Your search keyword '"YAMASHITA, TAKAHIRO"' showing total 20 results

1. Direct photoreception by pituitary endocrine cells regulates hormone release and pigmentation.

Author

Fukuda A, Sato K, Fujimori C, Yamashita T, Takeuchi A, Ohuchi H, Umatani C, and Kanda S

Subjects

Animals, Melanotrophs metabolism, Monophenol Monooxygenase metabolism, Ultraviolet Rays, Calcium metabolism, Fish Proteins metabolism, Fish Proteins genetics, Melanins biosynthesis, Melanins genetics, Oryzias metabolism, Oryzias genetics, Pituitary Gland metabolism, Skin Pigmentation genetics, Opsins genetics, Opsins metabolism

Abstract

The recent discovery of nonvisual photoreceptors in various organs has raised expectations for uncovering their roles and underlying mechanisms. In this work, we identified a previously unrecognized hormone-releasing mechanism in the pituitary of the Japanese rice fish (medaka) induced by light. Ca 2+ imaging analysis revealed that melanotrophs, a type of pituitary endocrine cell that secretes melanocyte-stimulating hormone, robustly increase the concentration of intracellular Ca 2+ during short-wavelength light exposure. Moreover, we identified Opn5m as the key molecule that drives this response. Knocking out opn5m attenuated melanogenesis by reducing tyrosinase expression in the skin. Our findings suggest a mechanism in which direct reception of short-wavelength light by pituitary melanotrophs triggers a pathway that might contribute to protection from ultraviolet radiation in medaka.

Published

2025

2. Functional diversification process of opsin genes for teleost visual and pineal photoreceptions.

Author

Fujiyabu C, Gyoja F, Sato K, Kawano-Yamashita E, Ohuchi H, Kusakabe TG, and Yamashita T

Subjects

Animals, Introns genetics, Amino Acid Sequence, Gene Duplication, Fishes genetics, Pineal Gland metabolism, Phylogeny, Evolution, Molecular, Opsins genetics, Opsins metabolism, Rhodopsin genetics, Rhodopsin metabolism

Abstract

Most vertebrates have a rhodopsin gene with a five-exon structure for visual photoreception. By contrast, teleost fishes have an intron-less rhodopsin gene for visual photoreception and an intron-containing rhodopsin (exo-rhodopsin) gene for pineal photoreception. Here, our analysis of non-teleost and teleost fishes in various lineages of the Actinopterygii reveals that retroduplication after branching of the Polypteriformes produced the intron-less rhodopsin gene for visual photoreception, which converted the parental intron-containing rhodopsin gene into a pineal opsin in the common ancestor of the Teleostei. Additional analysis of a pineal opsin, pinopsin, shows that the pinopsin gene functions as a green-sensitive opsin together with the intron-containing rhodopsin gene for pineal photoreception in tarpon as an evolutionary intermediate state but is missing in other teleost fishes, probably because of the redundancy with the intron-containing rhodopsin gene. We propose an evolutionary scenario where unique retroduplication caused a "domino effect" on the functional diversification of teleost visual and pineal opsin genes., (© 2024. The Author(s).)

Published

2024

3. Mammalian type opsin 5 preferentially activates G14 in Gq-type G proteins triggering intracellular calcium response.

Author

Sato K, Yamashita T, and Ohuchi H

Subjects

Humans, Mice, Animals, Calcium metabolism, Signal Transduction, Receptors, G-Protein-Coupled metabolism, Rod Opsins metabolism, Mammals metabolism, Opsins genetics, Opsins metabolism, GTP-Binding Protein alpha Subunits, Gq-G11 genetics, GTP-Binding Protein alpha Subunits, Gq-G11 metabolism

Abstract

Mammalian type opsin 5 (Opn5m), a UV-sensitive G protein-coupled receptor opsin highly conserved in vertebrates, would provide a common basis for UV sensing from lamprey to humans. However, G protein coupled with Opn5m remains controversial due to variations in assay conditions and the origin of Opn5m across different reports. Here, we examined Opn5m from diverse species using an aequorin luminescence assay and Gα-KO cell line. Beyond the commonly studied major Gα classes, Gαq, Gα11, Gα14, and Gα15 in the Gq class were individually investigated in this study, as they can drive distinct signaling pathways in addition to a canonical calcium response. UV light triggered a calcium response via all the tested Opn5m proteins in 293T cells, which was abolished by Gq-type Gα deletion and rescued by cotransfection with mouse and medaka Gq-type Gα proteins. Opn5m preferentially activated Gα14 and close relatives. Mutational analysis implicated specific regions, including α3-β5 and αG-α4 loops, αG and α4 helices, and the extreme C terminus, in the preferential activation of Gα14 by Opn5m. FISH revealed co-expression of genes encoding Opn5m and Gα14 in the scleral cartilage of medaka and chicken eyes, supporting their physiological coupling. This suggests that the preferential activation of Gα14 by Opn5m is relevant for UV sensing in specific cell types., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the content of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

