Damage to the albino rat retina produced by low intensity light.

Abstract—Continuous exposure of albino rats to low intensity light causes progressive deterioration of the photoreceptor cells. Losses in ERG (b-wave) sensitivity which accompany this ‘light damage’ are directly related to lowered rhodopsin levels in the retina. The same relationship has been observed in light adaptation studies in which the retina is not damaged. Thus, it appears that the production of b-wave responses is not seriously altered when photoreceptor morphology is disrupted.     

Light-induced Damage in the Retina: Differential Effects of Dimethylthiourea on Photoreceptor Survival, Apoptosis and DNA Oxidation

In the rat, photoreceptor cell death from exposure to intense visible light can be prevented by prior treatment with antioxidants. In this study we subjected albino rats raised in dim cyclic light and rats made more susceptible to light damage by rearing in darkness to exposures of green light that led to similar losses of photoreceptor cells. Rhodopsin and photoreceptor DNA, indicators of the number of surviving photoreceptor cells, were determined at various times over a period of 14 days after light exposure. Fragmentation of DNA was determined over a similar time course by neutral and alkaline agarose gel electrophoresis. Apoptosis in retinal DNA was measured by quantitating the appearance of 180 base pair (bp) nucleosomal fragments. Oxidation of DNA was measured by electrochemical detection of the nucleoside 8-hydroxydeoxyguanosine (8-OHdG) after separation by high-performance chromatography. For albino rats reared in dim cyclic light, 24 h of intense light exposure resulted in the loss of 50% rhodopsin and photoreceptor cell DNA. In dark-reared rats, the losses were 40%, respectively, after only 3 h of intense light treatment. In both cases pretreatment with the antioxidant dimethylthiourea (DMTU) prevented rhodopsin and photoreceptor cell DNA loss. The kinetics of the light-induced apoptosis depended markedly on the rearing environment of the rats. The DNA ladders appeared within 12 h of the onset of intense light in the rats reared in dim cyclic light. In these rats the 180 bp fragment was at two-thirds of its maximum intensity immediately after 24 h of light exposure and reached the maximum 12 h later. Dimethylthiourea partially inhibited ladder formation in rats reared in dim cyclic light and delayed the time of appearance of the 180 bp maximum by 6 h. By contrast, in rats reared in darkness the 180 bp fragment was undetected immediately after 3 h of light exposure and reached its maximum 2 days later. Pretreatment with DMTU completely eliminated DNA ladders in these rats. Alkaline gel electrophoresis revealed a pattern of single-strand DNA breaks, with relatively high molecular weight fragments, 6 h after light exposure of dark-reared rats. Single-strand DNA breaks in cyclic light rats corresponded with the onset of apoptotic ladders, but peak values preceded by 12 h the peak of DNA ladder formation. The quantity of 8-OHdG in retinal DNA remained close to control values in all samples with the exception of a peak of twice the control value 18 h after light exposure in the dark-reared rats and a value 60% higher 16 days after exposure in cyclic light animals. Dimethylthiourea had no effect on the amount of oxidized purine in any of the samples. The differences between dark-reared rats and rats reared in dim cyclic light in the kinetics of DNA fragmentation and in their response to treatment with DMTU is consistent with previous observations of fundamental differences in retinal cell physiology in these animals. In dim light-reared rats, the pathway to apoptosis may be qualitatively different from the pathway to net photoreceptor loss in rats reared in darkness. The lack of effect of DMTU on 8-OHdG formation suggests that the oxidation of DNA bases is not a causal factor in light-mediated photoreceptor cell death.     

