d1–d7) and constant darkness (d8–d14). Light pulses of 2 h were applied, at the end of the experimental night, during the first 3 days of the third week (d15–d18). Then, constant darkness was restored for the rest of the experiment (d19–d21). Results revealed that Talitrus saltator individuals as well as groups concentrated their activities in experimental night under light–dark cycle and in the presence of pulses; whereas, a clear drift of activity is observed under constant darkness. Periodogram analysis showed the presence of circadian component whatever the recording type. An ultradian period was revealed in individual recording whatever the regimen, while for groups, this component appeared only under nLD cycle. Furthermore, the locomotor rhythm is more defined under nLD cycle for individuals and in constant darkness for groups.     

Metabolic changes in the isolated rat jejunum exposed to continuous light or darkness]

Rats were kept for about seven weeks in continuous light or darkness. The oxygen consumption and glucose consumption by the isolated small intestine were determined. Data were compared to those of control animals kept under a light-dark cycle. Continuous exposure to light resulted in a 21% increase in anaerobic glycolysis. Continuous exposure to darkness increased anaerobic glycolysis by 18 and 12% respectively.     

Disruption of insect photoreceptor membrane by divalent ions: Dissimilar sensitivity of light- and dark-adapted mosquito rhabdomeres

Summary The conditions that lead to the formation of myelin figures in rhabdomere microvilli were studied in the larval ocelli of the mosquito Aedes aegypti. These artifacts can result from the addition of divalent ions, such as Ca²⁺, to primary-aldehyde fixatives, but they form subsequently during postfixation with OsO₄. In light-adapted ocelli, myelin figures are concentrated at the proximal ends of the microvilli along the cytoplasmic margin of the rhabdomere. The severity of the artifact is proportional to the ion concentration: scattered myelin whorls are induced by Ca²⁺ concentrations as low as 5 mM; they become abundant at 15 mM to 25 mM, and displace much of the rhabdomere margin at 50 mM. In contrast, even at high concentrations of Ca²⁺ few membrane whorls form in dark-adapted rhabdomeres, and these are mostly located at the distal ends of the microvilli. The differential response of the rhabdomere microvilli in light and darkness does not result from a direct action of light during fixation; it reflects an underlying difference between light- and dark-adapted photoreceptor membranes. We suggest that this differential sensitivity to divalent ions is associated with the shedding of membranes from the rhabdomere, a process that is enhanced by light and reduced in darkness.This work was supported by a grant (BNS 76-18623) from the National Science Foundation     

THE LABELLING OF THE GANGLIOSIDIC FRACTION FROM BRAINS OF RATS EXPOSED TO DIFFERENT LEVELS OF STIMULATION AFTER INJECTION OF [6-3H]-GLUCOSAMINE

[6-³H] Glucosamine was injected into rats and then they were submitted for 1 h to light (about 1100 lux) and sound, while their controls were kept in darkness. Two series of experiments were done: in one, the animals received the injection intracerebrally; in the other, the injection was intraperitoneal. In both series the ratios of specific radioactivities (c.p.m./μmol of NANA) in mitochondria1 gangliosidic fractions to those in synaptosomal gangliosidic fractions were higher for rats exposed to illumination and sound ?+ 74 per cent, P < 0·01 and + 49 per cent, P < 0·001 (in respectively, experiments with intracerebral and intraperitoneal injections) than for animals kept in dark. For animals iqjected intraperitoneally the specific radioactivity of the mitochondria1 gangliosidic fraction from rats exposed to light was higher (+ 11 per cent, P < 0.05) than that obtained from animals kept in dark. For synaptosomes the specific radioactivity of the gangliosidic fraction obtained from animals exposed to light was lower (?15 per cent, P < 0.01) than that obtained from animals kept in dark. In animals kept under the experimental conditions already described for more than 1 h the differences tended to disappear. No differences were observed between the two groups of rats in the amounts of radioactivity found in the brain.     

