Questioning photostasis.

Photostasis is a phenomenon where the photoreceptor outer segment (OS) length and its rhodopsin content vary depending on environmental lighting. When light is reduced for extended periods, it is argued that OS lengthen and its rhodopsin concentration rises to increase photon capture in darker environment. Increases in OS length may occur because the retinal pigment epithelium (RPE) cells reduce OS consumption in prolonged darkness. But sample sizes in assessing changes in OS length have been small, and results highly varied with no statistical analysis ever offered. Further, animals used were often albinos, which have abnormal RPE cells. Here we keep pigmented and albino mice for 21 days in darkness and compare OS length with those in a normal 12:12 light/dark environment. We measured approximately 1300 OS but found no statistically significant difference in their lengths between light and dark groups in either pigmentation phenotype, although there was a small trend in the data favoring OS extension in the dark. Given that earlier studies were undertaken on limited samples with no statistical analysis, our data pose serious questions for the notion of mammalian photostasis in terms of significant OS plasticity.

cAMP controls rod photoreceptor sensitivity via multiple targets in the phototransduction cascade.

In early studies, both cyclic AMP (cAMP) and cGMP were considered as potential secondary messengers regulating the conductivity of the vertebrate photoreceptor plasma membrane. Later discovery of the cGMP specificity of cyclic nucleotide-gated channels has shifted attention to cGMP as the only secondary messenger in the phototransduction cascade, and cAMP is not considered in modern schemes of phototransduction. Here, we report evidence that cAMP may also be involved in regulation of the phototransduction cascade. Using a suction pipette technique, we recorded light responses of isolated solitary rods from the frog retina in normal solution and in the medium containing 2 µM of adenylate cyclase activator forskolin. Under forskolin action, flash sensitivity rose more than twofold because of a retarded photoresponse turn-off. The same concentration of forskolin lead to a 2.5-fold increase in the rod outer segment cAMP, which is close to earlier reported natural day/night cAMP variations. Detailed analysis of cAMP action on the phototransduction cascade suggests that several targets are affected by cAMP increase: (a) basal dark phosphodiesterase (PDE) activity decreases; (b) at the same intensity of light background, steady background-induced PDE activity increases; (c) at light backgrounds, guanylate cyclase activity at a given fraction of open channels is reduced; and (d) the magnitude of the Ca(2+) exchanger current rises 1.6-fold, which would correspond to a 1.6-fold elevation of [Ca(2+)](in). Analysis by a complete model of rod phototransduction suggests that an increase of [Ca(2+)](in) might also explain effects (b) and (c). The mechanism(s) by which cAMP could regulate [Ca(2+)](in) and PDE basal activity is unclear. We suggest that these regulations may have adaptive significance and improve the performance of the visual system when it switches between day and night light conditions.

The Arf GAP ASAP1 provides a platform to regulate Arf4- and Rab11-Rab8-mediated ciliary receptor targeting.

Dysfunctional trafficking to primary cilia is a frequent cause of human diseases known as ciliopathies, yet molecular mechanisms for specific targeting of sensory receptors to cilia are largely unknown. Here, we show that the targeting of ciliary cargo, represented by rhodopsin, is mediated by a specialized system, the principal component of which is the Arf GAP ASAP1. Ablation of ASAP1 abolishes ciliary targeting and causes formation of actin-rich periciliary membrane projections that accumulate mislocalized rhodopsin. We find that ASAP1 serves as a scaffold that brings together the proteins necessary for transport to the cilia including the GTP-binding protein Arf4 and the two G proteins of the Rab family--Rab11 and Rab8--linked by the Rab8 guanine nucleotide exchange factor Rabin8. ASAP1 recognizes the FR ciliary targeting signal of rhodopsin. Rhodopsin FR-AA mutant, defective in ASAP1 binding, fails to interact with Rab8 and translocate across the periciliary diffusion barrier. Our study implies that other rhodopsin-like sensory receptors may interact with this conserved system and reach the cilia using the same platform.