4. Diversification processes of teleost intron-less opsin genes.

Author

Fujiyabu C, Sato K, Ohuchi H, and Yamashita T

Subjects

Animals, Phylogeny, Rhodopsin genetics, Rhodopsin metabolism, Zebrafish genetics, Oryzias genetics, Synteny genetics, Evolution, Molecular, Fishes genetics, Fishes physiology, Introns, Opsins genetics, Opsins metabolism

Abstract

Opsins are universal photosensitive proteins in animals. Vertebrates have a variety of opsin genes for visual and non-visual photoreceptions. Analysis of the gene structures shows that most opsin genes have introns in their coding regions. However, teleosts exceptionally have several intron-less opsin genes that are presumed to have been duplicated by an RNA-based gene duplication mechanism, retroduplication. Among these retrogenes, we focused on the Opn4 (melanopsin) gene responsible for non-image-forming photoreception. Many teleosts have five Opn4 genes including one intron-less gene, which is speculated to have been formed from a parental intron-containing gene in the Actinopterygii. In this study, to reveal the evolutionary history of Opn4 genes, we analyzed them in teleost (zebrafish and medaka) and non-teleost (bichir, sturgeon, and gar) fishes. Our synteny analysis suggests that the intron-less Opn4 gene emerged by retroduplication after the branching of the bichir lineage. In addition, our biochemical and histochemical analyses showed that, in the teleost lineage, the newly acquired intron-less Opn4 gene became abundantly used without substantial changes in the molecular properties of the Opn4 protein. This stepwise evolutionary model of Opn4 genes is quite similar to that of rhodopsin genes in the Actinopterygii. The unique acquisition of rhodopsin and Opn4 retrogenes would have contributed to the diversification of the opsin gene repertoires in the Actinopterygii and the adaptation of teleosts to various aquatic environments., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

5. Convergent evolutionary counterion displacement of bilaterian opsins in ciliary cells.

Author

Sakai K, Ikeuchi H, Fujiyabu C, Imamoto Y, and Yamashita T

Subjects

Animals, Nucleotides, Cyclic metabolism, Photoreceptor Cells metabolism, Vertebrates, Opsins genetics, Opsins metabolism, Rhodopsin genetics, Rhodopsin metabolism

Abstract

Opsins are universal photoreceptive proteins in animals. Vertebrate rhodopsin in ciliary photoreceptor cells photo-converts to a metastable active state to regulate cyclic nucleotide signaling. This active state cannot photo-convert back to the dark state, and thus vertebrate rhodopsin is categorized as a mono-stable opsin. By contrast, mollusk and arthropod rhodopsins in rhabdomeric photoreceptor cells photo-convert to a stable active state to stimulate IP 3 /calcium signaling. This active state can photo-convert back to the dark state, and thus these rhodopsins are categorized as bistable opsins. Moreover, the negatively charged counterion position crucial for the visible light sensitivity is different between vertebrate rhodopsin (Glu113) and mollusk and arthropod rhodopsins (Glu181). This can be explained by an evolutionary scenario where vertebrate rhodopsin newly acquired Glu113 as a counterion, which is thought to have led to higher signaling efficiency of vertebrate rhodopsin. However, the detailed evolutionary steps which led to the higher efficiency in vertebrate rhodopsin still remain unknown. Here, we analyzed the xenopsin group, which is phylogenetically distinct from vertebrate rhodopsin and functions in protostome ciliary cells. Xenopsins are blue-sensitive bistable opsins that regulate cAMP signaling. We found that a bistable xenopsin of Leptochiton asellus had Glu113 as a counterion but did not exhibit elevated signaling efficiency. Therefore, our results show that vertebrate rhodopsin and L. asellus xenopsin regulate cyclic nucleotide signaling in ciliary cells and displaced the counterion position from Glu181 to Glu113 via convergent evolution, whereas subsequently only vertebrate rhodopsin elevated its signaling efficiency by acquiring the mono-stable property., (© 2022. The Author(s), under exclusive licence to Springer Nature Switzerland AG.)