Human Retinal Light Sensitivity and Melatonin Rhythms Following Four Days in Near Darkness

The rods in the retina are responsible for night vision, whereas the cone system enables day vision. We studied whether rod function in humans exhibits an endogenous circadian rhythm and if changes occur in conditions of prolonged darkness. Seven healthy subjects (mean age±SD: 25.6±12.3 yr) completed a 4.5‐day protocol during which they were kept in complete darkness (days 1 and 4) and near darkness (<0.1 lux red light, days 2 and 3). Electroretinography (ERG) and saliva collections were done at intervals of at least 3 h for 27 h on days 1 and 4. Full‐field ERGs were recorded over 10 low‐intensity green light flashes known to test predominantly rod function. As a circadian marker, salivary melatonin concentration was measured by radioimmunoassay. The ERG data showed that rod responsiveness to light progressively diminished in darkness (significantly lower a‐ and b‐wave amplitudes, longer b‐wave implicit time). The decrease in amplitude (b‐wave) from day 1 to day 4 averaged 22±14%. After correction for the darkness‐related linear trend, the circadian variations in ERG indices were weak and usually non‐significant, with slightly higher responsiveness to light during the day than night. Rod sensitivity (by K index) tended to decrease. Strikingly, the overall amount of melatonin secretion (area under 24 h curve) also decreased from day 1 to day 4 by 33.1±18.9% (p=.017). The drift of the melatonin rhythm phase was within the normal range, less than 56 min over three days. There was no significant correlation between the changes in ERG responses and melatonin. In conclusion, scotopic retinal response to (low‐intensity) light and the amount of melatonin secreted are diminished when humans are kept in continuous darkness. Both processes may have a common underlying mechanism implicating a variety of neurochemicals known to be involved in the regulation of both photoreceptor and pineal gland function.     

Effects of light and dark on photoreceptors in the polychaete annelid Nereis limnicola

Summary The effects of light and dark on photoreceptors of the brackish-water polychaete annelid Nereis Hmnicola were studied by electron microscopy. Animals dark-adapted for one or two days exhibited well-formed straight microvilli (rhabdomeres) on the sensory cell processes. Continuous illumination of worms for one or two days caused extensive breakdown of the microvilli into vesicles and debris. Thirty minutes to three h of exposure of dark-adapted animals to light produced increasing severity of degradation of photoreceptoral microvilli. Light-adapted worms placed in darkness for one-half to three h showed progressive restoration of the microvilli to the dark-adapted condition. The products of degradation were internalized by both sensory and pigmented supportive cells by phagocytosis and pinocytosis.     

Endogenous patterns of photomechanical movements in teleosts and their relation to activity rhythms

Summary The retinal rods, cones and epithelial pigment of most lower vertebrates display rhythmic photomechanical (retinomotor) migrations in response to changes in ambient lighting conditions. This study examines the extent of these migrations in the absence of the daily changes in illumination (constant darkness and constant light) in three species of teleosts. Salmo trutta, a crepuscularly active fish, showed two peaks of light adaptation occurring around dawn and dusk when kept in constant darkness. Tinca tinca, a nocturnal species, also showed an endogenous rhythm during extended periods of darkness, but, unlike Salmo trutta, it was light-adapted throughout what would normally have been day. At the maximal extent of migration under conditions of continual darkness, the pigment migrated 59% as much as it did during a normal light/dark cycle. Nannacara anomala, a tropical diurnally active species, showed a similar but more pronounced rhythm than Tinea tinea for all 3 days of experimental darkness, behaving essentially identically to fish exposed to a light/dark cycle. Nannacara anomala also displayed a weak rhythm when kept in constant light.It is concluded from these and previous results that the pattern of endogenous photomechanical movement depends both on the activity pattern of a species and on the constancy of the lighting conditions to which it has been exposed during its lifetime.     

Rhabdom size and photoreceptor membrane turnover in a muscoid fly

Summary The cross-sectional area of rhabdomeres in the compound eye of the blowfly, Lucilia, was found to remain constant under 12 h light/12 h dark cyclic lighting, and 10 days constant light or darkness. It was reduced only slightly during 3 h light after 10 days darkness (by 21%), or on exposure to 2h darkness + 1.5 h light after 10 days light (by 10%). Morphological evidence indicates that shedding of photoreceptor membrane during turnover is achieved by an extracellular route, and by pinocytosis from the bases of the microvilli. The photoreceptor membrane shed by both mechanisms appears to accumulate in multivesicular bodies. The amount of photoreceptor membrane shedding, as indicated by numbers of multivesicular bodies, is constant throughout the day and night on cyclic lighting, decreases in constant darkness, but returns to its normal level after an exposure to 3 h light subsequent to 10 days darkness.     

