The inhibitory interaction of phosphodiesterase-6 (PDE6) with its c-subunit (Pc) is pivotal in vertebrate phototransduction. Here, crystal structures of a chimaeric PDE5/ PDE6 catalytic domain (PDE5/6cd) complexed with sildenafil or 3-isobutyl-1-methylxanthine and the Pc-inhibitory peptide Pc 70À87 have been determined at 2.9 and 3.0 Å , respectively. These structures show the determinants and the mechanism of the PDE6 inhibition by Pc and suggest the conformational change of Pc on transducin activation. Two variable H-and M-loops of PDE5/6cd form a distinct interface that contributes to the Pc-binding site. This allows the Pc C-terminus to fit into the opening of the catalytic pocket, blocking cGMP access to the active site. Our analysis suggests that disruption of the H-M loop interface and Pc-binding site is a molecular cause of retinal degeneration in atrd3 mice. Comparison of the two PDE5/6cd structures shows an overlap between the sildenafil and Pc 70À87 -binding sites, thereby providing critical insights into the side effects of PDE5 inhibitors on vision.
Aryl Hydrocarbon Receptor-interacting Protein-like 1 Is an Obligate Chaperone of Phosphodiesterase 6 and Is Assisted by the γ-Subunit of Its Client
Phosphodiesterase 6 (PDE6) is the effector enzyme in the phototransduction cascade and is critical for the health of both rod and cone photoreceptors. Its dysfunction, caused by mutations in either the enzyme itself or AIPL1 (aryl hydrocarbon receptor-interacting protein-like 1), leads to retinal diseases culminating in blindness. Progress in research on PDE6 and AIPL1 has been severely hampered by failure to express functional PDE6 in a heterologous expression system. Here, we demonstrated that AIPL1 is an obligate chaperone of PDE6 and that it enables low yield functional folding of cone PDE6C in cultured cells. We further show that the AIPL1-mediated production of folded PDE6C is markedly elevated in the presence of the inhibitory P␥-subunit of PDE6. As illustrated in this study, a simple and sensitive system in which AIPL1 and P␥ are co-expressed with PDE6 represents an effective tool for probing structure-function relationships of AIPL1 and reliably establishing the pathogenicity of its variants.Cyclic nucleotide phosphodiesterases of the sixth family (PDE6) 2 are the key effectors in the visual transduction cascade in rod and cone photoreceptors. In the dark, activity of the PDE6 catalytic dimers is restrained by two tightly bound inhibitory ␥-subunits (P␥). This allows cGMP to maintain depolarizing "dark" current through a cGMP-gated channel in the photoreceptor plasma membrane. Photoexcitation leads to G-protein-mediated activation of PDE6 followed by a drop in cytoplasmic cGMP, channel closure, and propagation of an electrical signal to downstream retinal neurons (1, 2). In addition to being essential to photoreceptor physiology, PDE6 is critical to the health and survival of rods and cones. Malfunctions caused by mutations in genes that encode either PDE6 or its putative chaperone, aryl hydrocarbon receptor-interacting protein-like 1 (AIPL1), lead to severe blinding retinal diseases.Mutations in the PDE6A, PDE6B, and PDE6G genes, which encode the catalytic PDE6AB subunits and P␥ of rod PDE6, respectively, are responsible for a significant proportion of cases of recessive retinitis pigmentosa (3-5) and can also lead to autosomal dominant congenital stationary night blindness (6). Mutations in their cone counterparts, PDE6C and PDE6H, cause autosomal recessive achromatopsia (7-10).PDE6 deficiency also appears to underlie one of the most severe forms of Leber congenital amaurosis (LCA type 4), a condition caused by mutations in the AIPL1 gene (11,12). LCA is an early onset inherited retinopathy and one of the main causes of blindness in children (13). The link between PDE6 and AIPL1 was discovered in studies of AIPL1 knock-out and knockdown mouse models, which revealed rapid severe retinal degeneration and a marked reduction in PDE6 protein levels and activity prior to the loss of photoreceptor cells (14, 15). Thus, the animal models recapitulated the hallmarks of LCA and suggested that AIPL1 is a potential chaperone of PDE6. This notion is consistent with the fact that AIPL1 contains an FK506-binding pro...