Extra-mitochondrial aerobic metabolism in retinal rod outer segments: new perspectives in retinopathies.

Vertebrate retinal rods are photoreceptors for dim-light vision. They display extreme sensitivity to light thanks to a specialized subcellular organelle, the rod outer segment. This is filled with a stack of membranous disks, expressing the proteins involved in visual transduction, a very energy demanding process. Our previous proteomic and biochemical studies have shed new light on the chemical energy processes that supply ATP to the outer segment, suggesting the presence of an extra-mitochondrial aerobic metabolism in rod outer segment, devoid of mitochondria, which would account for a quantitatively adequate ATP supply for phototransduction. Here the functional presence of an oxidative phosphorylation in the rod outer limb is examined for its relationship to many physiological and pathological data on the rod outer segment. We hypothesize that the rod outer limb is at risk of oxidative stress, in any case of impairment in the respiratory chain functioning, or of blood supply. In fact, the electron transfer chain is a major source of reactive O(2) species, known to produce severe alteration to the membrane lipids, especially those of the outer segment that are rich in polyunsaturated fatty acids. We propose that the disk membrane may become the target of reactive oxygen species that may be released by the electron transport chain under pathologic conditions. For example, during aging reactive oxygen species production increases, while cellular antioxidant capacity decreases. Also the apoptosis of the rod observed after exposure to bright or continuous illumination can be explained considering that an overfunctioning of phototransduction may damage the disk membrane to a point at which cytochrome c escapes from the intradiskal space, where it is presently supposed to be, activating a putative caspase 9 and the apoptosome. A pathogenic mechanism for many inherited and acquired retinal degenerations, representing a major problem in clinical ophthalmology, is proposed: a number of rod pathologies would be promoted by impairment of energy supply and/or oxidative stress in the rod outer segment. In conclusion we suppose that the damaging role of oxygen, be it hypoxia or hyperoxia invoked in most of the blinding diseases, acquired and even hereditary is to be seeked for inside the photoreceptor outer segment that would conceal a potential for cell death that is still to be recognized.

Polarized secretion of PEDF from human embryonic stem cell-derived RPE promotes retinal progenitor cell survival.

PURPOSE: Human embryonic stem cell-derived RPE (hES-RPE) transplantation is a promising therapy for atrophic age-related macular degeneration (AMD); however, future therapeutic approaches may consider co-transplantation of hES-RPE with retinal progenitor cells (RPCs) as a replacement source for lost photoreceptors. The purpose of this study was to determine the effect of polarization of hES-RPE monolayers on their ability to promote survival of RPCs. METHODS: The hES-3 cell line was used for derivation of RPE. Polarization of hES-RPE was achieved by prolonged growth on permeable inserts. RPCs were isolated from 16- to 18-week-gestation human fetal eyes. ELISA was performed to measure pigment epithelium-derived factor (PEDF) levels from conditioned media. RESULTS: Pigmented RPE-like cells appeared as early as 4 weeks in culture and were subcultured at 8 weeks. Differentiated hES-RPE had a normal chromosomal karyotype. Phenotypically polarized hES-RPE cells showed expression of RPE-specific genes. Polarized hES-RPE showed prominent expression of PEDF in apical cytoplasm and a marked increase in secretion of PEDF into the medium compared with nonpolarized culture. RPCs grown in the presence of supernatants from polarized hES-RPE showed enhanced survival, which was ablated by the presence of anti-PEDF antibody. CONCLUSIONS: hES-3 cells can be differentiated into functionally polarized hES-RPE cells that exhibit characteristics similar to those of native RPE. On polarization, hES-RPE cells secrete high levels of PEDF that can support RPC survival. These experiments suggest that polarization of hES-RPE would be an important feature for promotion of RPC survival in future cell therapy for atrophic AMD.

Function of MYO7A in the human RPE and the validity of shaker1 mice as a model for Usher syndrome 1B.

