Your search keyword '"Yamashita, Takahiro"' showing total 9 results

1. 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

2. The medaka mutant deficient in eyes shut homolog exhibits opsin transport defects and enhanced autophagy in retinal photoreceptors.

Author

Sato, Keita, Liu, Yang, Yamashita, Takahiro, and Ohuchi, Hideyo

Subjects

PHOTORECEPTORS, ORYZIAS latipes, AUTOPHAGY, CARRIER proteins, RETINITIS pigmentosa, RETINAL degeneration, RECESSIVE genes, CILIA & ciliary motion

Abstract

Eyes shut homolog (EYS) encodes a proteoglycan and the human mutation causes retinitis pigmentosa type 25 (RP25) with progressive retinal degeneration. RP25 most frequently affects autosomal recessive RP patients with many ethnic backgrounds. Although studies using RP models have facilitated the development of therapeutic medications, Eys has been lost in rodent model animals. Here we examined the roles for Eys in the maintenance of photoreceptor structure and function by generating eys-null medaka fish using the CRISPR-Cas9 system. Medaka EYS protein was present near the connecting cilium of wild-type photoreceptors, while it was absent from the eys−/− retina. The mutant larvae exhibited a reduced visual motor response compared with wild-type. In contrast to reported eys-deficient zebrafish at the similar stage, no retinal cell death was detected in the 8-month post-hatching (8-mph) medaka eys mutant. Immunohistochemistry showed a significant reduction in the length of cone outer segments (OSs), retention of OS proteins in the inner segments of photoreceptors, and abnormal filamentous actin network at the base of cone OSs in the mutant retina by 8 mph. Electron microscopy revealed aberrant structure of calyceal processes, numerous vesiculation and lamellar interruptions, and autophagosomes in the eys-mutant cone photoreceptors. In situ hybridization showed an autophagy component gene, gabarap, was ectopically expressed in the eys-null retina. These results suggest eys is required for regeneration of OS, especially of cone photoreceptors, and transport of OS proteins by regulating actin filaments. Enhanced autophagy may delay the progression of retinal degeneration when lacking EYS in the medaka retina. [ABSTRACT FROM AUTHOR]

Published

2023

3. 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

4. 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, Keita, Yamashita, Takahiro, Haruki, Yoshihiro, Ohuchi, Hideyo, Kinoshita, Masato, and Shichida, Yoshinori

Subjects

*PHOTORECEPTORS, *SPECIES distribution, *CLASSIFICATION of fish, *PHYSIOLOGICAL effects of ultraviolet radiation, *OPSINS, *BRAIN physiology, *RETINA physiology

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. [ABSTRACT FROM AUTHOR]

Published

2016

5. Comparative Studies on the Late Bleaching Processes of Four Kinds of Cone Visual Pigments and Rod Visual Pigment.

Author

Sato, Keita, Yamashita, Takahiro, Imamoto, Yasushi, and Shichida, Yoshinori

Subjects

*VISUAL pigments, *PHOTORECEPTORS, *RETINAL (Visual pigment), *CHROMOPHORES, *FLASH photolysis, *PHOTOCHEMISTRY, *ACID-base chemistry, *BINDING sites

Abstract

Visual pigments in rod and cone photoreceptor cells of vertebrate retinas are highly diversified photoreceptive proteins that consist of a protein moiety opsin and a light-absorbing chromophore 11-cis-retinal. There are four types of cone visual pigments and a single type of rod visual pigment. The reaction process of the rod visual pigment, rhodopsin, has been extensively investigated, whereas there have been few studies of cone visual pigments. Here we comprehensively investigated the reaction processes of cone visual pigments on a time scale of milliseconds to minutes, using flash photolysis equipment optimized for cone visual pigment photochemistry. We used chicken violet (L-group), chicken blue (M1-group), chicken green (M2-group), and monkey green (L-group) visual pigments as representatives of the respective groups of the phylogenetic tree of cone pigments. The S, M1, and M2 pigments showed the formation of a pH-dependent mixture of meta intermediates, similar to that formed from rhodopsin. Although monkey green (L-group) also formed a mixture of meta intermediates, pH dependency of meta intermediates was not observed. However, meta intermediates of monkey green became pH dependent when the chloride ion bound to the monkey green was replaced with a nitrate ion. These results strongly suggest that rhodopsin and S, M1, and M2 cone visual pigments share a molecular mechanism for activation, whereas the L-group pigment may have a special reaction mechanism involving the chloride-binding site. [ABSTRACT FROM AUTHOR]

