Immunoassay of rod visual pigment (opsin) in the eyes of rds mutant mice lacking receptor outer segments

Photoreceptor cells with profound structural deficits can support useful vision in mice

PURPOSE

In animal models of degenerative photoreceptor disease, there has been some success in restoring photoreception by transplanting stem cell-derived photoreceptor cells into the subretinal space. However, only a small proportion of transplanted cells develop extended outer segments, considered critical for photoreceptor cell function. The purpose of this study was to determine whether photoreceptor cells that lack a fully formed outer segment could usefully contribute to vision.

METHODS

Retinal and visual function was tested in wild-type and Rds mice at 90 days of age (Rds(P90)). Photoreceptor cells of mice homozygous for the Rds mutation in peripherin 2 never develop a fully formed outer segment. The electroretinogram and multielectrode recording of retinal ganglion cells were used to test retinal responses to light. Three distinct visual behaviors were used to assess visual capabilities: the optokinetic tracking response, the discrimination-based visual water task, and a measure of the effect of vision on wheel running.

RESULTS

Rds(P90) mice had reduced but measurable electroretinogram responses to light, and exhibited light-evoked responses in multiple types of retinal ganglion cells, the output neurons of the retina. In optokinetic and discrimination-based tests, acuity was measurable but reduced, most notably when contrast was decreased. The wheel running test showed that Rds(P90) mice needed 3 log units brighter luminance than wild type to support useful vision (10 cd/m(2)).

CONCLUSIONS

Photoreceptors that lack fully formed outer segments can support useful vision. This challenges the idea that normal cellular structure needs to be completely reproduced for transplanted cells to contribute to useful vision.

Restoration of photoreceptor ultrastructure and function in retinal degeneration slow mice by gene therapy

The gene Prph2 encodes a photoreceptor-specific membrane glycoprotein, peripherin-2 (also known as peripherin/rds), which is inserted into the rims of photoreceptor outer segment discs in a complex with rom-1 (ref. 2). The complex is necessary for the stabilization of the discs, which are renewed constantly throughout life, and which contain the visual pigments necessary for photon capture. Mutations in Prph2 have been shown to result in a variety of photoreceptor dystrophies, including autosomal dominant retinitis pigmentosa and macular dystrophy. A common feature of these diseases is the loss of photoreceptor function, also seen in the retinal degeneration slow (rds or Prph2 Rd2/Rd2) mouse, which is homozygous for a null mutation in Prph2. It is characterized by a complete failure to develop photoreceptor discs and outer segments, downregulation of rhodopsin and apoptotic loss of photoreceptor cells. The electroretinograms (ERGs) of Prph2Rd2/Rd2 mice have greatly diminished a-wave and b-wave amplitudes, which decline to virtually undetectable concentrations by two months. Subretinal injection of recombinant adeno-associated virus (AAV) encoding a Prph2 transgene results in stable generation of outer segment structures and formation of new stacks of discs containing both perpherin-2 and rhodopsin, which in many cases are morphologically similar to normal outer segments. Moreover, the re-establishment of the structural integrity of the photoreceptor layer also results in electrophysiological correction. These studies demonstrate for the first time that a complex ultrastructural cell defect can be corrected both morphologically and functionally by in vivo gene transfer.

