Calcium-dependent assembly of centrin-G-protein complex in photoreceptor cells

Photoexcitation of rhodopsin activates a heterotrimeric G-protein cascade leading to cyclic GMP hydrolysis in vertebrate photoreceptors. Light-induced exchanges of the visual G-protein transducin between the outer and inner segment of rod photoreceptors occur through the narrow connecting cilium. Here we demonstrate that transducin colocalizes with the Ca(2+)-binding protein centrin 1 in a specific domain of this cilium. Coimmunoprecipitation, centrifugation, centrin overlay, size exclusion chromatography, and kinetic light-scattering experiments indicate that Ca(2+)-activated centrin 1 binds with high affinity and specificity to transducin. The assembly of centrin-G-protein complex is mediated by the betagamma-complex. The Ca(2+)-dependent assembly of a G protein with centrin is a novel aspect of the supply of signaling proteins in sensory cells and a potential link between molecular translocations and signal transduction in general.     

Induction of the Unfolded Protein Response by Constitutive G-protein Signaling in Rod Photoreceptor Cells

Phototransduction is a G-protein signal transduction cascade that converts photon absorption to a change in current at the plasma membrane. Certain genetic mutations affecting the proteins in the phototransduction cascade cause blinding disorders in humans. Some of these mutations serve as a genetic source of “equivalent light” that activates the cascade, whereas other mutations lead to amplification of the light response. How constitutive phototransduction causes photoreceptor cell death is poorly understood. We showed that persistent G-protein signaling, which occurs in rod arrestin and rhodopsin kinase knock-out mice, caused a rapid and specific induction of the PERK pathway of the unfolded protein response. These changes were not observed in the cGMP-gated channel knock-out rods, an equivalent light condition that mimics light-stimulated channel closure. Thus transducin signaling, but not channel closure, triggers rapid cell death in light damage caused by constitutive phototransduction. Additionally, we show that in the albino light damage model cell death was not associated with increase in global protein ubiquitination or unfolded protein response induction. Taken together, these observations provide novel mechanistic insights into the cell death pathway caused by constitutive phototransduction and identify the unfolded protein response as a potential target for therapeutic intervention.     

Molecular design of an amplification cascade in vision

The photoexcitation of rhodopsin triggers a cascade that results in the hydrolysis of a large number of molecules of cyclic GMP. The molecular mechanism of this amplification cascade has been delineated. Transducin, a multisubunit perpheral membrane protein, is the information-carrying intermediate in the activation of the cyclic GMP phosphodiesterase. Photoexcited rhodopsin (R*) castalyzes the exchange of GRP for GDP bound to the α-subunit of transducin (T). About 500 molecules of T_α-GTP are formed per absorbed photon at low light levels. T_α-GTP, rekeased from the β- and γ-subunits of transducin, then activates the phosphodiesterase by relieving an inhibitory constraint imposed by its small sununit. Each actived phosphodiesterase molecule hydrolyzes more than 100 cyclic GMP/s, giving an overall gain of more than 500,000. Photoexcited rhodopsin triggers the activation of a molecule of transducin in a millisecond, which is sufficiently rapid to enable this cascade to participate in visual excitation. Hydrolysis of GTP bound to T_α seves to restore the system to the dark state. Transducin, like the G proteins of the adenylate cyclase casecade, can be specifically ADP-ribosylated by cholera toxin and pertussis toxin. In both cascades, labling by pertussis toxin blocks the capacity of transducin to interact with the excited receptor, whereas labeling by cholera toxin inhibits the hydrolysis of bound GTP, leading to persistent activation. Moreover, the moleculaar design of the hormone-triggered cyclic AMP cascade is similar to that of the light-triggered cyclic GMP cascade. It seems likely that transducin, the stimulatory G protein, the inhibitor G protein, and the ras protein are members of the same family of signal amplifiers. The study of the cyclic nucleotide cascade of vision is providing rewarding views of recurring motifs of signal amplification in nature.     

Photoreceptors of the retina and pinealocytes of the pineal gland share common components of signal transduction

Light absorbed by retinal photoreceptors triggers a cascade of reactions that initiate cGMP hydrolysis, cation channel closure and membrane hyperpolarization. Down-regulation of the cascade involves additional proteins that interfere with amplification along the cascade. Pinealocytes are activated by norepinephrine during the dark phase of the day/night cycle. Mature pinealocytes of the mammalian pineal express the known photoreceptor proteins that are implicated in down-regulation of the visual cascade, but the cascade components that produce cGMP hydrolysis and membrane hyperpolarization are absent. Pinealocytes accumulate cyclic AMP minimally when norepinephrine activates their beta adrenergic receptors alone, but the response is potentiated by the simultaneous activation of their alpha-1 adrenergic receptors. A model is proposed whereby phosducin, a phosphoprotein that binds the beta, gamma subunit of G-proteins, could modulate the synthesis of cyclic AMP by buffering the amount of beta, gamma G-protein subunits that are available for activating adenylate cyclase.Special issue dedicated to Dr. Frederick E. Samson.     