Published

2022

6. Amino acid residue at position 188 determines the UV-sensitive bistable property of vertebrate non-visual opsin Opn5.

Author

Fujiyabu C, Sato K, Nishio Y, Imamoto Y, Ohuchi H, Shichida Y, and Yamashita T

Subjects

Animals, Membrane Proteins chemistry, Opsins chemistry, Xenopus, Xenopus Proteins chemistry, Amino Acids chemistry, Membrane Proteins radiation effects, Opsins radiation effects, Ultraviolet Rays, Xenopus Proteins radiation effects

Abstract

Opsins are G protein-coupled receptors specialized for photoreception in animals. Opn5 is categorized in an independent opsin group and functions for various non-visual photoreceptions. Among vertebrate Opn5 subgroups (Opn5m, Opn5L1 and Opn5L2), Opn5m and Opn5L2 bind 11-cis retinal to form a UV-sensitive resting state, which is inter-convertible with the all-trans retinal bound active state by photoreception. Thus, these opsins are characterized as bistable opsins. To assess the molecular basis of the UV-sensitive bistable property, we introduced comprehensive mutations at Thr188, which is well conserved among these opsins. The mutations in Opn5m drastically hampered 11-cis retinal incorporation and the bistable photoreaction. Moreover, T188C mutant Opn5m exclusively bound all-trans retinal and thermally self-regenerated to the original form after photoreception, which is similar to the photocyclic property of Opn5L1 bearing Cys188. Therefore, the residue at position 188 underlies the UV-sensitive bistable property of Opn5m and contributes to the diversification of vertebrate Opn5 subgroups., (© 2022. The Author(s).)

Published

2022

7. Opn5L1 is a retinal receptor that behaves as a reverse and self-regenerating photoreceptor.

Author

Sato K, Yamashita T, Ohuchi H, Takeuchi A, Gotoh H, Ono K, Mizuno M, Mizutani Y, Tomonari S, Sakai K, Imamoto Y, Wada A, and Shichida Y

Subjects

Animals, Chickens, Chromatography, High Pressure Liquid, Factor Xa chemistry, HEK293 Cells, Humans, In Situ Hybridization, Light, Male, Photoreceptor Cells, Protein Binding, Recombinant Proteins chemistry, Regeneration, Retinaldehyde metabolism, Rhodopsin chemistry, Signal Transduction, Vitamin A chemistry, Xenopus metabolism, Opsins chemistry, Photoreceptor Cells, Vertebrate chemistry

Abstract

Most opsins are G protein-coupled receptors that utilize retinal both as a ligand and as a chromophore. Opsins' main established mechanism is light-triggered activation through retinal 11-cis-to-all-trans photoisomerization. Here we report a vertebrate non-visual opsin that functions as a Gi-coupled retinal receptor that is deactivated by light and can thermally self-regenerate. This opsin, Opn5L1, binds exclusively to all-trans-retinal. More interestingly, the light-induced deactivation through retinal trans-to-cis isomerization is followed by formation of a covalent adduct between retinal and a nearby cysteine, which breaks the retinal-conjugated double bond system, probably at the C 11 position, resulting in thermal re-isomerization to all-trans-retinal. Thus, Opn5L1 acts as a reverse photoreceptor. We conclude that, like vertebrate rhodopsin, Opn5L1 is a unidirectional optical switch optimized from an ancestral bidirectional optical switch, such as invertebrate rhodopsin, to increase the S/N ratio of the signal transduction, although the direction of optimization is opposite to that of vertebrate rhodopsin.

Published

2018

8. Evolutionary steps involving counterion displacement in a tunicate opsin.

Author

Kojima K, Yamashita T, Imamoto Y, Kusakabe TG, Tsuda M, and Shichida Y

Subjects

Amino Acid Sequence, Animals, Biological Evolution, Ciona intestinalis physiology, Evolution, Molecular, GTP-Binding Proteins metabolism, Glutamic Acid metabolism, Phylogeny, Receptors, G-Protein-Coupled metabolism, Rhodopsin metabolism, Rod Opsins metabolism, Urochordata physiology, Opsins chemistry, Opsins metabolism, Opsins physiology