Actual problems of the cerebrospinal fluid-contacting neurons

Cerebrospinal fluid (CSF)-contacting neurons form a part of the circumventricular organs of the central nervous system. Represented by different cytologic types and located in different regions, they constitute a CSF-contacting neuronal system, the most central periventricular ring of neurons in the brain organized concentrically according to our concept. Because the central nervous system of deuterostomian echinoderm starfishes and the prochordate lancelet is composed mainly of CSF-contacting-like neurons, we hypothesize that this cell type represents ancient cells, or protoneurons, in the vertebrate brain. Neurons may contact the ventricular CSF via their dendrites, axons, or perikarya. Most of the CSF-contacting nerve cells send their dendritic processes into the ventricular cavity, where they form ciliated terminals. These ciliated endings resemble those of known sensory cells. By means of axons, the CSF-contacting neurons also may contact the external CSF space, where the axons form terminals of neurohormonal type similar to those known in the neurohemal areas. The most simple CSF-contacting neurons of vertebrates are present in the terminal filum, spinal cord, and oblongate medulla. The dendritic pole of these medullospinal CSF-contacting neurons terminates with an enlargement bearing many stereocilia in the central canal. These cells are also supplied with a 9 x 2 + 2 kinocilium that may contact Reissner's fiber, the condensed secretory material of the subcommissural organ. The Reissner's fiber floating freely in the CSF leaves the central canal at the caudal open end of the terminal filum in lower vertebrates, and open communication is thus established between internal CSF and the surrounding tissue spaces. Resembling mechanoreceptors cytologically, the spinal CSF-contacting neurons send their axons to the outer surface of the spinal cord to form neurosecretory-type terminals. They also send collaterals to local neurons and to higher spinal segments. In the hypothalamic part of the diencephalon, neurons of two circumventricular organs, the paraventricular organ and the vascular sac, of the magnocellular neurosecretory nuclei and several parvocellular nuclei, form CSF-contacting dendritic terminals. A CSF-contacting neuronal area also was found in the telencephalon. The CSF-contacting dendrites of all these areas bear solitary 9 x 2 + 0 cilia and resemble chemoreceptors and developing photoreceptors cytologically. In electrophysiological experiments, the neurons of the paraventricular organ are highly sensitive to the composition of the ventricular CSF. The axons of the CSF-contacting neurons of the paraventricular organ and hypothalamic nuclei terminate in hypothalamic synaptic zones, and those of magno- and parvocellular neurosecretory nuclei also form neurohormonal terminals in the median eminence and neurohypophysis. The axons of the CSF-contacting neurons of the vascular sac run in the nervus and tractus sacci vasculosi to the nucleus (ganglion) sacci vasculosi. Some hypothalamic CSF-contacting neurons contain immunoreactive opsin and are candidates to represent the "deep encephalic photoreceptors." In the newt, cells derived from the subependymal layer develop photoreceptor outer segments protruding to the lumen of the infundibular lobe under experimental conditions. Retinal and pineal photoreceptors and some of their secondary neurons possess common cytologic features with CSF-contacting neurons. They contact the retinal photoreceptor space and pineal recess, respectively, both cavities being derived from the third ventricle. In addition to ciliated dendritic terminals, there are intraventricular axons and neuronal perikarya contacting the CSF. Part of the CSF-contacting axons are serotoninergic; their perikarya are situated in the raphe nuclei. Intraventricular axons innervate the CSF-contacting dendrites, intraventricular nerve cells, and/or the ventricular surface of the ependyma. (ABSTRACT TRUNCATED)

C57BL/6J-vit/vit mouse model of retinal degeneration: light microscopic analysis and evaluation of rhodopsin levels

The C57BL/6J-vit/vit mouse is a newly described model of retinal degeneration in which photoreceptor cells die over the course of a year and the retinal pigment epithelium is unevenly pigmented. The present study utilized histological and biochemical techniques to assess the progression of the retinal degeneration in the vit/vit mouse ages 2 weeks to 8 months. Results of systematic morphometric evaluation indicated that the inner nuclear and plexiform layers of the retina are similar in thickness to age-matched C57BL/6J controls, but the outer plexiform layer is significantly thinner by 4 months. Rows of photoreceptor cells are lost at a rate of about one per month beginning at 2 months of age. By 8 months, the photoreceptor cell nuclei have diminished to only two to three rows. Inner segments of the vit/vit retina are similar in length to controls. Outer segments separate from the RPE during the first 2 months, they seem to be elongated at 2-3 months, but become severely disrupted past 4 months. Beginning at about 5 months, numerous darkly-staining cells resembling photoreceptor cell nuclei are observed in the area of the inner and outer segments and the subretinal space. Spectrophotometric analysis of rhodopsin indicated similar levels in vit/vit and controls at 6 weeks but a 50% reduction by 22 weeks. At 46 weeks, the level of rhodopsin in the mutant animal was less than 0.1 nmol per retina. The loss of rhodopsin in the vit/vit retinas correlated strongly with the decreasing number of rows of photoreceptor cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Synaptic plasticity in the rod terminals after partial photoreceptor cell loss in the heterozygous rds mutant mouse

