Photoreceptors are compartmentalized neurons in which all proteins responsible for evoking visual signals are confined to the outer segment. Yet, the mechanisms responsible for establishing and maintaining photoreceptor compartmentalization are poorly understood. Here we investigated the targeting of two related membrane proteins, R9AP and syntaxin 3, one residing within and the other excluded from the outer segment. Surprisingly, we have found that only syntaxin 3 has targeting information encoded in its sequence and its removal redirects this protein to the outer segment. Furthermore, proteins residing in the endoplasmic reticulum and mitochondria were similarly redirected to the outer segment after removing their targeting signals. This reveals a pattern where membrane proteins lacking specific targeting information are delivered to the outer segment, which is likely to reflect the enormous appetite of this organelle for new material necessitated by its constant renewal. This also implies that every protein residing outside the outer segment must have a means to avoid this “default” trafficking flow.
Mutations in rhodopsin cause retinitis pigmentosa in humans and retinal degeneration in a multitude of other animals. We utilized high-resolution live imaging of the large rod photoreceptors from transgenic frogs (Xenopus) to compare the properties of fluorescently tagged rhodopsin, Rho-EGFP, and RhoP23H-EGFP. The mutant was abnormally distributed both in the inner and outer segments (OS), accumulating in the OS to a concentration of ∼0.1% compared to endogenous opsin. RhoP23H-EGFP formed dense fluorescent foci, with concentrations of mutant protein up to ten times higher than other regions. Wild-type transgenic Rho-EGFP did not concentrate in OS foci when co-expressed in the same rod with RhoP23H-EGFP. Outer segment regions containing fluorescent foci were refractory to fluorescence recovery after photobleaching, while foci in the inner segment exhibited recovery kinetics similar to OS regions without foci and Rho-EGFP. The RhoP23H-EGFP foci were often in older, more distal OS disks. Electron micrographs of OS revealed abnormal disk membranes, with the regular disk bilayers broken into vesiculotubular structures. Furthermore, we observed similar OS disturbances in transgenic mice expressing RhoP23H, suggesting such structures are a general consequence of mutant expression. Together these results show that mutant opsin disrupts OS disks, destabilizing the outer segment possibly via the formation of aggregates. This may render rods susceptible to mechanical injury or compromise OS function, contributing to photoreceptor loss.
The retina is among the most metabolically active tissues in the body, requiring a constant supply of blood glucose to sustain function. We assessed the impact of low blood glucose on the vision of C57BL/6J mice rendered hypoglycemic by a null mutation of the glucagon receptor gene, Gcgr. Metabolic stress from moderate hypoglycemia led to late-onset loss of retinal function in Gcgr ؊/؊ mice, loss of visual acuity, and eventual death of retinal cells. Retinal function measured by the electroretinogram b-wave threshold declined >100-fold from age 9 to 13 months, whereas decreases in photoreceptor function measured by the ERG a-wave were delayed by 3 months. At 10 months of age Gcgr ؊/؊ mice began to lose visual acuity and exhibit changes in retinal anatomy, including an increase in cell death that was initially more pronounced in the inner retina. Decreases in retinal function and visual acuity correlated directly with the degree of hypoglycemia. This work demonstrates a metabolic-stress-induced loss of vision in mammals, which has not been described previously. Linkage between low blood glucose and loss of vision in mice may highlight the importance for glycemic control in diabetics and retinal diseases related to metabolic stress as macular degeneration.C57BL/6J mice ͉ cell death ͉ glucagon receptor gene ͉ retinal function ͉ visual acuity C hanges in metabolism can affect vision. Lowering blood glucose (BG) can decrease human visual sensitivity (1-3) as does reducing the partial pressure of inhaled oxygen (4). Natural nighttime decreases in glucose availability (5, 6) parallel a decline in visual sensitivity that can be restored by glucose ingestion (7). In the cat, acute decreases in glucose supply can transiently reduce retinal sensitivity (8) and exacerbate the effects of hypoxia on the retina (9). The effects of metabolite supply on vision are not surprising in view of the high energy consumption by the retina (10, 11). Although the retina's high metabolic activity has been known for Ͼ40 years (12), the consequences of an inadequate supply of metabolites are not completely understood.We report here that a chronic decrease in BG in mice decreases retinal function, leading to a loss of vision and eventual degeneration of the retina. We observed decreases in both electroretinogram (ERG) a-and b-waves, as well as a loss in visual acuity. Retinal cell death, assayed by TUNEL, was increased in Gcgr Ϫ/Ϫ mice, and decreases in cell number were detected. These data indicate that a chronic decrease in BG leads to loss of vision and cell death in mice and highlight the possibility that the human retina may likewise be susceptible to hypoglycemia. ResultsGlucagon Receptor and Changes in BG. Hypoglycemia was induced in C57BL/6J mice by a null mutation of the glucagon receptor gene, Gcgr (13). Among its actions, the glucagon receptor under control of glucagon regulates gluconeogenesis to increase BG levels. Liver and kidney abundantly express Gcgr, and PCR analysis reveals trace levels of receptor mRNA in the retina of wi...
