Elena V. Olshevskaya

Ectopic Expression of a Microbial-Type Rhodopsin Restores Visual Responses in Mice with Photoreceptor Degeneration

The death of photoreceptor cells caused by retinal degenerative diseases often results in a complete loss of retinal responses to light. We explore the feasibility of converting inner retinal neurons to photosensitive cells as a possible strategy for imparting light sensitivity to retinas lacking rods and cones. Using delivery by an adeno-associated viral vector, here, we show that long-term expression of a microbial-type rhodopsin, channelrhodopsin-2 (ChR2), can be achieved in rodent inner retinal neurons in vivo. Furthermore, we demonstrate that expression of ChR2 in surviving inner retinal neurons of a mouse with photoreceptor degeneration can restore the ability of the retina to encode light signals and transmit the light signals to the visual cortex. Thus, expression of microbial-type channelrhodopsins, such as ChR2, in surviving inner retinal neurons is a potential strategy for the restoration of vision after rod and cone degeneration.

The human photoreceptor membrane guanylyl cyclase, RetGC, is present in outer segments and is regulated by calcium and a soluble activator

A human photoreceptor membrane guanylyl cyclase, RetGC, was recently cloned and expressed, but its localization and manner of regulation were not defined. We report here that RetGC is detected primarily in outer segments of human photoreceptor cells. Recombinant RetGC can be stimulated by a soluble retinal-specific factor. Ca2+ interferes with stimulation of RetGC by this factor with a cooperativity coefficient of 1.7 and EC50 near 200 nM. The Ca2+ sensitivities of recombinant RetGC and of guanylyl cyclase activity from rod outer segment membranes are very similar. Our findings indicate that RetGC is a photoreceptor-specific guanylyl cyclase which is stimulated by a retinal-specific activator and inhibited by physiologically relevant concentrations of free Ca2+. The Ca2+ sensitivity of RetGC may be responsible for some of the previously reported effects of Ca2+ on light adaptation and recovery of the dark state.

Constitutive Activation of Photoreceptor Guanylate Cyclase by Y99C Mutant of GCAP-1 POSSIBLE ROLE IN CAUSING HUMAN AUTOSOMAL DOMINANT CONE DEGENERATION

Photoreceptor membrane guanylate cyclases (RetGC) are regulated by calcium-binding proteins, GCAP-1 and GCAP-2. At Ca2+ concentrations below 100 nm, characteristic of light-adapted photoreceptors, guanylate cyclase-activating protein (GCAPs) activate RetGC, and at free Ca2+ concentrations above 500 nm, characteristic of dark-adapted photoreceptors, GCAPs inhibit RetGC. A mutation, Y99C, in human GCAP-1 was recently found to be linked to autosomal dominant cone dystrophy in a British family (Payne, A. M., Downes, S. M., Bessant, D. A. R., Taylor, R., Holder, G. E., Warren, M. J., Bird, A. C., and Bhattachraya, S. S. (1998) Hum. Mol. Genet. 7, 273–277). We produced recombinant Y99C GCAP-1 mutant and tested its ability to activate RetGC in vitro at various free Ca2+ concentrations. The Y99C mutation does not decrease the ability of GCAP-1 to activate RetGC. However, RetGC stimulated by the Y99C GCAP-1 remains active even at Ca2+ concentration above 1 μm. Hence, the cyclase becomes constitutively active within the whole physiologically relevant range of free Ca2+ concentrations. We have also found that the Y99C GCAP-1 can activate RetGC even in the presence of Ca2+-loaded nonmutant GCAPs. This is consistent with the fact that cone degeneration was dominant in human patients who carried such mutation (Payne, A. M., Downes, S. M., Bessant, D. A. R., Taylor, R., Holder, G. E., Warren, M. J., Bird, A. C., and Bhattachraya, S. S. (1998) Hum. Mol. Genet. 7, 273–277). A similar mutation, Y104C, in GCAP-2 results in a different phenotype. This mutation apparently does not affect Ca2+ sensitivity of GCAP-2. Instead, the Y104C GCAP-2 stimulates RetGC less efficiently than the wild-type GCAP-2. Our data indicate that cone degeneration associated with the Y99C mutation in GCAP-1 can be a result of constitutive activation of cGMP synthesis.

