Jacqueline C. Tanaka scite author profile

The successful restoration of visual function with recombinant adeno-associated virus (rAAV)-mediated gene replacement therapy in animals and humans with an inherited disease of the retinal pigment epithelium has ushered in a new era of retinal therapeutics. For many retinal disorders, however, targeting of therapeutic vectors to mutant rods and/or cones will be required. In this study, the primary cone photoreceptor disorder achromatopsia served as the ideal translational model to develop gene therapy directed to cone photoreceptors. We demonstrate that rAAV-mediated gene replacement therapy with different forms of the human red cone opsin promoter led to the restoration of cone function and day vision in two canine models of CNGB3 achromatopsia, a neuronal channelopathy that is the most common form of achromatopsia in man. The robustness and stability of the observed treatment effect was mutation independent, but promoter and age dependent. Subretinal administration of rAAV5-hCNGB3 with a long version of the red cone opsin promoter in younger animals led to a stable therapeutic effect for at least 33 months. Our results hold promise for future clinical trials of cone-directed gene therapy in achromatopsia and other cone-specific disorders.

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Photoreceptor channel activation by nucleotide derivatives

Tanaka¹,

Eccleston²,

Furman³

1989

Biochemistry

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Cyclic nucleotide activated sodium currents were recorded from photoreceptor outer segment membrane patches. The concentration of cGMP and structurally similar nucleotide derivatives was varied at the cytoplasmic membrane face; currents were generated at each concentration by the application of a voltage ramp. Nucleotide-activated currents were analyzed as a function of both concentration and membrane potential. For cGMP, the average K0.5 at 0 mV was 24 microM, and the activation was cooperative with an average Hill coefficient of 2.3. Of the nucleotide derivatives examined, only 8-[[(fluorescein-5-yl-carbamoyl)methyl]thio]-cGMP (8-Fl-cGMP) activated the channel at lower concentrations than cGMP with a K0.5 of 0.85 microM. The next most active derivative was 2-amino-6-mercaptopurine riboside 3',5'-monophosphate (6-SH-cGMP) which had a K0.5 of 81 microM. cIMP and cAMP had very high K0.5 values of approximately 1.2 mM and greater than 1.5 mM, respectively. All nucleotides displayed cooperativity in their response and were rapidly reversible. Maximal current for each derivative was compared to the current produced at 200 microM cGMP; only 8-Fl-cGMP produced an identical current. The partial agonists 6-SH-cGMP, cIMP, and cAMP activated currents which were approximately 90%, 80%, and 25% of the cGMP response, respectively. 5'-GMP, 2-aminopurine riboside 3',5'-monophosphate, and 2'-deoxy-cGMP produced no detectable current. The K0.5 values for cGMP activation, examined from -90 to +90 mV, displayed a weak voltage dependence of approximately 400 mV/e-fold; the index of cooperativity was independent of the applied field.(ABSTRACT TRUNCATED AT 250 WORDS)

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Monovalent selectivity of the cyclic guanosine monophosphate-activated ion channel.

Furman

Tanaka

1990

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Monovalent cation selectivity has been characterized for the 3',5'-cyclic guanosine monophosphate (cGMP)-activated channel in vertebrate photoreceptor outer segment plasma membranes without divalent cations. Macroscopic currents in excised, inside-out patches were activated with saturating concentrations of cGMP (200/zM). Using a bi-ionic protocol with symmetrical 120 mM ion concentrations across the membrane, alkali metal ions and certain organic cations were substituted for sodium on the cytoplasmic face. The relative permeabilities, determined from shifts in the reversal potential (Er~), were NH 4 >> Na > guanidinium > K > Li > Rb > Cs (3.34 : 1.0 : 0.97 : 0.93 : 0.92 : 0.74 : 0.50, respectively). Er~'S were also measured as a function of [Na], [NH4], and [Cs], and the slope of the relation was -59.8, -52.1, and -49.1 mV/decade, respectively. The slopes for NH4 and Cs differ significantly from the Nernst-Planck prediction of -58.2 mV/decade expected for a single ion channel. Relative permeabilities were also determined for the alkali metal series of ions with 20 mM ionic concentrations on both sides of the membrane. The permeability sequence at 20 mM was unchanged, but the relative permeability for NH 4 and Cs deviated significantly from the measurements at 120 mM with 1.46 and 0,75 ratios, respectively. The dependence of E~ on absolute concentrations and the deviation from NernstPlanck predictions are best explained by multi-ion occupancy of the cGMPactivated channel. Selectivity was also examined by comparing the conductance ratios as a function of potential. The conductance sequence relative to sodium at +80 mV was NH 4 > K > Rb > Cs > Li with values of 0.93 : 0.79 : 0.43 : 0.33 : 0.27, respectively. We conclude that the photoreceptor cGMP-activated channel shows little discrimination among monovalent cations without divalent cations, and that the relative permeability follows an Eisenman series IX for a high field strength site. The channel appears to process more than one ion at a time and to have asymmetric energy barriers with respect to the membrane plane for several ions.

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Transmembrane S1 Mutations inCNGA3from Achromatopsia 2 Patients Cause Loss of Function and Impaired Cellular Trafficking of the Cone CNG Channel

Patel

Bartoli

Fandino

et al. 2005

Invest. Ophthalmol. Vis. Sci.

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