Protein and Signaling Networks in Vertebrate Photoreceptor Cells

Koch, K W; Dell’Orco, Daniele

doi:10.3389/fnmol.2015.00067

Cited by 87 publications

(84 citation statements)

References 205 publications

(230 reference statements)

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“…While currently unsupported by experimental evidence, we speculate that phosphorylation at these sites could have a function in modulating/ deactivating the photo-transduction cascade. This could proceed in a manner similar to the deactivation of rhodopsin, which after photoexcitation undergoes conformational changes that allow its phosphorylation by rhodopsin kinase [85]. It is then capped by arrestin thereby preventing further activation of transducine.…”

Section: Phosphorylation Sitesmentioning

confidence: 99%

Molecular dynamics simulations disclose early stages of the photo-activation of cryptochrome 4

2018

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Birds appear to be equipped with a light-dependent, radical-pair-based magnetic compass that relies on truly quantum processes. While the identity of the sensory protein has remained speculative, cryptochrome 4 has recently been identified as the most auspicious candidate. Here, we report on allatom molecular dynamics (MD) simulations addressing the structural reorganisations that accompany the photoreduction of the flavin cofactor in the European robin cryptochrome 4 (ErCry4). Extensive MD simulations reveal that the photo-activation of ErCry4 induces large-scale conformational changes on short (hundreds of nanoseconds) timescales. Specifically, the photo-reduction is accompanied with the release of the C-terminal tail, structural rearrangements in the vicinity of the FAD-binding site, and the noteworthy formation of an α-helical segment at the N-terminal part. Some of these rearrangements appear to expose potential phosphorylation sites. We describe the conformational dynamics of the protein using a graph-based approach that is informed by the adjacency of residues and the correlation of their local motions. This approach reveals densely coupled reorganisation entities, i.e. graph communities, which could facilitate an efficient signal transduction due to a high density of hubs. These communities are interconnected by a small number of highly important residues. The network approach clearly identifies the sites restructuring upon photoactivation, which appear as protrusions or delicate bridges in the reorganisation network. We also find that, unlike in the homologous cryptochrome from D. melanogaster, the release of the C-terminal domain does not appear to be correlated with the transposition of a histidine residue close to the FAD cofactor.

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Section: Phosphorylation Sitesmentioning

confidence: 99%

Molecular dynamics simulations disclose early stages of the photo-activation of cryptochrome 4

2018

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“…While currently unsupported by experimental evidence, we speculate that phosphorylation at these sites could have a function in modulating/deactivating the photo-transduction cascade. This could proceed in a manner similar to the deactivation of rhodopsin, which after photoexcitation undergoes conformational changes that allow its phosphorylation by rhodopsin kinase [75]. It is then capped by arrestin thereby preventing further activation of transducine.…”

Section: Phosphorylation Sitesmentioning

confidence: 99%

Molecular dynamics simulations disclose early stages of the photo-activation of cryptochrome 4

Kattnig¹,

Nielsen²,

Solov’yov³

2018

Preprint

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Birds appear to be equipped with a light-dependent, radical-pair-based magnetic compass that relies on truly quantum processes. While the identity of the sensory protein has remained speculative, cryptochrome 4 has recently been identified as the most auspicious candidate. Here, we report on allatom molecular dynamics (MD) simulations addressing the structural reorganisations that accompany the photoreduction of the flavin cofactor in a model of the European robin cryptochrome 4 (ErCry4). Extensive MD simulations reveal that the photo-activation of ErCry4 induces large-scale conformational changes on short (hundreds of nanoseconds) timescales. Specifically, the photo-reduction is accompanied with the release of the C-terminal tail, structural rearrangements in the vicinity of the FAD-binding site, and the noteworthy formation of an -helical segment at the N-terminal part. Some of these rearrangements appear to expose potential phosphorylation sites. We describe the conformational dynamics of the protein using a graph-based approach that is informed by the adjacency of residues and the correlation of their local motions. This approach reveals densely coupled reorganisation communities, which facilitate an efficient signal transduction due to a high density of hubs. These communities are interconnected by a small number of highly important residues characterized by high betweenness centrality. The network approach clearly identifies the sites restructuring upon photoactivation, which appear as protrusions or delicate bridges in the reorganisation network. We also find that, unlike in the homologous cryptochrome from D. melanogaster, the release of the C-terminal domain does not appear to be correlated with the transposition of a histidine residue close to the FAD cofactor.

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“…Their synapses are in the outer plexiform layer, their nuclei are in the outer nuclear layer, their cell bodies with most of the mitochondria, endosomes, and protein synthesis machinery are in the inner segment layer, and finally their sensory OSs extend toward the RPE from the inner segments (Hoon et al, 2014; LaVail, 1983; Mustafi et al, 2009; Steinberg et al, 1980; Sung and Chuang, 2010). The photoreceptor OSs are modified primary cilia which have evolved to detect incoming light and initiate a signal transduction cascade which is the first domino in the long chain of signaling and cellular communications necessary for vision (Arshavsky and Wensel, 2013; Gilliam et al, 2012; Hoon et al, 2014; Hubbell et al, 2003; Koch and Dell’Orco, 2015; Li et al, 2004; Palczewski et al, 2000; Papermaster and Dreyer, 1974; Sung and Chuang, 2010; Zhou et al, 2012). …”

Section: Introductionmentioning

confidence: 99%

PRPH2/RDS and ROM-1: Historical context, current views and future considerations

Stuck

Conley

Naash

2016

Progress in Retinal and Eye Research

105

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Peripherin2 (PRPH2), also known as RDS (retinal degeneration slow) is a photoreceptor specific glycoprotein which is essential for normal photoreceptor health and vision. PRPH2/RDS is necessary for the proper formation of both rod and cone photoreceptor outer segments, the organelle specialized for visual transduction. When PRPH2/RDS is defective or absent, outer segments become disorganized or fail to form entirely and the photoreceptors subsequently degenerate. Multiple PRPH2/RDS disease-causing mutations have been found in humans, and they are associated with various blinding diseases of the retina such as macular degeneration and retinitis pigmentosa, the vast majority of which are inherited dominantly, though recessive LCA and digenic RP have also been associated with RDS mutations. Since its initial discovery, the scientific community has dedicated a considerable amount of effort to understanding the molecular function and disease mechanisms of PRPH2/RDS. This work has led to an understanding of how the PRPH2/RDS molecule assembles into complexes and functions as a necessary part of the machinery that forms new outer segment discs, as well as leading to fundamental discoveries about the mechanisms that underlie OS biogenesis. Here we discuss PRPH2/RDS-associated research and how experimental results have driven the understanding of the PRPH2/RDS protein and its role in human disease.

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Protein and Signaling Networks in Vertebrate Photoreceptor Cells

Cited by 87 publications

References 205 publications

Molecular dynamics simulations disclose early stages of the photo-activation of cryptochrome 4

Molecular dynamics simulations disclose early stages of the photo-activation of cryptochrome 4

Molecular dynamics simulations disclose early stages of the photo-activation of cryptochrome 4

PRPH2/RDS and ROM-1: Historical context, current views and future considerations

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