Calcium Binding, but Not a Calcium-Myristoyl Switch, Controls the Ability of Guanylyl Cyclase-activating Protein GCAP-2 to Regulate Photoreceptor Guanylyl Cyclase

Guanylyl cyclase-activating protein 2 (GCAP-2) is a recoverin-like calcium-binding protein that regulates photoreceptor guanylyl cyclase (RetGC) (Dizhoor, A. M., and Hurley, J. B. (1996)J. Biol. Chem. 271, 19346–19350). It was reported that myristoylation of a related protein, GCAP-1, was critical for its affinity for RetGC (Frins, S., Bonigk, W., Muller, F., Kellner, R., and Koch, K.-W. (1996) J. Biol. Chem. 271, 8022–8027). We demonstrate that the N terminus of GCAP-2, like those of other members of the recoverin family of Ca2+-binding proteins, is fatty acylated. However, unlike other proteins of this family, more GCAP-2 is present in the membrane fraction at low Ca2+ than at high Ca2+ concentrations. We investigated the role of the N-terminal fatty acyl residue in the ability of GCAP-2 to regulate RetGCs. Myristoylated or nonacylated GCAP-2 forms were expressed inEscherichia coli. Wild-type GCAP-2 and the Gly2→ Ala2 GCAP-2 mutant, which is unable to undergo N-terminal myristoylation, were also expressed in mammalian HEK293 cells. We found that compartmentalization of GCAP-2 in photoreceptor outer segment membranes is Ca2+- and ionic strength-sensitive, but it does not require the presence of the fatty acyl group and does not necessarily directly reflect GCAP-2 interaction with RetGC. The lack of myristoylation does not significantly affect the ability of GCAP-2 to stimulate RetGC. Nor does it affect the ability of the Ca2+-loaded form of GCAP-2 to compete with the GCAP-2 mutant that constitutively activates RetGC. We conclude that while Ca2+ binding plays a major regulatory role in GCAP-2 function, it does not operate through a calcium-myristoyl switch similar to the one found in recoverin.

The Y99C Mutation in Guanylyl Cyclase-Activating Protein 1 Increases Intracellular Ca2+ and Causes Photoreceptor Degeneration in Transgenic Mice

Guanylyl cyclase-activating proteins (GCAPs) are Ca2+-binding proteins that activate guanylyl cyclase when free Ca2+ concentrations in retinal rods and cones fall after illumination and inhibit the cyclase when free Ca2+ reaches its resting level in the dark. Several forms of retinal dystrophy are caused by mutations in GUCA1A, the gene coding for GCAP1. To investigate the cellular mechanisms affected by the diseased state, we created transgenic mice that express GCAP1 with a Tyr99Cys substitution (Y99C GCAP1) found in human patients with a late-onset retinal dystrophy (Payne et al., 1998). Y99C GCAP1 shifted the Ca2+ sensitivity of the guanylyl cyclase in photoreceptors, keeping it partially active at 250 nm free Ca2+, the normal resting Ca2+ concentration in darkness. The enhanced activity of the cyclase in the dark increased cyclic nucleotide-gated channel activity and elevated the rod outer segment Ca2+ concentration in darkness, measured by using fluo-5F and laser spot microscopy. In different lines of transgenic mice the magnitude of this effect rose with the Y99C GCAP1 expression. Surprisingly, there was little change in the rod photoresponse, indicating that dynamic Ca2+-dependent regulation of cGMP synthesis was preserved. However, the photoreceptors in these mice degenerated, and the rate of the cell loss increased with the level of the transgene expression, unlike in transgenic mice that overexpressed normal GCAP1. These results provide the first direct evidence that a mutation linked to congenital blindness increases Ca2+ in the outer segment, which may trigger the apoptotic process.