Abstract

Ci-opsin1 is a visible light-sensitive opsin present in the larval ocellus of an ascidian, Ciona intestinalis This invertebrate opsin belongs to the vertebrate visual and nonvisual opsin groups in the opsin phylogenetic tree. Ci-opsin1 contains candidate counterions (glutamic acid residues) at positions 113 and 181; the former is a newly acquired position in the vertebrate visual opsin lineage, whereas the latter is an ancestral position widely conserved among invertebrate opsins. Here, we show that Glu113 and Glu181 in Ci-opsin1 act synergistically as counterions, which imparts molecular properties to Ci-opsin1 intermediate between those of vertebrate- and invertebrate-type opsins. Synergy between the counterions in Ci-opsin1 was demonstrated by E113Q and E181Q mutants that exhibit a pH-dependent spectral shift, whereas only the E113Q mutation in vertebrate rhodopsin yields this spectral shift. On absorbing light, Ci-opsin1 forms an equilibrium between two intermediates with protonated and deprotonated Schiff bases, namely the MI-like and MII-like intermediates, respectively. Adding G protein caused the equilibrium to shift toward the MI-like intermediate, indicating that Ci-opsin1 has a protonated Schiff base in its active state, like invertebrate-type opsins. Ci-opsin1's G protein activation efficiency is between the efficiencies of vertebrate- and invertebrate-type opsins. Interestingly, the E113Y and E181S mutations change the molecular properties of Ci-opsin1 into those resembling invertebrate-type or bistable opsins and vertebrate ancient/vertebrate ancient-long or monostable opsins, respectively. These results strongly suggest that acquisition of counterion Glu113 changed the molecular properties of visual opsin in a vertebrate/tunicate common ancestor as a crucial step in the evolution of vertebrate visual opsins., Competing Interests: The authors declare no conflict of interest.

Published

2017

9. Adaptation of cone pigments found in green rods for scotopic vision through a single amino acid mutation.

Author

Kojima K, Matsutani Y, Yamashita T, Yanagawa M, Imamoto Y, Yamano Y, Wada A, Hisatomi O, Nishikawa K, Sakurai K, and Shichida Y

Subjects

Adaptation, Biological, Amino Acid Substitution, Animals, Evolution, Molecular, Opsins genetics, Ambystoma mexicanum physiology, Color Vision, Night Vision, Opsins chemistry, Xenopus physiology

Abstract

Most vertebrate retinas contain a single type of rod for scotopic vision and multiple types of cones for photopic and color vision. The retinas of certain amphibian species uniquely contain two types of rods: red rods, which express rhodopsin, and green rods, which express a blue-sensitive cone pigment (M1/SWS2 group). Spontaneous activation of rhodopsin induced by thermal isomerization of the retinal chromophore has been suggested to contribute to the rod's background noise, which limits the visual threshold for scotopic vision. Therefore, rhodopsin must exhibit low thermal isomerization rate compared with cone visual pigments to adapt to scotopic condition. In this study, we determined whether amphibian blue-sensitive cone pigments in green rods exhibit low thermal isomerization rates to act as rhodopsin-like pigments for scotopic vision. Anura blue-sensitive cone pigments exhibit low thermal isomerization rates similar to rhodopsin, whereas Urodela pigments exhibit high rates like other vertebrate cone pigments present in cones. Furthermore, by mutational analysis, we identified a key amino acid residue, Thr47, that is responsible for the low thermal isomerization rates of Anura blue-sensitive cone pigments. These results strongly suggest that, through this mutation, anurans acquired special blue-sensitive cone pigments in their green rods, which could form the molecular basis for scotopic color vision with normal red rods containing green-sensitive rhodopsin., Competing Interests: The authors declare no conflict of interest.

Published

2017

10. Two UV-Sensitive Photoreceptor Proteins, Opn5m and Opn5m2 in Ray-Finned Fish with Distinct Molecular Properties and Broad Distribution in the Retina and Brain.

Author

Sato K, Yamashita T, Haruki Y, Ohuchi H, Kinoshita M, and Shichida Y

Subjects

Animal Fins, Animals, Brain cytology, Brain radiation effects, Gene Expression Regulation, Ligands, Opsins genetics, Organ Specificity, Oryzias, Photoreceptor Cells, Vertebrate, Phylogeny, Protein Binding, Retina cytology, Retina radiation effects, Species Specificity, Ultraviolet Rays, Zebrafish, Brain metabolism, Opsins metabolism, Retina metabolism, Retinaldehyde analogs & derivatives, Retinaldehyde metabolism, Vision, Ocular

Abstract

Opn5 is a group within the opsin family of proteins that is responsible for visual and non-visual photoreception in animals. It consists of several subgroups, including Opn5m, the only subgroup containing members found in most vertebrates, including mammals. In addition, recent genomic information has revealed that some ray-finned fishes carry paralogous genes of Opn5m while other fishes have no such genes. Here, we report the molecular properties of the opsin now called Opn5m2 and its distributions in both the retina and brain. Like Opn5m, Opn5m2 exhibits UV light-sensitivity when binding to 11-cis-retinal and forms a stable active state that couples with Gi subtype of G protein. However, Opn5m2 does not bind all-trans-retinal and exhibits exclusive binding to 11-cis-retinal, whereas many bistable opsins, including fish Opn5m, can bind directly to all-trans-retinal as well as 11-cis-retinal. Because medaka fish has lost the Opn5m2 gene from its genome, we compared the tissue distribution patterns of Opn5m in medaka fish, zebrafish, and spotted gar, in addition to the distribution patterns of Opn5m2 in zebrafish and spotted gar. Opn5m expression levels showed a gradient along the dorsal-ventral axis of the retina, and preferential expression was observed in the ventral retina in the three fishes. The levels of Opn5m2 showed a similar gradient with preferential expression observed in the dorsal retina. Opn5m expression was relatively abundant in the inner region of the inner nuclear layer, while Opn5m2 was expressed in the outer edge of the inner nuclear layer. Additionally, we could detect Opn5m expression in several brain regions, including the hypothalamus, of these fish species. Opn5m2 expression could not be detected in zebrafish brain, but was clearly observed in limited brain regions of spotted gar. These results suggest that ray-finned fishes can generally utilize UV light information for non-image-forming photoreception in a wide range of cells in the retina and brain.