Differential expression and interaction with the visual G-protein transducin of centrin isoforms in mammalian photoreceptor cells

Photoisomerization of rhodopsin activates a heterotrimeric G-protein cascade leading to closure of cGMP-gated channels and hyperpolarization of photoreceptor cells. Massive translocation of the visual G-protein transducin, Gt, between subcellular compartments contributes to long term adaptation of photoreceptor cells. Ca(2+)-triggered assembly of a centrin-transducin complex in the connecting cilium of photoreceptor cells may regulate these transducin translocations. Here we demonstrate expression of all four known, closely related centrin isoforms in the mammalian retina. Interaction assays revealed binding potential of the four centrin isoforms to Gtbetagamma heterodimers. High affinity binding to Gtbetagamma and subcellular localization of the centrin isoforms Cen1 and Cen2 in the connecting cilium indicated that these isoforms contribute to the centrin-transducin complex and potentially participate in the regulation of transducin translocation through the photoreceptor cilium. Binding of Cen2 and Cen4 to Gbetagamma of non-visual G-proteins may additionally regulate G-proteins involved in centrosome and basal body functions.     

Visual transduction in rod outer segments

The visual transduction cascade of the retinal rod outer segment responds to light by decreasing membrane current. This ion channel is controlled by cyclic GMP which is, in turn, controlled by its synthesis and degradation by guanylate cyclase and phosphodiesterase, respectively. When light bleaches rhodopsin there is an induced exchange of GTP for GDP bound to the alpha subunit of the retinal G-protein, transducin (T). The T alpha.GTP then removes the inhibitory constraint of a small inhibitory subunit (PDE gamma) on the retinal cGMP phosphodiesterase (PDE). This results in activation of the PDE and in hydrolysis of cGMP. Recently both low and high affinity binding sites have been identified for PDE gamma on the PDE alpha/beta catalytic subunits. The discovery of two PDE gamma subunits, each with different binding affinities, suggests that a tightly regulated shut-off mechanism may be present.     

An improved rhodopsin/EGFP fusion protein for use in the generation of transgenic Xenopus laevis

Previous studies by Papermaster and coworkers introduced the use of rhodopsin-green fluorescent protein (rho-GFP) fusion proteins in the construction of transgenic Xenopus laevis with retinal rod photoreceptor cell-specific transgene expression [Moritz et al., J. Biol. Chem. 276 (2001) 28242-28251]. These pioneering studies have helped to develop the Xenopus system not only for use in the investigation of rhodopsin biosynthesis and targeting, but for studies of the phototransduction cascade as well. However, the rho-GFP fusion protein used in the earlier work had only 50% of the specific activity of wild-type rhodopsin for activation of transducin and only 10% of the activity of wild-type in rhodopsin kinase assays. While not a problem for the biosynthesis studies, this does present a problem for investigation of the phototransduction cascade. We report here an improved rhodopsin/EGFP fusion protein in which placement of the EGFP domain at the C-terminus of rhodopsin results in wild-type activity for activation of transducin, wild-type ability to serve as a substrate for rhodopsin kinase, and wild-type localization of the protein to the rod photoreceptor cell outer segment in transgenic X. laevis.     

Regulation of retinal cGMP cascade by phosducin in bovine rod photoreceptor cells. Interaction of phosducin and transducin.

