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Literature DB >> 15944125

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

K Saidas Nair¹, 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.

Abstract

In rod photoreceptors, arrestin localizes to the outer segment (OS) in the light and to the inner segment (IS) in the dark. Here, we demonstrate that redistribution of arrestin between these compartments can proceed in ATP-depleted photoreceptors. Translocation of transducin from the IS to the OS also does not require energy, but depletion of ATP or GTP inhibits its reverse movement. A sustained presence of activated rhodopsin is required for sequestering arrestin in the OS, and the rate of arrestin relocalization to the OS is determined by the amount and the phosphorylation status of photolyzed rhodopsin. Interaction of arrestin with microtubules is increased in the dark. Mutations that enhance arrestin-microtubule binding attenuate arrestin translocation to the OS. These results indicate that the distribution of arrestin in rods is controlled by its dynamic interactions with rhodopsin in the OS and microtubules in the IS and that its movement occurs by simple diffusion.

Entities: Chemical Gene

Mesh：

Substances：

Year: 2005 PMID： 15944125 PMCID： PMC2752952 DOI： 10.1016/j.neuron.2005.03.023

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

38 in total

1. Massive light-driven translocation of transducin between the two major compartments of rod cells: a novel mechanism of light adaptation.

Authors: Maxim Sokolov; Arkady L Lyubarsky; Katherine J Strissel; Andrey B Savchenko; Viktor I Govardovskii; Edward N Pugh; Vadim Y Arshavsky
Journal: Neuron Date: 2002-03-28 Impact factor: 17.173

Review 2. Protein translocation in photoreceptor light adaptation: a common theme in vertebrate and invertebrate vision.

Authors: Vadim Y Arshavsky
Journal: Sci STKE Date: 2003-10-14

3. Direct binding of visual arrestin to microtubules determines the differential subcellular localization of its splice variants in rod photoreceptors.

Authors: K Saidas Nair; Susan M Hanson; Matthew J Kennedy; James B Hurley; Vsevolod V Gurevich; Vladlen Z Slepak
Journal: J Biol Chem Date: 2004-07-21 Impact factor: 5.157

Review 4. The molecular acrobatics of arrestin activation.

Authors: Vsevolod V Gurevich; Eugenia V Gurevich
Journal: Trends Pharmacol Sci Date: 2004-02 Impact factor: 14.819

5. The thermal decay of the intermediates of rhodopsin in situ.

Authors: T G Ebrey
Journal: Vision Res Date: 1968-08 Impact factor: 1.886

6. Light-dependent translocation of arrestin in the absence of rhodopsin phosphorylation and transducin signaling.

Authors: Ana Mendez; Janis Lem; Melvin Simon; Jeannie Chen
Journal: J Neurosci Date: 2003-04-15 Impact factor: 6.167

7. Light adaptation through phosphoinositide-regulated translocation of Drosophila visual arrestin.

Authors: Seung-Jae Lee; Hong Xu; Lin-Woo Kang; L Mario Amzel; Craig Montell
Journal: Neuron Date: 2003-07-03 Impact factor: 17.173

8. Quantification of the cytoplasmic spaces of living cells with EGFP reveals arrestin-EGFP to be in disequilibrium in dark adapted rod photoreceptors.

Authors: Jon A Peet; Alvina Bragin; Peter D Calvert; Sergei S Nikonov; Shoba Mani; Xinyu Zhao; Joseph C Besharse; Eric A Pierce; Barry E Knox; Edward N Pugh
Journal: J Cell Sci Date: 2004-06-15 Impact factor: 5.285

9. Light-dependent translocation of visual arrestin regulated by the NINAC myosin III.

Authors: Seung-Jae Lee; Craig Montell
Journal: Neuron Date: 2004-07-08 Impact factor: 17.173

10. Light-dependent redistribution of visual arrestins and transducin subunits in mice with defective phototransduction.

Authors: Houbin Zhang; Wei Huang; Haikun Zhang; Xuemei Zhu; Cheryl M Craft; Wolfgang Baehr; Ching-Kang Chen
Journal: Mol Vis Date: 2003-06-09 Impact factor: 2.367

113 in total

Review 1. Synthetic biology with surgical precision: targeted reengineering of signaling proteins.

Authors: Vsevolod V Gurevich; Eugenia V Gurevich
Journal: Cell Signal Date: 2012-06-01 Impact factor: 4.315

Review 2. Photoreceptor signaling: supporting vision across a wide range of light intensities.

Authors: Vadim Y Arshavsky; Marie E Burns
Journal: J Biol Chem Date: 2011-11-10 Impact factor: 5.157

Review 3. Lessons from photoreceptors: turning off g-protein signaling in living cells.

Authors: Marie E Burns; Edward N Pugh
Journal: Physiology (Bethesda) Date: 2010-04

4. 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

5. Arrestin-1 expression level in rods: balancing functional performance and photoreceptor health.

Authors: X Song; S A Vishnivetskiy; J Seo; J Chen; E V Gurevich; V V Gurevich
Journal: Neuroscience Date: 2010-11-12 Impact factor: 3.590

6. Subcellular localization of regulator of G protein signaling RGS7 complex in neurons and transfected cells.

Authors: Evangelos Liapis; Simone Sandiford; Qiang Wang; Gabriel Gaidosh; Dario Motti; Konstantin Levay; Vladlen Z Slepak
Journal: J Neurochem Date: 2012-06-22 Impact factor: 5.372

Review 7. Photoreceptors at a glance.

Authors: Robert S Molday; Orson L Moritz
Journal: J Cell Sci Date: 2015-11-15 Impact factor: 5.285