Retinal degeneration-3 protein attenuates photoreceptor degeneration in transgenic mice expressing dominant mutation of human retinal guanylyl cyclase

Retinal degeneration protein 3 mutants are associated with cell-cycle arrest and apoptosis

Retinal degeneration protein 3 (RD3) plays a crucial role in controlling guanylate cyclase activity in photoreceptor rod and cone cells, and mediates trafficking processes within photoreceptor cells. Loss of RD3 function correlates with severe forms of retinal dystrophy and the development of aggressive neuroblastoma cancer. In the present study, we analyzed RD3 expression in glioblastoma in comparison to non-tumor tissue using public databases and qRT-PCR. We found that RD3 is downregulated in glioblastoma compared to non-tumor tissues. To better understand the cellular function of RD3 in the context of tumor development, we performed first functional cell culture studies to clarify a possible involvement of RD3 in cell survival and the cell cycle. Interestingly, RD3 overexpression significantly decreased cell viability, which subsequently led to cell-cycle arrest at the G2/M phase and induced cell apoptosis. Conversely, single-point mutations in RD3 at the exposed protein surface involved in RD3-target interaction diminished the impact of RD3. Therefore, a controlled RD3 expression level seems to be important for a balance of cell death and cell survival rate. These new functional mechanisms of RD3 expression could help in understanding tumor development and growth.

Phosphodiesterase 5 expression in photoreceptors rescues retinal degeneration induced by deregulation of membrane guanylyl cyclase

Mutations in retinal membrane guanylyl cyclase 1 (RetGC1) and its calcium-sensor protein (guanylyl cyclase activating protein 1, GCAP1) cause congenital dominant retinopathies by elevation of cGMP synthesis in photoreceptors in the dark. We explored counteracting the elevated cGMP synthesis causing photoreceptor degeneration using ectopic expression of a nonphotoreceptor cGMP phosphodiesterase (PDE) isozyme PDE5. PDE5 primary structure was modified to direct the delivery of the recombinant PDE5 (PDE5r) to rod outer segments, by placing a C-terminal fragment derived from a cone-specific alpha-subunit of PDE6C at the C terminus of the PDE5, which allowed PDE5r expressed under control of mouse rod opsin promoter to accumulate in rod outer segments. Expression of PDE5r did not affect calcium-sensitivity of RetGC regulation in PDE5rTg transgenic retinas, but increased cGMP hydrolysis in the dark, which partially desensitized PDR5rTg rods in the dark via an "equivalent light" effect, analogous to exposure to a constant dim light of ∼20 to 40 photons μm-2 sec-1. The calcium-sensitivity of RetGC regulation remained drastically shifted outside the normal physiological range in hybrid R838STgPDE5rTg rods expressing both PDE5r and R838S RetGC1, the mutant causing GUCY2D dominant retinopathy, but the hybrid rods demonstrated a dramatic rescue from degeneration caused by the R838S RetGC1. In a similar fashion, PDE5r expression rescued degeneration of rods harboring Y99C GCAP1, one of the GCAP1 mutants most frequently causing GUCA1A dominant retinopathy. Our results open a possibility that ectopic expression of PDE5 can be used as an approach to rescue presently incurable dominant GUCY2D and GUCA1A retinopathies at the expense of a moderate reduction in rod light-sensitivity.

Clinical, Genetic, Imaging and Electrophysiological Findings in a Cohort of Patients With GUCA1A-Associated Retinopathy

Purpose

To report findings in GUCA1A-associated retinopathy, a rare autosomal-dominant retinopathy.

Methods

Clinical features and investigations from molecularly confirmed patients at a large referral center were analyzed (retrospective cohort study).