Published

2016

11. Diversity of Active States in TMT Opsins.

Author

Sakai K, Yamashita T, Imamoto Y, and Shichida Y

Subjects

Animals, Diterpenes, Evolution, Molecular, HEK293 Cells, Humans, Oryzias, Phylogeny, Recombinant Proteins metabolism, Fish Proteins chemistry, Fish Proteins metabolism, Light, Opsins chemistry, Opsins metabolism, Retinaldehyde chemistry, Retinaldehyde metabolism

Abstract

Opn3/TMT opsins belong to one of the opsin groups with vertebrate visual and non-visual opsins, and are widely distributed in eyes, brains and other internal organs in various vertebrates and invertebrates. Vertebrate Opn3/TMT opsins are further classified into four groups on the basis of their amino acid identities. However, there is limited information about molecular properties of these groups, due to the difficulty in preparing the recombinant proteins. Here, we successfully expressed recombinant proteins of TMT1 and TMT2 opsins of medaka fish (Oryzias latipes) in cultured cells and characterized their molecular properties. Spectroscopic and biochemical studies demonstrated that TMT1 and TMT2 opsins functioned as blue light-sensitive Gi/Go-coupled receptors, but exhibited spectral properties and photo-convertibility of the active state different from each other. TMT1 opsin forms a visible light-absorbing active state containing all-trans-retinal, which can be photo-converted to 7-cis- and 9-cis-retinal states in addition to the original 11-cis-retinal state. In contrast, the active state of TMT2 opsin is a UV light-absorbing state having all-trans-retinal and does not photo-convert to any other state, including the original 11-cis-retinal state. Thus, TMT opsins are diversified so as to form a different type of active state, which may be responsible for their different functions.

Published

2015

12. Evolution of mammalian Opn5 as a specialized UV-absorbing pigment by a single amino acid mutation.

Author

Yamashita T, Ono K, Ohuchi H, Yumoto A, Gotoh H, Tomonari S, Sakai K, Fujita H, Imamoto Y, Noji S, Nakamura K, and Shichida Y

Subjects

Amino Acid Substitution, Animals, Callithrix, Chick Embryo, Humans, Membrane Proteins genetics, Mice, Mice, Inbred ICR, Opsins genetics, Retinaldehyde genetics, Retinaldehyde metabolism, Xenopus, Zebrafish, cis-trans-Isomerases genetics, cis-trans-Isomerases metabolism, Brain metabolism, Evolution, Molecular, Membrane Proteins metabolism, Mutation, Missense, Opsins metabolism, Retina metabolism, Ultraviolet Rays

Abstract

Opn5 is one of the recently identified opsin groups that is responsible for nonvisual photoreception in animals. We previously showed that a chicken homolog of mammalian Opn5 (Opn5m) is a Gi-coupled UV sensor having molecular properties typical of bistable pigments. Here we demonstrated that mammalian Opn5m evolved to be a more specialized photosensor by losing one of the characteristics of bistable pigments, direct binding of all-trans-retinal. We first confirmed that Opn5m proteins in zebrafish, Xenopus tropicalis, mouse, and human are also UV-sensitive pigments. Then we found that only mammalian Opn5m proteins lack the ability to directly bind all-trans-retinal. Mutational analysis showed that these characteristics were acquired by a single amino acid replacement at position 168. By comparing the expression patterns of Opn5m between mammals and chicken, we found that, like chicken Opn5m, mammalian Opn5m was localized in the ganglion cell layer and inner nuclear layer of the retina. However, the mouse and primate (common marmoset) opsins were distributed not in the posterior hypothalamus (including the region along the third ventricle) where chicken Opn5m is localized, but in the preoptic hypothalamus. Interestingly, RPE65, an essential enzyme for forming 11-cis-retinal in the visual cycle is expressed near the preoptic hypothalamus of the mouse and common marmoset brain but not near the region of the chicken brain where chicken Opn5m is expressed. Therefore, mammalian Opn5m may work exclusively as a short wavelength sensor in the brain as well as in the retina with the assistance of an 11-cis-retinal-supplying system.

