Analysis of the mechanisms underlying light adaptation and recovery following phototransduction is one of the goals outlined in the National Plan for Eye and Vision Research (www.nei.nih.gov/strategicplanning /np_retinal.asp). One of the most striking molecular events that occurs in retinal rods in response to illumination is the migration of rod G protein, transducin. In darkness, transducin concentrates in the outer segments (OS) of rods. In light, it migrates from the OS to the inner segment (IS), nuclear layer and the synaptic terminals. The significance and the mechanism responsible for this phenomenon are a subject of debate. Based on genetic studies in mice and drosophila, a number of vision scientists hypothesized that transducin movement requires active transport machinery. However, this laboratory showed that movement of transducin does not require ATP and therefore must be driven by diffusion rather than molecular motors. In this model, the light-dependence and directionality of transducin relocalization is explained by the following simple mechanism. Upon activation, rod transducin (i) dissociates into Galpha and Gbeta-gamma, (ii) the subunits become soluble and disperse throughout the cell. Dissociation of the subunits and their subsequent solubilization are the only two events necessary and sufficient for the release of transducin from the OS and subsequent relocalization. The proposed research will use this model to establish whether transducin translocation is indeed necessary for light adaptation, and whether it contributes to cell survival (protection from light damage).
Specific Aim 1 will design and test mutant forms of rod transducin alpha subunit that cannot translocate by virtue of the altered affinity to the membranes, Gbeta-gamma, and LGN, a putative binding partner in the inner compartments of the rods. These Galpha mutants will be first validated in transfected mammalian cells and then in situ using virally transformed mouse rods.
Specific Aim 2 is to express these dominant mutants in vivo (transgenic mice) in order to examine the effect on light adaptation and rod survival (retinal degeneration). A series of electrophysiological, biochemical and histological analyses will investigate light adaptation and long- term survival of the rods. This project will achieve two goals: establish the molecular mechanism of light-dependent rod transducin redistribution and understand physiologic significance of this phenomenon. This new basic knowledge will provide a conceptual framework for designing new strategies to prevent and treat retinal degenerative diseases.

Public Health Relevance

Many proteins re-localize within cells in response to external stimuli. This project investigates the basic principles and significance of light-dependent intracellular movements of a heterotrimeric G protein in photoreceptor rods. The proposed experiments will determine how the ability of the G protein to relocalize is important for light adaptation and long-term photoreceptor cells. The new insights are important for understanding currently incurable blinding diseases, and is also important for broader aspects of neuronal degeneration.

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Research Project (R01)
Project #
5R01EY018666-05
Application #
8458564
Study Section
Biology and Diseases of the Posterior Eye Study Section (BDPE)
Program Officer
Neuhold, Lisa
Project Start
2009-05-01
Project End
2014-04-30
Budget Start
2013-05-01
Budget End
2014-04-30
Support Year
5
Fiscal Year
2013
Total Cost
$343,170
Indirect Cost
$117,450
Name
University of Miami School of Medicine
Department
Pharmacology
Type
Schools of Medicine
DUNS #
052780918
City
Coral Gables
State
FL
Country
United States
Zip Code
33146
Levay, Konstantin; Slepak, Vladlen Z (2014) Regulation of Cop9 signalosome activity by the EF-hand Ca2+-binding protein tescalcin. J Cell Sci 127:2448-59
Križaj, David; Ryskamp, Daniel A; Tian, Ning et al. (2014) From mechanosensitivity to inflammatory responses: new players in the pathology of glaucoma. Curr Eye Res 39:105-19
Pronin, Alexey; Levay, Konstantin; Velmeshev, Dmitry et al. (2014) Expression of olfactory signaling genes in the eye. PLoS One 9:e96435
Mason, Benjamin; Schmale, Michael; Gibbs, Patrick et al. (2012) Evidence for multiple phototransduction pathways in a reef-building coral. PLoS One 7:e50371
Liapis, Evangelos; Sandiford, Simone; Wang, Qiang et al. (2012) Subcellular localization of regulator of G protein signaling RGS7 complex in neurons and transfected cells. J Neurochem 122:568-81
Dvoriantchikova, Galina; Ivanov, Dmitry; Barakat, David et al. (2012) Genetic ablation of Pannexin1 protects retinal neurons from ischemic injury. PLoS One 7:e31991
Dong, Qunfeng; Brulc, Jennifer M; Iovieno, Alfonso et al. (2011) Diversity of bacteria at healthy human conjunctiva. Invest Ophthalmol Vis Sci 52:5408-13
Sandiford, Simone L; Wang, Qiang; Levay, Konstantin et al. (2010) Molecular organization of the complex between the muscarinic M3 receptor and the regulator of G protein signaling, Gbeta(5)-RGS7. Biochemistry 49:4998-5006
Slepak, Vladlen Z (2009) Structure, function, and localization of Gýý5-RGS complexes. Prog Mol Biol Transl Sci 86:157-203
Rosenzweig, Derek H; Nair, K Saidas; Levay, Konstantin et al. (2009) Interaction of retinal guanylate cyclase with the alpha subunit of transducin: potential role in transducin localization. Biochem J 417:803-12