Published

2012

6. Covalent Bond between Ligand and Receptor Required for Efficient Activation in Rhodopsin.

Author

Matsuyama, Take, Yamashita, Takahiro, Imai, Hiroo, and Shichida, Yoshinori

Subjects

*RHODOPSIN, *G proteins, *LIGAND binding (Biochemistry), *PHOTORECEPTORS, *PHOTOISOMERIZATION, *BIOCHEMISTRY

Abstract

Rhodopsin is an extensively studied member of the G protein-coupled receptors (GPCRs). Although rhodopsin shares many features with the other GPCRs, it exhibits unique features as a photoreceptor molecule. A hallmark in the molecular structure of rhodopsin is the covalently bound chromophore that regulates the activity of the receptor acting as an agonist or inverse agonist. Here we show the pivotal role of the covalent bond between the retinal chromophore and the lysine residue at position 296 in the activation pathway of bovine rhodopsin, by use of a rhodopsin mutant K296G reconstituted with retinylidene Schiff bases. Our results show that photoreceptive functions of rhodopsin, such as regiospecific photoisomerization of the ligand, and its quantum yield were not affected by the absence of the covalent bond, whereas the activation mechanism triggered by photoisomerization of the retinal was severely affected. Furthermore, our results show that an active state similar to the Meta-II intermediate of wild-type rhodopsin did not form in the bleaching process of this mutant, although it exhibited relatively weak G protein activity after light irradiation because of an increased basal activity of the receptor. We propose that the covalent bond is required for transmitting structural changes from the photoisomerized agonist to the receptor and that the covalent bond forcibly keeps the low affinity agonist in the receptor, resulting in a more efficient G protein activation. [ABSTRACT FROM AUTHOR]

Published

2010

7. Expression and comparative characterization of Gq-coupled invertebrate visual pigments and melanopsin.

Author

Terakita, Akihisa, Tsukamoto, Hisao, Koyanagi, Mitsumasa, Sugahara, Michio, Yamashita, Takahiro, and Shichida, Yoshinori

Subjects

RETINAL ganglion cells, ULTRAVIOLET radiation, ELECTROPHYSIOLOGY, CELLULAR signal transduction, CYTOLOGICAL research

Abstract

A non-visual pigment melanopsin, which is localized in photosensitive retinal ganglion cells and is involved in the circadian photoentrainment and pupillary responses in mammals, is phylogenetically close to the visual pigments of invertebrates, such as insects and cephalopods. Recent studies suggested that melanopsin is a bistable pigment and drives a Gq-mediated signal transduction cascade, like the invertebrate visual pigments. Because detailed electrophysiological properties are somewhat different between the visual cells and the photosensitive ganglion cells, we here expressed and purified the invertebrate visual pigment and melanopsin to comparatively investigate their Gq-activation abilities. We successfully expressed and purified UV and blue light-sensitive visual pigments of the honeybee as well as the amphioxus melanopsin. Although the purified UV-sensitive pigment and the melanopsin lost their bistable nature during purification, reconstitution of the pigments in lipid vesicles resulted in return of the bistable nature. The light-dependent Gq-activation abilities among these reconstituted pigments are similar, suggesting that the electrophysiological differences do not depend on the Gq-activation step but rather on the other signal transduction steps and/or on cell properties. Our findings are also important in that this is the first report describes a heterologous large-scale expression of the Gq-coupled invertebrate visual pigments in cultured cells. [ABSTRACT FROM AUTHOR]

Published

2008

8. 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

9. 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