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Literature DB >> 20869596

Arrestin translocation is stoichiometric to rhodopsin isomerization and accelerated by phototransduction in Drosophila photoreceptors.

Akiko K Satoh¹, Hongai Xia, Limin Yan, Che-Hsiung Liu, Roger C Hardie, Donald F Ready.

Abstract

Upon illumination, visual arrestin translocates from photoreceptor cell bodies to rhodopsin and membrane-rich photosensory compartments, vertebrate outer segments or invertebrate rhabdomeres, where it quenches activated rhodopsin. Both the mechanism and function of arrestin translocation are unresolved and controversial. In dark-adapted photoreceptors of the fruitfly Drosophila, confocal immunocytochemistry shows arrestin (Arr2) associated with distributed photoreceptor endomembranes. Immunocytochemistry and live imaging of GFP-tagged Arr2 demonstrate rapid reversible translocation to stimulated rhabdomeres in stoichiometric proportion to rhodopsin photoisomerization. Translocation is very rapid in normal photoreceptors (time constant <10 s) and can also be resolved in the time course of electroretinogram recordings. Genetic elimination of key phototransduction proteins, including phospholipase C (PLC), Gq, and the light-sensitive Ca2+-permeable TRP channels, slows translocation by 10- to 100-fold. Our results indicate that Arr2 translocation in Drosophila photoreceptors is driven by diffusion, but profoundly accelerated by phototransduction and Ca2+ influx.

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Year: 2010 PMID： 20869596 PMCID： PMC2946946 DOI： 10.1016/j.neuron.2010.08.024

Source DB: PubMed Journal: Neuron ISSN： 0896-6273 Impact factor: 17.173

47 in total

Review 1. Adaptation in vertebrate photoreceptors.

Authors: G L Fain; H R Matthews; M C Cornwall; Y Koutalos
Journal: Physiol Rev Date: 2001-01 Impact factor: 37.312

2. Light-dependent redistribution of arrestin in vertebrate rods is an energy-independent process governed by protein-protein interactions.

Authors: K Saidas Nair; Susan M Hanson; Ana Mendez; Eugenia V Gurevich; Matthew J Kennedy; Valery I Shestopalov; Sergey A Vishnivetskiy; Jeannie Chen; James B Hurley; Vsevolod V Gurevich; Vladlen Z Slepak
Journal: Neuron Date: 2005-05-19 Impact factor: 17.173

Review 3. Mechanism of light-induced translocation of arrestin and transducin in photoreceptors: interaction-restricted diffusion.

Authors: Vladlen Z Slepak; James B Hurley
Journal: IUBMB Life Date: 2008-01 Impact factor: 3.885

4. INDO-1 measurements of absolute resting and light-induced Ca2+ concentration in Drosophila photoreceptors.

Authors: R C Hardie
Journal: J Neurosci Date: 1996-05-01 Impact factor: 6.167

5. A G protein-coupled receptor phosphatase required for rhodopsin function.

Authors: J Vinós; K Jalink; R W Hardy; S G Britt; C S Zuker
Journal: Science Date: 1997-08-01 Impact factor: 47.728

6. Fluorescence of photoreceptor cells observed in vivo.

Authors: N Franceschini; K Kirschfeld; B Minke
Journal: Science Date: 1981-09-11 Impact factor: 47.728

7. Effect of hydroxylamine on the subcellular distribution of arrestin (S-antigen) in rod photoreceptors.

Authors: N J Mangini; G L Garner; T I Okajima; L A Donoso; D R Pepperberg
Journal: Vis Neurosci Date: 1994 May-Jun Impact factor: 3.241

8. Temporal kinetics of the light/dark translocation and compartmentation of arrestin and alpha-transducin in mouse photoreceptor cells.

Authors: Rajesh V Elias; Steven S Sezate; Wei Cao; James F McGinnis
Journal: Mol Vis Date: 2004-09-15 Impact factor: 2.367

9. The trp gene is essential for a light-activated Ca2+ channel in Drosophila photoreceptors.

Authors: R C Hardie; B Minke
Journal: Neuron Date: 1992-04 Impact factor: 17.173

10. Drosophila photoreceptors and signaling mechanisms.

Authors: Ben Katz; Baruch Minke
Journal: Front Cell Neurosci Date: 2009-06-11 Impact factor: 5.505

27 in total

1. Arrestin-rhodopsin binding stoichiometry in isolated rod outer segment membranes depends on the percentage of activated receptors.

Authors: Martha E Sommer; Klaus Peter Hofmann; Martin Heck
Journal: J Biol Chem Date: 2010-12-17 Impact factor: 5.157

2. On visual pigment templates and the spectral shape of invertebrate rhodopsins and metarhodopsins.

Authors: Doekele G Stavenga
Journal: J Comp Physiol A Neuroethol Sens Neural Behav Physiol Date: 2010-08-20 Impact factor: 1.836

3. Few residues within an extensive binding interface drive receptor interaction and determine the specificity of arrestin proteins.

Authors: Sergey A Vishnivetskiy; Luis E Gimenez; Derek J Francis; Susan M Hanson; Wayne L Hubbell; Candice S Klug; Vsevolod V Gurevich
Journal: J Biol Chem Date: 2011-04-06 Impact factor: 5.157

Review 4. Functional interplay of visual, sensitizing and screening pigments in the eyes of Drosophila and other red-eyed dipteran flies.

Authors: D G Stavenga; M F Wehling; G Belušič
Journal: J Physiol Date: 2017-04-11 Impact factor: 5.182

5. Protein Gq modulates termination of phototransduction and prevents retinal degeneration.

Authors: Wen Hu; Didi Wan; Xiaoming Yu; Jinguo Cao; Peiyi Guo; Hong-Sheng Li; Junhai Han
Journal: J Biol Chem Date: 2012-03-02 Impact factor: 5.157

Review 6. The functional cycle of visual arrestins in photoreceptor cells.

Authors: Vsevolod V Gurevich; Susan M Hanson; Xiufeng Song; Sergey A Vishnivetskiy; Eugenia V Gurevich
Journal: Prog Retin Eye Res Date: 2011-07-29 Impact factor: 21.198

7. Loss of retinoschisin (RS1) cell surface protein in maturing mouse rod photoreceptors elevates the luminance threshold for light-driven translocation of transducin but not arrestin.

Authors: Lucia Ziccardi; Camasamudram Vijayasarathy; Ronald A Bush; Paul A Sieving
Journal: J Neurosci Date: 2012-09-19 Impact factor: 6.167