In the retina of mice heterozygous for the retinal degeneration slow gene (rds/+) the photoreceptor cells, both rods and cones, develop abnormal outer segments but establish normal synaptic contacts. The other retinal layers also show normal structural organization. Starting from the age of 2 months, a very slow loss of photoreceptor cells progresses throughout life. As a result, the photoreceptor cell population in the retina of the affected mice is reduced to less than half at the age of 9-18 months. In some of the surviving rod terminals during this period, an increase in the number of synaptic ribbons is recorded. At the same time, the profiles of processes originating from the second order neurons and participating in these synapses are also increased in number so that the multiple ribbons appear as centres of multiple synaptic sites. Morphometric measurements of the perimeter of the synaptic profiles in rod terminals show a significant increase in the rds/+ retina over that of the control retina. Observations based on serial electron microscopy indicate that multiple synaptic sites are developed while the number of the second order neuronal processes, entering the terminals, remains unchanged. The frequency of terminals with multiple synapses in the rds/+ retina increases with progressive photoreceptor cell loss. Similar changes do not occur in the terminals of the cones. It is postulated that loss of some rod photoreceptor cells within a group that is presynaptic to common bipolars or horizontal cells results in partial deafferentation which in turn stimulates the growth of the remaining synaptic elements. The possible compensatory effect and functional significance of such synaptic growth are discussed.

Arrestin mRNA expression, biosynthesis, and localization in degenerating photoreceptors of mutant rds mice retinas

The retinal photoreceptors of the mutant rds mouse are unable to form normal outer segments. Eventually the abnormal cells die in the months following birth. The genetic defect in the rds mouse was recently localized to the peripherin gene that encodes a protein in the outer segment disc margin. Although this mutation may explain the morphogenetic defect, i.e., the failure to form outer segments, the reason for subsequent cell death is not clear. Previously, we demonstrated that the capability to synthesize opsin, an outer segment integral membrane protein, is not compromised by the morphogenetic defect although the opsin steady-state content is considerably reduced, since it is not incorporated into an organized outer segment. We have now studied arrestin, a cytoplasmic protein that is part of the phototransduction cascade and appears to shuttle between the inner and outer segment during the light/dark cycle. Since rds mice lack outer segments, it was of interest to determine the effects of the photoreceptor abnormality on arrestin gene expression. Arrestin mRNA levels and protein synthetic rates were high in young rds retinas. When corrected for cell loss, the steady-state arrestin content per cell in the rds retina was comparable to normal. However, in the absence of an outer segment, the total amount of arrestin is concentrated in the remaining inner segment. Consequently, a relatively high level of arrestin is present in the rds inner segment throughout the light/dark cycle. We suggest that the morphogenetic defect indirectly precipitates secondary effects such as the persistent presence of high levels of arrestin or other soluble proteins in the abnormal photoreceptor inner segment, nucleus, and synaptic terminal. This condition, if toxic to the cells, may compromise photoreceptor viability in the rds retina.

Photoreceptor differentiation in cerebellar medulloblastoma: evidence for a functional photopigment and authentic S-antigen (arrestin)

The aim of the present study was to evaluate the putative photoreceptor differentiation found in certain cerebellar medulloblastomas. The analyses were focussed on S-antigen, rod-opsin (the apoprotein of the visual pigment rhodopsin) and 11-cis retinal (the prosthetic group of rhodopsin). Fresh frozen and paraffin-embedded biopsy specimens of three medulloblastomas were investigated by means of immunocytochemistry, enzyme-linked immunosorbent assay (ELISA), high-pressure liquid chromatography (HPLC), and immunoblotting. As shown in paraffin sections, one out of the three tumors (tumor A) contained S-antigen- and rod-opsin-immunoreactive tumor cells. The immunoblotting technique revealed in this tumor a single protein band of approximately 48-50 kDa that reacted with the S-antigen antibody and three protein bands of approximately 40, 75 and 110 kDa recognized by the rod-opsin antibody. These bands could not be detected in the two remaining tumors (tumor B and C). The rod-opsin content of tumor A was quantified by the ELISA; 11.7 pmol rod-opsin were calculated for the biopsy. The HPLC demonstrated the presence of 11-cis- and all-trans-retinal in tumor A, but not in tumors B and C. Furthermore, it was shown that 11-cis-retinal was converted to all-trans-retinal upon illumination of the tumor extract. The ratio between 11-cis- and all-trans-retinal was approximately 1:1 before illumination and 3:5 after illumination. A total of 2-3 pmol of retinal was found in the biopsy of tumor A. In addition all-trans-retinol was present in this tumor. The results indicate that certain medulloblastomas express a functional photopigment and S-antigen, another protein of the phototransduction cascade. They strongly support the concept that medulloblastoma cells may differentiate along the photoreceptor cell lineage.

