Rds Mice Research Articles

Retinal accumulation of the phosducin/T βγ and transducin complexes in developing normal mice and in mice and dogs with inherited retinal degeneration

Rod photoreceptors of mammalian retinas contain a 33-kDa phosphoprotein, phosducin, which complexes with the β,γ-subunits of transducin (T βγ). The level of phosducin phosphorylation is modulated by light, suggesting that the phosducin/T βγ complex has a pivotal role in light-regulated events that occur in photoreceptors. We have investigated, in developing mouse retinas, the age at which the complex is first detected and the subsequent accumulation of the phosducin/T βγ complex during postnatal life. Western blot analysis detected immunoreactivity both for phosducin and T β in retinal homogenates of 3-day-old mice. Thereafter, the level of immunoreactivity for both proteins increased steadily, to reach adult levels in the next 2 postnatal weeks. Gel filtration analysis of extracts from immature mouse retina showed that phosducin and t β co-eluted, like the phosducin/T βγ complex of adult retina, as a 77-kDa complex, indicating that the phosducin/T βγ complex is formed when photoreceptors first synthesize the components of the complex. While the levels of the phosducin/T βγ complex increased steadily during the first 2 postnatal weeks, the subunits of transducin complex, T α together with additional amounts of T βγ, only started to appear around the 7–9th postnatal day, and the level of transducin complex increased sharply at 11–14 days to reach adult levels that are similar to those of phosducin/T βγ complex. Similar studies of immature retinas from rd mouse, rds mouse, rcd Irish setter and erd Norwegian elkhound showed that the composition and level of accumulation of both phosducin/T βγ and transducin were essentially normal in each case. The ability of rd mouse photoreceptors to form both the phosducin/T βγ complex and transducin contrasts with the failure of rd photoreceptors to assemble a phosphodiesterase complex of normal composition and function.

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.

Immological determination of transducin content in retinas exhibiting inherited degeneration

The inherited disorders of rd mice and affected Irish setter dogs are characterized by the accumulation of cyclic GMP (cGMP). Since the cGMP level in normal retinal rods is regulated by a light-activated enzyme cascade involving rhodopsin, transducin, and phosphodiesterase, an abnormality associated with any of these three proteins would cause cGMP accumulation. In order to determine the relationship between different forms of retinal degeneration and the transducin content in the affected retinas, affinity-purified antibodies directed against the individual subunits of bovine transducin were prepared. These antibodies, which recognized transducin in many vertebrate species, were used to compare the retinal content of this protein at various stages of inherited photoreceptor degeneration. In each of the disorders studied (rd and rds mice, RCS rat, and affected Irish setter dog), retinas at early stages of degeneration displayed two characteristics similar to those of normal control retinas. First, all three subunits of transducin were detected and found to have normal electrophoretic mobility, suggesting that these disorders are unlikely to be due to changes in the composition of transducin subunits. Second, the amount of cross-reactive T beta always exceeded those of T alpha and T gamma. This disproportionately higher amount of T beta-like protein became more pronounced as the visual cells degenerated. In retinas which had undergone complete photoreceptor degeneration, cross-reactive T alpha and T gamma were undetectable. In contrast, anti-T beta gamma antibodies detected an amount of T beta-like polypeptide corresponding to 10-25% of the control. Since our anti-T beta gamma antibodies recognize the beta subunit of the GTP-binding N proteins of the adenylate cyclase system, this finding suggests that this residual T beta-like protein, which is not part of transducin, may be associated with other GTP-binding regulatory proteins.

Genetic expression of cyclic GMP phosphodiesterase activity defines abnormal photoreceptor differentiation in neurological mutants of inherited retinal degeneration.

We have examined cyclic GMP concentrations, guanylate cyclase activities, and cyclic GMP phosphodiesterase (PDE) activities in developing retinas of congenic mice with different allelic combinations at the retinal degeneration (rd) and retinal degeneration slow (rds) loci. Although guanylate cyclase activities were found to be uniformly low in the mutant retinas, striking differences in PDE activity and cyclic GMP levels were observed in retinas of the various genotypes. Homozygous rds mice, which lack receptor outer segments, showed reduced retinal PDE activity and cyclic GMP concentration in comparison to normal animals. In heterozygous rds/+ mice with abnormal outer segments, the levels were intermediate. In retinas of homozygous rd mice, PDE activity was lower than in rds retinas and cyclic GMP levels were much higher. In mice homozygous for both rd and rds genes, retinal PDE activities were even lower than in single homozygous rd mice; the cyclic GMP level reached the same high value as in the rd animals, persisted for a longer time at this high level, and did not correlate with the rate of photoreceptor cell loss. Thus, a marked variation in PDE activity appears to be the major manifestation of abnormal outer segment differentiation and eventual degeneration of photoreceptor cells in these neurological mutants. An increased cyclic GMP level seems to be an essential corollary in the expression of the rd gene even in the absence of outer segments, but it appears unlikely that an abnormally high nucleotide level in itself causes photoreceptor cell death.

