Abstract
Recent work has established potential new functional roles for NSF in the photoreceptor. First, the interaction of Arr1 and NSF is ATP-dependent, and the N-terminal domain of Arr1 interacts with the N and D1 junctional domains of NSF. The Arr1-NSF interactions are greater in the photoreceptor synaptic terminal in the dark. Furthermore, Arr1 enhances the NSF ATPase activity and increases the NSF disassembly activities, which are critical for NSF functions in sustaining a higher rate of exocytosis in the photoreceptor synapses and the compensatory endocytosis to retrieve vesicle membrane and vesicle proteins for vesicle recycling. These data demonstrate the Arr1 and NSF interaction are necessary for both maintenance and modulation of normal photoreceptor synaptic regulation. Second, NSF colocalizes and specifically binds to RP2, especially in the ciliary and synaptic region of the photoreceptor, and NSF-RP2 interaction may play an important role in membrane protein trafficking in the photoreceptor. Inherited retinal degeneration affects about 1 in 2,000-3,000 individuals in the world and is the leading cause of visual loss in young people and accounts for a large proportion of blindness in adult life. These studies accelerate our ability to gain insight into the diverse roles of the NSF in the photoreceptor cells and enable us to understand more precisely the molecular mechanisms underlying night blindness associated with clinically diagnosed Oguchi disease or other forms of retinitis pigmentosa.