Changes in behaviour and eye-morphology of BoreomysisMegalops G.O. Sars (Crustacea : Mysidacea) following exposure to short periods of artificial and natural daylight

Boreomysis megalops G.O. Sars were collected from 240 m depth using a protective cod-end, which shielded the eyes from light exposure. Animals were divided into groups which were exposed to darkness (DE) or to natural or artificial daylight (LE) for periods of 1–15 min or 4 h. Some animals were thereafter kept in aquaria under simulated habitat light conditions (light/dark cycles). The animals were observed in infra-red (IR) light. DE animals showed a vertical zonation behaviour in the laboratory similar to that obtained from sledge data: i.e. the animals stayed close to the bottom during daytime (light) and spread out vertically at night (darkness).LE individuals showed putative pathological changes both in zonation behaviour in the laboratory and in eye-morphology. The photoreceptor membranes of the six main retinula cells were damaged. The seventh cell was unaffected by light exposures. A correlation was found between the extent of damage to the eye and the degree of modification of vertical zonation behaviour. The groups exposed to the least light showed the smallest changes in zonation behaviour and eye-morphology. The light induced changes were not reversed even after 4 days in the aquarium under simulated habitat light conditions. In conclusion, deep living animals with well-developed and very light sensitive eyes should be protected from daylight during sampling and handling. IR light should be used for observation purposes.     

Changes in retinal fine structure induced in the crab Libinia by light and dark adaptation

Summary The cytological influence of light and dark adaptation (LA and DA) on the retinular cells of the spider crab Libinia emarginata has been studied by light and electron microscopy in four adaptive states: 17 hours darkness, 5 hours darkness, 5 hours diffuse light and 17 hours diffuse light. The rhabdom's fine structure is typical of decapods but its dual overall form and position mingle certain features of both apposition and superposition compound eye types. Distal and proximal retinal pigments both showed adaptive migration, but the distal pigment cells moved over a restricted range, and DA separated the retinular cell pigment granules into two groups, perinuclear and basilar.In the rhabdom no changes in its position, dimensions or microvillus fine structure were observed with LA or DA. But at the base of the rhabdom microvilli the rate of pinocytosis was strongly affected by the eye's adaptive state, being lowest after 17 hours DA and greatest after 17 hours LA; the wall of the 0.1 microvesicles so formed, looked like the membrane of the rhabdom microvillus and they were the same size as the vesicles in multivesicular bodies and in vesicular lamellar bodies.Three categories of complex cytoplasmic particles about 1 in diameter (multivesicular bodies, vesicular lamellar bodies and purely lamellar bodies) were all increased in number by decreased DA and by increased LA; similar quantitative effects occurred in the endoplasmic reticulum and in the ribosomes.The pinocytotic vesicles and the complex cytoplasmic bodies may represent part of an intracellular system to dispose of rhabdom metabolites whose production was initiated or increased by light absorption.Cytoplasmic and perirhabdomal vacuoles mainly distal in location, were also affected by light, but inversely; their maximal extent occurred after 17 hours DA; less DA or any LA significantly decreased their presence and aggregation.The data reported are of interest not only because they correlate retinal fine structure with the metabolism of vision but also because they provide a new and specific tool for distinguishing active from inactive neurosensory cells in the optic pathway.This research was initiated with the aid of U.S. Public Health Service Grant NB-03076 and has been continued with the support of U.S. Air Force Grant AFOSR-1064. The authors wish to thank Dr. Joseph G. Gall and Dr. William R. Adams for generously sharing their electron microscopic facilities; they are also grateful to Mrs. Mabelita Campbell for her collaboration on the light microscopy.     

Influence of light and darkness on the ultrastructure of the pineal organ in the blind cave fish,Astyanax mexicanus

Ultrastructural changes of the pineal organ were investigated in the blind cave fish, Astyanax mexicanus, kept under continous artificial light (5000 lux), in continuous darkness, and under natural light conditions. The pineal end-vesicle of the fish kept under natural photoperiod consisted of photoreceptor cells and supporting cells mixed with a few ganglion cells. The photoreceptor cells possessed well-developed outer segments with regularly arranged lamellar membranes. The supporting cells contained a number of lipid droplets and large globular cisternae filled with fine granules. In the fish kept under continuous light or in darkness, the pineal end-vesicle displayed a dilated lumen, and the outer segments of the receptors showed signs of degeneration. Furthermore, alterations of cell organelles were observed in the photoreceptor and supporting cells.     