Comparison of the lens crystallin proteins from normal, rd, and rds mutant mice utilizing specific monoclonal antibodies

The lens proteins from three lines of congenic mice which are homozygous for the gene retinal degeneration ( rd) or retinal degeneration slow ( rds) or carrying the normal alleles (normal) were analyzed by SDS-PAGE and by immunological reactivity to specific monoclonal antibodies. The lens proteins of normal, rd, and rds mice showed a similar developmental pattern between postnatal day 0 and postnatal day 30. The expression of the 25000 molecular weight (MW) β-crystallin polypeptide which appears postnatally in the normal lens was not affected by retinal abnormalities in the mutant mice. It is concluded that the regulation of the 25000 MW β-crystallin polypeptide is not dependent upon differentiation or maintenance of the photo-receptor outer segments or continued presence of the photoreceptor cells.

Cyclic nucleotide content and phosphodiesterase activity in the rds mouse 020/A) retina

Cyclic nucleotide metabolism was examined in the retina and in the retinal pigment epithelium (RPE)-choroid complex of the rds mouse (020/A), a mutant in which discrete photoreceptor outer segment disc structures fail to develop. In retinas of both rds and control (Balb/c) mice, cyclic AMP levels peak at 10–15 days (20–25 pmol mg −1 protein). The level drops to about 10 pmol mg −1 at about one month in normal retinas but remains high in affected retinas. Cyclic GMP levels increase five-fold in Balb/c retinas as ROS develop whereas, in affected retinas, the levels remain constant and low (about 5 pmol mg −1). In RPE-choroid, cyclic nucleotide levels are similar in control and affected mice. Cyclic AMP phosphodiesterase (PDE) activity is somewhat higher in affected than in control retinas; conversely, cyclic GMP-PDE is lower. Both cyclic AMP-PDE and cyclic GMP-PDE activities are different in normal and affected RPE-choroid. Thus, although the rds (020/A) mouse belongs to the early-onset photoreceptor dysplasia group of hereditary retinal degenerations on a morphological basis, it does not exhibit high retinal cyclic GMP levels and thus appears to be distinct from other animals exhibiting early postnatal photoreceptor dysfunction.

Development and degeneration of retina in rds mutant mice: light microscopy.

Changes during the development and degeneration of the retina in 020/A mice, which are homozygous for the newly reported rds (retinal degeneration slow), gene were studied by histological and enzyme-histochemical methods with Balb/c mice carrying the normal allele as control. During normal development the total thickness of the retina grows from the time of birth till the age of 21 days and thereafter gradually diminishes, while the thicknesses of the component layers show a characteristic and differential change in course of their histogenesis. In the normal retina the perikarya of the cones are more frequent in the central than in the peripheral areas. The cone frequency in the central retina, but not in the periphery, increases with age and implies selective loss of rod cells in older animals. In the homozygous rds mice, the receptor layer remains rudimentary, but the other retinal layers show a normal trend of growth during the first 2 weeks after birth. Thereafter th morphological layers containing visual cell structures--the receptor, the outer nuclear, and the outer plexiform layers--begin to reduce. The loss of visual cells is readily marked by the reduction of the outer nuclear layer and is first evident at 2 weeks after birth. Degeneration is more rapid up to the age of 2-3 months, when the outer nuclear layer is reduced to half of its original thickness; thereafter degeneration progresses more slowly. The receptor and the outer plexiform layers are also simultaneously reduced. At 9 months, the peripheral parts of the retina, and at 12 months, the entire retina is completely lacking in visual cells. In the central retina of the mutant, rod and cone cell populations are equally affected up to the age of 6 months, as their relative frequency remains similar to the normal. In the peripheral retina, where cell loss is more pronounced, and in the central retina at 9 months an increase in relative frequency of cones is recorded and indicate increased susceptibility of the rods to later degenerative changes. The inner parts of the retina, including inner nuclear, inner plexiform, and ganglion cell layers, remain morphologically unaffected until irregular vascularization follows total loss of visual cells. The pigment epithelium is also affected at this late stage and appears depleted and patchy. In the normal retina, macrophages which are positively stained for the enzyme N-acetyl-beta-glucosaminidase appear in the inner layers with the growth of the retinal vasculature. In the mutant, increased frequency and stainability of the macrophages are discernible in the inner retina at 11 days. The macrophages migrate outwards and are observed in the outer nuclear layer and in the optic ventricle during the period of degeneration. These findings are compared with the observations in the other retinal degeneration mutants in rodents, and in retinitis pigmentosa in humans. The suitability of the rds mice as an animal model system for the human disease is emphasized.