Structural and functional differences of two forms of GTP-binding protein, Gq, in the cephalopod retina

Visual phototransduction components in cephalopod chromatophores suggest dermal photoreception

Cephalopod mollusks are renowned for their colorful and dynamic body patterns, produced by an assemblage of skin components that interact with light. These may include iridophores, leucophores, chromatophores and (in some species) photophores. Here, we present molecular evidence suggesting that cephalopod chromatophores – small dermal pigmentary organs that reflect various colors of light – are photosensitive. RT-PCR revealed the presence of transcripts encoding rhodopsin and retinochrome within the retinas and skin of the squid Doryteuthis pealeii, and the cuttlefish Sepia officinalis and Sepia latimanus. In D. pealeii, Gqα and squid TRP channel transcripts were present in the retina and in all dermal samples. Rhodopsin, retinochrome and Gqα transcripts were also found in RNA extracts from dissociated chromatophores isolated from D. pealeii dermal tissues. Immunohistochemical staining labeled rhodopsin, retinochrome and Gqα proteins in several chromatophore components, including pigment cell membranes, radial muscle fibers, and sheath cells. This is the first evidence that cephalopod dermal tissues, and specifically chromatophores, may possess the requisite combination of molecules required to respond to light.

Opsin1-2, G(q)α and arrestin levels at Limulus rhabdoms are controlled by diurnal light and a circadian clock

Dark and light adaptation in photoreceptors involve multiple processes including those that change protein concentrations at photosensitive membranes. Light- and dark-adaptive changes in protein levels at rhabdoms have been described in detail in white-eyed Drosophila maintained under artificial light. Here we tested whether protein levels at rhabdoms change significantly in the highly pigmented lateral eyes of wild-caught Limulus polyphemus maintained in natural diurnal illumination and whether these changes are under circadian control. We found that rhabdomeral levels of opsins (Ops1-2), the G protein activated by rhodopsin (G(q)α) and arrestin change significantly from day to night and that nighttime levels of each protein at rhabdoms are significantly influenced by signals from the animal's central circadian clock. Clock input at night increases Ops1-2 and G(q)α and decreases arrestin levels at rhabdoms. Clock input is also required for a rapid decrease in rhabdomeral Ops1-2 beginning at sunrise. We found further that dark adaptation during the day and the night are not equivalent. During daytime dark adaptation, when clock input is silent, the increase of Ops1-2 at rhabdoms is small and G(q)α levels do not increase. However, increases in Ops1-2 and G(q)α at rhabdoms are enhanced during daytime dark adaptation by treatments that elevate cAMP in photoreceptors, suggesting that the clock influences dark-adaptive increases in Ops1-2 and G(q)α at Limulus rhabdoms by activating cAMP-dependent processes. The circadian regulation of Ops1-2 and G(q)α levels at rhabdoms probably has a dual role: to increase retinal sensitivity at night and to protect photoreceptors from light damage during the day.

Degradation of the non-palmitoylated invertebrate visual guanine-nucleotide binding protein, iGq alpha(C3,4A), by the ubiquitin-proteasomal pathway is regulated by its activation and translocation to the cytoplasm

Light-dependent translocation of invertebrate visual guanine-nucleotide binding protein, iGq alpha, from rhabdomeric membranes to the cytoplasm is one of many mechanisms that contribute to light adaptation in the invertebrate eye. We have previously cloned iGq alpha from a Loligo pealei photoreceptor cDNA library and shown that when expressed in HEK 293T cells it is palmitoylated. In this study we compared the activation, cytoplasmic translocation, and turnover of iGq alpha with that of a non-palmitoylated mutant, iGq alpha(C3,4A). In the HEK 293T cells, muscarinic M1 receptors coupled equally well to iGq alpha and iGq alpha(C3,4A) to activate phospholipase C. Activation of iGq alpha(C3,4A), but not iGq alpha, induced translocation of the alpha subunit from the membrane to cytosol with rapid degradation of the soluble protein resulting in a decreased half-life for iGq alpha(C3,4A) of 10 hours compared to 20 hours for iGq alpha. Degradation of iGq alpha(C3,4A) was inhibited by proteasomal inhibitors but not by inhibitors of lysosomal proteases or calpain. The presence of the proteasomal inhibitor led to the accumulation of polyubiquitinated species of either iGq alpha or iGq alpha(C3,4A). Our results suggest that palmitoylation of iGq alpha is required to maintain membrane association of the protein in its active conformation, and whereas membrane-bound and soluble iGq alpha can be polyubiquitinated, membrane association protects the protein from rapid degradation by the proteasomal pathway.

