Retinal degenerations in the dog II. Development of the retina in rod-cone dysplasia

The kinetics of rod outer segment production and turnover were studied in Irish setter dogs with a recessively inherited photoreceptor degeneration (rod-cone dysplasia). Affected and littermate control (heterozygote) dogs, 16–50 days of age, were injected intravitreally with [³H]leucine after electroretinographic studies. Normal age-matched mongrel dogs were also used as controls. Between 6 hr and 8 days following intravitreal injection, eyes were removed and processed for microscopic and radioautographic studies.In affected dogs, the rod components of the electroretinogram were not recordable. Cone components were recordable but failed to develop normally. Morphologically, rod inner segments were diminutive and the outer segments short and contained disorganized and disoriented disc material. Cone inner segments became broad and club-shaped. Radio-autography showed label accumulation within inner segments, but only sporadic and randomly distributed label in the narrow outer segment layer. These results suggest that in Irish setters with rod-cone dysplasia, there is a defect in the morphogenesis of the rod outer segments during postnatal retinal differentiation.     

Retinal degenerations in the dog. I. Rod dysplasia

Rod dysplasia is a recessively inherited photoreceptor disease affecting the Norwegian elkhound breed. Rod photoreceptors fail to develop normally; the inner segments are diminutive and the outer segments disorganized and disoriented. This developmental failure is associated with complete absence of electroretinographically recordable rod mediated responses. Cones develop and function normally. Cones are selectively spared in the disease process and degeneration begins only after there is extensive damage to the rod photoreceptors. In the end stages of the disease, the electroretinogram is not recordable and the photoreceptor layer is absent. Gliosis, loss of retinal layer organization and occasional intraretinal pigment epithelial migration are characteristic of the late stage of the disease.     

Autosomal dominant rod-cone dysplasia in the Rdy cat. 1. Light and electron microscopic findings

Detailed morphological analyses, including retinal layer thickness studies, were performed on heterozygous affected cats with autosomal dominant rod-cone dysplasia (gene symbol Rdy). Abnormalities were evident in retinas from the earliest age examined (2 weeks). Both rod and cone photoreceptors were affected equally by the dystrophy which was characterized by retarded and abnormal development of the visual cells. Photoreceptor inner segments remained rudimentary and outer segments did not elongate normally. Outer segment material was sparse and consisted mostly of whorls of disorganized and disoriented disc lamellae. Photoreceptor cell synaptic terminals showed delayed and incomplete synaptogenesis. Degenerative changes were first observed at 4.5 weeks of age and were characterized by the appearance of pyknotic nuclei in the outer nuclear layer and displacement of photoreceptor cells into the subretinal space. Degeneration began in central retinal regions and proceeded towards the periphery, resulting in progressive loss of the photoreceptor cell layers. By 30 weeks of age only two to five rows of nuclei remained in the outer nuclear layer. Area centralis degenerative lesions in advanced affected eyes were characterized by focal absence of the retinal pigment epithelium and choriocapillaris and thinning of the underlying tapetum. Retinal autoradiography showed that in normal kittens aged between 4.5 and 11 weeks of age rod outer segment renewal rates varied between 2.49 and 2.79 microns per 24 hr. The failure to form a labelled band in retinal autoradiograms from Rdy-affected kittens most probably indicates defective rod disc morphogenesis. It appears that the genetic defect in Rdy cats permits retarded development of the photoreceptor cells, but becomes lethal when these cells begin functional differentiation.     