PURPOSE: To investigate the function of MYO7A in human RPE cells and to test the validity of using shaker1 RPE in preclinical studies on therapies for Usher syndrome 1B by comparing human and mouse cells. METHODS: MYO7A was localized by immunofluorescence. Primary cultures of human and mouse RPE cells were used to measure melanosome motility and rod outer segment (ROS) phagocytosis and digestion. MYO7A was knocked down in the human RPE cells by RNAi to test for a mutant phenotype in melanosome motility. RESULTS: The distribution of MYO7A in the RPE of human and mouse was found to be comparable, both in vivo and in primary cultures. Primary cultures of human RPE cells phagocytosed and digested ROSs with kinetics comparable to that of primary cultures of mouse RPE cells. Melanosome motility was also comparable, and, after RNAi knockdown, consisted of longer-range fast movements characteristic of melanosomes in shaker1 RPE. CONCLUSIONS: The localization and function of MYO7A in human RPE cells is comparable to that in mouse RPE cells. Although shaker1 retinas do not undergo degeneration, correction of mutant phenotypes in the shaker1 RPE represents a valid preclinical test for potential therapeutic treatments.

Up-regulation of complement factor B in retinal pigment epithelial cells is accompanied by complement activation in the aged retina.

Complement activation is involved in the pathogenesis of age-related macular degeneration. How complement is activated in the retina is not known. Previously we have shown that complement factor H (CFH) is constitutively expressed by retinal pigment epithelial (RPE) cells and the production of CFH is negatively regulated by inflammatory cytokines and oxidative insults. Here we investigated the production and regulation of complement factor B (CFB) in RPE cells. Immunohistochemistry showed that CFB is expressed at low levels on the apical portion of the RPE cells in normal physiological conditions. With age, CFB expression increases and extends to the basal part of RPE cells. Confocal microscopy and real-time PCR of RPE cultures indicated that the production of CFB by RPE cells is positively regulated by TNF-alpha, IFN-gamma and long-term (30 days) photoreceptor outer segments treatments. Increased CFB expression in RPE cells in vivo is accompanied by the accumulation of complement C3 and C3a deposition at the Bruch's membrane and the basal layer of RPE cells. Our results suggest that RPE cells play important roles in regulating complement activation in the retina. Increased complement activation in the aged retina may be important for retinal homeostasis in the context of accumulating photoreceptor waste products.

An hypothesis to account for the renewal of outer segments in rod and cone photoreceptor cells: renewal as a surrogate antioxidant.

It is undisputed that glutathione (GSH) is an important cellular antioxidant. Although it is commonly believed that GSH is present in all retinal cells, several publications show that GSH is not immunologically detectable in outer segments of rod and cone photoreceptor cells, but is present in inner retinal cells and the pigment epithelium. Using these intriguing and surprising findings as a starting point, an hypothesis is proposed that the renewal of outer segments serves as a surrogate antioxidant for GSH and that the exceptional vulnerability of photoreceptor cells to certain toxic chemicals is linked to the deficiency in GSH in outer segments as a reductant, a detoxicant, and as an enzymatic cofactor. It is suggested that this deficiency of GSH is not damaging to outer segments under normal conditions, because renewal serves to replace any damaged molecules before they increase to detrimental levels. However, when photoreceptors are stressed, the renewal of outer segments alone is not capable of overcoming the higher rates of oxidizing and detrimental chemical reactions, and the health of the entire photoreceptor cell is at risk. The hypothesis is supported by a consideration of the essential role of the NADPH-dependent retinol reductase, by the different localization within photoreceptor cells of two key metabolic enzymes that are sensitive to oxidation, glyceraldehyde-3-phosphate dehydrogenase and the sodium-potassium ATPase, and by a consideration of the effects of toxic chemicals that selectively damage photoreceptor cells.

Signal transducing membrane complexes of photoreceptor outer segments.