Changes in the Inner Retinal Cells after Intense and Constant Light Exposure in Sprague-Dawley Rats

Light insult causes photoreceptor death. Few studies reported that continuous exposure to light affects horizontal, Müller and ganglion cells. We aimed to see the effect of constant light exposure on bipolar and amacrine cells. Adult Sprague-Dawley rats were exposed to 300 or 3000 lux for 7 days in 12-h light: 12-h dark cycles (12L:12D). The latter group was then exposed to 24L:0D for 48 h to induce significant damage. The same animals were reverted to 300 lux and reared for 15 days in 12L:12D cycles. They were sacrificed on different days to find the degree of retinal recovery, if any, from light injury. Besides photoreceptor death, continuous light for 48 h resulted in downregulation of parvalbumin in amacrine cells and recoverin in cone bipolar cells (CBC). Rod bipolar cells (RBC) maintained an unaltered pattern of PKC-α expression. Upon reversal, there were increased expressions of parvalbumin in amacrine cells and recoverin in CBC, while RBC showed an increasing trend of PKC-α expression. The data show that damage in bipolar and amacrine cells after exposure to intense, continuous light can be ameliorated upon reversal to normal LD cycles to which the animals were initially acclimated to.     

Effects of environmental lighting and dietary vitamin A on the vulnerability of the retina to light damage.

Abstract—The damaging effect of visible light on photoreceptors and pigment epithelium has been studied mainly in the albino rat with continuous or intermittent exposures to green light for up to several days. Similar damage as in the albino rat but with different doses of light and different times of exposures were observed in pigmented rats, hamster strains, mouse strains and in the nocturnal monkey. The damage is graded histologically mainly by the size of the area of the retina over which the photoreceptors have died. The damage is quantitatively assessed by the measurement of ERG and DNA content of the retina. The action spectrum for the irreversible damage agress with the absorption curve for rhodopsin. Threshold damage occurs with diffuse light that reduces acutely the rhodopsin of the whole retina by about 10%. Damage is a function of body and eye temperature during exposure. At a body temperature of 42°, 2–4 h of exposure produces the same damage as exposure for 30 h at normal temperature using 1500 lux. The damage is also very markedly dependent upon the light history of the animal prior to exposure. Cyclic environmental light of I to 10 ft-cd for several days or weeks reduces very significantly the damaging effect compared to animals reared simultaneously in continuous darkness. Cyclic light rearing is associated with a reduction in opsin and rhodopsin of the whole retina, an increase in the molar phospholipid/opsin ratio and a reduction in the length of the outer segment. Protection is also produced by Vitamin A deficiency but significantly only when rhodopsin content is decreased by maintenance in very weak cyclic light. Thus Vitamin A deficiency and environmental light seem to use the same mechanism. Results do not support the possibility that damage is caused by a cytotoxic effect of retinol.     

Light induced and circadian effects on retinal photoreceptor cell crystallins

Crystallins in the retina may serve a chaperone-like protective function. In this study we measured mRNA levels for alpha-, beta- and gamma-crystallins in rat retinas following treatment with potentially damaging levels of light. We also determined crystallin protein patterns in photoreceptor cell rod outer segments (ROSs) isolated from rats exposed to intense light. Weanling albino rats were maintained in a dim cyclic light environment or in darkness for 40days. At P60 animals were treated with intense visible light, for as long as 8h, beginning at various times of the day or night. Retinas were excised immediately after light treatment and used for quantitative RT-PCR, or to prepare ROSs for western analysis. Some eyes were frozen in OCT for crystallin immunohistochemistry. Intense light exposure led to increases in mRNA expression for all retinal crystallins and to changes in ROS crystallin immunoreactivity. These light-induced changes were found to depend on the time of day that exposure started, duration of light treatment and previous light rearing history. We suggest that crystallin synthesis in retina exhibits a dependence on both light stress and circadian rhythm and that within photoreceptor cells crystallins appear to migrate in a light-independent, circadian fashion.     

Light‐Induced Retinal Degeneration Is Prevented by Zinc,a Component in the Age‐related Eye Disease Study Formulation†

Mineral supplements are often included in multivitamin preparations because of their beneficial effects on metabolism. In this study, we used an animal model of light‐induced retinal degeneration to test for photoreceptor cell protection by the essential trace element zinc. Rats were treated with various doses of zinc oxide and then exposed to intense visible light for as long as 8 h. Zinc treatment effectively prevented retinal light damage as determined by rhodopsin and retinal DNA recovery, histology and electrophoretic analysis of DNA damage and oxidized retinal proteins. Zinc oxide was particularly effective when given before light exposure and at doses two‐ to four‐fold higher than recommended by the age‐related eye disease study group. Treated rats exhibited higher serum and retinal pigment epithelial zinc levels and an altered retinal gene expression profile. Using an Ingenuity database, 512 genes with known functional annotations were found to be responsive to zinc supplementation, with 45% of these falling into a network related to cellular growth, proliferation, cell cycle and death. Although these data suggest an integrated and extensive regulatory response, zinc induced changes in gene expression also appear to enhance antioxidative capacity in retina and reduce oxidative damage arising from intense light exposure.     

