Increased proteasomal activity supports photoreceptor survival in inherited retinal degeneration.
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2018-04-30
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Inherited retinal degenerations, affecting more than 2 million people worldwide, are caused by mutations in over 200 genes. This suggests that the most efficient therapeutic strategies would be mutation independent, i.e., targeting common pathological conditions arising from many disease-causing mutations. Previous studies revealed that one such condition is an insufficiency of the ubiquitin-proteasome system to process misfolded or mistargeted proteins in affected photoreceptor cells. We now report that retinal degeneration in mice can be significantly delayed by increasing photoreceptor proteasomal activity. The largest effect is observed upon overexpression of the 11S proteasome cap subunit, PA28α, which enhanced ubiquitin-independent protein degradation in photoreceptors. Applying this strategy to mice bearing one copy of the P23H rhodopsin mutant, a mutation frequently encountered in human patients, quadruples the number of surviving photoreceptors in the inferior retina of 6-month-old mice. This striking therapeutic effect demonstrates that proteasomes are an attractive target for fighting inherited blindness.
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Lobanova, Ekaterina S, Stella Finkelstein, Jing Li, Amanda M Travis, Ying Hao, Mikael Klingeborn, Nikolai P Skiba, Raymond J Deshaies, et al. (2018). Increased proteasomal activity supports photoreceptor survival in inherited retinal degeneration. Nature communications, 9(1). p. 1738. 10.1038/s41467-018-04117-8 Retrieved from https://hdl.handle.net/10161/17215.
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Scholars@Duke
Nikolai Petrovich Skiba
My research focuses on applying mass spectrometry based proteomics to study proteins in eye tissues, cells and sub-cellular compartments to understand mechanisms of vision. An important aspect of my research is to identify proteins in different compartments of retinal photoreceptor cells, their amount and modification status at different cell states defined by the light conditions, genotype, disease etc. This information can be valuable in understanding molecular mechanisms of vision and biology of the photoreceptor cell. Another important aspect of my research is to assist basic scientist and clinicians in our department in their proteomic needs which include identification of proteins and other biomolecules in a given biological sample, detection of protein post-translational modifications and sequence variations, elucidation of protein-protein interactions and also characterization of changes in the protein concentration and composition in a biological sample at different conditions.
Vadim Y Arshavsky
The Biology and Pathophysiology of Vertebrate Photoreceptor Cells
Research conducted in our laboratory is dedicated to understanding how vision is performed on the molecular level. Most of our work is centered on vertebrate photoreceptor cells, which are sensory neurons responsible for light detection in the eye. Photoreceptors capture photons, produce an electrical signal, and transmit this information to the secondary neurons in the retina, and ultimately to the brain, through modulation of their synaptic release.
The main experimental direction of our laboratory is to elucidate the cellular processes responsible for building the light-sensitive organelle of photoreceptor cells, called the outer segment, and for populating this organelle with proteins supporting its structure and conducting visual signaling. Of particular interest is the mechanism by which outer segments form their “disc” membrane stacks providing vast membrane surfaces for efficient photon capture. Outer segment membranes are continuously renewed throughout the lifetime of a photoreceptor, with new discs added to the outer segment base and old discs phagocytosed at the tip by the retinal pigment epithelium. As a result, the entire mammalian outer segment is replaced with new discs over the course of 8-10 days. One of the central goals of our current studies is to elucidate the signaling pathway that acts as a “control center” to initiate the formation of each new disc with the strikingly regular frequency of approximately 80 times per day.
Our second major research direction explores a connection between understanding the basic function of rods and cones and practical, translational ideas aiming to ameliorate retinal degeneration caused by mutations in critical photoreceptor-specific proteins. Several years ago, we found that photoreceptors bearing a broad spectrum of disease-associated mutations suffer from a common cellular stress factor, proteasomal overload, i.e. insufficient ability of the ubiquitin-proteasome system to process misfolded and/or mislocalized proteins produced in these cells. Our more recent data demonstrate that the enhancement of protein degradation machinery in these cells causes a remarkable delay in the progression of photoreceptor degeneration. We continue investigating photoreceptor proteostasis in further mechanistic depth and seek optimal strategies to employ proteasomal activation as a means to ameliorate or cure inherited blindness.
During our studies, we explore high-end applications of mass spectrometry-based proteomics and were the first laboratory adopting several advanced proteomic approaches to vision research. Of particular significance are the applications of so-called “label-free” quantitative proteomics for simultaneous elucidation of multiple protein distributions among different compartments of the photoreceptor cells and for identification of unique protein components of various photoreceptor membranes. Using label-free proteomics, we demonstrated that a small protein PRCD (progressive rod and cone degeneration) is a unique component of photoreceptor discs and subsequently identified several novel unique components of the plasma membrane enclosing the rod outer segment. Most recently, we adopted a highly efficient and accurate methodology for simultaneous absolute quantification of several dozen proteins, termed MS Western. This method allowed us to determine the precise molar ratio amongst all major functional and structural proteins residing in the light-sensitive outer segments of photoreceptor cells.
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