Evidence for multiple signaling pathways in single squid olfactory receptor neurons

At least two different G-protein-mediated transduction cascades, the adenylate cyclase and phospholipase C (PLC) pathway, process chemosensory stimuli for various species. In squid olfactory receptor neurons (ORNs), physiological studies indicate that both pathways may be present; however, confirmation of the transduction molecules at the protein level is absent. Here we provide evidence that the G-proteins involved in both adenylate cyclase and PLC pathways are present in squid ORNs (Lolliguncula brevis). We used immunoblotting to show that Galpha(olf), Galpha(q), and a downstream effector, enzyme PLC140, are present in the squid olfactory epithelium (OE). To localize these proteins to one or more of the five morphological cell types described for squid OE, paraformaldehyde-fixed olfactory organs were cryosectioned (10 microm), double-labeled for Galpha(olf), Galpha(q), or PLC140, and imaged. Analysis of serial sections from entire olfactory organs for epithelial area and patterns of immunofluorescence revealed a region of highest immunoreactivity at the anterior half of the organ. At the cellular level, type 1 cells could not be distinguished morphologically and were not included in the analysis. The three labeling patterns observed in type 2 cells were Galpha(q) alone, PLC140 alone, and colocalization of Galpha(q) and PLC140. Subsets of cell types 3, 4, and 5 showed colocalization of Galpha(olf) with Galpha(q) but not with PLC140. These data suggest that the PLC pathway predominates in type 2 cells; however, coexpression of Galpha(olf) with Galpha(q) in cell types 3, 4, and 5 suggests that both pathways may participate in olfactory transduction in non-type 2 squid ORNs.

Palmitoylation is required for membrane association of activated but not inactive invertebrate visual Gqalpha

The invertebrate visual G protein, iGqalpha plays a central role in invertebrate phototransduction by relaying signals from rhodopsin to phospholipase C leading to membrane depolarization. Previous studies have shown reversible association of iGqalpha with rhabdomeric membranes regulated by light. To address the mechanism of membrane association we cloned iGqalpha from a Loligo pealei photoreceptor cDNA library and expressed it in HEK293T cells. Mutations were introduced to eliminate putative sites for palmitoylation at cysteines in positions 3 and 4. Membrane and soluble fractions were prepared from cells where iGqalpha was either activated or maintained in the GDP-bound form, followed by identification of iGqalpha through immunoblot analysis. The wild-type iGqalpha was entirely membrane-bound and shown to be post-translationally modified by palmitoylation. The mutant iGqalpha (C3,4A) was not palmitoylated yet it was found to be membrane-associated in the inactive state, however, approximately half of the protein became soluble when activated. These results suggest that palmitoylation is not required for membrane association of iGqalpha in the inactive state but is important in maintaining the stable membrane association of activated iGqalpha-GTP. The mechanism by which iGqalpha moves away from the membrane into the cytosol in response to prolonged light-stimulation in the native squid eye appears, therefore, to involve both activation and depalmitoylation processes.

Regulation of light-dependent Gqalpha translocation and morphological changes in fly photoreceptors

Heterotrimeric G-proteins relay signals between membrane-bound receptors and downstream effectors. Little is known, however, about the regulation of Galpha subunit localization within the natural endogenous environment of a specialized signaling cell. Here we show, using live Drosophila flies, that light causes massive and reversible translocation of the visual Gqalpha to the cytosol, associated with marked architectural changes in the signaling compartment. Molecular genetic dissection together with detailed kinetic analysis enabled us to characterize the translocation cycle and to unravel how signaling molecules that interact with Gqalpha affect these processes. Epistatic analysis showed that Gqalpha is necessary but not sufficient to bring about the morphological changes in the signaling organelle. Furthermore, mutant analysis indicated that Gqbeta is essential for targeting of Gqalpha to the membrane and suggested that Gqbeta is also needed for efficient activation of Gqalpha by rhodopsin. Our results support the 'two-signal model' hypothesis for membrane targeting in a living organism and characterize the regulation of both the activity-dependent Gq localization and the cellular architectural changes in Drosophila photoreceptors.

Distinct characteristic of Galpha(h) (transglutaminase II) by compartment: GTPase and transglutaminase activities

Galpha(h) (transglutaminase II) is a bifunctional enzyme possessing transglutaminase and GTPase activities. To better understand the factors affecting these two functions of Galpha(h), we have examined the characteristics of purified Galpha(h) from membrane and cytosol. GTP binding activity of mouse heart Galpha(h) was higher in membrane than that from cytosol. Furthermore, phospholipase C-delta1 (PLC-delta1) activity and coimmunoprecipitation of Galpha(h)-coupled PLC-delta1 in the alpha(1)-adrenoceptor-Galpha(h)-PLC-delta1 complex preparations were increased by phenylephrine in the presence of membranous Galpha(h). On the other hand, transglutaminase activity of cytosolic Galpha(h) was higher than that from membrane Galpha(h). These results demonstrate that bifunctions of Galpha(h) are regulated by its localization that can reflect the cellular functions of Galpha(h).

Dissociation of G-protein alpha from rhabdomeric membranes decreases its interaction with rhodopsin and increases its degradation by calpain

Photoactivation of invertebrate rhodopsin activates a GTP-binding protein, Gq, which in turn activates a phospholipase C (PLC) enzyme. Gqalpha is a membrane-associated protein that is progressively released from the membrane by washing with buffers containing increasing concentrations of beta-mercaptoethanol (beta-ME). Isolated, soluble Gqalpha showed a decreased ability to be activated by rhodopsin but was more active in stimulating PLC when compared with the membrane-associated form of Gqalpha. The calcium-activated protease, calpain, selectively cleaved the soluble but not the membrane-bound form of Gqalpha. Calpain cleaved a small peptide from the amino-terminus of Gqalpha reducing the ability of the G-protein to bind GTP. The uncoupling of Gqalpha from rhodopsin and subsequent calcium-dependent proteolysis to further inactivate the G-protein may therefore be a regulatory mechanism of light adaptation in rhabdomeric photoreceptors.