Development and degeneration of retina in rds mutant mice: ultraimmunohistochemical localization of S-antigen

In the developing photoreceptor cells of the homozygous rds mutant mice S-antigen is localized over the ciliary protrusion as in the control mice, and to a lesser extent over the inner segments, perikaryal cytoplasma and the cell terminals. As the outer segments develop in the normal retina, the discs become increasingly immunoreactive. In the rds/rds retina the outer segments fail to develop but small membrane bound vesicles, immunoreactive for S-antigen are extruded and phagocytized by the retinal pigment epithelium. In the retina of older mutant mice, as the photoreceptor cells degenerate slowly, the surviving cells continue to show persistent immunoreactivity for S-antigen in the different regions of the photoreceptor cells. In the heterozygotes the outer segments are reduced and appear abnormal, but the localization of S-antigen is similar to normal. In the receptor region of the normal retina and in the deviant membranous structures in the mutant retina the localization of S-antigen is similar to that of opsin. However, some differences in the subcellular localization of these two photoreceptor specific proteins have been observed. It is concluded that the rds gene acts subsequent to the synthesis of these proteins and possibly at the site of disc assembly.

Opsin gene expression during early and late phases of retinal degeneration in rds mice

Opsin mRNA levels, opsin synthetic rates and localization of opsin were studied throughout the photoreceptor's life span in the rds mice. Mutant mice 11 days to 11 months old were investigated. Opsin mRNA levels were studied by means of northern blot analysis. Opsin synthesis was measured by incorporation of [35S]methionine into newly synthesized opsin in vitro. Distribution of opsin in the retina was determined by immunoelectron microscopy. Opsin mRNA was detected in young as well as old retinas, and opsin synthesis could be detected at early phases of degeneration but not in late phases. The absence of opsin synthesis in older rds mice might be due to translational down-regulation or some other defect in the capacity to synthesize opsin. In young mice, opsin was detected in the subretinal space in opsin-laden vesicular membranes: such membranes were absent from retinas of older mice. This disappearance parallels the cessation of opsin synthesis and the consequent failure to deliver opsin to the subretinal space in retinas from older mice. Immunochemical analysis revealed the presence of small amounts of opsin in all retinas up to 11 months of age. Immunoelectron microscopy localized the residual opsin, mostly to the plasma membrane which envelops the nuclei and synaptic terminals. These opsin molecules might be a consequence of very low levels of opsin synthesis, too low to be detected by our assays, or may have been synthesized at an earlier age and retained in the plasma membrane of the old mutant photoreceptors.

Localization of the rhodopsin gene to the distal half of mouse chromosome 6

We have assigned the mouse rhodopsin gene, Rho, to chromosome 6 using DNA from a set of mouse-hamster somatic hybrid cell lines and a partial cDNA clone for mouse opsin. This assignment rules out the direct involvement of the rhodopsin gene in the known mouse mutations that produce retinal degeneration, including retinal degeneration slow (rds, chromosome 17), retinal degeneration (rd, chromosome 5), Purkinje cell degeneration (pcd, chromosome 13), and nervous (nr, chromosome 8). Segregation of Rho-specific DNA fragment differences among 50 animals from an interspecific backcross (C57BL/6J X Mus spretus) X C57BL/6J indicates that the Rho locus is 4.0 +/- 2.8 map units distal to the locus for the proto-oncogene Raf-1 and 18.0 +/- 5.4 map units proximal to the locus for the proto-oncogene Kras-2. Linkage to Raf-1 was confirmed using four sets of recombinant inbred strains. The two loci RAF1 and RHO are also syntenic on human chromosome 3, but on opposite arms.

