Structural and Functional Role of Helices I and II in Rhodopsin

Bosch, Laia; Ramon, Eva; Valle, Luís J. del; Garriga, Pere

doi:10.1074/jbc.m301319200

Cited by 33 publications

(9 citation statements)

References 58 publications

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“…As M39R rhodopsin is expressed more productively by mammalian cells than P23H rhodopsin, and a proportion remains able to form a light-responsive complex with retinal, it was selected as an intermediate RP-associated rhodopsin mutation (Davies et al 2012;Ramon et al 2014). G51A is the most common nonsynonymous rhodopsin mutation in humans (Lek et al 2016), displays a less severe phenotype in vitro and in patients (Cideciyan et al 1998;Bosch et al 2003), and may be an asymptomatic variant (Athanasiou et al 2018). These three rhodopsin mutants were each expressed using the mCherry reporter yeast strain.…”

Section: Magnitude Of Light-activated Signal Transduction In Yeast Comentioning

confidence: 99%

Coupling of Human Rhodopsin to a Yeast Signaling Pathway Enables Characterization of Mutations Associated with Retinal Disease

et al. 2018

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G protein-coupled receptors (GPCRs) are crucial sensors of extracellular signals in eukaryotes, with multiple GPCR mutations linked to human diseases. With the growing number of sequenced human genomes, determining the pathogenicity of a mutation is challenging, but can be aided by a direct measurement of GPCR-mediated signaling. This is particularly difficult for the visual pigment rhodopsin-a GPCR activated by light-for which hundreds of mutations have been linked to inherited degenerative retinal diseases such as retinitis pigmentosa. In this study, we successfully engineered, for the first time, activation by human rhodopsin of the yeast mating pathway, resulting in signaling via a fluorescent reporter. We combine this novel assay for rhodopsin lightdependent activation with studies of subcellular localization, and the upregulation of the unfolded protein response in response to misfolded rhodopsin protein. We use these assays to characterize a panel of rhodopsin mutations with known molecular phenotypes, finding that rhodopsin maintains a similar molecular phenotype in yeast, with some interesting differences. Furthermore, we compare our assays in yeast with clinical phenotypes from patients with novel disease-linked mutations. We demonstrate that our engineered yeast strain can be useful in rhodopsin mutant classification, and in helping to determine the molecular mechanisms underlying their pathogenicity. This approach may also be applied to better understand the clinical relevance of other human GPCR mutations, furthering the use of yeast as a tool for investigating molecular mechanisms relevant to human disease.

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Section: Magnitude Of Light-activated Signal Transduction In Yeast Comentioning

confidence: 99%

Coupling of Human Rhodopsin to a Yeast Signaling Pathway Enables Characterization of Mutations Associated with Retinal Disease

et al. 2018

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“…To recapitulate, the functional role of TM-5 in the latter has not been established whereas the Gly51 in TM-1 and Gly89 in TM-2 have been linked to the retinal degenerative disease autosomal dominant retinitis pigmentosa (35) while Glu113 in TM-3, Ala169 in TM-4, Trp265 in TM-6 and Lys296 in TM7 are functionally important (36,37). Indeed, only TM-5 [positions 200–225 (38); z -score of −6.12] in bovine rhodopsin is considered simple by TMSOC and was masked in the sequence.…”

Section: Proof Of Conceptmentioning

confidence: 99%

Transmembrane helix: simple or complex

Wong¹,

Maurer‐Stroh²,

Schneider³

et al. 2012

Nucleic Acids Research

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Transmembrane helical segments (TMs) can be classified into two groups of so-called ‘simple’ and ‘complex’ TMs. Whereas the first group represents mere hydrophobic anchors with an overrepresentation of aliphatic hydrophobic residues that are likely attributed to convergent evolution in many cases, the complex ones embody ancestral information and tend to have structural and functional roles beyond just membrane immersion. Hence, the sequence homology concept is not applicable on simple TMs. In practice, these simple TMs can attract statistically significant but evolutionarily unrelated hits during similarity searches (whether through BLAST- or HMM-based approaches). This is especially problematic for membrane proteins that contain both globular segments and TMs. As such, we have developed the transmembrane helix: simple or complex (TMSOC) webserver for the identification of simple and complex TMs. By masking simple TM segments in seed sequences prior to sequence similarity searches, the false-discovery rate decreases without sacrificing sensitivity. Therefore, TMSOC is a novel and necessary sequence analytic tool for both the experimentalists and the computational biology community working on membrane proteins. It is freely accessible at http://tmsoc.bii.a-star.edu.sg or available for download.

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“…The homology model of melanopsin (maximal absorbance λmax = 447 nm) based on the crystal structure of squid rhodopsin (λmax = 490 nm) shows that 43 nm spectral shift is due to increased bond-length alternation of the protonated Schiff base of 11-cis-retinal chromophore, induced by N87Q mutation and water-mediated H-bonding interactions with the Schiff base linkage [19]. This phenomenon is analogous to spectral changes observed in the G89Q bovine rhodopsin mutants [32]. The alignment with novel OctR structure reveals N88 position for mutagenesis for developing "blue light" bistable recombinant Rho.…”

Section: Zhgun Et Al a Novel Rhodopsin Gene From Octopus Vulgaris Fomentioning

confidence: 76%

A Novel Rhodopsin Gene from Octopus vulgaris for Optobioelectronics Materials

Zhgun¹,

Avdanina²,

Eldarov³

et al. 2015

NanoWorld J

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The unique photochromic retinal protein from rhabdomeric octopus membranes -octopus rhodopsin (OctR) has emerged as promising material for biomolecular photonic applications due to its unique properties and advantages. Here we report isolation of the novel full length octR gene from retina cDNA of Octopus vulgaris eyes and its sequence comparison with rhodopsins of other cephalopods and vertebrates. The isolated gene can be used to develop various expression systems for production of recombinant OctR for structural studies and novel optobioelectronic applications. The alignment of amino acid (a.a.) sequence with different opsins revealed similarity to cephalopoda rhodopsins (Rho) and to human melanopsin from intrinsically photosensitive retinal ganglion cells. The alingment of OctR a.a. sequence with mammalian and cephalopoda Rho with known 3D structures revealed promising substitutions V2C and W292C for developing stable and functionally active recombinant OctR after heterologous expression.

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Structural and Functional Role of Helices I and II in Rhodopsin

Cited by 33 publications

References 58 publications

Coupling of Human Rhodopsin to a Yeast Signaling Pathway Enables Characterization of Mutations Associated with Retinal Disease

Coupling of Human Rhodopsin to a Yeast Signaling Pathway Enables Characterization of Mutations Associated with Retinal Disease

Transmembrane helix: simple or complex

A Novel Rhodopsin Gene from Octopus vulgaris for Optobioelectronics Materials

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