Photoexcitation of retinal rod photoreceptor cells involves the activation of cGMP enzyme cascade in which sequential activation of rhodopsin, transducin, and the cGMP phosphodiesterase in the rod outer segment constitutes the signal amplification mechanism. Phosducin, a 33-kDa phosphoprotein, has been shown to form a tight complex with the T beta gamma subunit of transducin. In this study, we examined the interaction of phosducin-T beta gamma and the possible regulatory role of phosducin on the cGMP cascade. Addition of phosducin to photolyzed rod outer segment (ROS) membrane reduced the GTP hydrolysis activity of transducin as well as the subsequent activation of the cGMP phosphodiesterase. Phosducin also inhibited the pertussis toxin-catalyzed ADP-ribosylation of transducin, indicating that the interaction between the T alpha and T beta gamma subunits of transducin was interrupted upon binding of phosducin. The inhibitory effects of phosducin were reversed by the addition of exogenous T beta gamma. These results suggest that phosducin is capable of regulating the amount of T beta gamma available to interact with T alpha to form the active transducin complex and thereby functions as a negative regulator of the cGMP cascade. The phosducin-induced alteration of the subunit organization of transducin was examined by chemical cross-linking method using para-phenyl dimaleimide as cross-linker. It was found that the cross-linking among T alpha and T beta gamma was blocked in the presence of phosducin. This result implies that T beta gamma may undergo a conformational change upon phosducin binding which leads to the release of T alpha. Since phosducin is a soluble protein, the interaction with transducin only occurs when transducin is dissociated from ROS disc membrane. Indeed, phosducin failed to dissociate membrane-bound transducin and did not inhibit the initial cycle of transducin activation as measured by the presteady state GTP hydrolysis. However, phosducin interacts effectively with transducin released into solution after the initial activation and blocks the re-binding of T alpha. T beta gamma to ROS membrane by forming a tight complex with T beta gamma. This interaction may play an important role in regulating the turnover of the cGMP cascade in photoreceptor cells.     

Role of membrane integrity on G protein-coupled receptors: Rhodopsin stability and function

Rhodopsin is a prototypical G protein-coupled receptor (GPCR) - a member of the superfamily that shares a similar structural architecture consisting of seven-transmembrane helices and propagates various signals across biological membranes. Rhodopsin is embedded in the lipid bilayer of specialized disk membranes in the outer segments of retinal rod photoreceptor cells where it transmits a light-stimulated signal. Photoactivated rhodopsin then activates a visual signaling cascade through its cognate G protein, transducin or Gt, that results in a neuronal response in the brain. Interestingly, the lipid composition of ROS membranes not only differs from that of the photoreceptor plasma membrane but is critical for visual transduction. Specifically, lipids can modulate structural changes in rhodopsin that occur after photoactivation and influence binding of transducin. Thus, altering the lipid organization of ROS membranes can result in visual dysfunction and blindness.     

Characterization of a bovine cone photoreceptor phosphodiesterase purified by cyclic GMP-sepharose chromatography

The biochemical bases for the differences in cone and rod photoreceptor physiology have not been thoroughly examined because of the difficulty in obtaining cone photoreceptor components. We report here the purification and preliminary characterization of a bovine cyclic GMP phosphodiesterase (PDE) which is enriched in cone photoreceptors. The cone PDE was purified at least 15,000-fold to apparent homogeneity from bovine retinas by DEAE-cellulose and cGMP-Sepharose affinity chromatography. The trypsin-activated cone PDE hydrolyzed cGMP with efficiency similar to that of the rod PDE. However, a number of characteristics distinguished the cone PDE from the rod isozyme including the subunit structure. As previously reported, the apparent molecular weight of the cone PDE large subunit (alpha') was slightly larger than either of the large subunits of the rod PDE (93,500 versus 88,000 and 84,000). Three other smaller polypeptides were associated with the alpha' subunit (Mr = 11,000, 13,000, and 15,000), one of which (11,000) may be identical to the rod PDE gamma subunit. Cone phosphodiesterase binds at least 10-fold more cyclic GMP/mol of PDE than the rod photoreceptor isozyme. Cyclic GMP binds to this noncatalytic site with high affinity (Kd = 11 nM) and dissociates very slowly (t1/2 = 10-20 min at 37 degrees C). Purified rod transducin activated the cone PDE in solution to at least 90% of the trypsin-activated level. The concentration of rod transducin required for half-maximal activation of cone PDE (15 nM) was 50-fold lower than that necessary for half-maximal activation of rod PDE. Thus several properties of the cone phosphodiesterase clearly distinguish it from the rod isozyme and could account for some differences in cone and rod physiology.     

11-cis- and all-trans-retinols can activate rod opsin: rational design of the visual cycle