Progressive retinal atrophy in the Abyssinian cat. Electron microscopy

Seven adult Abyssinian cats at different stages of a recessively inherited retinal degenerative disease (progressive retinal atrophy) were studied ultrastructurally. At the stage of early disease, in 2-yr-old cats, disorganized and vesiculated discs were found in less than half of the rod outer segments in the periphery, while similar changes were seen in the central retina only infrequently or in patches. Cones appeared normal in all areas of the retina at the early stage. With progression of disease, the lesions were more advanced in all areas of the retina, and involved both rods and cones, with the most severe alterations found in the midperiphery. At the advanced stage, in a 6-yr-old cat, both rods and cones were lost, the inner nuclear layer thus being separated from the pigment epithelium by Müller cell processes and a few remaining outer plexiform processes only. Remnants of photoreceptor outer and inner segments, macrophages, and what appeared to be displaced photoreceptor cell nuclei could be found occasionally in the subretinal space, however. Clumps of pigment granules were often observed in the photoreceptor layer in the non-tapetal fundus. The pigment epithelium remained morphologically intact as a single layer of uninterrupted cells throughout the disease process, as did tapetal cells and choriocapillaris. There was no difference in the severity of disease between the peripheral tapetal and non-tapetal fundus. In the inner retina, only minor alterations were observed. These changes appeared at a later time than photoreceptor degeneration, and were considered secondary to the latter.     

Ultrastructure of remnant photoreceptors in advanced hereditary retinal degeneration

The outer layers of the retinas of pigmented rats affected with hereditary retinal degeneration (rdy) were studied at an advanced stage in the degenerative process, ie, in 200 day old animals. At this age, most of the photoreceptors that survived the degenerative process were cones. The chromatin pattern of their nuclei clearly differentiated them from rods, displaced pigment cells and/or presumptive macrophages that also were found in the outer nuclear layer. None of the cones encountered had outer segments although structures resembling outer segment discs were found with a single cilium. Cones that had inner segments were found in regions of the retina that contained large accumulations of cellular debris. Cones that had lost both inner or outer segments, on the other hand, were found in regions that contained less debris. In such cells, the perikaryon of the cone was rich in mitochondria and other organelles; and the cilium arose directly from the cell body. The morphology of the cones and the fact that they were found in regions of the retina that contained different amounts of cellular debris suggested that cones with inner segments were in an early stage of degeneration while those that had lost inner segments were in a later stage of degeneration. All the cones encountered contained a variety of organelles including: free ribosomes, rough endoplasmic reticulum, and the Golgi apparatus. The cones that survived retinal degeneration therefore appeared to retain the cellular organelles needed for the production of photosensitive pigments. As a consequence, they may be capable of photoreceptor functions.     

Photic history modifies susceptibility to retinal damage in albino trout

Albino vertebrates exposed to intense light typically lose photoreceptors via apoptosis, and thus serve as useful models of retinal degeneration. In contrast, albino rainbow trout exposed to intense light maintain populations of rod and cone nuclei despite substantial damage to rod outer segments (ROS). The aim of this study was to differentiate between two hypotheses that could account for this divergent result: (1) trout rod nuclei remain intact during light damage, or (2) rod nuclei die but are replaced by cell proliferation. A further aim was to examine whether photic history modulates retinal damage, as in rodents. Albino and normally pigmented trout were moved from defined photic regimes into full daylight, while some were not moved to serve as protected controls. ROS were always maintained in pigmented fish and in albinos protected from full daylight. In albinos exposed to full daylight, ROS were removed over most of the central retina, whereas rod nuclei were maintained in the outer nuclear layer over 10 days. Pyknotic and TUNEL-labeled rod nuclei were abundant in affected albinos at all time-points tested. Rod death occurred without a decrease in the number of rod nuclei, confirming that proliferation must be replacing cells. Indeed a transient increase in proliferation was observed in retinal progenitors of albinos receiving 5 days of damaging light. This proliferative response was decreased with further damage. Cones remained intact even in areas where rod nuclei had degenerated. Pretreatment with light of moderate versus low intensity light affected the cell death and proliferative responses, and the ectopic localization of rod opsin. We conclude that apoptotic demise of rods, but not cones, occurred during light damage in retinas of albino trout and proliferative responses have a limited a capacity to replace lost rods.     

