The early loss of photoreceptors in some retinal degenerations in mice has been shown to have a profound effect on vascular development of the retina. To better characterize this relationship, we have examined the formation of retinal blood vessels during the first month of life in 8 lines of transgenic rats with different ages of onset and rates of photoreceptor cell loss mediated by the expression of mutant rhodopsin (P23H and S334ter). The number of capillary profiles in the superficial plexus (SP) and deep capillary plexus (DCP) of the retina were quantified in retinal sections taken at postnatal day (P) 8, 10, 12, 15 and 30. In normal wild-type rats, the SP and DCP had mostly established mature, adult patterns by P15, as previously shown. In the transgenic rats, the loss of photoreceptors had relatively little effect on the SP. By contrast, the loss of photoreceptors during vascular development had a major impact on the DCP. In the two lines with early and most rapid photoreceptor loss, S334ter-7 and S334ter-3, where about 90% and 65%, respectively, of the photoreceptors were already lost by P15, the DCP either failed to form (S334ter-7) or the number of capillary profiles was less than 7% of controls (S334ter-3). In lines where almost all photoreceptors were still present at P15 (S334ter-4, S334ter-9, P23H-2 and P23H-3), the number of profiles in the DCP were the same as in wild-type controls at P30. In two lines with an intermediate rate of degeneration (S334ter-5 and P23H-1), where only about 25% of the photoreceptors were lost by P15, there was an intermediate number of vascular profiles in the DCP at P30. Thus, a very close relationship between the number of photoreceptors and vessel profiles in the DCP during its development exists in the transgenic rats, and the loss of photoreceptors results in the failure or inhibition of the DCP to develop. Several mechanisms may explain this relationship including changes in the level of physiological oxygen tension or alteration in the release of angiogenic factors that normally drive vessel development. Analysis of older transgenic retinas up to 1 year of age revealed that (1) vascular profiles are lost from the DCP in essentially all lines once fewer than about 30-33% of photoreceptors remain; (2) in those lines where the DCP essentially did not develop (S334ter-7 and S334ter-3), the effect of photoreceptor absence was permanent, and there was no late vascularization of the DCP; (3) the number of capillary profiles in the SP remained no different from controls in any of the lines, despite long-standing loss of photoreceptors; and (4) neovascularization of the RPE by retinal capillaries occurred with a latency of 60-180 days after the loss of photoreceptors, except in S334ter-7 rats, where neovascularization essentially did not occur. Analysis of RCS rats was carried out for comparison.

The S334ter rhodopsin (Rho) rat (line 4) bears the rhodopsin gene with an early termination codon at residue 334 that is a model for several such mutations found in human patients with autosomal dominant retinitis pigmentosa (ADRP). The Unfolded Protein Response (UPR) is implicated in the pathophysiology of several retinal disorders including ADRP in P23H Rho rats. The aim of this study was to examine the onset of UPR gene expression in S334ter Rho retinas to determine if UPR is activated in ADRP animal models and to investigate how the activation of UPR molecules leads to the final demise of S334ter Rho photoreceptors. RT-PCR was performed to evaluate the gene expression profiles for the P10, P12, P15, and P21 stages of the development and progression of ADRP in S334ter Rho photoreceptors. We determined that during the P12-P15 period, ER stress-related genes are strongly upregulated in transgenic retinas, resulting in the activation of the UPR that was confirmed using western blot analysis and RT-PCR. The activation of UPR was associated with the increased expression of JNK, Bik, Bim, Bid, Noxa, and Puma genes and cleavage of caspase-12 that together with activated calpains presumably compromise the integrity of the mitochondrial MPTP, leading to the release of pro-apoptotic AIF1 into the cytosol of S334ter Rho photoreceptor cells. Therefore, two major cross-talking pathways, the UPR and mitochondrial MPTP occur in S334ter-4 Rho retina concomitantly and eventually promote the death of the photoreceptor cells.

The aim of this study was to examine the temporal relationship between behaviorally measured visual thresholds, photoreceptor degeneration and dysfunction, synaptic and neuronal morphology changes in the retina in the S334ter line 4 rat. Specifically, we examined the optokinetic tracking (OKT) behavior in S334ter rats daily and found that OKT thresholds reflected normal values at eye opening but quickly reduced to a non-response level by postnatal day (P) 22. By contrast, the scotopic electroretinogram (ERG) showed a much slower degeneration, with substantial scotopic function remaining after P90 as previously demonstrated for this line of rats. Photopic b-wave amplitudes revealed functional levels between 70 and 100% of normal between P30 and P90. Histological evidence demonstrated that photoreceptor degeneration occurred over many months, with an outer nuclear layer (ONL) roughly half the thickness of a normal age-matched control at P90. Immunohistochemical analysis revealed a number of changes in retinal morphology in the Tg S334ter line 4 rat that occur at or before P40 including: elevated levels of rod opsin expression in the ONL, cone photoreceptor morphology changes, glial cell activation, inner retinal neuron sprouting, and microglial cell activation. Many of these changes were evident at P30 and in some cases as early as eye opening (P15). Thus, the morphological changes occurred in concert with or before the very rapid loss of the behavioral (OKT) responses, and significantly before the loss of photoreceptors and photoreceptor function.

Endoplasmic reticulum (ER) protein misfolding activates the unfolded protein response (UPR) to help cells cope with ER stress. If ER homeostasis is not restored, UPR promotes cell death. The mechanisms of UPR-mediated cell death are poorly understood. The PKR-like endoplasmic reticulum kinase (PERK) arm of the UPR is implicated in ER stress-induced cell death, in part through up-regulation of proapoptotic CCAAT/enhancer binding protein homologous protein (CHOP). Chop((-)/(-)) cells are partially resistant to ER stress-induced cell death, and CHOP overexpression alone does not induce cell death. These findings suggest that additional mechanisms regulate cell death downstream of PERK. Here we find dramatic suppression of antiapoptosis XIAP proteins in response to chronic ER stress. We find that PERK down-regulates XIAP synthesis through eIF2α and promotes XIAP degradation through ATF4. Of interest, PERK's down-regulation of XIAP occurs independently of CHOP activity. Loss of XIAP leads to increased cell death, whereas XIAP overexpression significantly enhances resistance to ER stress-induced cell death, even in the absence of CHOP. Our findings define a novel signaling circuit between PERK and XIAP that operates in parallel with PERK to CHOP induction to influence cell survival during ER stress. We propose a "two-hit" model of ER stress-induced cell death involving concomitant CHOP up-regulation and XIAP down-regulation both induced by PERK.