Literature DB >> 15017136

Dipolar assisted rotational resonance NMR of tryptophan and tyrosine in rhodopsin.

Evan Crocker1, Ashish B Patel, Markus Eilers, Shobini Jayaraman, Elena Getmanova, Philip J Reeves, Martine Ziliox, H Gobind Khorana, Mordechai Sheves, Steven O Smith.   

Abstract

Two dimensional (2D) solid-state (13)C.(13)C dipolar recoupling experiments are performed on a series of model compounds and on the visual pigment rhodopsin to establish the most effective method for long range distance measurements in reconstituted membrane proteins. The effects of uniform labeling, inhomogeneous B(1) fields, relaxation and dipolar truncation on cross peak intensity are investigated through NMR measurements of simple amino acid and peptide model compounds. We first show that dipolar assisted rotational resonance (DARR) is more effective than RFDR in recoupling long-range dipolar interactions in these model systems. We then use DARR to establish (13)C-(13)C correlations in rhodopsin. In rhodopsin containing 4'-(13)C-Tyr and 8,19-(13)C retinal, we observe two distinct tyrosine-to-retinal correlations in the DARR spectrum. The most intense cross peak arises from a correlation between Tyr268 and the retinal 19-(13)CH(3), which are 4.8 A apart in the rhodopsin crystal structure. A second cross peak arises from a correlation between Tyr191 and the retinal 19-(13)CH(3), which are 5.5 A apart in the crystal structure. These data demonstrate that long range (13)C em leader (13)C correlations can be obtained in non-crystalline integral membrane proteins reconstituted into lipid membranes containing less than 150 nmoles of protein. In rhodopsin containing 2-(13)C Gly121 and U-(13)C Trp265, we do not observe a Trp-Gly cross peak in the DARR spectrum despite their close proximity (3.6 A) in the crystal structure. Based on model compounds, the absence of a (13)C em leader (13)C cross peak is due to loss of intensity in the diagonal Trp resonances rather than to dipolar truncation.

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Year:  2004        PMID: 15017136     DOI: 10.1023/B:JNMR.0000019521.79321.3c

Source DB:  PubMed          Journal:  J Biomol NMR        ISSN: 0925-2738            Impact factor:   2.835


  13 in total

1.  Expression and purification of rhodopsin and its mutants from stable mammalian cell lines: application to NMR studies.

Authors:  P J Reeves; J Klein-Seetharaman; E V Getmanova; M Eilers; M C Loewen; S O Smith; H G Khorana
Journal:  Biochem Soc Trans       Date:  1999-12       Impact factor: 5.407

2.  Crystal structure of rhodopsin: A G protein-coupled receptor.

Authors:  K Palczewski; T Kumasaka; T Hori; C A Behnke; H Motoshima; B A Fox; I Le Trong; D C Teller; T Okada; R E Stenkamp; M Yamamoto; M Miyano
Journal:  Science       Date:  2000-08-04       Impact factor: 47.728

3.  Constitutively active mutants of rhodopsin.

Authors:  P R Robinson; G B Cohen; E A Zhukovsky; D D Oprian
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4.  Solid-state NMR studies of the mechanism of the opsin shift in the visual pigment rhodopsin.

Authors:  S O Smith; I Palings; M E Miley; J Courtin; H de Groot; J Lugtenburg; R A Mathies; R G Griffin
Journal:  Biochemistry       Date:  1990-09-04       Impact factor: 3.162

5.  Magic angle spinning NMR of the protonated retinylidene Schiff base nitrogen in rhodopsin: expression of 15N-lysine- and 13C-glycine-labeled opsin in a stable cell line.

Authors:  M Eilers; P J Reeves; W Ying; H G Khorana; S O Smith
Journal:  Proc Natl Acad Sci U S A       Date:  1999-01-19       Impact factor: 11.205

6.  Requirement of rigid-body motion of transmembrane helices for light activation of rhodopsin.

Authors:  D L Farrens; C Altenbach; K Yang; W L Hubbell; H G Khorana
Journal:  Science       Date:  1996-11-01       Impact factor: 47.728

7.  Rhodopsin: structural basis of molecular physiology.

Authors:  S T Menon; M Han; T P Sakmar
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8.  The effects of amino acid replacements of glycine 121 on transmembrane helix 3 of rhodopsin.

Authors:  M Han; S W Lin; S O Smith; T P Sakmar
Journal:  J Biol Chem       Date:  1996-12-13       Impact factor: 5.157

9.  (1)H and (13)C MAS NMR evidence for pronounced ligand-protein interactions involving the ionone ring of the retinylidene chromophore in rhodopsin.

Authors:  Alain F L Creemers; Suzanne Kiihne; Petra H M Bovee-Geurts; Willem J DeGrip; Johan Lugtenburg; Huub J M de Groot
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10.  Identification of glutamic acid 113 as the Schiff base proton acceptor in the metarhodopsin II photointermediate of rhodopsin.

Authors:  F Jäger; K Fahmy; T P Sakmar; F Siebert
Journal:  Biochemistry       Date:  1994-09-13       Impact factor: 3.162
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  15 in total

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2.  Coupling of retinal isomerization to the activation of rhodopsin.

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7.  Location of the retinal chromophore in the activated state of rhodopsin*.

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10.  Helix movement is coupled to displacement of the second extracellular loop in rhodopsin activation.

Authors:  Shivani Ahuja; Viktor Hornak; Elsa C Y Yan; Natalie Syrett; Joseph A Goncalves; Amiram Hirshfeld; Martine Ziliox; Thomas P Sakmar; Mordechai Sheves; Philip J Reeves; Steven O Smith; Markus Eilers
Journal:  Nat Struct Mol Biol       Date:  2009-02-01       Impact factor: 15.369
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