PROJECT SUMMARY/ABSTRACT: Proper function in the duplex retina depends on the utilization of rods and cones in the processing of visual information across the scotopic and photopic ranges of illumination. Importantly, when either type of photoreceptor is lost during retinal degeneration, the remaining photoreceptors, be they rods or cones, cannot perform the function of the opposite cell type. Most vertebrate retinae have this “duality” barrier and many current vision restoration efforts are targeted towards replacing the lost photoreceptor population. However, the elasmobranch L. erinacea (Little skate) has a pure-rod simplex retina, which can function under scotopic and photopic illumination. We have a poor understanding of what factors govern this remarkable plasticity in the skate retina, but a detailed knowledge of how this is achieved could hold the key to expanding the functional repertoire of surviving rods or cones in diseased duplex retinae. We propose that the skate retina exhibits a number of hybrid features on the molecular and ultrastructural levels that mediate its functional plasticity. Furthermore, our preliminary data leads us to two main hypotheses: 1) Skate rods function under scotopic and photopic conditions through a combination of morphological adaptations at the level of the synaptic terminal, and genetic adaptations at the level of opsin expression; and: 2) The skate retina exhibits multiple adaptions in the cell circuitry downstream of rods in order to accommodate for their functional plasticity. We have based these predictions on several pieces of preliminary data. First, a long-wavelength sensitive opsin (LWS) can be detected in the global genome of the skate. Second, multiple hybrid features are present at the ultrastructural level in the synaptic terminals of the skate rods. Third, there is a 3-fold increase in the number of postsynaptic processes that invaginate into a skate rod terminal, compared to rods from duplex retinae. Therefore, we will test our hypotheses in the following specific aims: Aim 1: To analyze differences in gene expression in light- and dark-adapted pure-rod retinae and uncover molecular mechanisms of functional plasticity. The objective of Aim 1 is to determine what molecular factors mediate this unusual functional plasticity. Aim 2: To determine the contribution of cell- and circuit-level structural and physiological characteristics mediating functional plasticity in a pure-rod retina. The objectives of Aim 2 are to determine if skate rods posses ultrastructural elements that mediate their functional plasticity, and if the retinal circuitry downstream of rods has evolved specific structural and physiological attributes in order to accommodate for a wider range of inputs. The proposed research is innovative because the simplex skate retina has evolved naturally to the present state and allows us the unique opportunity to study and describe the properties of rod circuitry within the context of ...