Retinal degenerations in the dog: IV. Early retinal degeneration (erd) in Norwegian elkhounds

A new early onset hereditary retinal degeneration is characterized in Norwegian elkhound dogs. This disease, termed early retinal degeneration (erd), was studied in 10 affected dogs, from 30 days- to 7 years old, clinically, by electroretinography, and by light- and electron-microscopic morphology. Control studies were performed on 49 non-affected dogs. Affected dogs are initially nightblind, and become totally blind between 12- and 18 months of age. The postnatal development of their rod and cone photoreceptors is abnormal both structurally and functionally. Morphologically, rod and cone inner- and outer-segment growth occurs but appears uncoordinated. Adjacent rods become very disparate in the size and proportions of their inner- and outer segments. Prominent villiform processes extend from the inner segments of rods and, to a lesser extent, cones. Synaptic terminals of rods and cones fail to develop properly. The b-wave of the electroretinogram fails to develop and the electroretinogram (ERG) remains a-wave-dominated. Subsequent to these abnormalities of development, the rods and cones degenerate, rapidly at first and later more gradually. In normal dogs, development of the ERG a- and b-waves is shown to follow, respectively, morphologic development of the photoreceptor outer segments and synaptic terminals. Similarly the abnormal development and subsequent degeneration of photoreceptor outer segments and synaptic terminals in affected dogs, correspond in time course to development and degeneration of the ERG a- and b-waves.     

The ageing photoreceptor

With age many retinal neurons are lost. In humans the rod photoreceptor population in the perimacular region is subject to approximately 30% loss over life. Those that remain have been reported to suffer from extensive convolutions and localized swellings of their outer segments abnormally increasing their disc content and outer segment length. Here we examine quantitatively age-related changes in rat rod photoreceptors. The rat retina is approximately 97% rod dominated. Here, aged rods showed significant reductions in outer segment length. The discs in their outer segments had a similar density, irrespective of whether they were young or old, however, in aged animals a higher proportion were misregistered. Surprisingly, in all of the tissue examined, we found no evidence for any convolution of outer segments or localized swelling as reported in humans, rather all remained straight. There are methodological differences between the research reported here and that undertaken on human retinae. There are also major differences in overall retinal architecture between humans and rodents that could contribute to differences in the aging process of individual cells. If it is the case that individual photoreceptors age differently in rodents compared to humans, it may pose significant problems for the use of this animal model in studies of ageing and age related outer retinal disease.     

快速退变性视网膜变性感光细胞超微结构变化分析

目的 了解快速退变性遗传性视网膜变性的感光细胞在出生后早期发生的形态学变化,为临床治疗提供依据.方法 取出生后不同时间的rd小鼠及正常对照小鼠各6只的视网膜,经光镜、扫描电镜和透射电镜观察感光细胞的形态发生发育和结构变化过程,比较二者的动态变化和形态学差异.结果 rd鼠生后1周开始出现感光细胞节段变短,内节段内线粒体变性改变多见;偶见感光细胞核旁胞浆内出现肿胀变形的线粒体.2周时节段层变薄,内节段结构已不完整,外节膜盘少见,变形且排列不整齐;外核层细胞层数明显减少,可见核固缩及染色质凝聚,偶见外丛状层部分神经突起内出现变性的线粒体.3周时节段层近消失,外核层只剩一层细胞,胞浆内可见髓样结构;外丛状层变薄.4周时内节段高度变形,视网膜色素上皮层与外核层之间出现大量不成形结构.外核层仅残存少许胞体,胞浆内出现多量不成形结构.外丛状层极薄,部分区域已消失.结论 rd鼠在出生后早期就发生感光细胞的变性改变,细胞内线粒体改变明显.其感光细胞变性发生早,进展快,呈快速退变特点.     