Development and degeneration of retina in rds mutant mice: immunoassay of the rod visual pigment rhodopsin

Development and loss of photoreceptor cells in mice, afflicted by the rds (retinal degeneration slow) gene, was analyzed by measuring the ocular visual pigment content as rhodopsin (spectroscopy) and opsin (immunoassay). With regard to the postnatal age, where opsin was just detectable, and to the initial rate of opsin synthesis, the mutants did not strongly deviate from the normal animals. The final maximal visual pigment level was, however, about half of normal for the heterozygous mutants and about 3% of normal for the homozygous mutants, both in the pigmented and in the albino strain. In the pigmented normal or heterozygous mutant the (rhod)opsin levels remain stable up to at least 1 year of age. For the corresponding albino animals this was only observed up to 9 months of age. Thereafter the level declines. In the homozygous mutants, maximal opsin levels were observed at about 3 weeks postnatal. Subsequently, this level gradually declined to about 40% in the pigmented and about 15% in the albino mutant. The results indicate that the rds gene does not directly affect the biosynthetic pathways of opsin. The physiological effect of the rds gene is aggravated by photodamage for which the albino animal is particularly susceptible.

Interphotoreceptor retinoid-binding protein (IRBP) in the postnatal developing rds mutant mouse retina: EM immunocytochemical localization

The distribution of IRBP was examined in postnatal developing retinas of rds (020/A) mutant mice and Balb/c controls by EM immunocytochemistry. Light labeling for IRBP was detected in mutant and control retinas by postnatal day 9 (P9) largely in the interphotoreceptor matrix (IPM). At P14, some photoreceptors in the rds retina showed a higher density of label in the Golgi for IRBP than neighboring cells and those of controls processed simultaneously. This high density of label for IRBP was observed also in the Golgi of a small population of photoreceptor cells at P18, P19 and P21 in rds retinas. These cells were found to represent approximately 3-5% of the photoreceptor population. The density of label for IRBP at the apical RPE region was obviously low in the rds retinas by P18, P19 and P21. However, this same region in controls of the same ages was densely labeled for IRBP. The low density of labeling at the apical RPE region in the rds retinas may indicate a change in the rate of synthesis, secretion, distribution and/or degradation in the IPM. The high density of intracellular labeling in a small population of cells may be indicative of impaired secretion, an increase in IRBP synthesis or the initiation of photoreceptor deterioration. Whether the differences observed in the distribution of IRBP in the rds mutant are primary or secondary effects of the genetic lesion remains undetermined.

Differentiation in medulloblastomas: correlation between the immunocytochemical demonstration of photoreceptor markers (S-antigen, rod-opsin) and the survival rate in 66 patients

Biopsy specimens of 66 medulloblastomas were investigated by means of S-antigen and rod-opsin immunocytochemistry. The patients were operated between 1969 and 1988 and the medical records were retrospectively evaluated to correlate the immunocytochemical features of the tumors to the course of the disease. S-antigen- and rod-opsin-immunoreactive tumor cells were found in 19 out of 66 cases. Since in the normal non-neoplastic state immunoreactive S-antigen and rod-opsin are restricted to retinal photoreceptors and a class of pinealocytes derived from photoreceptor cells, the occurrence of these proteins in certain tumor cells of medulloblastomas suggests a differentiation of these cells along the photoreceptor cell lineage and allows the identification of a special subtype of medulloblastoma displaying photoreceptor-specific characteristics. This subtype appears to be closely related to retinoblastomas and pineal cell tumors. The incidence of this subtype corresponds to approximately 30% of all medulloblastomas. Correlation between the demonstration of immunoreactive S-antigen and rod-opsin and the course of the disease revealed a 10-year survival rate of 50.6% for patients with medulloblastomas displaying photoreceptor-specific characteristics and maximally 11% for patients suffering from medulloblastomas devoid of these markers. Although the statistical evaluation does not provide a significant result, the estimated P-value of 0.085 indicates a distinct trend toward a better prognosis for patients suffering from medulloblastomas with photoreceptor-specific features. The validity of this trend needs to be proven in further studies with a greater number of patients.