Dimerization of Guanylyl Cyclase-activating Protein and a Mechanism of Photoreceptor Guanylyl Cyclase Activation

Ca2+-binding guanylyl cyclase-activating proteins (GCAPs) stimulate photoreceptor membrane guanylyl cyclase (retGC) in the light when the free Ca2+concentrations in photoreceptors decrease from 600 to 50 nm. RetGC activated by GCAPs exhibits tight dimerization revealed by chemical cross-linking (Yu, H., Olshevskaya, E., Duda, T., Seno, K., Hayashi, F., Sharma, R. K., Dizhoor, A. M., and Yamazaki, A. (1999) J. Biol. Chem. 274, 15547–15555). We have found that the Ca2+-loaded GCAP-2 monomer undergoes reversible dimerization upon dissociation of Ca2+. The ability of GCAP-2 and its several mutants to activate retGC in vitro correlates with their ability to dimerize at low free Ca2+ concentrations. A constitutively active GCAP-2 mutant E80Q/E116Q/D158N that stimulates retGC regardless of the free Ca2+ concentrations forms dimers both in the absence and in the presence of Ca2+. Several GCAP-2/neurocalcin chimera proteins that cannot efficiently activate retGC in low Ca2+concentrations are also unable to dimerize in the absence of Ca2+. Additional mutation that restores normal activity of the GCAP-2 chimera mutant also restores its ability to dimerize in the absence of Ca2+. These results suggest that dimerization of GCAP-2 can be a part of the mechanism by which GCAP-2 regulates the photoreceptor guanylyl cyclase. The Ca2+-free GCAP-1 is also capable of dimerization in the absence of Ca2+, but unlike GCAP-2, dimerization of GCAP-1 is resistant to the presence of Ca2+.

Instead of Binding Calcium, One of the EF-hand Structures in Guanylyl Cyclase Activating Protein-2 Is Required for Targeting Photoreceptor Guanylyl Cyclase

Guanylyl cyclaseactivator proteins (GCAPs) are calcium-binding proteins closely related to recoverin, neurocalcin, and many other neuronal Ca2+-sensor proteins of the EF-hand superfamily. GCAP-1 and GCAP-2 interact with the intracellular portion of photoreceptor membrane guanylyl cyclase and stimulate its activity by promoting tight dimerization of the cyclase subunits. At low free Ca2+ concentrations, the activator form of GCAP-2 associates into a dimer, which dissociates when GCAP-2 binds Ca2+ and becomes inhibitor of the cyclase. GCAP-2 is known to have three active EF-hands and one additional EF-hand-like structure, EF-1, that deviates form the EF-hand consensus sequence. We have found that various point mutations within the EF-1 domain can specifically affect the ability of GCAP-2 to interact with the target cyclase but do not hamper the ability of GCAP-2 to undergo reversible Ca2+-sensitive dimerization. Point mutations within the EF-1 region can interfere with both the activation of the cyclase by the Ca2+-free form of GCAP-2 and the inhibition of retGC basal activity by the Ca2+-loaded GCAP-2. Our results strongly indicate that evolutionary conserved and GCAP-specific amino acid residues within the EF-1 can create a contact surface for binding GCAP-2 to the cyclase. Apparently, in the course of evolution GCAP-2 exchanged the ability of its first EF-hand motif to bind Ca2+ for the ability to interact with the target enzyme.

Mg2+/Ca2+ cation binding cycle of guanylyl cyclase activating proteins (GCAPs): role in regulation of photoreceptor guanylyl cyclase

Photon absorption by photoreceptors activates hydrolysis of cGMP, which shuts down cGMP-gated channels and decreases free Ca2+ concentrations in outer segment. Suppression of Ca2+ influx through the cGMP channel by light activates retinal guanylyl cyclase through guanylyl cyclase activating proteins (GCAPs) and thus expedites photoreceptors recovery from excitation and restores their light sensitivity. GCAP1 and GCAP2, two ubiquitous among vertebrate species isoforms of GCAPs that activate retGC during rod response to light, are myristoylated Ca2+/Mg2+-binding proteins of the EF-hand superfamily. They consist of one non-metal binding EF-hand-like domain and three other EF-hands, each capable of binding Ca2+ and Mg2+. In the metal binding EF-hands of GCAP1, different point mutations can selectively block binding of Ca2+ or both Ca2+ and Mg2+ altogether. Activation of retGC at low Ca2+ (light adaptation) or its inhibition at high Ca2+ (dark adaptation) follows a cycle of Ca2+/Mg2+ exchange in GCAPs, rather than release of Ca2+ and its binding by apo-GCAPs. The Mg2+ binding in two of the EF-hands controls docking of GCAP1 with retGC1 in the conditions of light adaptation and is essential for activation of retGC. Mg2+ binding in a C-terminal EF-hand contributes to neither retGC1 docking with the cyclase nor its subsequent activation in the light, but is specifically required for switching the cyclase off in the conditions of dark adaptation by binding Ca2+. The Mg2+/Ca2+ exchange in GCAP1 and 2 operates within different range of intracellular Ca2+ concentrations and provides a two-step activation of the cyclase during rod recovery.