Signal transduction in outer segments of vertebrate photoreceptors is mediated by a series of reactions among multiple polypeptides that form protein-protein complexes within or on the surface of the disk and plasma membranes. The individual components in the activation reactions include the photon receptor rhodopsin and the products of its absorption of light, the three subunits of the G protein, transducin, the four subunits of the cGMP phosphodiesterase, PDE6 and the four subunits of the cGMP-gated cation channel. Recovery involves membrane complexes with additional polypeptides including the Na(+)/Ca(2+), K(+) exchanger, NCKX2, rhodopsin kinases RK1 and RK7, arrestin, guanylate cyclases, guanylate cyclase activating proteins, GCAP1 and GCAP2, and the GTPase accelerating complex of RGS9-1, G(beta5L), and membrane anchor R9AP. Modes of membrane binding by these polypeptides include transmembrane helices, fatty acyl or isoprenyl modifications, polar interactions with lipid head groups, non-polar interactions of hydrophobic side chains with lipid hydrocarbon phase, and both polar and non-polar protein-protein interactions. In the course of signal transduction, complexes among these polypeptides form and dissociate, and undergo structural rearrangements that are coupled to their interactions with and catalysis of reactions by small molecules and ions, including guanine nucleotides, ATP, Ca(2+), Mg(2+), and lipids. The substantial progress that has been made in understanding the composition and function of these complexes is reviewed, along with the more preliminary state of our understanding of the structures of these complexes and the challenges and opportunities that present themselves for deepening our understanding of these complexes, and how they work together to convert a light signal into an electrical signal.

A novel technique to study pore-forming peptides in a natural membrane.

The biophysical characteristics and the pore formation dynamics of synthetic or naturally occurring peptides forming membrane-spanning channels were investigated by using isolated photoreceptor rod outer segments (OS) recorded in whole-cell configuration. Once blocking the two OS endogenous conductances (the cGMP channels by light and the Na(+):Ca(2+),K(+) exchanger by removing one of the transported ion species from both sides of the membrane, i.e. K(+), Na(+) or Ca(2+)), the OS membrane resistance (R ( m )) was typically larger than 1 GOmega in the presence of 1 mM external Ca(2+). Therefore, any exogenous current could be studied down to the single channel level. The peptides were applied to (and removed from) the extracellular OS side in approximately 50 ms with a computer-controlled microperfusion system, in which every perfusion parameter, as the rate of solution flow, the temporal sequence of solution changes or the number of automatic, self-washing cycles were controlled by a user-friendly interface. This technique was then used to determine the biophysical properties and the pore formation dynamics of antibiotic peptaibols, as the native alamethicin mixture, the synthesized major component of the neutral fraction (F50/5) of alamethicin, and the synthetic trichogin GA IV.

Effects of lipid peroxidation-related protein modifications on RPE lysosomal functions and POS phagocytosis.

PURPOSE: Lipofuscin accumulation in the RPE is a common downstream pathogenic pathway in various monogenic and complex retinal diseases including age-related macular degeneration (AMD). Lipid peroxidation-induced modification of proteins is thought to play a role in lipofuscinogenesis and may contribute to RPE dysfunction. A prior study demonstrated that a variety of lipofuscin-associated proteins are damaged by aberrant covalent modifications of malondialdehyde (MDA) and 4-hydroxynonenal (HNE). The present study was conducted to test the hypothesis that these damaged proteins are more resistant to proteolytic attack and act as protease inhibitors. METHODS: Isolated photoreceptor outer segments (POS) were radioactively labeled and in vitro modified with MDA and HNE. Pure lysosomal fractions isolated from human RPE were tested for their proteolytic activities toward modified and unmodified POS proteins. In parallel, modified and radiolabeled POS were fed to RPE cell cultures for phagocytosis and their lysosomal degradation as well as intracellular accumulation was compared with unmodified POS. RESULTS: Both experimental approaches revealed that MDA or HNE modifications strikingly increase the resistance of POS proteins to the attack by lysosomal proteases. When cultured RPE cells were fed with modified or unmodified POS the amount of degraded POS proteins was reduced by approximately 60% to 70% for the modified POS compared with those in normal control subjects. Some of the modified proteins remained undegraded in the lysosomal compartment of cultured RPE cells and were still detectable 3 weeks after feeding, whereas unmodified POS were completely degraded within 1 week after feeding. Moreover, modified proteins had the potential to impair degradation of unmodified proteins, indicating their efficacy as proteolytic antagonists. CONCLUSIONS: The results indicate that lipid peroxidation-derived protein modifications are involved in lipofuscinogenesis and may contribute to cell damaging effects of lipofuscin in retinal diseases such as AMD.

