2012
DOI: 10.1073/pnas.1117268109
|View full text |Cite
|
Sign up to set email alerts
|

Effect of channel mutations on the uptake and release of the retinal ligand in opsin

Abstract: In the retinal binding pocket of rhodopsin, a Schiff base links the retinal ligand covalently to the Lys296 side chain. Light transforms the inverse agonist 11-cis-retinal into the agonist all-trans-retinal, leading to the active Meta II state. Crystal structures of Meta II and the active conformation of the opsin apoprotein revealed two openings of the 7-transmembrane (TM) bundle towards the hydrophobic core of the membrane, one between TM1/TM7 and one between TM5/TM6, respectively. Computational analysis rev… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
1
1
1
1

Citation Types

9
88
2

Year Published

2013
2013
2020
2020

Publication Types

Select...
8

Relationship

2
6

Authors

Journals

citations
Cited by 75 publications
(107 citation statements)
references
References 43 publications
9
88
2
Order By: Relevance
“…Our 2.3 Å crystal structure of this mutant reveals the water network around retinal in an unprecedented detail: We observe four new water molecules that are probably not specific for this mutant, as the structure of the retinal binding pocket has not changed compared to previous structures of metarhodopsin-II [17,21]. However, one of the previously described water molecules in this region is missing in our structure, likely because the hydrophobic mutation T94I [26], as the smaller alanine side chain would not be able to affect retinal hydrolysis as described above.…”
Section: T94mentioning
confidence: 65%
See 1 more Smart Citation
“…Our 2.3 Å crystal structure of this mutant reveals the water network around retinal in an unprecedented detail: We observe four new water molecules that are probably not specific for this mutant, as the structure of the retinal binding pocket has not changed compared to previous structures of metarhodopsin-II [17,21]. However, one of the previously described water molecules in this region is missing in our structure, likely because the hydrophobic mutation T94I [26], as the smaller alanine side chain would not be able to affect retinal hydrolysis as described above.…”
Section: T94mentioning
confidence: 65%
“…According to a study of mutations in the retinal entry channel [26], T94I 2.61 may even reduce constitutive activity of opsin. The same study shows increased constitutive activity for 11 out of 15 mutations close to the retinal binding pocket, none of which is correlated with CSNB.…”
Section: 61mentioning
confidence: 99%
“…The question remains why only four mutations in rhodopsin cause CSNB, whereas many other known mutations increase constitutive activity of opsin [26], interfere with retinal binding [19], increase thermal isomerization [34] or preactivate dark-state rhodopsin [17,35]. Our structural data indicate that substitutions that specifically perturb the E113-K296 activation switch result in CSNB (Fig 4), likely by destabilizing the inactive conformation and selectively favouring a short-lived preactivated conformation at the same time.…”
Section: Relevance To Csnbmentioning
confidence: 88%
“…The active conformation of opsin thus seems to preform a binding pocket into which several retinal isomers can bind. Once the right retinal isomer is in place, a SB is formed and snaps into the strong salt bridge with its counterion E113 to force the seven-helix bundle into the inactive rhodopsin dark state [2,19]. The G90D mutation prevents an efficient snapping by forming a salt bridge with K296, the site of SB formation.…”
Section: Resultsmentioning
confidence: 99%
“…Cones have been optimized for fast regeneration, with cone opsin meta-intermediate states being short lived compared with those of rhodopsin (Imai et al, 2005), and a cone-specific MĂŒller cell retinoid cycle (Das et al, 1992) providing a dedicated pool of 11-cis retinal. These faster kinetic properties are hypothesized to be facilitated in cone opsins via the relative 'openness' of the chromophore binding pocket, which allows water molecules, and therefore other small molecules such as hydroxylamine, to access the chromophore where they can participate in Schiff base hydrolysis (Chen et al, 2012;Piechnick et al, 2012;Wald et al, 1955). Rhodopsins, in contrast, are optimized for sensitivity and signal amplification; therefore, E122/I189 and a tighter overall structure contribute to a slower active state decay, allowing for the activation of multiple G proteins (Chen et al, 2012;Starace and Knox, 1997), increased thermal stability relative to cone opsins (Barlow, 1964) and a resistance to hydroxylamine (Dartnall, 1968).…”
Section: Discussionmentioning
confidence: 99%