Literature DB >> 10339563

How vertebrate and invertebrate visual pigments differ in their mechanism of photoactivation.

M Nakagawa1, T Iwasa, S Kikkawa, M Tsuda, T G Ebrey.   

Abstract

In vertebrate visual pigments, a glutamic acid serves as a negative counterion to the positively charged chromophore, a protonated Schiff base of retinal. When photoisomerization leads to the Schiff base deprotonating, the anionic glutamic acid becomes protonated, forming a neutral species that activates the visual cascade. We show that in octopus rhodopsin, the glutamic acid has no anionic counterpart. Thus, the "counterion" is already neutral, so no protonated form of an initially anionic group needs to be created to activate. This helps to explain another observation-that the active photoproduct of octopus rhodopsin can be formed without its Schiff base deprotonating. In this sense, the mechanism of light activation of octopus rhodopsin is simpler than for vertebrates, because it eliminates one of the steps required for vertebrate rhodopsins to achieve their activating state.

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Year:  1999        PMID: 10339563      PMCID: PMC26857          DOI: 10.1073/pnas.96.11.6189

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  20 in total

1.  Octopus photoreceptor membranes. Surface charge density and pK of the Schiff base of the pigments.

Authors:  Y Koutalos; T G Ebrey; H R Gilson; B Honig
Journal:  Biophys J       Date:  1990-08       Impact factor: 4.033

Review 2.  Cyclic GMP cascade of vision.

Authors:  L Stryer
Journal:  Annu Rev Neurosci       Date:  1986       Impact factor: 12.449

3.  A novel photointermediate of octopus rhodopsin activates its G-protein.

Authors:  M Nakagawa; S Kikkawa; K Tominaga; N Tsugi; M Tsuda
Journal:  FEBS Lett       Date:  1998-10-02       Impact factor: 4.124

4.  Transient spectra of intermediates in the photolytic sequence of octopus rhodopsin.

Authors:  M Tsuda
Journal:  Biochim Biophys Acta       Date:  1979-03-15

5.  Effect of carboxylic acid side chains on the absorption maximum of visual pigments.

Authors:  E A Zhukovsky; D D Oprian
Journal:  Science       Date:  1989-11-17       Impact factor: 47.728

6.  Resonance Raman spectroscopy of octopus rhodopsin and its photoproducts.

Authors:  C Pande; A Pande; K T Yue; R Callender; T G Ebrey; M Tsuda
Journal:  Biochemistry       Date:  1987-08-11       Impact factor: 3.162

7.  Flash photolysis and low temperature photochemistry of bovine rhodopsin with a fixed 11-ene.

Authors:  B Mao; M Tsuda; T G Ebrey; H Akita; V Balogh-Nair; K Nakanishi
Journal:  Biophys J       Date:  1981-08       Impact factor: 4.033

8.  Resonance Raman spectra of octopus acid and alkaline metarhodopsins.

Authors:  T Kitagawa; M Tsuda
Journal:  Biochim Biophys Acta       Date:  1980-07-24

9.  Determinants of visual pigment absorbance: identification of the retinylidene Schiff's base counterion in bovine rhodopsin.

Authors:  J Nathans
Journal:  Biochemistry       Date:  1990-10-16       Impact factor: 3.162

10.  Aspartic acid 85 in bacteriorhodopsin functions both as proton acceptor and negative counterion to the Schiff base.

Authors:  S Subramaniam; D A Greenhalgh; H G Khorana
Journal:  J Biol Chem       Date:  1992-12-25       Impact factor: 5.157
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  8 in total

1.  A spectrally silent transformation in the photolysis of octopus rhodopsin: a protein conformational change without any accompanying change of the chromophore's absorption.

Authors:  Y Nishioku; M Nakagawa; M Tsuda; M Terazima
Journal:  Biophys J       Date:  2001-06       Impact factor: 4.033

2.  Molecular basis for ultraviolet vision in invertebrates.

Authors:  Ernesto Salcedo; Lijun Zheng; Meridee Phistry; Eve E Bagg; Steven G Britt
Journal:  J Neurosci       Date:  2003-11-26       Impact factor: 6.167

3.  Energetics and volume changes of the intermediates in the photolysis of octopus rhodopsin at a physiological temperature.

Authors:  Yoshinori Nishioku; Masashi Nakagawa; Motoyuki Tsuda; Masahide Terazima
Journal:  Biophys J       Date:  2002-08       Impact factor: 4.033

Review 4.  Microbial and animal rhodopsins: structures, functions, and molecular mechanisms.

Authors:  Oliver P Ernst; David T Lodowski; Marcus Elstner; Peter Hegemann; Leonid S Brown; Hideki Kandori
Journal:  Chem Rev       Date:  2013-12-23       Impact factor: 60.622

5.  Highly conserved glutamic acid in the extracellular IV-V loop in rhodopsins acts as the counterion in retinochrome, a member of the rhodopsin family.

Authors:  A Terakita; T Yamashita; Y Shichida
Journal:  Proc Natl Acad Sci U S A       Date:  2000-12-19       Impact factor: 11.205

6.  Thermal properties of rhodopsin: insight into the molecular mechanism of dim-light vision.

Authors:  Jian Liu; Monica Yun Liu; Jennifer B Nguyen; Aditi Bhagat; Victoria Mooney; Elsa C Y Yan
Journal:  J Biol Chem       Date:  2011-06-09       Impact factor: 5.157

Review 7.  Rhodopsins: An Excitingly Versatile Protein Species for Research, Development and Creative Engineering.

Authors:  Willem J de Grip; Srividya Ganapathy
Journal:  Front Chem       Date:  2022-06-22       Impact factor: 5.545

8.  Lamprey Parapinopsin ("UVLamP"): a Bistable UV-Sensitive Optogenetic Switch for Ultrafast Control of GPCR Pathways.

Authors:  Dennis Eickelbeck; Till Rudack; Stefan Alexander Tennigkeit; Tatjana Surdin; Raziye Karapinar; Jan-Claudius Schwitalla; Brix Mücher; Maiia Shulman; Marvin Scherlo; Philipp Althoff; Melanie D Mark; Klaus Gerwert; Stefan Herlitze
Journal:  Chembiochem       Date:  2019-10-30       Impact factor: 3.164
  8 in total

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