Published

2014

13. A non-mammalian type opsin 5 functions dually in the photoreceptive and non-photoreceptive organs of birds.

Author

Ohuchi H, Yamashita T, Tomonari S, Fujita-Yanagibayashi S, Sakai K, Noji S, and Shichida Y

Subjects

Adrenal Glands, Animals, Chickens, Light, Photoreceptor Cells, Vertebrate chemistry, Ultraviolet Rays, Birds physiology, Opsins physiology, Photoreceptor Cells, Vertebrate physiology

Abstract

A mammalian type opsin 5 (neuropsin) is a recently identified ultraviolet (UV)-sensitive pigment of the retina and other photosensitive organs in birds. Two other opsin 5-related molecules have been found in the genomes of non-mammalian vertebrates. However, their functions have not been examined as yet. Here, we identify the molecular properties of a second avian opsin 5, cOpn5L2 (chicken opsin 5-like 2), and its localization in the post-hatch chicken. Spectrophotometric analysis and radionucleotide-binding assay have revealed that cOpn5L2 is a UV-sensitive bistable pigment that couples with the Gi subtype of guanine nucleotide-binding protein (G protein). As a bistable pigment, it also shows the direct binding ability to agonist all-trans-retinal to activate G protein. The absorption maxima of UV-light-absorbing and visible light-absorbing forms were 350 and 521 nm, respectively. Expression analysis showed relatively high expression of cOpn5L2 mRNA in the adrenal gland, which is not photoreceptive but an endocrine organ, while lower expression was found in the brain and retina. At the protein level, cOpn5L2 immunoreactive cells were present in the chromaffin cells of the adrenal gland. In the brain, cOpn5L2 immunoreactive cells were found in the paraventricular and supraoptic nuclei of the anterior hypothalamus, known for photoreceptive deep brain areas. In the retina, cOpn5L2 protein was localized to subsets of cells in the ganglion cell layer and the inner nuclear layer. These results suggest that the non-mammalian type opsin 5 (Opn5L2) functions as a second UV sensor in the photoreceptive organs, while it might function as chemosensor using its direct binding ability to agonist all-trans-retinal in non-photoreceptive organs such as the adrenal gland of birds.

Published

2012

14. Opn5 is a UV-sensitive bistable pigment that couples with Gi subtype of G protein

Author

Yamashita, Takahiro, Ohuchi, Hideyo, Tomonari, Sayuri, Ikeda, Keiko, Sakai, Kazumi, Shichida, Yoshinori, and Crouch, Rosalie K.

Published

2010

15. Two Opsin 3-Related Proteins in the Chicken Retina and Brain: A TMT-Type Opsin 3 Is a Blue-Light Sensor in Retinal Horizontal Cells, Hypothalamus, and Cerebellum.

Author

Kato, Mutsuko, Sugiyama, Takashi, Sakai, Kazumi, Yamashita, Takahiro, Fujita, Hirofumi, Sato, Keita, Tomonari, Sayuri, Shichida, Yoshinori, and Ohuchi, Hideyo

Subjects

OPSINS, HYPOTHALAMUS, MEMBRANE proteins, CEREBELLUM, G proteins

Abstract

Opsin family genes encode G protein-coupled seven-transmembrane proteins that bind a retinaldehyde chromophore in photoreception. Here, we sought potential as yet undescribed avian retinal photoreceptors, focusing on Opsin 3 homologs in the chicken. We found two Opsin 3-related genes in the chicken genome: one corresponding to encephalopsin/panopsin (Opn3) in mammals, and the other belonging to the teleost multiple tissue opsin (TMT) 2 group. Bioluminescence imaging and G protein activation assays demonstrated that the chicken TMT opsin (cTMT) functions as a blue light sensor when forced-expressed in mammalian cultured cells. We did not detect evidence of light sensitivity for the chicken Opn3 (cOpn3). In situ hybridization demonstrated expression of cTMT in subsets of differentiating cells in the inner retina and, as development progressed, predominant localization to retinal horizontal cells (HCs). Immunohistochemistry (IHC) revealed cTMT in HCs as well as in small numbers of cells in the ganglion and inner nuclear layers of the post-hatch chicken retina. In contrast, cOpn3-IR cells were found in distinct subsets of cells in the inner nuclear layer. cTMT-IR cells were also found in subsets of cells in the hypothalamus. Finally, we found differential distribution of cOpn3 and cTMT proteins in specific cells of the cerebellum. The present results suggest that a novel TMT-type opsin 3 may function as a photoreceptor in the chicken retina and brain. [ABSTRACT FROM AUTHOR]

Published

2016

16. Vertebrate Ancient-Long Opsin Has Molecular Properties Intermediate between Those of Vertebrate and Invertebrate Visual Pigments.