Continuing damage to rat retinal DNA during darkness following light exposure

The damaging effects of visible light on the mammalian retina can be detected as functional, morphological or biochemical changes in the photoreceptor cells. Although previous studies have implicated short-lived reactive oxygen species in these processes, the termination of light exposure does not prevent continuing damage. To investigate the degenerative processes persisting during darkness following light treatment, rats were exposed to 24 h of intense visible light and the accumulation of DNA damage to restriction fragments containing opsin, insulin 1 or interleukin-6 genes was measured as single-strand breaks (ssb) on alkaline agarose gels. With longer dark treatments all three DNA fragments showed increasing DNA damage. Treatment of rats with the synthetic antioxidant dimethylthiourea prior to light exposure reduced the initial development of alkali-sensitive strand breaks and allowed significant repair of all three DNA fragments. The time course of double-strand DNA breaks was also examined in specific genes and repetitive DNA. Nucleosomal DNA laddering was evident immediately following the 24 h light treatment and increased during the subsequent dark period. The increase in the intensity of the DNA ladder pattern suggests a continuation of enzymatically mediated apoptotic processes triggered during light exposure. The protective effects of antioxidant suggests that the light-induced DNA degradative process includes both early oxidative reactions and enzymatic processes that continue after cessation of light exposure.     

Effect of visible light on normal and P23H-3 transgenic rat retinas: characterization of a novel retinoic acid derivative present in the P23H-3 retina

Transgenic rats with the P23H mutation in rhodopsin exhibit increased susceptibility to light damage, compared with normal animals. It is known that light-induced retinal damage requires repetitive bleaching of rhodopsin and that photoreceptor cell loss is by apoptosis; however, the underlying molecular mechanism(s) leading to photoreceptor cell death are still unknown. Photoproducts, such as all-trans retinal or other retinoid metabolites, released by the extensive bleaching of rhodopsin could lead to activation of degenerative processes, especially in animals genetically predisposed to retinal degenerations. Using wild-type and transgenic rats carrying the P23H opsin mutation, we evaluated the effects of acute intense visible light on retinoid content, type and distribution in ocular tissues. Rats were exposed to green light (480-590 nm) for 0, 5, 10, 30 and 120 min. Following light treatment, rats were sacrificed and neural retinas were dissected free of the retinal pigment epithelium. Retinoids were extracted from retinal tissues and then subjected to HPLC and mass spectral analysis. We found that the light exposure affected relative levels of retinoids in the neural retina and retinal pigment epithelium of wild-type and P23H rat eyes similarly. In the P23H rat retina but not the wild-type rat retina, we found a retinoic acid-like compound with an absorbance maximum of 357 nm and a mass of 304 daltons. Production of this retinoic acid-like compound in transgenic rats is influenced by the age of the animals and the duration of light exposure. It is possible that this unique retinoid may be involved in the process of light-induced retinal degeneration.     

Damage to rat retinal DNA induced in vivo by visible light

Intense visible light can damage retinal photoreceptor cells by photochemical or thermal processes, leading to cell death. The precise mechanism of light-induced damage is unknown; however, oxidative stress is thought to be involved, based on the protective effect of antioxidants on the light-exposed retina. To explore the in vivo effects of light on retinal DNA, rats were exposed to intense visible light for up to 24 h and the time courses of single-strand breaks in restriction fragments containing the opsin, insulin 1 and interleukin-6 genes were measured. All three gene fragments displayed increasing single-strand modifications with increasing light exposure. Treatment with the antioxidant dimethylthiourea prior to light exposure delayed the development of net damage. The time course of double-strand DNA damage was also examined in specific genes and in repetitive DNA. The appearance of discrete 140-200 base-pair DNA fragments after 20 h of light exposure implicated a nonrandom, possibly enzymatic damaging mechanism. The generation of nucleosome core-sized DNA fragments, in conjunction with single-strand breaks, suggests two phases of light-induced retinal damage, with random attack on DNA by activated oxygen species preceding enzymatic degradation.     

