Abstract
Light-induced rhodopsin signaling is turned off with sub-second kinetics by rhodopsin phosphorylation followed by arrestin-1 binding. To test the availability of the arrestin-1 pool in dark-adapted outer segment (OS) for rhodopsin shutoff, we measured photoresponse recovery rates of mice with arrestin-1 content in the OS of 2.5%, 5%, 60%, and 100% of wild type (WT) level by two-flash ERG with the first (desensitizing) flash at 160, 400, 1000, and 2500 photons/rod. The time of half recovery (thalf) in WT retinas increases with the intensity of the initial flash, becoming ∼2.5-fold longer upon activation of 2500 than after 160 rhodopsins/rod. Mice with 60% and even 5% of WT arrestin-1 level recovered at WT rates. In contrast, the mice with 2.5% of WT arrestin-1 had a dramatically slower recovery than the other three lines, with the thalf increasing ∼28 fold between 160 and 2500 rhodopsins/rod. Even after the dimmest flash, the rate of recovery of rods with 2.5% of normal arrestin-1 was two times slower than in other lines, indicating that arrestin-1 level in the OS between 100% and 5% of WT is sufficient for rapid recovery, whereas with lower arrestin-1 the rate of recovery dramatically decreases with increased light intensity. Thus, the OS has two distinct pools of arrestin-1: cytoplasmic and a separate pool comprising ∼2.5% that is not immediately available for rhodopsin quenching. The observed delay suggests that this pool is localized at the periphery, so that its diffusion across the OS rate-limits the recovery. The line with very low arrestin-1 expression is the first where rhodopsin inactivation was made rate-limiting by arrestin manipulation.
Highlights
Humans express,800 different G-protein-coupled receptors (GPCR), among which rhodopsin is the best characterized [1]
Dark-adapted rod outer segment (OS) of transgenic mice expressing arrestin-1 at 4% (Tr-4Arr2/2), 12% (Tr-12Arr2/2), 50% (Arr+/2), and 100% of wild type (WT) contain,7.6, 15, 180, and 300 mM arrestin-1, respectively, which constitutes 2.5%, 5%, 60%, and 100% of normal WT level, respectively
Using desensitizing flash of 20.4 logcd*s/m2 (400 photoisomerizations/rod), we previously found that recovery rates of the three lines with 100%, 60%, and 5% of WT arrestin-1 level in the OS are surprisingly similar, whereas rod recovery in mice with 2.5% of normal arrestin-1 content in the OS is dramatically slowed (Fig. 1) [10]
Summary
Humans express ,800 different G-protein-coupled receptors (GPCR), among which rhodopsin is the best characterized [1]. The biochemical mechanism of rod phototransduction serves as a model of GPCR-driven signaling cascades [1]. Rhodopsin is activated by photoconversion of covalently attached retinal. Rhodopsin is inactivated by GRK1 phosphorylation, followed by high-affinity binding of arrestin-1 when three attached phosphates are accumulated [2,3]. While the functional role of many players in rod phototransduction have been qualitatively established using genetically modified mice (reviewed in [4]), the biological significance of the exact expression level of each protein was rarely addressed experimentally. The studies where rods with different expression levels of rhodopsin [5,6], RGS9 [7,8], GRK1
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