Inherited retinal degenerations are a common cause of untreatable blindness worldwide, with retinitis pigmentosa and cone dystrophy affecting approximately 1 in 3500 and 1 in 10,000 individuals, respectively. A major limitation to the development of effective therapies is the lack of availability of animal models that fully replicate the human condition. Particularly for cone disorders, rodent, canine, and feline models with no true macula have substantive limitations. By contrast, the cone-rich macula of a nonhuman primate (NHP) closely mirrors that of the human retina. Consequently, well-defined NHP models of heritable retinal diseases, particularly cone disorders that are predictive of human conditions, are necessary to more efficiently advance new therapies for patients. We have identified 4 related NHPs at the California National Primate Research Center with visual impairment and findings from clinical ophthalmic examination, advanced retinal imaging, and electrophysiology consistent with achromatopsia. Genetic sequencing confirmed a homozygous R565Q missense mutation in the catalytic domain of PDE6C, a cone-specific phototransduction enzyme associated with achromatopsia in humans. Biochemical studies demonstrate that the mutant mRNA is translated into a stable protein that displays normal cellular localization but is unable to hydrolyze cyclic GMP (cGMP). This NHP model of a cone disorder will not only serve as a therapeutic testing ground for achromatopsia gene replacement, but also for optimization of gene editing in the macula and of cone cell replacement in general.
Phosphodiesterase-6 (PDE6) is the key effector enzyme of the phototransduction cascade in rods and cones. The catalytic core of rod PDE6 is a unique heterodimer of PDE6A and PDE6B catalytic subunits. The functional significance of rod PDE6 heterodimerization and conserved differences between PDE6AB and cone PDE6C and the individual properties of PDE6A and PDE6B are unknown. To address these outstanding questions, we expressed chimeric homodimeric enzymes, enhanced GFP (EGFP)-PDE6C-A and EGFP-PDE6C-B, containing the PDE6A and PDE6B catalytic domains, respectively, in transgenic Xenopus laevis. Similar to EGFP-PDE6C, EGFP-PDE6C-A and EGFP-PDE6C-B were targeted to the rod outer segments and concentrated at the disc rims. PDE6C, PDE6C-A, and PDE6C-B were isolated following selective immunoprecipitation of the EGFP fusion proteins. All three enzymes, PDE6C, PDE6C-A, and PDE6C-B, hydrolyzed cGMP with similar K m (20 -23 M) and k cat (4200 -5100 s ؊1 ) values. Likewise, the K i values for PDE6C, PDE6C-A, and PDE6C-B inhibition by the cone-and rod-specific PDE6 ␥-subunits (P␥) were comparable. Recombinant cone transducin-␣ (G␣ t2 ) and native rod G␣ t1 fully and potently activated PDE6C, PDE6C-A, and PDE6C-B. In contrast, the half-maximal activation of bovine rod PDE6 required markedly higher concentrations of G␣ t2 or G␣ t1 . Our results suggest that PDE6A and PDE6B are enzymatically equivalent. Furthermore, PDE6A and PDE6B are similar to PDE6C with respect to catalytic properties and the interaction with P␥ but differ in the interaction with transducin. This study significantly limits the range of mechanisms by which conserved differences between PDE6A, PDE6B, and PDE6C may contribute to remarkable differences in rod and cone physiology.Vertebrates rely on two types of photoreceptor cells, rods and cones, for vision. The phototransduction cascades in rods and cones are principally similar. The central components of the rod and cone signaling pathways, visual pigments, transducins (G t ), and retinal cGMP-phosphodiesterases (PDE6) 2 are distinct but highly homologous proteins (1-3). In contrast, the physiology of rods and cones is strikingly different. Rods are exceptionally sensitive to light and provide for nighttime (scotopic) vision, whereas cones are markedly less sensitive and signal during daytime (photopic receptors). Cone electrical responses to light are smaller in amplitude and much faster than rod responses. Furthermore, cones adapt to a much broader range of illumination conditions than rods and can function in intensely bright light (1-3). The molecular origin(s) of the differences in physiology of rods and cones is one of the key unresolved questions of vertebrate phototransduction (3). The physiological differences may be due to sequence and concentration differences between signaling proteins in rods and cones, as well as to characteristic photoreceptor morphologies of rods and cones (3, 4).Sequence differences in rod and cone transduction components are limited, but well conserved, among vertebrate sp...