Author

Sato, Keita, Yamashita, Takahiro, Ohuchi, Hideyo, and Shichida, Yoshinori

Subjects

*VERTEBRATES, *OPSINS, *G proteins, *SCHIFF bases, *ISOMERIZATION, *XENOPUS

Abstract

VA/VAL opsin is one of the four kinds of nonvisual opsins that are closely related to vertebrate visual pigments in the phylogenetic tree of opsins. Previous studies indicated that among these opsins, parapinopsin and pinopsin exhibit molecular properties similar to those of invertebrate bistable visual pigments and vertebrate visual pigments, respectively. Here we show that VA/VAL opsin exhibits molecular properties intermediate between those of parapinopsin and pinopsin. VAL opsin from Xenopus tropicalis was expressed in cultured cells, and the pigment with an absorption maximum at 501 nm was reconstituted by incubation with 11-cis-retinal. Light irradiation of this pigment caused cis-to-trans isomerization of the chromophore to form a state having an absorption maximum in the visible region. This state has the ability to activate Gi and Gt types of G proteins. Therefore, the active state of VAL opsin is a visible light-absorbing intermediate, which probably has a protonated retinylidene Schiff base as its chromophore, like the active state of parapinopsin. However, this state was apparently photoinsensitive and did not show reverse reaction to the original pigment, unlike the active state of parapinopsin, and instead similar to that of pinopsin. Furthermore, the Gi activation efficiency of VAL opsin was between those of pinopsin and parapinopsin. Thus, the molecular properties of VA/VAL opsin give insights into the mechanism of conversion of the molecular properties from invertebrate to vertebrate visual pigments. [ABSTRACT FROM AUTHOR]

Published

2011

17. Pinopsin evolved as the ancestral dim-light visual opsin in vertebrates.

Author

Sato, Keita, Yamashita, Takahiro, Kojima, Keiichi, Sakai, Kazumi, Matsutani, Yuki, Yanagawa, Masataka, Yamano, Yumiko, Wada, Akimori, Iwabe, Naoyuki, Ohuchi, Hideyo, and Shichida, Yoshinori

Subjects

*VISUAL pigments, *OPSINS, *VERTEBRATES, *PHOTORECEPTORS, *ISOMERIZATION

Abstract

Pinopsin is the opsin most closely related to vertebrate visual pigments on the phylogenetic tree. This opsin has been discovered among many vertebrates, except mammals and teleosts, and was thought to exclusively function in their brain for extraocular photoreception. Here, we show the possibility that pinopsin also contributes to scotopic vision in some vertebrate species. Pinopsin is distributed in the retina of non-teleost fishes and frogs, especially in their rod photoreceptor cells, in addition to their brain. Moreover, the retinal chromophore of pinopsin exhibits a thermal isomerization rate considerably lower than those of cone visual pigments, but comparable to that of rhodopsin. Therefore, pinopsin can function as a rhodopsin-like visual pigment in the retinas of these lower vertebrates. Since pinopsin diversified before the branching of rhodopsin on the phylogenetic tree, two-step adaptation to scotopic vision would have occurred through the independent acquisition of pinopsin and rhodopsin by the vertebrate lineage. Sato et al. show that pinopsin, an extraocular opsin, is also expressed in a subpopulation of retinal photoreceptor cells in lower vertebrates. Its retinal expression coupled to its low thermal isomerization rate suggests that pinopsin can function as a visual pigment and provides some insights into the evolution of scotopic vision in vertebrates. [ABSTRACT FROM AUTHOR]

Published

2018

18. Direct Observation of the pH-Dependent Equilibrium between Metarhodopsins I and II and the pH-Independent Interaction of Metarhodopsin II with Transducin C-Terminal Peptide.

