Opsins form a family of light-activated, retinal-dependent, G protein-coupled receptors (GPCRs) that serve a multitude of visual and nonvisual functions. Opsin 3 (OPN3 or encephalopsin), initially identified in the brain, remains one of the few members of the mammalian opsin family with unknown function and ambiguous light absorption properties. We recently discovered that OPN3 is highly expressed in human epidermal melanocytes (HEMs)-the skin cells that produce melanin. The melanin pigment is a critical defense against ultraviolet radiation (UVR), and its production is mediated by the Gαs-coupled melanocortin 1 receptor (MC1R). The physiological function and light sensitivity of OPN3 in melanocytes are yet to be determined. Here, we show that in HEMs, OPN3 acts as a negative regulator of melanin production by modulating the signaling of MC1R. OPN3 negatively regulates the cyclic adenosine monophosphate (cAMP) response evoked by MC1R via activation of the Gαi subunit of G proteins, thus decreasing cellular melanin levels. In addition to their functional relationship, OPN3 and MC1R colocalize at both the plasma membrane and in intracellular structures, and can form a physical complex. Remarkably, OPN3 can bind retinal, but does not mediate light-induced signaling in melanocytes. Our results identify a function for OPN3 in the regulation of the melanogenic pathway in epidermal melanocytes; we have revealed a light-independent function for the poorly characterized OPN3 and a pathway that greatly expands our understanding of melanocyte and skin physiology. opsin3 | encephalopsin | melanocytes | melanocortin 1 receptor | pigmentation U nlike most mammals, which have melanin-producing melanocytes predominantly in the hair follicle bulb (1), humans are uniquely equipped with melanocytes in the outermost layer of the skin, the epidermis (2, 3). These neural crest-derived melanocytes are the only source of the photoprotective pigment melanin in human skin, and thus are critical for the defense against solar ultraviolet radiation (UVR)-induced genotoxic damage (4-6).Solar UVR at the surface of the earth is composed of ∼5% short-wavelength UVB rays and ∼95% long-wavelength UVA rays. Much of our current knowledge about melanogenesis in epidermal melanocytes stems from the well-characterized UVBinduced melanin pathway (7). UVB elicits DNA damage in epidermal keratinocytes, triggering facultative skin darkening through increased melanin production in neighboring melanocytes (8). UVB-irradiated keratinocytes and melanocytes locally secrete α-melanocyte stimulating hormone (α-MSH), an agonist of the Gαs-coupled melanocortin 1 receptor (MC1R) that is primarily expressed on melanocytes (8,9). MC1R has a pivotal role in determining pigmentation, as several naturally occurring loss-offunction MC1R variants are associated with the redhead phenotype (10, 11) characterized by a pale complexion and increased sensitivity to UVR (12). Downstream, α-MSH-induced MC1R activation leads to stimulation of adenylyl cyclase (AC) and production of...
RhoPDE is a type I rhodopsin/phosphodiesterase gene fusion product from the choanoflagellate Salpingoeca rosetta. The gene was discovered around the time that a similar type I rhodopsin/guanylyl cyclase fusion protein, RhoGC, was shown to control phototaxis of an aquatic fungus through a cGMP signaling pathway. RhoPDE has potential as an optogenetic tool catalyzing the hydrolysis of cyclic nucleotides. Here we provide an expression and purification system for RhoPDE, as well as a crystal structure of the C-terminal phosphodiesterase catalytic domain. We show that RhoPDE contains an even number of transmembrane segments, with N- and C-termini both located on the cytoplasmic surface of the cell membrane. The purified protein exhibits an absorption maximum at 490 nm in the dark state, which shifts to 380 nm upon exposure to light. The protein acts as a cGMP-selective phosphodiesterase. However, the activity does not appear to be modulated by light. The protein is also active with cAMP as a substrate, but with a roughly 5–7-fold lower kcat. A truncation consisting solely of the phosphodiesterase domain is also active with a kcat for cGMP roughly 6–9-fold lower than that of the full-length protein. The isolated PDE domain was crystallized, and the X-ray structure showed the protein to be a dimer similar to human PDE9. We anticipate that the purification system introduced here will enable further structural and biochemical experiments to improve our understanding of the function and mechanism of this unique fusion protein.