Pathogenesis of progressive rod-cone degeneration in miniature poodles

Visual cell pathologic changes and outer segment renewal were investigated in miniature poodles with progressive rod-cone degeneration. Early in this disease, visual cells in the posterior pole and equatorial regions show outer segment lamellar disorientation and vesicular profiles. Visual cells are normal in the periphery. Outer segment renewal determined after intravitreal injection of 3H-leucine was abnormally slower in affected animals than in controls. This renewal abnormality was similar in structurally normal and diseased photoreceptors, suggesting that the renewal defect is the earliest recognizable abnormality in the disease. The pigment epithelium was normal; the presence and density of pigment did not appear to affect the extent and severity of the disease or modify the abnormal renewal rate. As the disease progressed, photoreceptor outer segments were lost, and the remaining diminutive photoreceptors accumulated label in the inner segment and perinuclear zones. Sodium dodecyl sulfate gel electrophoresis of crude rod outer segment preparations showed no differences in opsin synthesis between normal and affected retinas early in the disease, but opsin synthesis decreased in the late stage of the disease.     

A frameshift mutation in RPGR exon ORF15 causes photoreceptor degeneration and inner retina remodeling in a model of X-linked retinitis pigmentosa

PURPOSE: To characterize the course of retinal disease in X-linked progressive retinal atrophy 2 (XLPRA2), a canine model of early onset X-linked retinitis pigmentosa (XLRP) caused by a two-nucleotide microdeletion in RPGR ORF15. METHODS: The retinas of 25 XLPRA2-affected dogs (age range, 2-40.6 weeks) and age-matched control subjects were collected, fixed, and embedded in epoxy resin for morphologic evaluation or in optimal cutting temperature (OCT) medium for TUNEL assay and immunohistochemistry. Cell-specific antibodies were used to examine changes in rods and cones and to evaluate the effects of the primary photoreceptor degeneration on inner retinal cells. RESULTS: Abnormal development of photoreceptors was recognizable as early as 3.9 weeks of age. Outer segment (OS) misalignment was followed by their disorganization and fragmentation. Reduction in length and broadening of rod and cone inner segments (IS) was next observed, followed by the focal loss of rod and cone IS at later time points. The proportion of dying photoreceptors peaked at approximately 6 to 7 weeks of age and was significantly reduced after 12 weeks. In addition to rod and cone opsin mislocalization, there was early rod neurite sprouting, retraction of rod bipolar cell dendrites, and increased Müller cell reactivity. Later in the course of the disease, changes were also noted in horizontal cells and amacrine cells. CONCLUSIONS: XLPRA2 is an early-onset model of XLRP that is morphologically characterized by abnormal photoreceptor maturation followed by progressive rod-cone degeneration and early inner retina remodeling. The results suggest that therapeutic strategies for this retinal degeneration should target not solely photoreceptor cells but also inner retinal neurons.     

Retinal pathology of canine X-linked progressive retinal atrophy, the locus homologue of RP3

PURPOSE: To describe the course of photoreceptor disease in canine X-linked retinal degeneration. METHODS: Retinas from 55 dogs (44 males, 8 carrier females, 3 homozygous females) were obtained by enucleation under general anesthesia. After fixation and dehydration, tissues were embedded in epoxy resin, sectioned at 1 microm for light microscopy and stained with azure II/methylene blue and a paraphenylenediamine counterstain. For electron microscopy, regions identified by light microscopy were selected and cut at 60 nm. Sections were stained with uranyl acetate-lead citrate. Electroretinography from an additional group of normal males, affected males, and carrier females was performed and the rod and cone responses evaluated. RESULTS: The earliest lesion detectable by electron microscopy was vesiculation of rod discs, followed by disruption of outer segments and death of rods. Loss of cones and progressive atrophy of inner retinal layers followed. Lesions were most severe in the peripheral retina and advanced toward the optic disc with disease progression. Significant variation in disease severity was present in males despite the presence of the same disease allele in all affected dogs. Carrier females displayed generalized reduction in photoreceptor density as well as multifocal areas of complete rod loss. The electroretinogram (ERG) findings were compatible with the histopathologic abnormalities. Homozygous females had lesions similar to those seen in affected males. CONCLUSIONS: X-linked retinal degeneration is characterized by initial degeneration of rod photoreceptors, followed by loss of cones and progressive atrophy of the inner retina. Carrier females display a phenotype consistent with random X-chromosome inactivation. Variation in genetic background may alter expression of the disease allele in affected animals, thus accounting for variation in phenotypic expression of the disease.     