Transducin translocation contributes to rod survival and enhances synaptic transmission from rods to rod bipolar cells
In rod photoreceptors, several phototransduction components display light-dependent translocation between cellular compartments. Notably, the G protein transducin translocates from rod outer segments to inner segments/spherules in bright light, but the functional consequences of translocation remain unclear. We generated transgenic mice where light-induced transducin translocation is impaired. These mice exhibited slow photoreceptor degeneration, which was prevented if they were dark-reared. Physiological recordings showed that control and transgenic rods and rod bipolar cells displayed similar sensitivity in darkness. After bright light exposure, control rods were more strongly desensitized than transgenic rods. However, in rod bipolar cells, this effect was reversed; transgenic rod bipolar cells were more strongly desensitized than control. This sensitivity reversal indicates that transducin translocation in rods enhances signaling to rod bipolar cells. The enhancement could not be explained by modulation of inner segment conductances or the voltage sensitivity of the synaptic Ca 2+ current, suggesting interactions of transducin with the synaptic machinery.retina | adaptation | presynaptic modulation | SNARE complex | palmitoylation
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...
Photoreceptor rod and cone phosphodiesterases comprise the sixth family of cyclic nucleotide phosphodiesterases (PDE6). PDE6s have uniquely evolved as effector enzymes in the vertebrate phototransduction cascade. To understand the evolution of the PDE6 family, we have examined PDE6 in lamprey, an ancient vertebrate group. A single PDE6 catalytic subunit transcript was found in the sea lamprey Petromyzon marinus cDNA library. The lamprey PDE6 sequence showed a high degree of homology with mammalian PDE6 and equally distant relationships with the rod and cone enzymes. In contrast, two different PDE6 inhibitory Pgamma subunits, a cone-type Pgamma1 and a mixed cone/rod-type Pgamma2, have been identified in the lamprey retina. Immunofluorescence analysis demonstrated that Pgamma1 and Pgamma2 are expressed in the long and short photoreceptors of sea lamprey, respectively. The catalytic PDE6 subunit was present in the photoreceptors of both types and colocalized with the Pgamma subunits. Recombinant Pgamma1 and Pgamma2 potently inhibited trypsin-activated lamprey and bovine PDE6 enzymes. Our results point to a high degree of conservation of PDE6 genes during the vertebrate evolution. The apparent duplication of the Pgamma gene in the stem of vertebrate lineage may have been an essential component of the evolution of scotopic vision in early vertebrates.
cGMP-phosphodiesterases of the PDE6 family are expressed in retinal photoreceptor cells, where they mediate the phototransduction cascade. A system for expression of PDE6 in vitro is lacking, thus straining progress in understanding the structure-function relationships of the photoreceptor enzyme. Here, we report generation and characterization of bacterially expressed chimeric PDE5/6 catalytic domains which are highly soluble, catalytically active, and sensitive to inhibition by the PDE6 Pgamma subunit. Two flexible PDE6 loops, H and M, impart chimeric PDE5/6 catalytic domains with PDE6-like properties. The replacement of the PDE6 H-loop into the PDE5 catalytic domain increases the catalytic rate and the K(m) value for cGMP hydrolysis, whereas the substitution of the M-loop produces catalytic PDE domains responsive to Pgamma. Multiple PDE6 segments preventing functional expression of the catalytic domain are identified, supporting the requirement for specialized photoreceptor chaperones to assist PDE6 folding in vivo.
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