Tyrosinase biosynthesis in adult mammalian retinal pigment epithelial cells.

Tyrosinase (EC 1.14.18.1) is the rate limiting enzyme of melanogenesis and it is unclear whether it is synthesized in postnatal retinal pigment epithelium (RPE). Cultured RPE cells from cattle were fed with isolated rod outer segments (ROS). After phagocytosis, RPE cells were tested for tyrosinase presence and activity with three independent methods: (1) ultrastructural DOPA (l-3,4-dihydroxyphenylalanine) histochemistry (2) immunocytochemistry with anti-tyrosinase antibodies (3) measuring tyrosine hydroxylase activity using [(3)H]tyrosine. With all three methods tyrosinase was found in RPE cells after ROS-feeding but was absent without feeding. In contrast to the classical hypothesis, we demonstrated with three independent methods that the expression of tyrosinase and its enzymatic activity are induced in cultured adult RPE by phagocytosis of rod outer segments (ROS) in vitro.

Induction of angiogenic cytokine expression in cultured RPE by ingestion of oxidized photoreceptor outer segments.

PURPOSE: Normal aging is associated with accumulation of lipofuscin pigment in the retinal pigment epithelium (RPE). This may occur as a result of phagocytosis and incomplete degradation of oxidized photoreceptor outer segments (POS). This study was undertaken to determine whether phagocytosis of UV-irradiated POS (artificial lipofuscin) would increase expression in the RPE of various chemotactic and angiogenic cytokines. METHODS: ARPE-19 cells were exposed to latex beads (0.76 micro m), naïve bovine POS, and UV-irradiated POS (Ox-POS; 2 x 10(7)/mL), and supernatants were collected at 18 and 36 hours. The supernatants were assayed for IL-8, monocyte chemotactic protein-(MCP)-1, and TNF-alpha by ELISA. Protein synthesis and NFkappaB activity were inhibited by actinomycin D and SN50, respectively. Phagocytosis and generation of intracellular reactive oxygen species were assessed by flow cytometry. Confocal and electron microscopy studies were also performed to verify phagocytosis and cellular integrity. RESULTS: IL-8 and MCP-1 levels were decreased in the naïve POS group (IL-8: 473.76 +/- 66.9 pg/mL, P = 0.0005; MCP-1: 550.1 +/- 21.8 pg/mL, P = 0.0001), but were increased in the Ox-POS group (IL-8: 1348.8 +/- 164.9 pg/mL; MCP-1: 1772.28 +/- 65.19 pg/mL) compared with the control (IL-8: 741.09 +/- 39.8 pg/mL; MCP-1: 1413.47 +/- 38.4 pg/mL) and latex bead groups (data not shown). TNF-alpha levels were not affected. At 12 hours (but not at 6 hours), ROS were increased in the Ox-POS group. The cytokine increases observed were dependent on de novo protein synthesis and were NF-kappaB dependent. CONCLUSIONS: Ingestion by RPE of oxidized bovine POS stimulates expression of the chemotactic and angiogenic factors IL-8 and MCP-1 that have the capability to promote angiogenesis directly, or indirectly through the accumulation of immune cells such as macrophages, which themselves may release angiogenic promoters and degrade Bruch's membrane. This may be of significance in the development of exudative AMD.

Acceleration of key reactions as a strategy to elucidate the rate-limiting chemistry underlying phototransduction inactivation.