遗传性视网膜变性动物模型感光细胞节段早期变化的形态学研究

目的：了解遗传性视网膜变性的感光细胞节段在出生后早期发生的形态学变化，为临床诊治提供参考信息。方法：取出生后不同时间的retinal degeneration(rd)、retinaldegenerationslow(rds)小鼠及正常对照小鼠视网膜，经光镜、扫描电镜和透射电镜观察感光细胞节段的形态发生发育和结构变化过程，比较其在各型的动态变化和各型间的形态学差异。结果：rd鼠节段变性发生早，生后1周时开始出出节段变短，线粒体变性改变多见；2周时节段层变薄，内节段结构不完整，外节膜盘变形、排列紊乱；3周时节段层近消失。rds鼠外节段不发育，变性发生晚，2周时内节段变短；3周时明显变短；4周时细胞器减少、内节段变形。结论：感光细胞节段的变性改变与其基因型相关，不同遗传背景的视网膜变性有着不同的表型。     

Rod Outer Segment Maintenance Is Enhanced in the Presence of bFGF, CNTF and GDNF

We employed a morphological assay of outer segment collapse to determine if growth factors or other supplements directly affect dissociated rod photoreceptors in vitro. The morphological changes in outer segments were correlated with the light responsiveness of rods. Time-lapse video microscopy was used to observe the collapse of rod outer segments from isolated single cells and small clumps of cells. A consistent pattern of outer segment collapse into the inner segment was observed, yielding a convenient assay of the effects of neurotrophic factors on photoreceptor functional maintenance. The functional state of rods, defined as light-responsiveness, was measured with suction electrode recordings and matched with the various stages of outer segment collapse. Ciliary neurotrophic factor (CNTF) and glial cell-line-derived neurotrophic factor (GDNF) at a high concentration, yielded statistically significant improvements in rat outer segment survival times. Basic fibroblast growth factor (bFGF), which rescues photoreceptors in several rodent models of retinal degeneration, produced a significant increase in survival time in the presence of the cofactor heparin. In 4 out of 10 cases using human tisue, bFGF also yielded a significant increase in survival times. When brain-derived neurotrophic factor (BDNF) was applied to rat rods, outer segment survival times did not change. Outer segments collapsed more quickly when either pigment epithelial cell derived factor (PEDF) or sugarN-acetyld-galactosamine (NAD-gal) were present. Our results show that rod photoreceptors can respond to bFGF, GDNF and CNTF in vitro and provide evidence for a direct effect of these neurotrophic factors on rods. The rapid collapse of isolated photoreceptors in this model provides a convenient means for testing various neurotrophic agents and the induced cellular responses.     

Longitudinal assessment of retinal structure and function reveals a rod-cone degeneration in a guinea pig model initially presented as night blind

