Your search keyword '"Rod Opsins classification"' showing total 5 results

1. Molecular evolution of arthropod color vision deduced from multiple opsin genes of jumping spiders.

Author

Koyanagi M, Nagata T, Katoh K, Yamashita S, and Tokunaga F

Subjects

Amino Acid Sequence, Animals, Cloning, Molecular, DNA, Complementary genetics, Molecular Sequence Data, Phylogeny, Rod Opsins chemistry, Rod Opsins classification, Rod Opsins radiation effects, Sequence Alignment, Sequence Homology, Amino Acid, Spiders classification, Ultraviolet Rays, Color Perception genetics, Evolution, Molecular, Rod Opsins genetics, Spiders genetics

Abstract

Among terrestrial animals, only vertebrates and arthropods possess wavelength-discrimination ability, so-called "color vision". For color vision to exist, multiple opsins which encode visual pigments sensitive to different wavelengths of light are required. While the molecular evolution of opsins in vertebrates has been well investigated, that in arthropods remains to be elucidated. This is mainly due to poor information about the opsin genes of non-insect arthropods. To obtain an overview of the evolution of color vision in Arthropoda, we isolated three kinds of opsins, Rh1, Rh2, and Rh3, from two jumping spider species, Hasarius adansoni and Plexippus paykulli. These spiders belong to Chelicerata, one of the most distant groups from Hexapoda (insects), and have color vision as do insects. Phylogenetic analyses of jumping spider opsins revealed a birth and death process of color vision evolution in the arthropod lineage. Phylogenetic positions of jumping spider opsins revealed that at least three opsins had already existed before the Chelicerata-Pancrustacea split. In addition, sequence comparison between jumping spider Rh3 and the shorter wavelength-sensitive opsins of insects predicted that an opsin of the ancestral arthropod had the lysine residue responsible for UV sensitivity. These results strongly suggest that the ancestral arthropod had at least trichromatic vision with a UV pigment and two visible pigments. Thereafter, in each pancrustacean and chelicerate lineage, the opsin repertoire was reconstructed by gene losses, gene duplications, and function-altering amino acid substitutions, leading to evolution of color vision.

Published

2008

2. Rod and cone opsin families differ in spectral tuning domains but not signal transducing domains as judged by saturated evolutionary trace analysis.

Author

Carleton KL, Spady TC, and Cote RH

Subjects

Amino Acid Sequence, Animals, Color Perception physiology, Databases, Nucleic Acid, Likelihood Functions, Molecular Conformation, Molecular Sequence Data, Mutation, Phylogeny, Retinal Cone Photoreceptor Cells physiology, Retinal Diseases genetics, Retinal Rod Photoreceptor Cells physiology, Rod Opsins classification, Sequence Analysis, Protein, Vertebrates classification, Color Perception genetics, Evolution, Molecular, Rod Opsins genetics, Vertebrates genetics

Abstract

The visual receptor of rods and cones is a covalent complex of the apoprotein, opsin, and the light-sensitive chromophore, 11-cis-retinal. This pigment must fulfill many functions including photoactivation, spectral tuning, signal transmission, inactivation, and chromophore regeneration. Rod and cone photoreceptors employ distinct families of opsins. Although it is well known that these opsin families provide unique ranges in spectral sensitivity, it is unclear whether the families have additional functional differences. In this study, we use evolutionary trace (ET) analysis of 188 vertebrate opsin sequences to identify functionally important sites in each opsin family. We demonstrate the following results. (1) The available vertebrate opsin sequences produce a definitive description of all five vertebrate opsin families. This is the first demonstration of sequence saturation prior to ET analysis, which we term saturated ET (SET). (2) The cone opsin classes have class-specific sites compared to the rod opsin class. These sites reside in the transmembrane region and tune the spectral sensitivity of each opsin class to its characteristic wavelength range. (3) The cytoplasmic loops, primarily responsible for signal transmission and inactivation, are essentially invariant in rod versus cone opsins. This indicates that the electrophysiological differences between rod and cone photoreceptors cannot be ascribed to differences in the protein interaction regions of the opsins. SET shows that chromophore binding and regeneration are the only aspects of opsin structure likely to have functionally significant differences between rods and cones, whereas excitatory and adaptational properties of the opsin families appear to be functionally invariant.

Published

2005

3. Paleomolecular biology unravels the evolutionary mystery of vertebrate UV vision.

Author

Zhang J

Subjects

Animals, Color Perception physiology, DNA, Recombinant genetics, Gene Deletion, Gene Duplication, Humans, Light, Multigene Family, Mutagenesis, Site-Directed, Rod Opsins chemistry, Rod Opsins classification, Species Specificity, Vertebrates genetics, Color Perception genetics, Evolution, Molecular, Phylogeny, Rod Opsins genetics, Ultraviolet Rays, Vertebrates physiology

Published

2003

4. Molecular analysis of the evolutionary significance of ultraviolet vision in vertebrates.

Author

Shi Y and Yokoyama S

Subjects

Amino Acid Sequence, Amino Acid Substitution, Animals, Behavior, Animal, Color Perception physiology, DNA, Recombinant genetics, Environment, Gene Deletion, Gene Duplication, Humans, Light, Molecular Sequence Data, Multigene Family, Mutagenesis, Site-Directed, Pseudogenes, Rod Opsins chemistry, Rod Opsins classification, Sequence Alignment, Sequence Homology, Amino Acid, Species Specificity, Vertebrates genetics, Color Perception genetics, Evolution, Molecular, Phylogeny, Rod Opsins genetics, Ultraviolet Rays, Vertebrates physiology

Abstract

Many fish, amphibians, reptiles, birds, and some mammals use UV vision for such basic activities as foraging, mate selection, and communication. UV vision is mediated by UV pigments in the short wavelength-sensitive type 1 (SWS1) group that absorb light maximally (lambda max) at approximately 360 nm. Reconstructed SWS1 pigments of most vertebrate ancestors have lambda max values of approximately 360 nm, whereas the ancestral avian pigment has a lambda max value of 393 nm. In the nonavian lineage, UV vision in many modern species is inherited directly from the vertebrate ancestor, whereas violet vision in others has evolved by different amino acid replacements at approximately 10 specific sites. In the avian lineage, the origin of the violet pigment and the subsequent restoration of UV pigments in some species are caused by amino acid replacements F49V/F86S/L116V/S118A and S90C, respectively. The use of UV vision is associated strongly with UV-dependent behaviors of organisms. When UV light is not available or is unimportant to organisms, the SWS1 gene can become nonfunctional, as exemplified by coelacanth and dolphin.

Published

2003

5. Colour vision. Dalton's eyes and monkey genes.

Author

Tovée MJ

Subjects

Animals, Cercopithecidae genetics, Chemistry history, Chromosomes, Human, Pair 7, Color Vision Defects classification, Color Vision Defects history, England, History, 18th Century, History, 19th Century, Humans, Mutation, Night Blindness genetics, Protein Conformation, Retinal Cone Photoreceptor Cells physiology, Retinaldehyde physiology, Rhodopsin deficiency, Rhodopsin genetics, Rod Opsins chemistry, Rod Opsins classification, Sequence Homology, Nucleic Acid, X Chromosome, Cercopithecidae physiology, Color Perception genetics, Color Vision Defects genetics, Rod Opsins genetics

Abstract

Recent molecular genetic studies show how changes in the protein component of a visual pigment alters its absorbance; they also explain the abnormal colour vision of one of the great pioneers of visual science.

Published

1995