PURPOSE: A reconstituted system was used to establish a strategy to determine the rate-limiting chemistry responsible for recovery of the dim-flash response in rod photoreceptors. METHODS: A general approach for identifying the rate-limiting step in a series of reactions is to evaluate the consequences of accelerating each step separately, while monitoring the rate of formation of the end product of the series. This strategy was applied to the reactions involved in quenching phototransduction in bovine rod outer segment (bROS) homogenates. The decay of photoactivated rhodopsin (R*) and inactivation of transducin by guanosine triphosphate (GTP) hydrolysis are the leading candidates for limiting the rate of phototransduction turn-off. These reactions were accelerated separately and together by adding hydroxylamine and/or the regulator of G-protein signaling-9 catalytic domain (RGS9d) while monitoring phosphodiesterase (PDE) activity triggered by a pulse of light in bROS homogenates. RESULTS: PDE activity in bROS homogenates triggered by a flash of light returned to its dark value with a rate constant of 0.087 +/- 0.002 seconds in this system. The rate of PDE recovery increased to 0.11 +/- 0.004 seconds when R* decay was accelerated with 10 to 50 mM hydroxylamine, suggesting that R* inactivation limits the rate of phototransduction turn-off under these conditions. Adding both hydroxylamine and RGS9d, a factor that accelerates transducin inactivation, increased the rate of PDE decay even further. RGS9d had no effect on PDE recovery kinetics unless quenching of R* was also accelerated. CONCLUSIONS: Under in vitro conditions in bROS homogenates, the quenching of R* normally limits the rate of phototransduction shut-off. If R* decay is accelerated, inactivation of transducin by GTP hydrolysis becomes rate limiting. This study offers a general approach that could be used to investigate the rate-limiting chemistry of phototransduction turn-off in vivo.

[A role of protein kinase C in signal reactions in outer segments of the bovine retinal rods]. / Rol' proteinkinasy C v signal'nykh reaktsiiakh v naruzhnykh segmentakh palochek setchatki byka.

The effect of modulators of protein kinase C activity on Ca2+ translocation in dark-adapted and bleached retinal rod outer segments (ROS) was studied. The activators (1,2-diacyl glycerol and phorbol-12-myristate-13-acetate) and the inhibitor (chelerythrine chloride) of protein kinase C were shown to stimulate and inhibit the ATP-dependent Ca(2+)-uptake in dark-adapted retinal ROS, correspondingly. Apparently, this action is due to the influence of protein kinase C on Ca(2+)-ATPase activity in these vesicular structures. No involvement of modulators of protein kinase C activity on ATP-dependent Ca(2+)-uptake in bleached retinal ROS was found. The influence of protein kinase C on Ca(2+)-release from retinal ROS was observed. It was shown that the activators and inhibitors of protein kinase C increased the efficiency of this process both in dark-adapted and bleached retinal ROS. The mechanisms of action of the protein kinase C activity modulators on the Ca(2+)-uptake and Ca(2+)-release in retinal ROS are discussed.

Gas6 binding to photoreceptor outer segments requires gamma-carboxyglutamic acid (Gla) and Ca(2+) and is required for OS phagocytosis by RPE cells in vitro.

The phagocytosis of photoreceptor outer segments by retinal pigment epithelial (RPE) cells plays a critical role in preserving normal retinal function. Recently the receptor protein tyrosine kinase (RTK) Mer, has been shown to be necessary for this cellular process to take place. Gas6, the ligand for the Mer RTK, can specifically and selectively stimulate the phagocytosis of photoreceptor outer segments (OS) by normal cultured rat RPE cells, as we have previously reported. The Gas6 protein has been shown to associate with plasma membrane phosphatidylserine by its amino-terminal portion, while its carboxyl-terminal portion can bind and activate Mer and its related RTKs, Axl and Tyro-3. Given the capability of Gas6 to interact with more than one molecule, we have performed a series of experiments to further dissect the interactions of Gas6 with the OS and RPE and to determine the specific calcium requirements necessary for Gas6 to exert its stimulatory effect on phagocytosis. These experiments show that Gas6 must bind to OS before the stimulation of OS ingestion can occur and that this binding requires a Ca(2+) concentration of 500-600 microM. The same Ca(2+) concentration is required for the Gas6 mediated stimulation of OS ingestion. We further demonstrate that in order to bind to OS and to stimulate OS phagocytosis, Gas6 requires gamma-carboxylation in a vitamin K-dependent reaction. By analogy with other systems, we propose that Ca(2+) mediates the linkage between the gamma-carboxyglutamic acid (Gla)-rich N-terminal region of Gas6 with phospholipids, presumably phosphatidylserine, in the plasma membrane of the OS. Only after this binding has occurred can Gas6 interact with receptor molecule(s) on the surface of the RPE, and activate RPE cell signaling pathways leading to OS ingestion. These studies further underscore the importance of Gas6 in the phagocytic function of the RPE and open new avenues of investigation to understand the molecular events mediated and triggered by Gas6, and its interaction with the OS and RPE.