We have previously reported a naturally occurring retinopathy in a population of guinea pigs, where the affected animals presented a defect of the rod-mediated vision. The purpose of this study was to investigate if the mutants were affected with a stationary or degenerative retinopathy and to identify the cellular origin of this unique disorder. Electroretinogram (ERG) [postnatal day 1 (P1) to P450], light (LM) and electron microscopy (EM) [P5, P150, P450], and immunohistochemistry [P30, P150, P450] were evaluated from normal and mutant animals. Irrespective of age, the scotopic ERGs of mutants could only be evoked by bright flashes, and the resulting ERGs were of photopic waveform. Interestingly, the amplitude of the cone and the rod/cone a-waves was always of smaller amplitude in mutants, but this difference tended to decrease with age. In contrast, the b-waves were of larger amplitude than normal in photopic ERGs obtained prior to age 25 (days) and prior to age 10 for rod/cone ERGs. LM revealed, in mutants, an absence of the outer segment layer (OSL) with a reduction in the outer nuclear layer (ONL) thickness. EM disclosed the presence of cone outer segment (OS) while no rod OS could be evidenced. Immunohistochemistry revealed the presence of rhodopsin, both cone opsins as well as normal synaptophysin immunoreactivity. Finally, neither the retinal structure nor the function in the mutants achieved normal development. Results suggest that mutant animals are suffering from a degenerative retinal disorder that affects the structure and function of rods and cones.     

Hereditary retinal degeneration in the Rhode Island Red chicken: ultrastructural analysis

An electron microscopic analysis of photoreceptor degeneration in a congenitally blind strain of chickens is presented. The mutation was named rd, meaning 'retinal degeneration'. Although the chicks were behaviorally and electrophysiologically blind at the time of hatching, their retinas appeared morphologically comparable to normal chicks at this stage. Both groups had well-developed photoreceptor cells, although outer segments were typically disoriented or misaligned. In the normal, and to some degree in the rd, retina, outer segments became organized within the first week posthatching. In the rd retina at that time, however, more outer segments were disorganized and disoriented. Disc-like membranes were also seen in some inner segments. Many photoreceptors had distended inner segment tips containing a granular cytoplasm. Membraneous debris was present in the subretinal space. Over the next 2-3 weeks there was a reduction in number of inner segments, outer segments and photoreceptor nuclei of both rods and cones. Photoreceptor cell bodies in the outer nuclear layer were replaced by Mueller cell processes. By the end of the second month, a larger cone:rod ratio was apparent, and a large proportion of the remaining cones were double cones. Intact outer segments were rarely seen at that time. Few and sporadic cone cells, identified by a pale-staining oil droplet, were the predominant surviving photoreceptors by 6 months of age. At the later stages examined, the pigment epithelium (PE) appeared to be undergoing degenerative changes. A general thinning of cells and hypopigmentation of PE cells was apparent, although hyperpigmented, hypertrophied PE cells were also present which bulged into the subretinal space. Pigmented cells of unknown origin were also noted in the subretinal space at the later time points.     

S-antigen in a hereditary visual cell disease. Immunocytochemical and immunological studies

S-antigen is a photoreceptor-specific and potentially autoantigenic protein. Using light microscopic immunocytochemistry, the localization of S-antigen was studied in the retinas of normal dogs and Irish setters affected with rod-cone dysplasia, a hereditary retinal degeneration characterized by abnormal cGMP metabolism and arrested outer segment differentiation. Normal and affected dogs were also tested for the presence of humoral and cellular immunity to S-antigen. S-antigen was present in both rods and cones during inner and outer segment differentiation, but there was an apparent loss of immunoreactivity in cones as the retina matured. The developmental appearance and localization of S-antigen in affected retinas was similar to that of normals. S-antigen immunoreactivity decreased during the early stages of rod loss (39-57 days), but was still present in photoreceptor somata in the late stages of retinal degeneration. No significant difference was found between normal and affected setters in humoral immunity to S-antigen, indicating that it probably does not stimulate autoimmunity in red 1. Because normal dog lymphocytes failed to respond when sensitized to bovine S-antigen, cellular immunity to S-antigen in this disease cannot be ruled out.     

Effects of retinal detachment on rod disc membrane assembly in cultured frog retinas.

