As a result of an early deficiency in cyclic nucleotide phosphodiesterase activity, guanosine 3',5'-monophosphate accumulates in retinal photoreceptor cells before they begin to degenerate. It is suggested that degeneration of the photoreceptor cells is related to an imbalance in their metabolism or function which is caused by the elevated levels of cyclic guanosine monophosphate.
Observations are presented of a combined light and electron microscopic study of synaptogenesis in the photoreceptor terminal of visuallycompetent mice. Our study suggests that photoreceptor synaptogenesis in these retina progresses through a sequence of postnatal changes which leads to the ordered arrangement of processes within the adult photoreceptor terminal. On the 5th postnatal day, neuronal processes form synaptic contacts with a photoreceptor terminal, usually in the vicinity of a synaptic ribbon. Following the formation of synaptic contacts, the processes invaginate into the photoreceptor terminal, maintaining their position, lateral to a synaptic ribbon. Beginning on about the 10th day, a central process enters the terminal to yield a triad configuration which is a characteristic of a mature photoreceptor terminal. The formation of triads is essentially complete by the 14th postnatal day.Our observations suggest that horizontal cell processes form synaptic contacts with the photoreceptor terminal before bipolar cell dendrites, implying that the horizontal cells mature in advance of the bipolar cells. This possibility is discussed in terms of the appearance of the electroretinogram (ERG) in the developing mouse retina.
Irish setter dogs affected with a rod/cone dysplasia (locus designation, rcdl) display markedly elevated levels of retinal cGMP during postnatal development. The photoreceptor degeneration commences =25 days after birth and culminates at about 1 year when the population of rods and cones is depleted. A histone-sensitive retinal cGMP phospho- subunit by 49 residues, thus removing the C-terminal domain that is required for posttranslational processing and membrane association. These results suggest that the redl gene encodes the rod photoreceptor PDE 13 subunit and that a nonsense mutation in this gene is responsible for the production of a nonfunctional rod PDE and the photoreceptor degeneration in the rcdl/rcdl Irish setter dogs.The Irish setter rod/cone dysplasia leading to a rapidly progressing loss of photoreceptors (1) is inherited as an autosomal recessive trait (genetic locus, rcdl). The early onset of the photoreceptor degeneration has been well defined by morphological and biochemical studies (2-4). Clin-ically, the disorder is grouped within a famnily of related canine retinal degenerations which are termed progressive retinal atrophies (5). In affected dogs, retina and photoreceptor development appears normal until 13 days of age (4), but subsequent development of rod photoreceptor cells is arrested. Rod photoreceptor degeneration is evident by 1 month of age; nearly all of the rod photoreceptors have degenerated by 5 months, and cone photoreceptor degeneration is completed by about 1 year (for review, see refs. 6 and 7).The earliest known biochemical manifestation of the rcdl phenotype is a rapid accumulation of cGMP to levels that are about 10-fold above those of age-matched controls (2-4, 8). These features are reminiscent of the phenotype seen in the rd mouse in which a nonsense mutation in exon 7 ofthe cGMP phosphodiesterase (PDE) (-subunit gene prevents the formation of a functional enzyme (9) leading to elevated cGMP levels and a rapid rod photoreceptor degeneration. Earlier studies of retinas from normal and affected Irish setters showed that the a and 'y mRNAs of affected dog PDE were of normal size and abundance (10), whereas the /-subunit mRNA level appeared to be reduced (11,12). This finding, similar to that in the rd mouse, suggests a defect in the dog PDE l3-subunit gene. Since a previous study showed the presence of a histone sensitive cGMP PDE activity in affected, immature Irish setter retinas (13), we reinvestigated its origin by an HPLC method which is capable of separating rod and cone PDEs (14). In this paper we identify the residual PDE activity in affected Irish setter retinas as comigrating with cone PDE, whereas rod PDE activity is completely absent. We further provide evidence that a functional /3 subunit is not produced in affected retinas and that a nonsense mutation near the C-terminal end of the /-subunit gene leads to truncation and destabilization of the gene product,
Photoreceptors of mammalian retinas contain a 33-kDa (33K) protein that is phosphorylated, in vitro, by cyclic nucleotide dependent protein kinases. The 33K protein is phosphorylated in the dark, in situ, and dephosphorylated upon illumination. The soluble 33K protein from bovine retinas has been purified to near homogeneity by extraction at pH 5.7 and chromatography on ion-exchange, gel filtration, and hydroxylapatite columns. In the native conformation, the 33K protein is associated with a 37-kDa (37K) and a 10-kDa (10K) protein, forming a trimeric complex with a sedimentation coefficient of 4.9 S and an apparent molecular mass of 77 kDa. The 33K protein can be dissociated from the 37K/10K complex by centrifugation in the presence of high pH and high salt; the subunits reassociate to form the trimeric complex upon recentrifugation in an isotonic buffer with neutral pH. The 33K protein is phosphorylated rapidly by exogenous kinase, in vitro, whereas the 37K and 10K subunits remain unphosphorylated. The 37K and 10K subunits cross-react with antibodies prepared against the beta- and gamma-subunits, respectively, of bovine transducin, indicating that the 37K and 10K subunits are immunologically identical with beta- and gamma-transducin, respectively. No immuno-cross-reactivity was observed between the 33K protein and an antibody against the alpha-subunit of bovine transducin. The 33K-beta-/gamma-transducin complex exhibits striking similarity to transducin in its subunit structure and mode of subunit interaction, suggesting it may play an important role in the metabolism and function of rod photoreceptor cells.
Guanosine 3',5'-monophosphate (cyclic GMP) metabolism in developing eye rudiments of Xenopus laevis embryos in culture is disrupted by the phosphodiesterase inhibitor isobutylmethylxanthine. At low concentrations of inhibitor the rudiments develop normally, but at higher concentrations of the inhibitor, cyclic GMP accumulates in the rudiments and the retinal photoreceptor cells degenerate selectively. The isobutylmethylxanthine-induced photoreceptor degeneration is associated with an accumulation of cyclic GMP and, in this respect, it stimulates an early biochemical defect in the inherited degenerative disease of rd mice.
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