Pupil size following dark adaptation in patients with retinitis pigmentosa

According to the equivalent light hypothesis, molecular defects in the photoreceptor lead to a continuous activation of the photoreceptor cascade in a manner equivalent to real light. The consequences in diseases such as retinitis pigmentosa (RP) are as disruptive to the cells as real light. Two forms of the equivalent light hypothesis can be distinguished: strong - mutations in rhodopsin or other cascade proteins in some forms of RP continuously excite the visual phototransduction cascade; weak - disruption of outer segments in all patients with RP eliminates circulating dark current and blocks neurotransmitter release in a manner similar to real light. Both forms of the equivalent light hypothesis predict that pupils of patients with RP will be constricted like those of normal subjects in the light. The purpose of this study was to test the equivalent light hypothesis by determining whether steady-state pupil diameter following full dark adaptation is abnormally small in any of a sample of patients with RP. Thirty-five patients with RP and 15 normal subjects were tested. Direct steady-state pupillometric measures were obtained from one eye in a full-field dome after 45 min of dark adaptation by videotaping the pupil with an infrared camera. Mean pupil diameter in the dark was comparable (t = -0.15, P = 0.88) between patients with RP (6.85 Ý 0.58 mm) and normal subjects (6.82 Ý 0.76 mm). The results of the present study are clearly counter to the prediction of the second (weaker) form of the equivalent light hypothesis

A functioning chimera of the cyclic nucleotide-binding domain from the bovine retinal rod ion channel and the DNA-binding domain from catabolite gene-activating protein.

The eukaryotic cyclic nucleotide-gated (CNG) ion channels are a family of large membrane proteins activated by cytoplasmic cGMP or cAMP. Their cyclic nucleotide-binding domain is structurally homologous with that of the catabolite gene-activator protein (CAP), a soluble Escherichia coli transcription factor. Differences in ligand activation among sensory channels suggest differences in the underlying molecular mechanisms of signal readout. To study the structural, functional, and conformational consequences of nucleotide binding, we fused the cyclic nucleotide-binding domain from the bovine retinal rod CNG channel alpha subunit (Bralpha) to the DNA-binding domain from CAP. The chimera forms a soluble dimer that binds both cGMP and cAMP with association constants of 3.7 x 10(4) M(-1) for [(3)H]cGMP and 3.1 x 10(4) M(-1) for [(3)H]cAMP. The binding of cAMP, but not cGMP, exposes a chymotrypsin cleavage site in the chimera at a position similar to the site in the CAP exposed by cAMP binding. At high cAMP concentrations, a biphasic pattern of cleavage is seen, suggesting that the low-affinity cAMP binding sites are also occupied. Cyclic AMP promotes specific binding to a DNA fragment encoding the lac operator region; the K(d) for the protein-DNA binding is approximately 200 nM, which is 2-fold higher than the K(d) for CAP under identical conditions. A 7 A crystal structure shows that the overall secondary and tertiary structure of Bralpha/CAP is the same as that of CAP with two cAMP molecules bound per dimer. The biochemical characterization of the chimera suggests it will be a useful system for testing hypotheses about channel activation, providing further insight into channel function.