The authors compared rod outer segment (ROS) disc membrane assembly rates in detached and attached frog retinas to determine if there was a rapid impairment of membrane assembly in response to retinal detachment. Membrane assembly was quantified in vitro by incubating retinas in medium containing Lucifer yellow, which is entrapped by nascent discs. Video microscopy was used to detect incorporation of the dye. During the first 10 hr after separation of the retina from the retinal pigment epithelium (RPE), ROS-disc membrane assembly in isolated Xenopus laevis neural retinas continued at a near normal rate, 0.81 microns/10 hr, a 13% reduction (P less than .01), compared with the 0.93 microns/10 hr observed in attached control retinas. The morphology of the OS appeared normal in most rod photoreceptors by transmission electron microscopy, although vesiculation of the most basal OS membranes was seen in a small population (25%) of rods. Approximately 90% of rod photoreceptors continued to assemble OS membranes for more than 10 hr after detachment, but by the end of 2 days, only 55% were still making new discs. The percentage of rods with normal basal OS membranes also decreased (to approximately 50%). Therefore, only 25% were assembling morphologically normal discs 2 days after detachment. In attached control regions, rod photoreceptors showed a comparatively minor response to culture conditions; assembly of morphologically normal discs continued for 2 days in about 85% and ceased in only 10%. These results indicate that the effects on disc membrane assembly of disrupting photoreceptor-RPE interaction in vitro initially are slight but become progressively severe with time.     

Hereditary retinal degeneration in the Rhode Island Red chicken. I. Histology and ERG

Hereditary blindness in Rhode Island Red chickens was analyzed at various post-hatching stages by light microscopy and electrophysiological recordings. At the time of hatching the retina of affected chicks appeared morphologically normal and identical to that of control, non-affected chicks. Whereas the electroretinographic (ERG) response to light stimulus in normal chicks was near the adult level at the time of hatching, no ERG either under light- or dark-adapted conditions was measurable in affected chicks at any stage examined. Photoreceptor cells of affected animals were seen to undergo degenerative changes after about one week post-hatching. Decrease in number of outer segments, spaces between inner segments and large spaces in the outer nuclear layer were apparent by Day 10. By Day 21, most of the photoreceptor inner segments appeared swollen, and the decrease in number of outer segments and photoreceptor nuclei was noteworthy. By the end of the second month no outer segments were seen and the majority of identifiable inner segments were from cones, a larger proportion than normally present being double cones. By six months, very few photoreceptor inner segments and nuclei remained; most inner segments were deformed and diminutive but usually contained a clearstaining oil droplet characteristic of the principal member of the double cone. In all stages after one week of age, pycnotic nuclei and thinning of inner retinal layers accompanied photoreceptor degeneration. In all specimens examined, degeneration of retinal cells was more pronounced in the superior central retina than in the periphery. Pathological changes were frequently also noted in the pigment epithelium overlying degenerating retina. Because the chick retina is well developed at birth, contains a fovea and a significant cone population and because cones (particularly one specific type) survive rods, we believe that this congenitally-blind chicken may be a useful model for studies on human hereditary retinal degenerations.     

Membrane addition to rod photoreceptor outer segments: light stimulates membrane assembly in the absence of increased membrane biosynthesis

The effect of light on the biosynthesis and the assembly of rod photoreceptor outer segment membranes was analyzed in vitro using retinas from Xenopus laevis. The number of open discs at the base of the outer segment was used as a morphologic index to evaluate relative differences in rates of membrane assembly. Assembly was stimulated in vitro by light, as evidenced by a greater number of open discs that accumulated in light-exposed retinas than that in retinas maintained under the same conditions but in darkness. Quantitative autoradiography indicated, however, that unlike membrane assembly, the incorporation of 3H-leucine or 3H-mannose into proteins by rods was nearly identical in light-stimulated and dark-maintained retinas. Likewise, the synthesis of opsin, a protein destined for the rod outer segment, was not affected by light. We conclude from these studies that the enhanced rate of outer segment membrane assembly that occurs during the early light phase of the diurnal cycle takes place in the absence of an increase in the rate of biosynthesis of opsin, the major outer segment membrane protein.