Rana El Danaf

Research Scientist Affiliation: NYU Abu Dhabi
Email: rne1@nyu.edu
Education: PhD Virginia Commonwealth University, Richmond, Virginia

Research Areas: Neuroscience, Drosophila Melanogaster, Visual system, Development


The visual system of Drosophila provides a powerful model for understanding how the specificity of connections between different neuronal subtypes arises during development. It is comprised of four neuropils (lamina, medulla, lobula and lobula plate) that are each essential for processing various visual stimuli. Projection neurons in the lobula, including the lobula columnar neurons (LCs), are thought to integrate different visual cues and send that information to the central brain via their axonal projections, leading specific behavioral outputs to be manifested in response to these stimuli. LCs comprise several subtypes that are characterized by unique morphological and functional properties. Interestingly, each LC subtype projects to a distinct optic glomerulus forming highly specific, neighboring yet non-overlapping synaptic domains. The aim of Rana’s research is to understand how this precise pattern of axon-target matching occurs throughout development, as well as to uncover the mechanisms controlling this process.

Prior to joining the Desplan lab, Rana completed her postdoctoral studies at the University of California San Diego, and joined the Department of Neurobiology at Stanford University as a research scientist. During that time, Rana designed and carried out studies aimed to understand visual system development, organization and disease in rodent and non-human primate models. The main goal of her research was to understand the progression of neurodegeneration in glaucoma, the second leading cause of blindness in the world. A hallmark feature of this disease is the death of retinal ganglion cells (RGCs), the neurons that connect the eyes to the brain. Work that Rana performed on this showed that specific RGC subtypes are more susceptible to injury and then, death, in response to a well-established rodent glaucoma model. These findings aimed towards the identification of clinically relevant biomarkers, which can potentially allow for earlier detection of the disease.