Retinitis pigmentosa (RP) is a type of inherited retinal degenerative disease, which leads to blindness. The primary pathological event of this disease is the death of rods because of genetic mutations. The S334ter-line-3 rat is a transgenic model developed to express a rhodopsin mutation similar to that found in RP. In this study, the rod's death triggered are organization of the cone mosaic into an orderly array of rings. Four observations were relevant to understand this reorganization. First, rods died in hot spots, which progressively increased as circular waves, leaving rod-less zones behind. Second, rings of cones formed around these zones. Third, remodeled Müller glia processes enveloped cones and filled the center of their rings. Zonula occludens-1 located between the photoreceptor inner segments and the apical processes of Müller cells showed in the rings. Fourth, these rings were formed before the onset of cone cell deaths and were maintained until late stages of RP. From these observations,we hypothesize that cone-Müller-cell interactions mediate and maintain the rings. A test of this hypothesis can be performed by injecting DL-a-aminoadipic acid (AAA), which is known to disrupt Müller cell metabolism. A single intravitreal injection of AAA at P50 disrupted the rings of cones 3 days after the injection. These findings indicate that the rearrangement of cones in rings is modulated by Müller cells in RP. Thus, if the relationship between photoreceptors and Müller glia is better understood, the latter could potentially be manipulated for effective neuroprotection or the restoration of normal cone arrays.
We have recently described the surviving cones and Müller-glia process remodeling in retinitis pigmentosa (RP) and shown that rod degeneration triggers the reorganization of the cone mosaic into an orderly array of rings. Within these rings, remodeled Müller-glia processes envelope cones. Here, we report the spatiotemporal pattern of healthy rods, their relationship with dying rods and the way that rod death stimulates the modification of cone spatial-distribution patterns and Müller-glia processes in the S334ter-line-3 rat, a transgenic model expressing a rhodopsin mutation that causes RP. The spatial patterns of rods, cones, microglial and Müller cells were labeled by immunocytochemistry with cell-type-specific markers at various stages of deveopment in rat whole-mount retinas. Spatial patterns of dying cells were examined by TUNEL staining. The S334ter rod mosaic began to develop small holes around postnatal day 10. These hot-spots of cell death progressively increased in size, leaving larger rod-less holes behind. The holes were temporarily occupied by active microglial cells, before being replaced by remodeled Müller-cell processes. Our data suggest that the hot spots of rod death create holes in the rod mosaic early in retinal degeneration and that the resulting pattern triggers the modification of the spatial-distribution patterns of cones and glia cells.
In retinitis pigmentosa (RP), the death of cones normally follows some time after the degeneration of rods. Recently, surviving cones in RP have been studied and reported in detail. These cones undergo extensive remodeling in their morphology. Here we report an extension of the remodeling study to consider possible modifications of spatial-distribution patterns. For this purpose we used S334ter-line-3 transgenic rats, a transgenic model developed to express a rhodopsin mutation causing RP. In this study, retinas were collected at postnatal (P) days P5–30, 90, 180, and P600. We then immunostained the retinas to examine the morphology and distribution of cones and to quantify the total cone numbers. Our results indicate that cones undergo extensive changes in their spatial distribution to give rise to a mosaic comprising an orderly array of rings. These rings first begin to appear at P15 at random regions of the retina and become ubiquitous throughout the entire tissue by P90. Such distribution pattern loses its clarity by P180 and mostly disappears at P600, at which time the cones are almost all dead. In contrast, the numbers of cones in RP and normal conditions do not show significant differences at stages as late as P180. Therefore, rings do not form by cell death at their centers, but by cone migration. We discuss its possible mechanisms and suggest a role for hot spots of rod death and the remodeling of Müller cell process into zones of low density of photoreceptors.
The Sex-lethal (Sxl) early transcripts have a unique 5 exon and a splicing pattern that differs from that of the late transcripts. While the late transcripts are regulated sex specifically by control of exon 3 inclusion, the early transcripts are not. While the late transcripts include exon 3 by default, the early transcripts skip exon 3. Splicing patterns of a reporter gene that mimics the early transcript, and its variants, were analyzed in Drosophila transformants and tissue culture cells. The results demonstrate that the early, in contrast to the late, splicing pattern is not regulated by stage-specific or sex-specific trans-acting factors, and so the pattern appears to arise from some type of intrinsic splice site preference or compatibility. Inclusion or exclusion of exon 3 is determined by the identity of the upstream 5 splice site region as late or early. The important region of the early exon lies within 233 nucleotides of the immediately adjacent intron.Splicing reactions remove intron sequences from premRNA and join exons together with exquisite precision. These reactions are carried out within the spliceosome, using several snRNA molecules and many associated proteins. Accuracy in splicing requires that the appropriate pre-mRNA splice sites, which may be separated by vast distances, be recognized and distinguished from among many closely related sequences. Three minimum sequence elements have been identified (33)(34)(35). At the 5Ј splice site, there is a short consensus sequence that is complementary to sequences of U1 snRNA; the branch point sequence is recognized by U2 snRNA; at the 3Ј splice site, the last two nucleotides of the intron are invariantly AG (31). In addition, in higher eukaryotic cells, a polypyrimidine tract is usually located between the branch point and 3Ј splice site; it is bound by the protein U2AF, which enhances the binding of U2 snRNA to the branch point (56, 57). To some degree, the likelihood of choosing a particular splice site correlates with how closely it matches the consensus sequence. Nevertheless, these limited sequence requirements are not sufficient to explain the accuracy observed in splice site selection, as sequences matching the consensus are often found unused within introns. Additional features have also been identified as important for selection of the correct pair of 5Ј and 3Ј splice sites (5).Sequence context beyond the splice sites and branch point can influence splice site selection and splicing efficiency. For example, exon sequences have been known for some time to influence splice site selection, and several exonic purine-rich splicing enhancers have recently been characterized (12,24,28,47,53,54). Some of these enhancers have been shown to be bound by members of the SR family of proteins, which as a class appear to be involved in joining 5Ј and 3Ј splice sites across exons as well as introns (14). While SR proteins are essential for splicing in general, they can also differentially influence the choice of splice sites in a concentration-dependent ma...
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