Fatty acid composition and ultrastructure of photoreceptive membranes in the crayfish Procambarus clarkii under conditions of thermal and photic stress

The ultrastructural state of the crayfish visual membrane is correlated with its fatty acid composition during times of photic and thermal stress and the period over which the dynamic events occur is investigated. Crayfish kept at 4 °C under constant darkness contain in their rhabdoms significantly increased amounts of unsaturated fatty acids such as 16:1, 18:1, 20:5, and 22:6 compared with individuals kept at 25 °C. The ratio of unsaturated/saturated fatty acids (UFA/SFA-ratio) amounts to 2.17 in the cold-water- and 1.46 in the warm water-acclimated animals. The visual membranes of crayfish suddenly transferred from 4 °C to 25 °C exhibited ultrastructural modifications such as membrane collapse and disappearance of microvillar dense␣core-filaments most clearly 3 h post-transfer. Parallel to the structural changes a significant increase in fatty acid 18:0 was observed, while the amounts of 16:1 and 20:1 decreased. When 4 °C, dark-adapted crayfish were exposed to light alone and not a temperature increase, only fatty acid 22:6 showed a significant reduction to 10% of its pre-experimental level within 2 h of exposure. Thereafter, it slowly increased again. In cold water-acclimated crayfish that had been exposed to light of 5000 lx for 3␣weeks no significant change of the UFA/SFA ratio was observed, although fatty acid species 18:0, 20:4, and 20:5 had increased at the expense of fatty acids 14:0, 16:0, 16:1, 18:1, 20:1, and 22:6. The total amount of fatty acids, however, had become significantly smaller (from 0.058 ng g⁻¹ body weight in the dark-adapted to 0.048 ng g⁻¹ in the light-adapted crayfish). Morphologically the rhabdom volume had decreased by approx. 20%, but ultrastructurally rhabdom microvilli remained almost unchanged. The amount of peroxidized lipids in the retina following irradiation with bright white light in the cold-adapted crayfish fell during the first 2 h of exposure from 0.4 nmol g⁻¹ to 0.32 nmol g⁻¹, but after 12 h of exposure had reached a level of 0.48 nmol g⁻¹. Greatest structural abnormalities to the visual membranes occurred when dark-adapted, cold-acclimated crayfish were suddenly subjected to bright light and an increase in water temperature. Under such conditions the microvillar arrangement was disrupted and membrane collapse and disappearance of core-filaments were apparent. Our results provide evidence that the fatty acid composition of the membranes determines to a considerable extent the structural integrity of the photoreceptor, but that it is too simplistic a model to think that peroxidation of membrane lipids alone is responsible for the disintegration of the photoreceptive membranes in the crayfish eye following exposure to bright light. Accepted: 4 July 1996     

Acute Behavioral Responses to Light and Darkness in Nocturnal Mus musculus and Diurnal Arvicanthis niloticus

The term masking refers to immediate responses to stimuli that override the influence of the circadian timekeeping system on behavior and physiology. Masking by light and darkness plays an important role in shaping an organism's daily pattern of activity. Nocturnal animals generally become more active in response to darkness (positive masking) and less active in response to light (negative masking), and diurnal animals generally have opposite patterns of response. These responses can vary as a function of light intensity as well as time of day. Few studies have directly compared masking in diurnal and nocturnal species, and none have compared rhythms in masking behavior of diurnal and nocturnal species. Here, we assessed masking in nocturnal mice (Mus musculus) and diurnal grass rats (Arvicanthis niloticus). In the first experiment, animals were housed in a 12:12 light-dark (LD) cycle, with dark or light pulses presented at 6 Zeitgeber times (ZTs; with ZT0 = lights on). Light pulses during the dark phase produced negative masking in nocturnal mice but only at ZT14, whereas light pulses resulted in positive masking in diurnal grass rats across the dark phase. In both species, dark pulses had no effect on behavior. In the 2nd experiment, animals were kept in constant darkness or constant light and were presented with light or dark pulses, respectively, at 6 circadian times (CTs). CT0 corresponded to ZT0 of the preceding LD cycle. Rhythms in masking responses to light differed between species; responses were evident at all CTs in grass rats but only at CT14 in mice. Responses to darkness were observed only in mice, in which there was a significant increase in activity at CT 22. In the 3rd experiment, animals were kept on a 3.5:3.5-h LD cycle. Surprisingly, masking was evident only in grass rats. In mice, levels of activity during the light and dark phases of the 7-h cycle did not differ, even though the same animals had responded to discrete photic stimuli in the first 2 experiments. The results of the 3 experiments are discussed in terms of their methodological implications and for the insight they offer into the mechanisms and evolution of diurnality.