RhoGC is a rhodopsin (Rho)-guanylyl cyclase (GC) gene fusion molecule that is central to zoospore phototaxis in the aquatic fungus It has generated considerable excitement because of its demonstrated potential as a tool for optogenetic manipulation of cell-signaling pathways involving cyclic nucleotides. However, a reliable method for expressing and purifying RhoGC is currently lacking. We present here an expression and purification system for isolation of the full-length RhoGC protein expressed in HEK293 cells in detergent solution. The protein exhibits robust light-dependent guanylyl cyclase activity, whereas a truncated form lacking the 17- to 20-kDa N-terminal domain is completely inactive under identical conditions. Moreover, we designed several RhoGC mutants to increase the utility of the protein for optogenetic studies. The first class we generated has altered absorption spectra designed for selective activation by different wavelengths of light. Two mutants were created with blue-shifted (E254D, λ = 390 nm; D380N, λ = 506 nm) and one with red-shifted (D380E, λ = 533 nm) absorption maxima relative to the wild-type protein (λ = 527 nm). We also engineered a double mutant, E497K/C566D, that changes the enzyme to a specific, light-stimulated adenylyl cyclase that catalyzes the formation of cAMP from ATP. We anticipate that this expression/purification system and these RhoGC mutants will facilitate mechanistic and structural exploration of this important enzyme.
RhoGC is a fusion protein from the aquatic fungus , combining a type I rhodopsin domain with a guanylyl cyclase domain. It has generated excitement as an optogenetics tool for the manipulation of cyclic nucleotide signaling pathways. To investigate the regulation of the cyclase activity, we isolated the guanylyl cyclase domain from with (GCwCC) and without (GC) the coiled-coil linker. Both constructs were constitutively active but were monomeric as determined by size-exclusion chromatography and analytical ultracentrifugation, whereas other class III nucleotidyl cyclases are functional dimers. We also observed that crystals of GC have only a monomer in an asymmetric unit. Dimers formed when crystals were grown in the presence of the non-cyclizable substrate analog 2',3'-dideoxyguanosine-5'-triphosphate, MnCl, and tartrate, but their quaternary structure did not conform to the canonical pairing expected for class III enzymes. Moreover, the structure contained a disulfide bond formed with an active-site Cys residue required for activity. We consider it unlikely that the disulfide would form under intracellular reducing conditions, raising the possibility that this unusual dimer might have a biologically relevant role in the regulation of full-length RhoGC. Although we did not observe it with direct methods, a functional dimer was identified as the active state by following the dependence of activity on total enzyme concentration. The low affinity observed for GC monomers is unusual for this enzyme class and suggests that dimer formation may contribute to light activation of the full-length protein.
Opsins form a family of light-activated, retinal-dependent G-protein coupled receptors (GPCRs) that serve a multitude of visual and non-visual functions. Opsin3 (OPN3 or encephalopsin), initially identified in the brain, remains one of the few members of the mammalian opsin family with unknown function and ambiguous light-absorption properties. We recently discovered that OPN3 is highly expressed in human epidermal melanocytes-the skin cells that produce melanin. The melanin pigment is a critical defense against ultraviolet radiation and its production is mediated by the Gs-coupled melanocortin-1 receptor (MC1R). The physiological function and light-sensitivity of OPN3 in melanocytes is yet to be determined.Here we show that in human epidermal melanocytes OPN3 acts as a negative regulator of melanin production by interacting with MC1R and modulating its cAMP signaling. OPN3 negatively regulates the cAMP response evoked by MC1R via activation of the Gαi subunit of G-proteins, thus decreasing cellular melanin levels. In addition to their functional relationship, OPN3 and MC1R colocalize at both the plasma membrane and in intracellular structures and form a physical complex. Remarkably, OPN3 can bind retinal, but does not mediate light-induced signaling in melanocytes. Our results identify a novel function for OPN3 in the regulation of the melanogenic pathway in epidermal melanocytes. Our results reveal a light-independent function for the poorly characterized OPN3 and a novel pathway that greatly expands our understanding of melanocyte and skin physiology. Key words:Opsin3 | Encephalopsin | Melanocortin 1 Receptor | Pigmentation | Human Epidermal Melanocyte SignificanceOur data reveals a novel function for the non-visual opsin OPN3 in regulating the pigmentation of human melanocytes by interacting with and modulating the activity of MC1R.
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