Enhanced ALA-induced fluorescence in hyperparathyroidism

INTRODUCTION: Intraoperative localization of parathyroid glands can be challenging especially in minimally invasive surgery. Fluorescence diagnosis using the photosensitizer aminolevulinic acid (ALA) has been described to identify normal parathyroid glands during experimental bilateral neck exploration. The present study evaluated fluorescence differences between hyperplastic and normal parathyroid glands as a precondition for a clinical application of the technique. MATERIALS AND METHODS: Polycystic kidney disease (PKD) rats with hyperparathyroidism due to hyperplastic parathyroid glands and Wistar rats with normal parathyroid glands were photosensitized by peritoneal lavage with ALA solution. After surgical exposure of thyroid and parathyroid glands the operative site was observed under blue light conditions using the d-light system to assess fluorescence characteristics of each tissue. Fluorescence intensities of parathyroid glands and surrounding thyroid tissue were measured by spectrometry. Parathyroid hormone in serum of the rats was determined by enzyme-linked immunosorbent assay (ELISA). RESULTS: Observation of the exposed thyroid site showed a subjectively stronger red fluorescence of the parathyroid glands in the PKD rats in comparison to the Wistar rats, whereas thyroid tissue appeared equally fluorescent. In the PKD animals, spectrometric fluorescence intensity was 10 times higher in the parathyroid glands than in the thyroid gland, whereas in the Wistar rats the ratio was 3.2:1. Fluorescence intensity in the parathyroid glands was more than twice in the PKD rats than in the Wistar rats, however slightly lower in the thyroid tissue. ELISA confirmed the pathophysiological change of a hyperparathyroidism with significantly increased serum levels of parathyroid hormone in the PKD rats. DISCUSSION: Hyperparathyroidism enhances ALA-induced fluorescence of the parathyroid glands. A combined surgical fluorescence strategy may justify a unilateral, minimally invasive approach in selected patients and serve to improve the capability of the surgeon to safely and efficiently manage parathyroid diseases.     

Investigation of the protecting envelopes of natural and synthetic emulsions

The fine structure of fatty globules in artificial emulsion, in crude human milk and in the cells of mammary glands of both virgin and nursing albino rats were studied. The envelopes of milk fatty globules have been shown to consist of a diffuse protein layer bordering upon fat followed by a trilaminar unit membrane. The envelope of the artificial fatty globule posseses only the diffuse protein layer. The spatial interrelationships of the envelopes of the milk fatty globules are discussed in relation to the mode of lactic fat formation inside the cells of the mammary gland.     

THE RECOVERY OF THE ALBINO RAT ELECTRORETINOGRAM AFTER PARTIAL LIGHT ADAPTATION

Abstract— The ERG obtained from albino rats was recorded every 90 sec after the eye was exposed to an adapting white light of known energy. The normalized a-wave regeneration curves for a constant test stimulus obtained from different rats, using different adapting light energies, were identical and superimposable, except that a delay between the time that the adapting light was turned off and the time that the a-wave appeared was observed for the high energy adapting light experiments. This delay increased as the adapting light energy increased.     

Evidence for a circadian rhythm of susceptibility to retinal light damage

This study investigated a possible circadian rhythm of light damage susceptibility in photoreceptors of both cyclic light-reared and dark-reared rats. A single exposure to intense green light was administered, beginning either in the early light period, the late light period or the dark period. In some animals exposed in the dark period, the synthetic antioxidant dimethylthiourea was administered before or after the onset of intense light exposure. Retinas were examined either immediately after exposure or after 2 weeks of recovery in darkness. Rod outer segment length and outer nuclear layer thickness measurements were used to assess light damage, along with qualitative analysis of swelling and disruption of the outer retinal layers. In all animals, retinal light damage was the most severe when intense light exposure began during the dark period. However, this severe damage was significantly reduced by pretreatment with the antioxidant. In a separate set of unexposed animals, fluctuations in plasma adrenocorticotropic hormone (ACTH) and corticosterone concentrations followed the same time course, regardless of the light regime during rearing. Our data support the notion of a circadian rhythm of light damage susceptibility that peaks in the dark period and yet can be modulated by the exogenous administration of an antioxidant.     