Author

Sato, Keito, Morizumi, Takefumi, Yamashita, Takahiro, and Shichida, Yoshinori

Subjects

*RHODOPSIN, *BOVIDAE, *OPSINS, *PEPTIDES, *LYSINE, *APOPROTEINS, *METARHODOPSINS

Abstract

Bovine rhodopsin contains 11-cis-retinal as a light-absorbing chromophore that binds to a lysine residue of, the apoprotein opsin via a protonated Schiff base linkage. Light isomerizes 11-cis-retinal into the all-transform, which eventually leads to the formation of an enzymatically active state, metarhodopsin II (MIT). It is widely believed that MIT forms a pH-dependent equilibrium with metarhodopsin I (Ml), but direct evidence for this equilibrium has not been reported. Here, we confirmed this equilibrium by direct observation of the mutual conversions of MI and M II upon changing the pH of the MI/MII mixture. We also observed a reversible binding of the synthetic peptide constituting the C-terminal II amino acids of the transducin α-subunit to Mil, which resulted in change of the amounts of MI and Mu in the equilibrium. Interestingly,addition of the peptide did not induce a simple pKa shift but rather induced an increase of the MII fraction at high pH. These results indicate that in addition to the MlI that is formed from MI in a pH-dependent manner there also exists another M II, which is in equilibrium with MI in a pH-independent manner and can bind to the peptide. Therefore, there is no need for proton uptake by the protein moiety of opsin for the binding to the peptide. [ABSTRACT FROM AUTHOR]

Published

2010

19. Unique haplotype in exon 3 of cone opsin mRNA affects splicing of its precursor, leading to congenital color vision defect

Author

Ueyama, Hisao, Muraki-Oda, Sanae, Yamade, Shinichi, Tanabe, Shoko, Yamashita, Takahiro, Shichida, Yoshinori, and Ogita, Hisakazu

Subjects

*HAPLOTYPES, *EXONS (Genetics), *OPSINS, *MESSENGER RNA, *GENETIC engineering, *PROTEIN precursors, *COLOR vision

Abstract

Abstract: We have analyzed L/M visual pigment gene arrays in 119 Japanese men with protanopia color vision defect and found that five had a normal gene order of L–M. Among the five men, two (identified as A376 and A642) had apparently normal L genes. To clarify their L gene defect, the whole L or M gene from A376 and control subjects was cloned in an expression vector. Total RNA extracted from the transfected HEK293 cells was analyzed by Northern blot and reverse transcription-polymerase chain reaction. The product from the cloned L gene of A376 was smaller than the normal control due to the absence of exon 3. To investigate such exon-skipping at splicing, minigenes of exon 3 accompanying introns 2 and 3 were prepared from A376, A642, and control subjects. The minigenes of A376 (L) and A642 (L) showed the product lacking exon 3 only, while the minigene of normal control N44 (L) showed the product retaining exon 3 only. Exchanging of introns 2 and 3 between the A376 (L) and N44 (L) minigenes showed that the skipping of exon 3 was caused by the exon itself. Seven differences in exon 3 between A376 (L) and N44 (L) were all within already-known polymorphisms as follows: G151-3, C153-1, G155-3, A171-1, T171-3, G178-1 and G180-1 in A376 (L) and A642 (L), and A151-3, A153-1, C155-3, G171-1, G171-3, A178-1 and T180-1 in N44 (L). An in vitro mutagenesis experiment with these nucleotides in the minigenes showed that exon 3 was completely skipped at splicing only in the haplotype observed in A376 (L) and A642 (L). These results suggest that complete skipping of exon 3 at splicing, due to the unique haplotype of the exon, causes loss of expression of L-opsin in these men. [Copyright &y& Elsevier]

Published

2012

20. Photochemical Nature of Parietopsin.

Author

Sakai, Kazumi, Imamoto, Yasushi, Chih-Ying Su, Tsukamoto, Hisao, Yamashita, Takahiro, Terakita, Akihisa, King-Wai Yau, and Shichida, Yoshinori

Subjects

*OPSINS, *PARIETAL eye, *PHOTORECEPTORS, *MOLECULAR structure, *PHOTOSENSITIVITY, *METARHODOPSINS

Abstract

Parietopsin is a nonvisual green light-sensitive opsin closely related to vertebrate visual opsins and was originally identified in lizard parietal eye photoreceptor cells. To obtain insight into the functional diversity of opsins, we investigated by UV-visible absorption spectroscopy the molecular properties of parietopsin and its mutants exogenously expressed in cultured cells and compared the properties to those of vertebrate and invertebrate visual opsins. Our mutational analysis revealed that the counterion in parietopsin is the glutamic acid (Glu) in the second extracellular loop, corresponding to Glu181 in bovine rhodopsin. This arrangement is characteristic of invertebrate rather than vertebrate visual opsins. The photosensitivity and the molar extinction coefficient of parietopsin were also lower than those of vertebrate visual opsins, features likewise characteristic of invertebrate visual opsins. On the other hand, irradiation of parietopsin yielded meta-I, meta-II, and meta-III intermediates after batho and lumi intermediates, similar to vertebrate visual opsins. The pH-dependent equilibrium profile between meta-I and meta-II intermediates was, however, similar to that between acid and alkaline metarhodopsins in invertebrate visual opsins. Thus, parietopsin behaves as an "evolutionary intermediate" between invertebrate and vertebrate visual opsins. [ABSTRACT FROM AUTHOR]

Published

2012