A role for GCAP2 in regulating the photoresponse. Guanylyl cyclase activation and rod electrophysiology in GUCA1B knock-out mice.

Cyclic GMP serves as the second messenger in visual transduction, linking photon absorption by rhodopsin to the activity of ion channels. Synthesis of cGMP in photoreceptors is supported by a pair of retina-specific guanylyl cyclases, retGC1 and -2. Two neuronal calcium sensors, GCAP1 and GCAP2, confer Ca2+ sensitivity to guanylyl cyclase activity, but the importance and the contribution of each GCAP is controversial. To explore this issue, the gene GUCA1B, coding for GCAP2, was disrupted in mice, and the capacity for knock-out rods to regulate retGC and generate photoresponses was tested. The knock-out did not compromise rod viability or alter outer segment ultrastructure. Levels of retGC1, retGC2, and GCAP-1 expression did not undergo compensatory changes, but the absence of GCAP2 affected guanylyl cyclase activity in two ways; (a) the maximal rate of cGMP synthesis at low [Ca2+] dropped 2-fold and (b) the half-maximal rate of cGMP synthesis was attained at a higher than normal [Ca2+]. The addition of an antibody raised against mouse GCAP2 produced similar effects on the guanylyl cyclase activity in wild type retinas. Flash responses of GCAP2 knock-out rods recovered more slowly than normal. Knock-out rods became more sensitive to flashes and to steps of illumination but tended to saturate at lower intensities, as compared with wild type rods. Therefore, GCAP2 regulation of guanylyl cyclase activity quickens the recovery of flash and step responses and adjusts the operating range of rods to higher intensities of ambient illumination.

Constitutive Excitation by Gly90Asp Rhodopsin Rescues Rods from Degeneration Caused by Elevated Production of cGMP in the Dark

Previous experiments indicate that congenital human retinal degeneration caused by genetic mutations that change the Ca2+ sensitivity of retinal guanylyl cyclase (retGC) can result from an increase in concentration of free intracellular cGMP and Ca2+ in the photoreceptors. To rescue degeneration in transgenic mouse models having either the Y99C or E155G mutations of the retGC modulator guanylyl cyclase-activating protein 1 (GCAP-1), which produce elevated cGMP synthesis in the dark, we used the G90D rhodopsin mutation, which produces constitutive stimulation of cGMP hydrolysis. The effects of the G90D transgene were evaluated by measuring retGC activity biochemically, by recording single rod and electroretinogram (ERG) responses, by intracellular free Ca2+ measurement, and by retinal morphological analysis. Although the G90D rhodopsin did not alter the abnormal Ca2+ sensitivity of retGC in the double-mutant animals, the intracellular free cGMP and Ca2+ concentrations returned close to normal levels, consistent with constitutive activation of the phosphodiesterase PDE6 cascade in darkness. G90D decreased the light sensitivity of rods but spared them from severe retinal degeneration in Y99C and E155G GCAP-1 mice. More than half of the photoreceptors remained alive, appeared morphologically normal, and produced electrical responses, at the time when their siblings lacking the G90D rhodopsin transgene lost the entire retinal outer nuclear layer and no longer responded to illumination. These experiments indicate that mutations that lead to increases in cGMP and Ca2+ can trigger photoreceptor degeneration but that constitutive activation of the transduction cascade in these animals can greatly enhance cell survival.