Neuroendocrine control of appetite and metabolism

Body homeostasis is predominantly controlled by hormones secreted by endocrine organs. The central nervous system contains several important endocrine structures, including the hypothalamic-pituitary axis. Conventionally, neurohormones released by the hypothalamus and the pituitary gland (hypophysis) have received much attention owing to the unique functions of the end hormones released by their target peripheral organs (e.g., glucocorticoids released by the adrenal glands). Recent advances in mouse genetics have revealed several important metabolic functions of hypothalamic neurohormone-expressing cells, many of which are not readily explained by the action of the corresponding classical downstream hormones. Notably, the newly identified functions are better explained by the action of conventional neurotransmitters (e.g., glutamate and GABA) that constitute a neuronal circuit. In this review, we discuss the regulation of appetite and metabolism by hypothalamic neurohormone-expressing cells, with a focus on the distinct contributions of neurohormones and neurotransmitters released by these neurons.Subject terms: Hypothalamus, Homeostasis     

EFFECTS OF DIETARY VITAMIN E AND SELENIUM ON LIGHT DAMAGE TO THE RAT RETINA*,†

Abstract—In this study we have investigated effects of dietary supplementation or deficiency in α-tocopherol (vitamin E) and selenium on acute light stress to albino rats. Selenium, which is an essential component of the enzyme glutathione peroxidase, and α-tocopherol are thought to be important in preventing in vivo lipid peroxidation. Before light stress, sections of paraffin embedded eyes show an intense yellow autofluorescent pigment localized in the retinal pigment epithelium (RPE) of the deficient rats which is barely visible in tissue sections from the supplemented rats. The fluorescent pigment is thought to be the result of damaging lipid peroxidation reactions. In addition the dcficient rats show increased electroretinogram (ERG) thresholds and decreased ERG-amplitudes compared to the supplemented rats. Acute 12 h light stress did not produce an increase in autofluorescent pigment in the RPE of the supplemented or deficient rats. The supplemented rats. however. showed marked light damage effects as measured by ERG-parameters. Contrary to our expectations, the deficient rats showed a lesser amount of light damage to the ERG than the supplemented rats. Our ERG results to date fail to implicate r-tocopherol levels or glutathione peroxidase activity as major factors in protecting the retina and pigment epithelium from damage after acute light stress.     

Visual functional effects of constant blue light in a retinal degenerate rat model

Retinal degenerative conditions increase susceptibility to light damage, but rapid retinal degeneration (RD) models show less susceptibility to cyclic dim light. We investigated whether constant blue light (BL) exposure can eliminate the residual visual responses in a comparatively rapid RD rat model. Pigmented rhodopsin mutant S334ter line-3 rat pups (21 days old) were exposed for 5-6 consecutive days to constant BL. Visual behavior was evaluated with an optokinetic head tracking apparatus. Electrophysiological recordings were made from the superior colliculus (SC). S-antigen, red-green opsin and rhodopsin immunoreactive residual photoreceptors were counted. Following BL exposure, head tracking was significantly reduced at 0.25 cycles degree(-1) in 38-day-old line 3 rats. With a 0.125 cycles degree(-1) stimulus, the head tracking performance of 80-day-old BL rats were similar to that of 220-day-old no-BL-treated line-3 rats. SC recordings also revealed a significant decrease in the residual photoreceptor activity. Histological evaluation showed reduction of the rod population in the central area of the light-damaged retina. Exposure to constant BL considerably reduces the residual visual responses in a rapid degenerating RD rat model.     