Results

Nineteen patients (14 families), with five different variants, were included: p.(Tyr99Cys) in 10 families and p.(Leu84Phe), p.(Ile107Thr), p.(Glu111Ala), and p.(leu176Phe) in 1 family each. Mean (SD) ages at first and last visits were 38 (17) and 48 (15) years, respectively. Mean (SD) logMAR visual acuities at the first and last visits were 0.67 (0.61) and 0.94 (0.58) for right eyes and 0.63 (0.63) and 0.95 (0.74) for left eyes. Acuities ranged from 0.00 logMAR to no light perception. Most described progressive problems with central and color vision. Across 144 patient visits, logMAR acuity correlated with age (Spearman coefficients of 0.43 and 0.54 for right and left eyes, P < 0.001), with a high interocular correlation (coefficient 0.90, P < 0.001). Optical coherence tomography showed irregularity and then loss of the central ellipsoid zone. Ultra-widefield imaging showed peripheral degeneration in some patients. Electrophysiology (n = 13) was consistent with cone dystrophy (n = 11) or macular dystrophy (n = 2). Compared with the common p.(Tyr99Cys) variant, patients with p.(Glu111Ala) (n = 2) had worse vision; those with p.(Leu84Phe) (n = 3) were younger with earlier-onset visual loss. Patients with p.(Ile107Thr) (n = 2) showed later presentation, with milder acuity reduction.

Conclusions

We present genotypic and phenotypic findings from the largest cohort with GUCA1A retinopathy. Most had progressive visual loss and electrophysiologic evidence of cone dystrophy. Possible genotype-phenotype correlations emerged, but subgroups were small for four of five variants.

Dysregulated Arginine Metabolism Is Linked to Retinal Degeneration in Cep250 Knockout Mice

Purpose

Degeneration of retinal photoreceptors is frequently observed in diverse ciliopathy disorders, and photoreceptor cilium gates the molecular trafficking between the inner and the outer segment (OS). This study aims to generate a homozygous global Cep250 knockout (KO) mouse and study the resulting phenotype.

Methods

We used Cep250 KO mice and untargeted metabolomics to uncover potential mechanisms underlying retinal degeneration. Long-term follow-up studies using optical coherence tomography (OCT) and electroretinography (ERG) were performed.

Results

OCT and ERG results demonstrated gradual thinning of the outer nuclear layer (ONL) and progressive attenuation of the scotopic ERG responses in Cep250-/- mice. More TUNEL signal was observed in the ONL of these mice. Immunostaining of selected OS proteins revealed mislocalization of these proteins in the ONL of Cep250-/- mice. Interestingly, untargeted metabolomics analysis revealed arginine-related metabolic pathways were altered and enriched in Cep250-/- mice. Mis-localization of a key protein in the arginine metabolism pathway, arginase 1 (ARG1), in the ONL of KO mice further supports this model. Moreover, adeno-associated virus (AAV)-based retinal knockdown of Arg1 led to similar architectural and functional alterations in wild-type retinas.

Conclusions

Altogether, these results suggest that dysregulated arginine metabolism contributes to retinal degeneration in Cep250-/- mice. Our findings provide novel insights that increase understanding of retinal degeneration in ciliopathy disorders.

cGMP Signaling in Photoreceptor Degeneration

Photoreceptors in the retina are highly specialized neurons with photosensitive molecules in the outer segment that transform light into chemical and electrical signals, and these signals are ultimately relayed to the visual cortex in the brain to form vision. Photoreceptors are composed of rods and cones. Rods are responsible for dim light vision, whereas cones are responsible for bright light, color vision, and visual acuity. Photoreceptors undergo progressive degeneration over time in many hereditary and age-related retinal diseases. Despite the remarkable heterogeneity of disease-causing genes, environmental factors, and pathogenesis, the progressive death of rod and cone photoreceptors ultimately leads to loss of vision/blindness. There are currently no treatments available for retinal degeneration. Cyclic guanosine 3', 5'-monophosphate (cGMP) plays a pivotal role in phototransduction. cGMP governs the cyclic nucleotide-gated (CNG) channels on the plasma membrane of the photoreceptor outer segments, thereby regulating membrane potential and signal transmission. By gating the CNG channels, cGMP regulates cellular Ca2+ homeostasis and signal transduction. As a second messenger, cGMP activates the cGMP-dependent protein kinase G (PKG), which regulates numerous targets/cellular events. The dysregulation of cGMP signaling is observed in varieties of photoreceptor/retinal degenerative diseases. Abnormally elevated cGMP signaling interferes with various cellular events, which ultimately leads to photoreceptor degeneration. In line with this, strategies to reduce cellular cGMP signaling result in photoreceptor protection in mouse models of retinal degeneration. The potential mechanisms underlying cGMP signaling-induced photoreceptor degeneration involve the activation of PKG and impaired Ca2+ homeostasis/Ca2+ overload, resulting from overactivation of the CNG channels, as well as the subsequent activation of the downstream cellular stress/death pathways. Thus, targeting the cellular cGMP/PKG signaling and the Ca2+-regulating pathways represents a significant strategy for photoreceptor protection in retinal degenerative diseases.

