The long-term objectives of this research program are to understand cGMP-gated cation channel protein structure/function relationships in rod photoreceptors and to translate this understanding to the treatment of patients with retinitis pigmentosa (RP) and related disorders. We will focus our studies on the channel ?-subunit and the associated soluble glutamic acid rich protein (GARP) GARP2, both encoded by the Cngb1 locus, examining the structural and functional roles of the GARP region in three specific aims. We previously generated a homozygous Cngb1 photoreceptor null (X1 KO) mouse resulting not only in partial loss of channel function but also severe structural perturbations establishing in vivo that these proteins are necessary for normal rod outer segment ROS disk morphogenesis and structural integrity. We hypothesized that the GARP2 sequence on the ?-subunit is required for plasma membrane/disc membrane interaction. To test this we created transgenic mice expressing an N-terminally truncated ?-subunit (T?) devoid of all GARP2 sequence on the X1 KO background. Despite the absence of soluble GARP2, the entire ?-subunit GARP2 region and only one glutamate rich segment remaining on T?, there is significant but not complete structural and functional rescue. To determine the basis for the observed rescue (A.) we will analyze these mice structurally using histology, immunocytochemistry and ultrastructure analysis by transmission and Cryo-EM and functionally using ERG, single cell physiology and a now established retina punch preparation. In the X1 KO and X26 mice that do not express the ?-subunit and in X1 KO also missing soluble GARPs the photoresponse is attenuated. In WT mice overexpressing GARP2 a significant increase in phototransduction gain was observed demonstrating a previously unknown role for GARP2 in modulating phototransduction. (B.) We hypothesize that GARP2 regulates rod dark noise and also contributes to novel slow Burnsian adaptation. To test this we will use our established physiologic tools to compare phototransduction parameters in WT, GARP2 overexpressing, T? transgenic mice and mice expressing full length ?-subunit during activation, recovery and adaptation to further define the role of GARP2 and the ?-subunit in modulating the photoresponse. Using novel zinc finger nuclease technology we have established GARP2-specific knockout mice deleted for the last unique GARP2 exon and a potential hypomorph that is missing the GARP2 3'-UT region. (C.) We will use these mice to test the hypothesis that GARP2 is required for structure and function in the rods. We will perform structural analysis to determine effects on disk morphogenesis and overall outer segment structure and functional analysis to complement studies proposed in Aims A. and B. and to directly examine the role of GARP2 in rod function. The proposed studies document a comprehensive plan to define the structural importance of the GARP region and to define the role of GARP2 in modulating the rod photoresponse. The studies may also yield new targets for intervention treatments for certain forms of hereditary retinal degeneration.

Public Health Relevance

The proposed studies are focused on a novel gene in the retina that is required for normal vision. Defects in the gene cause some forms of the disease retinitis pigmentosa, a progressive hereditary form of blindness. The disease affects a significant portion of the US and world populations and currently there is no established treatment. This application seeks to identify fundamental properties of the genes encoded proteins that will provide essential information needed to develop a treatment for this blinding disorder.

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Research Project (R01)
Project #
4R01EY018143-08
Application #
9126549
Study Section
Biology of the Visual System Study Section (BVS)
Program Officer
Neuhold, Lisa
Project Start
2007-04-01
Project End
2017-08-31
Budget Start
2016-09-01
Budget End
2017-08-31
Support Year
8
Fiscal Year
2016
Total Cost
Indirect Cost
Name
University of Alabama Birmingham
Department
Other Health Professions
Type
Schools of Optometry/Opht Tech
DUNS #
063690705
City
Birmingham
State
AL
Country
United States
Zip Code
35294
DeRamus, Marci L; Stacks, Delores A; Zhang, Youwen et al. (2017) GARP2 accelerates retinal degeneration in rod cGMP-gated cation channel ?-subunit knockout mice. Sci Rep 7:42545
Ding, Xi-Qin; Thapa, Arjun; Ma, Hongwei et al. (2016) The B3 Subunit of the Cone Cyclic Nucleotide-gated Channel Regulates the Light Responses of Cones and Contributes to the Channel Structural Flexibility. J Biol Chem 291:8721-34
Chakraborty, Dibyendu; Conley, Shannon M; Pittler, Steven J et al. (2016) Role of RDS and Rhodopsin in Cngb1-Related Retinal Degeneration. Invest Ophthalmol Vis Sci 57:787-97
Chakraborty, Dibyendu; Conley, Shannon M; DeRamus, Marci L et al. (2015) Varying the GARP2-to-RDS Ratio Leads to Defects in Rim Formation and Rod and Cone Function. Invest Ophthalmol Vis Sci 56:8187-98
Sarfare, Shanta; McKeown, Alex S; Messinger, Jeffrey et al. (2014) Overexpression of rod photoreceptor glutamic acid rich protein 2 (GARP2) increases gain and slows recovery in mouse retina. Cell Commun Signal 12:67
Lu, Rongwen; Levy, Alexander M; Zhang, Qiuxiang et al. (2013) Dynamic near-infrared imaging reveals transient phototropic change in retinal rod photoreceptors. J Biomed Opt 18:106013
Zhang, Qiu-Xiang; Zhang, Youwen; Lu, Rong-Wen et al. (2012) Comparative intrinsic optical signal imaging of wild-type and mutant mouse retinas. Opt Express 20:7646-54
Zhang, Youwen; Rubin, Glen R; Fineberg, Naomi et al. (2012) Age-related changes in Cngb1-X1 knockout mice: prolonged cone survival. Doc Ophthalmol 124:163-75
Lu, Rong-Wen; Curcio, Christine A; Zhang, Youwen et al. (2012) Investigation of the hyper-reflective inner/outer segment band in optical coherence tomography of living frog retina. J Biomed Opt 17:060504
Gilliam, Jared C; Chang, Juan T; Sandoval, Ivette M et al. (2012) Three-dimensional architecture of the rod sensory cilium and its disruption in retinal neurodegeneration. Cell 151:1029-41

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