A developmental study of interphotoreceptor retinoid-binding protein (IRBP) in single and double homozygous rd and rds mutant mouse retinae

Interphotoreceptor retinoid-binding protein (IRBP) was studied using immunochemical and immunocytochemical techniques in retinae of mice with allelic combinations at the rd and rds loci at different stages of development and degeneration. Until postnatal day 7 (P7), IRBP is located intracellularly in developing retinae of the different genotypes. Thereafter, IRBP is present mainly in the interphotoreceptor matrix. As previously noted, cell death is slowest in the heterozygous +/+,rds/+ mutant with loss increasing in order in +/+,rds/rds, rd/rd, rds/rds and rd/rd,+/+ animals. The IRBP content of the total retina also approximates this pattern, with lowest amounts by far in rd/rd, rds/rds and rd/rd,+/+ mutants (after P14). Interestingly though, IRBP loss significantly precedes visual cell loss in the rd/rd,rds/rds retina. In all the mutants, the remaining rod cells in the outer nuclear layer exhibit synthesis of intracellularly located IRBP at late stages of degeneration. In the single homozygous rd/rd,+/+ and the double homozygous rd/rd,rds/rds mutants, IRBP is present intracellularly during the entire degenerative process with somewhat less intracellular IRBP in the rd/rd,rds/rds mutant. Retinae of homozygous +/+,rds/rds and heterozygous +/+,rds/+ animals exhibit a normal distribution pattern of IRBP immunoreactivity until loss of photoreceptor cells becomes pronounced at later stages of the disease. Many of the remaining cells at this time are probably cone elements although they are structurally changed. Double labeling with IRBP and S-antigen demonstrates, in many but not all, the presence of both proteins in the same cell body. Immunocytochemistry clearly demonstrated the presence of IRBP in remaining photoreceptor cells at late stages of the disease. Thus, the biochemically measured loss of IRBP appears to be a complex process neither directly dependent on the loss of photoreceptor outer segments and reduced interphotoreceptor matrix space (e.g. there is a sustained IRBP level in rodless rds mutants) nor simply due to cell death (e.g. in the rd/rd,rds/rds mutant, IRBP loss significantly precedes cell loss). That this IRBP is mainly intracellular, however, may indicate an abnormality in secretion which, combined with other factors, induces a degenerated and less differentiated phenotype.

Antibodies against retinal photoreceptor-specific proteins reveal axonal projections from the photosensory pineal organ in teleosts

With the aid of specific antisera to the retinal proteins S-antigen and alpha-transducin and to the rhodopsin apoprotein opsin, we have labeled various cell populations in the pineal organ, parapineal organ, habenular nucleus, and subcommissural organ in two teleost species: the rainbow trout and the European minnow. Although these proteins are associated with photoreceptor functions, not only photoreceptor cells but also the majority of parenchymal cells in the pineal organ were immunoreactive. Immunoreactive cells with dendrite- and axonlike processes were observed also in the parapineal organ and the habenular nucleus. Furthermore, S-antigen-immunoreactive, long, axonal processes were observed in the pineal organ and could be traced from the pineal organ to the habenular nucleus and to the pretectal area. In the light of recent HRP electron microscopical and immunocytochemical studies we propose (1) that not only the classical pineal photoreceptor cells of poikilothermic vertebrates but also other types of CSF-contacting neurons may be the phylogenetic ancestors of mammalian pinealocytes, and (2) a close interrelationship between the pineal organ and the limbic system, effectuated by the direct projections from pineal photoreceptors/CSF-contacting neurons/pinealocytes to the habenular nucleus, and by displaced "pinealocytelike" elements scattered in the habenular nucleus.