PDE6 (phosphodiesterase-6) is the effector molecule in the vertebrate phototransduction cascade. Progress in understanding the structure and function of PDE6 has been hindered by lack of an expression system of the enzyme. Here we report ectopic expression and analysis of compartmentalization and membrane dynamics of the enhanced green fluorescent protein (EGFP) fusion protein of human cone PDE6C in rods of transgenic Xenopus laevis. EGFP-PDE6C is correctly targeted to the rod outer segments in transgenic Xenopus, where it displayed a characteristic striated pattern of EGFP fluorescence. Immunofluorescence labeling indicated significant and light-independent co-localization of EGFP-PDE6C with the disc rim marker peripherin-2 and endogenous frog PDE6. The diffusion of EGFP-PDE6C on disc membranes investigated with fluorescence recovery after photobleaching was markedly slower than theoretically predicted. The enzymatic characteristics of immunoprecipitated recombinant PDE6C were similar to known properties of the native bovine PDE6C. PDE6C was potently inhibited by the cone-and rod-specific PDE6 ␥-subunits. Thus, transgenic Xenopus laevis is a unique expression system for PDE6 well suited for analysis of the mechanisms of visual diseases linked to PDE6 mutations.Phosphodiesterases of cyclic nucleotides (PDEs) 2 are essential enzymes controlling cellular levels of cAMP and cGMP. Eleven families of PDEs have been identified in mammals on the grounds of sequence homology, substrate selectivity, and regulation (1). Photoreceptor-specific PDEs in rods and cones comprise the sixth PDE family (PDE6) and serve as the effector enzymes in the vertebrate phototransduction cascade (1-5). Rod PDE6 is composed of homologous catalytic ␣-subunit (PDE6A) and -subunit (PDE6B) and two copies of a small inhibitory ␥-subunit (P␥) (3). Cone PDE6 is a catalytic dimer of two identical ␣Ј-subunits (PDE6C) (3). A cone-specific inhibitory P␥-subunit is highly homologous to the rod P␥ (6). In rod photoreceptors, PDE6 is located in the specialized compartments called rod outer segments (ROS), where it associates with disc membranes. The membrane attachment of PDE6 is mediated by farnesylation of the PDE6A C terminus and geranylgeranylation of the PDE6B C terminus (7). In cones, geranylgeranylated PDE6C resides on infoldings of the cone outer segment plasma membrane (8). Following photoexcitation of rod or cone photoreceptor cells, PDE6 is activated by the GTPbound transducin ␣-subunit (G␣ t GTP) that relieves the P␥ inhibition of the enzyme. cGMP hydrolysis by active PDE6 leads to a cellular response due to a closure of cGMP-gated channels in the photoreceptor plasma membrane (2-5).Although PDE6 plays a prominent role in vertebrate vision, the structure-function relationships of PDE6 are poorly understood in comparison with other key phototransduction proteins. The lack of an expression system for PDE6 has become a major impediment for PDE6 research. Importantly, an expression system for PDE6 is required to elucidate the mechanisms of visua...
G protein–coupled receptor (GPCR) cascades rely on membrane protein diffusion for signaling and are generally found in spatially constrained subcellular microcompartments. How the geometry of these microcompartments impacts cascade activities, however, is not understood, primarily because of the inability of current live cell–imaging technologies to resolve these small structures. Here, we examine the dynamics of the GPCR rhodopsin within discrete signaling microcompartments of live photoreceptors using a novel high resolution approach. Rhodopsin fused to green fluorescent protein variants, either enhanced green fluorescent protein (EGFP) or the photoactivatable PAGFP (Rho-E/PAGFP), was expressed transgenically in Xenopus laevis rod photoreceptors, and the geometries of light signaling microcompartments formed by lamellar disc membranes and their incisure clefts were resolved by confocal imaging. Multiphoton fluorescence relaxation after photoconversion experiments were then performed with a Ti–sapphire laser focused to the diffraction limit, which produced small sub–cubic micrometer volumes of photoconverted molecules within the discrete microcompartments. A model of molecular diffusion was developed that allows the geometry of the particular compartment being examined to be specified. This was used to interpret the experimental results. Using this unique approach, we showed that rhodopsin mobility across the disc surface was highly heterogeneous. The overall relaxation of Rho-PAGFP fluorescence photoactivated within a microcompartment was biphasic, with a fast phase lasting several seconds and a slow phase of variable duration that required up to several minutes to reach equilibrium. Local Rho-EGFP diffusion within defined compartments was monotonic, however, with an effective lateral diffusion coefficient Dlat = 0.130 ± 0.012 µm2s−1. Comparison of rhodopsin-PAGFP relaxation time courses with model predictions revealed that microcompartment geometry alone may explain both fast local rhodopsin diffusion and its slow equilibration across the greater disc membrane. Our approach has for the first time allowed direct examination of GPCR dynamics within a live cell signaling microcompartment and a quantitative assessment of the impact of compartment geometry on GPCR activity.
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