Rhodopsin is the photosensitive pigment in the rod photoreceptor cell. Upon absorption of a photon, the covalently bound 11- cis-retinal isomerizes to the all- trans form, enabling rhodopsin to activate transducin, its G protein. All -trans-retinal is then released from the protein and reduced to all -trans-retinol. It is subsequently transported to the retinal pigment epithelium where it is converted to 11- cis-retinol and oxidized to 11- cis-retinal before it is transported back to the photoreceptor to regenerate rhodopsin and complete the visual cycle. In this study, we have measured the effects of all -trans- and 11- cis-retinals and -retinols on the opsin's ability to activate transducin to ascertain their potentials for activating the signaling cascade. Only 11- cis-retinal acts as an inverse agonist to the opsin. All -trans-retinal, all -trans-retinol, and 11- cis-retinol are all agonists with all -trans-retinal being the most potent agonist and all -trans-retinol being the least potent. Taken as a whole, our study is consistent with the hypothesis that the steps in the visual cycle are optimized such that the rod can serve as a highly sensitive dim light receptor. All -trans-retinal is immediately reduced in the photoreceptor to prevent back reactions and to weaken its effectiveness as an agonist before it is transported out of the cell; oxidation of 11- cis-retinol occurs in the retinal pigment epithelium and not the rod photoreceptor cell because 11- cis-retinol can act as an agonist and activate the signaling cascade if it were to bind an opsin, effectively adapting the cell to light.     

Transretinal ERG Recordings from Mouse Retina: Rod and Cone Photoresponses

There are two distinct classes of image-forming photoreceptors in the vertebrate retina: rods and cones. Rods are able to detect single photons of light whereas cones operate continuously under rapidly changing bright light conditions. Absorption of light by rod- and cone-specific visual pigments in the outer segments of photoreceptors triggers a phototransduction cascade that eventually leads to closure of cyclic nucleotide-gated channels on the plasma membrane and cell hyperpolarization. This light-induced change in membrane current and potential can be registered as a photoresponse, by either classical suction electrode recording technique^1,2 or by transretinal electroretinogram recordings (ERG) from isolated retinas with pharmacologically blocked postsynaptic response components^3-5. The latter method allows drug-accessible long-lasting recordings from mouse photoreceptors and is particularly useful for obtaining stable photoresponses from the scarce and fragile mouse cones. In the case of cones, such experiments can be performed both in dark-adapted conditions and following intense illumination that bleaches essentially all visual pigment, to monitor the process of cone photosensitivity recovery during dark adaptation^6,7. In this video, we will show how to perform rod- and M/L-cone-driven transretinal recordings from dark-adapted mouse retina. Rod recordings will be carried out using retina of wild type (C57Bl/6) mice. For simplicity, cone recordings will be obtained from genetically modified rod transducin α-subunit knockout (Tα^-/-) mice which lack rod signaling⁸.     

Signal transduction enzymes of vertebrate photoreceptors

A flash of light initiates a cascade of biochemical reactions inside vertebrate photoreceptor cells, culminating in hydrolysis of intracellular cyclic GMP and hyperpolarization of the cell. The cell recovers by shutting down this cascade and resynthesizing cGMP. Many of the reactions responsible for the excitation and recovery phases of the photoresponse have been identified. Here I review some characteristics of the proteins that participate in these reactions.     

Rhodopsin controls a conformational switch on the transducin gamma subunit

Rhodopsin, a prototypical G protein-coupled receptor, catalyzes the activation of a heterotrimeric G protein, transducin, to initiate a visual signaling cascade in photoreceptor cells. The betagamma subunit complex, especially the C-terminal domain of the transducin gamma subunit, Gtgamma(60-71)farnesyl, plays a pivotal role in allosteric regulation of nucleotide exchange on the transducin alpha subunit by light-activated rhodopsin. We report that this domain is unstructured in the presence of an inactive receptor but forms an amphipathic helix upon rhodopsin activation. A K65E/E66K charge reversal mutant of the gamma subunit has diminished interactions with the receptor and fails to adopt the helical conformation. The identification of this conformational switch provides a mechanism for active GPCR utilization of the betagamma complex in signal transfer to G proteins.     

Signal transduction in the visual cascade involves specific lipid-protein interactions

In retinal rod photoreceptor cells, transducin (Gt) and cyclic GMP phosphodiesterase (PDE) are peripherally anchored to the cytoplasmic surface of the disk saccules. We have examined the role of specific phospholipids in the interaction of these proteins with native osmotically intact disk vesicles, employing spin-labeled phospholipid analogues (2% of total phospholipids) and bovine serum albumin back-exchange assay. Inactive GDP-bound transducin exclusively reduced the extraction of negatively charged phosphatidylserine. The effect disappeared upon activation of the G-protein with guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS). PDE affected the extraction of the zwitterionic phosphatidylcholine and, to a smaller extent, of phosphatidylethanolamine. When active GtGTPgammaS interacted with the PDE to form the active effector, the interaction with phosphatidylcholine was specifically enhanced. Each copy of the G-protein bound 3 +/- 1 molecules of phosphatidylserine, whereas the PDE bound a much larger amount (70 +/- 10) of a mixture of phosphatidylcholine and ethanolamine. The results are interpreted as a head group-specific and state-dependent interaction of the signaling proteins with the phospholipids of the photoreceptor membrane.     