Retinal degeneration protein 3 controls membrane guanylate cyclase activities in brain tissue

The retinal degeneration protein RD3 is involved in regulatory processes of photoreceptor cells. Among its main functions is the inhibition of photoreceptor specific membrane guanylate cyclases during trafficking from the inner segment to their final destination in the outer segment. However, any physiological role of RD3 in non-retinal tissue is unsolved at present and specific protein targets outside of retinal tissue have not been identified so far. The family of membrane bound guanylate cyclases share a high homology of their amino acid sequences in their cytoplasmic domains. Therefore, we reasoned that membrane guanylate cyclases that are activated by natriuretic peptides are also regulated by RD3. We analyzed transcript levels of the rd3 gene and natriuretic peptide receptor genes Npr1 and Npr2 in the mouse retina, cerebellum, hippocampus, neocortex, and the olfactory bulb during development from the embryonic to the postnatal stage at P60. The rd3 gene showed a lower expression level than Npr1 and Npr2 (encoding for GC-A and GC-B, respectively) in all tested brain tissues, but was at least one order of magnitude higher in the retina. RD3 and natriuretic peptide receptor GCs co-express in the retina and brain tissue leading to functional tests. We expressed GC-A and GC-B in HEK293T cells and measured the inhibition of GCs by RD3 after activation by natriuretic peptides yielding inhibitory constants around 25 nM. Furthermore, endogenous GCs in astrocytes were inhibited by RD3 to a similar extent. We here show for the first time that RD3 can inhibit two hormone-stimulated GCs, namely GC-A and GC-B indicating a new regulatory feature of these hormone receptors.

Structural basis of retinal membrane guanylate cyclase regulation by GCAP1 and RD3

Retinal membrane guanylate cyclases (RetGC1 and RetGC2) are expressed in photoreceptor rod and cone cells, where they promote the onset of visual recovery during phototransduction. The catalytic activity of RetGCs is regulated by their binding to regulatory proteins, guanylate cyclase activating proteins (GCAP1-5) and the retinal degeneration 3 protein (RD3). RetGC1 is activated by its binding to Ca2+-free/Mg2+-bound GCAP1 at low cytosolic Ca2+ levels in light-activated photoreceptors. By contrast, RetGC1 is inactivated by its binding to Ca2+-bound GCAP1 and/or RD3 at elevated Ca2+ levels in dark-adapted photoreceptors. The Ca2+ sensitive cyclase activation helps to replenish the cytosolic cGMP levels in photoreceptors during visual recovery. Mutations in RetGC1, GCAP1 or RD3 that disable the Ca2+-dependent regulation of cyclase activity are genetically linked to rod/cone dystrophies and other inherited forms of blindness. Here I review the structural interaction of RetGC1 with GCAP1 and RD3. I propose a two-state concerted model in which the dimeric RetGC1 allosterically switches between active and inactive conformational states with distinct quaternary structures that are oppositely stabilized by the binding of GCAP1 and RD3. The binding of Ca2+-free/Mg2+-bound GCAP1 is proposed to activate the cyclase by stabilizing RetGC1 in an active conformation (R-state), whereas Ca2+-bound GCAP1 and/or RD3 inhibit the cyclase by locking RetGC1 in an inactive conformation (T-state). Exposed hydrophobic residues in GCAP1 (residues H19, Y22, M26, F73, V77, W94) are essential for cyclase activation and could be targeted by rational drug design for the possible treatment of rod/cone dystrophies.