Diseases Caused by Defects in the Visual Cycle: Retinoids as Potential Therapeutic Agents

Travis, Gabriel H.; Golczak, Marcin; Moise, Alexander R.; Palczewski, Krzysztof

doi:10.1146/annurev.pharmtox.47.120505.105225

Cited by 368 publications

(464 citation statements)

References 210 publications

(222 reference statements)

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“…Patients suffering from diseases affecting the visual cycle, such as Stargardt's dystrophy, Best disease, or Oguchi disease, should require extra care as they might suffer increased susceptibility to light damage, as was found in animal models. 7,32 Continued research on photochemical damage is relevant because many open questions remain, only some of them treated in this limited review. An action spectrum for freely moving animals exposed to continuous light for one or more natural days, thus in the 'Noell conditions', is still lacking, and the search for the photosensitizers underlying the Ham-type action spectrum is far from complete.…”

Section: Eyementioning

confidence: 99%

Light damage to the retina: an historical approach

Norren

Vos²

2015

Eye

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A brief review of retinal light damage is presented. Thermal damage requires a local rise in temperature of at least 10°C, causing an instant denaturation of proteins. The primary absorber is melanin. Photochemical damage occurs at body temperature and involves cellular damage by reactive forms of oxygen. The photosensitizers are photoproducts of the visual pigments. First indications that non-thermal damage might exist, in particular in the case of eclipse blindness, was presented by Vos in 1962. Attribution thereof to photochemical action was presented in 1966 by Noell et al who also measured the first action spectrum, in rat. It turned out to be identical to the absorption spectrum of rhodopsin. However, in 1976 and 1982 Ham et al found a quite different spectrum in monkeys, peaking at short wavelengths. The latter spectrum, but not the former, was confirmed since in numerous publications with animal models including rat. In ophthalmological practice a 'sunburn' was at first the only complaint caused by light damage. To avoid this, patients with dilated pupils should always be advised to wear sunglasses. Since the invention of the laser accidents have been reported, the most recent development is youth playfully pointing a strong laser pen in their eyes with marked consequences. The operation microscope and endoilluminators should always be used as brief as possible to avoid photochemical damage. Arguments for implant lenses that block not only the UV but also part of the visible spectrum seem too weak to justify extra costs.

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Section: Eyementioning

confidence: 99%

Light damage to the retina: an historical approach

Norren

Vos²

2015

Eye

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“…In Drosophila, defects in the generation of the chromophore cause profound reductions in opsin levels [71], while this is not the case in vertebrate rods and cones [72]. It has been suggested that the chromophore accelerates opsin maturation by facilitating deglycosylation and transport of the opsin [73,74].…”

Section: Maturation Of Rhodopsinmentioning

confidence: 99%

“…Vitamin A (all-trans retinol) is subsequently transported to the retinal pigment cells where it is converted to the chromophore through a process dependent on the PINTA retinoid-binding protein and the NINAG oxidoreductase. The chromophore is transported to the photoreceptor cells where it binds to the opsin resulting in the generation of rhodopsin pigment epithelium (RPE) [72], it appears that Drosophila retinal pigment cells are the closest functional equivalent to the RPE. The ninaG gene encodes an oxidoreductase, which is proposed to act in the conversion of (3R)-3hydroxyretinol to the 3S enantiomer in the compound eye [82,83].…”