Changes in the localization and content of opsin during retinal development in the rds mutant mouse: immunocytochemistry and immunoassay

Electron-microscope immunocytochemistry and antibody staining of nitrocellulose replicas of SDS gels (Western blots) were used in a developmental study to detect the presence and localization of opsin in the developing photoreceptors of rds (020/A) mutant mice and their BALB/c normal controls. Western blot analysis of isolated retinal membranes first detected opsin at 10 postnatal days in both strains. Opsin levels rose progressively with development in BALB/c normal retinas. In contrast, levels in the rds retina became undetectable by 30 days after peaking at 15 days. Specific binding of anti-opsin antibodies was first observed by immunocytochemistry at postnatal 5 days in the distal plasma membrane of the connecting cilium in both BALB/c and rds retinas. Thereafter, labeling intensity increased progressively with development in the BALB/c retina. Anti-opsin labeling remained localized primarily to the plasma membrane of the distal cilium and to the outer segment with the exception that light labeling of the inner-segment plasma membrane was observed from 5-15 postnatal days. Antibody binding to photoreceptors in the rds mouse retina predominated in the plasma membrane of the connecting cilium at 5 postnatal days, but opsin was present at higher density in the inner segment plasma membrane at 5-, 10-, 15- and 20 postnatal days, when compared with BALB/c photoreceptors. From 10-20 postnatal days opsin-rich vesicles were observed in the ventricular (subretinal) space of the rds retina. Maximum intensity of labeling was observed at 15 postnatal days. By 30 postnatal days, labeling of the ciliary and inner-segment plasma membrane decreased to near background levels.

Development and degeneration of retina in rds mutant mice: ultraimmunohistochemical localization of opsin

In normal retina the developing photoreceptor cells first show presence of opsin over the distal ends of the ciliary protrusions. In a fully differentiated cell intense activity is seen over the rod outer-segment discs; some activity is also seen over the Golgi zone and near the distal ends of the inner segments but the other parts of the receptor cell appear negative. In the pigment epithelium opsin is seen only over phagosomes containing rod outer segment debris. In the homozygous rds mutant retina, developing receptor cells show opsin activity over the ciliary protrusions as in the normal. These ciliary protrusions grow in size and show increased opsin activity and presumably constitute the site of phototransduction in the mutant retina. Although typical disc structures remain lacking, variable amounts of immunopositive, irregular, membranous structures are occasionally observed. The inner segments in the mutant cells show very little immunoreactivity but the perikarya and the spherule terminals show increased immunoreactivity in comparison with the normal. At the onset of degeneration, some of the receptor cells in the mutant retina show extrusion of small, membrane-bound vesicles which are immunopositive for opsin. Some receptor cells undergoing lysis disintegrate and also add to the opsin-positive vesicular structures in the interphotoreceptor space. The vesicles are phagocytized by pigment epithelial cells. In older mutant mice at an advanced stage of degeneration, the receptor cells show reduced opsin activity. In heterozygous mutant mice the outer segments are reduced in length and the discs are abnormal in form. However, the intensity and the pattern of opsin localization in the outer segments and at other sites are similar to normal.

Enzyme-linked immunosorbent assay for quantitative determination of the visual pigment rhodopsin in total-eye extracts

A versatile, multispecies enzyme-linked immunosorbent assay for the rod visual pigment (rhod)opsin has been developed. For this quantitative inhibition assay a monospecific polyclonal antiserum is used which is elicited in rabbits against bovine rod outer-segment membranes. Detergent concentrations as high as 1.0% can be used in the assay with only a slight loss in sensitivity. The assay allows quantitative determination of the apoprotein opsin with a detection level of about 0.04 pmol per sample by using standards prepared by illumination of spectrophotometrically determined amounts of rhodopsin. The antiserum shows considerable cross-reactivity with opsin from several species (mouse, rat, quail, monkey and man). The high degree of monospecificity and cross-reactivity of the antiserum already allowed quantitation of opsin content in crude eye extracts of mouse, rat and quail with a sensitivity comparable to that of bovine opsin. Similar types of multispecies immunoassays for quantitation of highly conserved membrane proteins can be developed using the described approach, requiring only a monospecific antiserum elicited against an easily accessible species and crude tissue extracts both for coating and as a source of the inhibitory antigen.