Expression and characterization of human PDEδ and its Caenorhabditiselegans ortholog CEδ

Cyclic GMP phosphodiesterase (PDE) is rod photoreceptor disk membrane-associated via C-terminal lipid tails. PDEδ, a recently identified subunit, was shown to disrupt PDE/membrane interaction under physiological conditions, without affecting PDE catalytic activity. We found that a PDEδ ortholog from the eyeless nematode Caenorhabditiselegans (termed CEδ) solubilizes bovine PDE in vitro with an EC₅₀ very similar to PDEδ. Immobilized PDEδ and CEδ both bind, in addition to bovine PDE, an N-terminal fragment of human retinitis pigmentosa GTPase regulator, but not rhodopsin kinase and Ran binding protein 1. The results suggest that PDEδ and CEδ may regulate membrane binding of a variety of proteins in photoreceptors and other tissues.     

Visible light modulates the expression of cancer-retina antigens

Proteins involved in the visual signaling cascade show light-dependent expression levels in photoreceptor cells. Recently, these proteins have been described to be expressed in neuroectodermal tumors and to function as cancer-retina antigens. Here, we show that light can down-regulate gene expression of rhodopsin, transducin, and cyclic guanosine 3',5'-monophosphate phosphodiesterase 6 (PDE6) and up-regulate guanylyl cyclase 1, recoverin, and arrestin in human melanoma cells in vitro, comparable to physiologic changes earlier observed in photoreceptor cells. Similar modulation can be detected at the protein level in melanoma cells except for no changes in PDE6 protein levels. Two regulatory pathways have been identified: Sp1/Sp3/Sp4 proteins for rhodopsin and PDE6, and mitogen-activated protein kinases for recoverin and arrestin. The visual cascade and retinoic acid as its derivate do not play any role in this process. Putative explanations for light-dependent modulation of cancer-retina antigen expression in melanoma cells are discussed.     

Rapid transducin deactivation in intact stacks of bovine rod outer segment disks as studied by light scattering techniques. Arrestin requires additional soluble proteins for rapid quenching of rhodopsin catalytic activity

In photoreceptors of the living retina both activation and deactivation of transducin must occur in less than 1 s. In ROS preparations used for in vitro studies, however, deactivation takes minutes. This is due to the fact that activated transducin is released into the free aqueous space, whereby GTPase activity and consequent deactivation of the protein are slowed down, and due to the dilution of soluble ROS proteins involved in the quenching of rhodopsin activity. In this paper, using a convenient, non-invasive light scattering assay, we demonstrate that in an intact stack of disks, where active transducin stays membrane associated and is rapidly deactivated, the activity of rhodopsin can also be quenched in the time range of seconds when soluble ROS proteins are supplemented. Arrestin, the 48 kDa protein of the photoreceptor, is one of the proteins required for rapid recovery, however, it requires the synergistic action of other soluble proteins (besides rhodopsin kinase) in order to exert its effect: When arrestin is included in the reaction mixture without the 'helper protein(s)', it cannot speed recovery, and when a mixture of soluble proteins is added which lacks arrestin, there is also no effect. The nature and identity of this (these) helper protein(s) are still unclear.     

Regulation of retinal transducin by C-terminal peptides of rhodopsin.

Transducin is a multi-subunit guanine-nucleotide-binding protein that mediates signal coupling between rhodopsin and cyclic GMP phosphodiesterase in retinal rod outer segments. Whereas the T alpha subunit of transducin binds guanine nucleotides and is the activator of the phosphodiesterase, the T beta gamma subunit may function to link physically T alpha with photolysed rhodopsin. In order to determine the binding sites of rhodopsin to transducin, we have synthesized eight peptides (Rhod-1 etc.) that correspond to the C-terminal regions of rhodopsin and to several external and one internal loop region. These peptides were tested for their inhibition of restored GTPase activity of purified transducin reconstituted into depleted rod-outer-segment disc membranes. A marked inhibition of GTPase activity was observed when transducin was pre-incubated with peptides Rhod-1, Rhod-2 and Rhod-3. These peptides correspond to opsin amino acid residues 332-339, 324-331 and 317-321 respectively. Peptides corresponding to the three external loop regions or to the C-terminal residues 341-348 did not inhibit reconsituted GTPase activity. Likewise, Rhod-8, a peptide corresponding to an internal loop region of rhodopsin, did not inhibit GTPase activity. These findings support the concept that these specific regions of the C-terminus of rhodopsin serve as recognition sites for transducin.