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Literature DB >> 21650174

H-bond network around retinal regulates the evolution of ultraviolet and violet vision.

Ahmet Altun¹, Keiji Morokuma, Shozo Yokoyama.

Abstract

Ancestors of vertebrates used ultraviolet vision. Some descendants preserved ultraviolet vision, whereas some others replaced it with violet vision, and then, some of avian lineages reinvented ultraviolet vision. Ultraviolet (absorption at ∼360 nm) and violet (410-440 nm) sensitivities of visual pigments are known to be affected by around 20 amino acid substitutions. The present quantum mechanical/molecular mechanical calculations show that these substitutions modify a H-bond network formed by two waters and sites 86, 90, 113, 114, 118, and 295, which determines the protonation state of Schiff base linked 11-cis-retinal. A pigment is ultraviolet-sensitive when it is more stable with an unprotonated retinal (SBR) form than with its protonated analogue (PSBR) and is violet-sensitive when the PSBR form is more stable. These results establish for the first time the chemical basis of ultraviolet and violet vision in vertebrates.

Entities: Chemical Gene Mutation Species

Mesh：

Substances：

Year: 2011 PMID： 21650174 PMCID： PMC3158842 DOI： 10.1021/cb200100f

Source DB: PubMed Journal: ACS Chem Biol ISSN： 1554-8929 Impact factor: 5.100

23 in total

1. The photobleaching sequence of a short-wavelength visual pigment.

Authors: A Kusnetzow; A Dukkipati; K R Babu; D Singh; B W Vought; B E Knox; R R Birge
Journal: Biochemistry Date: 2001-07-03 Impact factor: 3.162

2. Calculating absorption shifts for retinal proteins: computational challenges.

Authors: M Wanko; M Hoffmann; P Strodel; A Koslowski; W Thiel; F Neese; T Frauenheim; M Elstner
Journal: J Phys Chem B Date: 2005-03-03 Impact factor: 2.991

3. Structure, function, and wavelength selection in blue-absorbing proteorhodopsin.

Authors: Jason R Hillebrecht; Jhenny Galan; Rekha Rangarajan; Lavoisier Ramos; Kristina McCleary; Donald E Ward; Jeffrey A Stuart; Robert R Birge
Journal: Biochemistry Date: 2006-02-14 Impact factor: 3.162

4. PAML 4: phylogenetic analysis by maximum likelihood.

Authors: Ziheng Yang
Journal: Mol Biol Evol Date: 2007-05-04 Impact factor: 16.240

Review 5. Evolution of dim-light and color vision pigments.

Authors: Shozo Yokoyama
Journal: Annu Rev Genomics Hum Genet Date: 2008 Impact factor: 8.929

6. Studies in vitamin A; reactions of retinene1 with amino compounds.

Authors: S BALL; F D COLLINS
Journal: Biochem J Date: 1949 Impact factor: 3.857

7. Spectral tuning of deep red cone pigments.

Authors: Tabitha L Amora; Lavoisier S Ramos; Jhenny F Galan; Robert R Birge
Journal: Biochemistry Date: 2008-03-28 Impact factor: 3.162

8. Elephants and human color-blind deuteranopes have identical sets of visual pigments.

Authors: Shozo Yokoyama; Naomi Takenaka; Dalen W Agnew; Jeheskel Shoshani
Journal: Genetics Date: 2005-03-21 Impact factor: 4.562

9. Color tuning in short wavelength-sensitive human and mouse visual pigments: ab initio quantum mechanics/molecular mechanics studies.

Authors: Ahmet Altun; Shozo Yokoyama; Keiji Morokuma
Journal: J Phys Chem A Date: 2009-10-29 Impact factor: 2.781

10. Spectral tuning in visual pigments: an ONIOM(QM:MM) study on bovine rhodopsin and its mutants.

Authors: Ahmet Altun; Shozo Yokoyama; Keiji Morokuma
Journal: J Phys Chem B Date: 2008-05-13 Impact factor: 2.991

15 in total

Review 1. Advances in understanding the molecular basis of the first steps in color vision.