Chemistry and Biosynthesis of the Hypothalamic Releasing and Inhibiting Neurohormones

The hypothalamus secretes hormones which in turn affect the release of hormones from the anterior lobe of the pituitary gland. Evidence has so far been adduced for the existence of seven hypothalamic releasing hormones and three inhibiting hormones. These neurohormones are all oligopeptides and occur in only nanogram amounts in the hypothalamus. The study of synthetic analogs has provided valuable information regarding their mechanism of action.     

PHOTOCONTROL OF HYPOCOTYL ELONGATION IN DE-ETIOLATED Cucumis sativus L. A BLUE-LIGHT-INDUCED POST-ILLUMINATION BURST OF GROWTH

Abstract— A rapid transient increase in the growth rate of Cucumis sativus L. seedlings is found to occur after a transition from fluorescent white light to darkness. The post-illumination burst of growth starts after about 20 min of darkness and lasts for 30 to 50 min. The response occurs after long periods of continuous white light, in cycles of white light and darkness, whether the cotyledons are covered or exposed. The post-illumination burst is an expression of the loss of photocontrol of hypocotyl inhibition via the specific blue light photoreceptor because (a) its kinetics resemble those of recovery from blue-light inhibition, and (b) it only occurs on transition from a blue-rich to a blue-poor light environment.     

Genetic, age and light mediated effects on crystallin protein expression in the retina

To probe for possible relationships between retinal crystallins and retinal degenerations, protein expression was compared in normal Sprague-Dawley rats, treated or not with intense light, Royal College of Surgeons (RCS) rats and transgenic rats expressing rhodopsin mutations. Rats were reared in dim cyclic light for 21-75 days. Photoreceptor cell DNA levels were determined at various ages to assess the rates of visual cell loss. 1D- and 2D-gel electrophoresis was used to profile retinal protein expression. Crystallins were identified by western analysis and by tandem mass spectrometry. In normal rat retinas, alpha, beta and gamma crystallins were present, although alphaA- and gamma-crystallins exhibited some increase with age. As measured by DNA levels, the rate of genetically induced photoreceptor cell loss was greater in rats with faster degenerating retinas (RCS, S334-ter Line 4, P23H Line 3) than in rats with slower degenerating retinas (S334-ter Line 9, P23H Line 2). In genetic models of retinal degeneration increased levels of immunoreactivity for all crystallins, especially alphaA-insert, correlated with the different rates of photoreceptor loss. In the light induced degeneration model alphaA-insert was unchanged, truncated alphaB-crystallin levels were increased and gamma-crystallins were greatly reduced. In the RCS rat retina 16 different crystallins were identified. Our data suggests that an increase in crystallin expression occurs during various retinal degenerations and that the increases may be related to the severity, type and onset of retinal degeneration.     

Histopathological Changes in Liver and Heart Tissue Associated with Experimental Ultraviolet Radiation A and B Exposure on Wistar Albino Rats

This study aims to evaluate the influences of ultraviolet radiation A and B ( UVA + B) exposure on the liver and heart organs of albino rats. Female Wistar Albino rats, whose hair of the dorsal skin was shaved, were exposed to a combined UVA + B radiation for 2 h/day, for 4 weeks in order to be compared with the control group. Histopathological findings in vital organs (liver and heart) were evaluated. Tissues were fixed in 10% buffered formalin (pH = 7.2) and embedded in paraffin. The histopathological findings were examined on the H&E stained sections with light microscopy. The results show that the liver and the heart were injured in the UVA + B group. Liver tissue in the UVA + B group showed minimal vacuolation, enlargement of hepatocytes and bile duct proliferation, and the heart tissue showed hibernomas; uniform large cells resembling brown fat with coarsely granular to multivacuolated cytoplasm that is eosinophilic or pale with a small central nucleus. The number of hibernoma cases was significantly higher in the UVA + B group compared with the control group (P = 0.021). The control group showed normal liver and heart histology with normal adipose tissue in the pericardium. As a result, UVA + B exposure has toxic effects, especially on the liver and the heart of Wistar albino rats. UV radiation may cause such adverse effects in humans. Therefore, protection against the harmful effects of UV radiation is of significant importance for skin and organs.