Section: Maturation Of Rhodopsinmentioning

confidence: 99%

Phototransduction and retinal degeneration in Drosophila

Wang

Montell

2007

Pflugers Arch - Eur J Physiol

257

303

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Drosophila visual transduction is the fastest known G-protein-coupled signaling cascade and has therefore served as a genetically tractable animal model for characterizing rapid responses to sensory stimulation. Mutations in over 30 genes have been identified, which affect activation, adaptation, or termination of the photoresponse. Based on analyses of these genes, a model for phototransduction has emerged, which involves phosphoinoside signaling and culminates with opening of the TRP and TRPL cation channels. Many of the proteins that function in phototransduction are coupled to the PDZ containing scaffold protein INAD and form a supramolecular signaling complex, the signalplex. Arrestin, TRPL, and Gα q undergo dynamic light-dependent trafficking, and these movements function in long-term adaptation. Other proteins play important roles either in the formation or maturation of rhodopsin, or in regeneration of phosphatidylinositol 4,5-bisphosphate (PIP 2 ), which is required for the photoresponse. Mutation of nearly any gene that functions in the photoresponse results in retinal degeneration. The underlying bases of photoreceptor cell death are diverse and involve mechanisms such as excessive endocytosis of rhodopsin due to stable rhodopsin/arrestin complexes and abnormally low or high levels of Ca 2+ . Drosophila visual transduction appears to have particular relevance to the cascade in the intrinsically photosensitive retinal ganglion cells in mammals, as the photoresponse in these latter cells appears to operate through a remarkably similar mechanism.

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“…Disease is typically associated with the production of harmful gene products that promote pathology by inhibiting critical pathways resulting in cell death. [24][25][26] Strategies to prevent photoreceptor death during retinal degenerative disease such as gene replacement therapies or inhibition of cell death pathways have been undertaken with some success; [27][28][29] however, effective treatments for these blinding disorders are lacking.…”

mentioning

confidence: 99%

Autophagy supports survival and phototransduction protein levels in rod photoreceptors

et al. 2015

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Damage and loss of the postmitotic photoreceptors is a leading cause of blindness in many diseases of the eye. Although the mechanisms of photoreceptor death have been extensively studied, few studies have addressed mechanisms that help sustain these non-replicating neurons for the life of an organism. Autophagy is an intracellular pathway where cytoplasmic constituents are delivered to the lysosomal pathway for degradation. It is not only a major pathway activated in response to cellular stress, but is also important for cytoplasmic turnover and to supply the structural and energy needs of cells. We examined the importance of autophagy in photoreceptors by deleting the essential autophagy gene Atg5 specifically in rods. Loss of autophagy led to progressive degeneration of rod photoreceptors beginning at 8 weeks of age such that by 44 weeks few rods remained. Cone photoreceptor numbers were only slightly diminished following rod degeneration but their function was significantly decreased. Rod cell death was apoptotic but was not dependent on daily light exposure or accelerated by intense light. Although the light-regulated translocation of the phototransduction proteins arrestin and transducin were unaffected in rods lacking autophagy, Atg5-deficient rods accumulated transducin-α as they degenerated suggesting autophagy might regulate the level of this protein.This was confirmed when the light-induced decrease in transducin was abolished in Atg5-deficient rods and the inhibition of autophagy in retinal explants cultures prevented its degradation. These results demonstrate that basal autophagy is essential to the long-term health of rod photoreceptors and a critical process for maintaining optimal levels of the phototransduction protein transducin-α. As the lack of autophagy is associated with retinal degeneration and altered phototransduction protein degradation in the absence of harmful gene products, this process may be a viable therapeutic target where rod cell loss is the primary pathologic event. Autophagy is an intracellular pathway where cytoplasmic constituents are delivered to the lysosomes for degradation. Defective autophagy can contribute to the age-dependent accumulation of damaged proteins and organelles leading to altered cellular homeostasis and loss of function. [1][2][3][4][5] The metabolic roles of autophagy can be classified into two types, basal and induced. In nutrient-rich conditions, autophagy is suppressed but still occurs at low levels (basal autophagy); however, when cells are subjected to stress (starvation, injury, hypoxia), autophagy is activated immediately (induced autophagy). 6 Induced autophagy maintains the amino acid pool inside cells to adapt to starvation while constitutive autophagy has been shown to function as a cell-repair mechanism that is important for long-lived postmitotic cells. 7-11 Defects in autophagy have been associated with neurodegenerative diseases, 12-15 diabetes, 16,17 lysosomal storage disease 18 and the loss of vision. 19 In addition to macroautophagy, m...

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Diseases Caused by Defects in the Visual Cycle: Retinoids as Potential Therapeutic Agents

Cited by 368 publications

References 210 publications

Light damage to the retina: an historical approach

Light damage to the retina: an historical approach

Phototransduction and retinal degeneration in Drosophila

Autophagy supports survival and phototransduction protein levels in rod photoreceptors

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