Authors: Lukas Hofmann; Krzysztof Palczewski
Journal: Prog Retin Eye Res Date: 2015-07-15 Impact factor: 21.198

2. Synthetic biology of phenotypic adaptation in vertebrates: the next frontier.

Authors: Shozo Yokoyama
Journal: Mol Biol Evol Date: 2013-04-19 Impact factor: 16.240

3. Color Tuning in rhodopsins: the origin of the spectral shift between the chloride-bound and anion-free forms of halorhodopsin.

Authors: Mikhail N Ryazantsev; Ahmet Altun; Keiji Morokuma
Journal: J Am Chem Soc Date: 2012-03-16 Impact factor: 15.419

4. Quantum mechanical/molecular mechanical structure, enantioselectivity, and spectroscopy of hydroxyretinals and insights into the evolution of color vision in small white butterflies.

Authors: Sivakumar Sekharan; Shozo Yokoyama; Keiji Morokuma
Journal: J Phys Chem B Date: 2011-12-06 Impact factor: 2.991

5. Synthesis of Experimental Molecular Biology and Evolutionary Biology: An Example from the World of Vision.

Authors: Shozo Yokoyama
Journal: Bioscience Date: 2012-11 Impact factor: 8.589

6. Epistatic adaptive evolution of human color vision.

Authors: Shozo Yokoyama; Jinyi Xing; Yang Liu; Davide Faggionato; Ahmet Altun; William T Starmer
Journal: PLoS Genet Date: 2014-12-18 Impact factor: 5.917

7. Complementary shifts in photoreceptor spectral tuning unlock the full adaptive potential of ultraviolet vision in birds.

Authors: Matthew B Toomey; Olle Lind; Rikard Frederiksen; Robert W Curley; Ken M Riedl; David Wilby; Steven J Schwartz; Christopher C Witt; Earl H Harrison; Nicholas W Roberts; Misha Vorobyev; Kevin J McGraw; M Carter Cornwall; Almut Kelber; Joseph C Corbo
Journal: Elife Date: 2016-07-12 Impact factor: 8.140

H-bond network around retinal regulates the evolution of ultraviolet and violet vision.

1. The photobleaching sequence of a short-wavelength visual pigment.

2. Calculating absorption shifts for retinal proteins: computational challenges.

3. Structure, function, and wavelength selection in blue-absorbing proteorhodopsin.

4. PAML 4: phylogenetic analysis by maximum likelihood.

Review 5. Evolution of dim-light and color vision pigments.

6. Studies in vitamin A; reactions of retinene1 with amino compounds.

7. Spectral tuning of deep red cone pigments.

8. Elephants and human color-blind deuteranopes have identical sets of visual pigments.

9. Color tuning in short wavelength-sensitive human and mouse visual pigments: ab initio quantum mechanics/molecular mechanics studies.

10. Spectral tuning in visual pigments: an ONIOM(QM:MM) study on bovine rhodopsin and its mutants.

Review 1. Advances in understanding the molecular basis of the first steps in color vision.

2. Synthetic biology of phenotypic adaptation in vertebrates: the next frontier.

3. Color Tuning in rhodopsins: the origin of the spectral shift between the chloride-bound and anion-free forms of halorhodopsin.

4. Quantum mechanical/molecular mechanical structure, enantioselectivity, and spectroscopy of hydroxyretinals and insights into the evolution of color vision in small white butterflies.

5. Synthesis of Experimental Molecular Biology and Evolutionary Biology: An Example from the World of Vision.

6. Epistatic adaptive evolution of human color vision.

7. Complementary shifts in photoreceptor spectral tuning unlock the full adaptive potential of ultraviolet vision in birds.

Review 8. Vitamin A₁/A₂ chromophore exchange: Its role in spectral tuning and visual plasticity.

9. A simple method for studying the molecular mechanisms of ultraviolet and violet reception in vertebrates.

10. Adaptive evolutionary paths from UV reception to sensing violet light by epistatic interactions.

Review 5. Evolution of dim-light and color vision pigments.

Review 1. Advances in understanding the molecular basis of the first steps in color vision.

Review 8. Vitamin A1/A2 chromophore exchange: Its role in spectral tuning and visual plasticity.

Review 8. Vitamin A₁/A₂ chromophore exchange: Its role in spectral tuning and visual plasticity.