Distinct and atypical intrinsic and extrinsic cell death pathways between photoreceptor cell types upon specific ablation of Ranbp2 in cone photoreceptors.

Abstract

Non-autonomous cell-death is a cardinal feature of the disintegration of neural networks in neurodegenerative diseases, but the molecular bases of this process are poorly understood. The neural retina comprises a mosaic of rod and cone photoreceptors. Cone and rod photoreceptors degenerate upon rod-specific expression of heterogeneous mutations in functionally distinct genes, whereas cone-specific mutations are thought to cause only cone demise. Here we show that conditional ablation in cone photoreceptors of Ran-binding protein-2 (Ranbp2), a cell context-dependent pleiotropic protein linked to neuroprotection, familial necrotic encephalopathies, acute transverse myelitis and tumor-suppression, promotes early electrophysiological deficits, subcellular erosive destruction and non-apoptotic death of cones, whereas rod photoreceptors undergo cone-dependent non-autonomous apoptosis. Cone-specific Ranbp2 ablation causes the temporal activation of a cone-intrinsic molecular cascade highlighted by the early activation of metalloproteinase 11/stromelysin-3 and up-regulation of Crx and CoREST, followed by the down-modulation of cone-specific phototransduction genes, transient up-regulation of regulatory/survival genes and activation of caspase-7 without apoptosis. Conversely, PARP1+ -apoptotic rods develop upon sequential activation of caspase-9 and caspase-3 and loss of membrane permeability. Rod photoreceptor demise ceases upon cone degeneration. These findings reveal novel roles of Ranbp2 in the modulation of intrinsic and extrinsic cell death mechanisms and pathways. They also unveil a novel spatiotemporal paradigm of progression of neurodegeneration upon cell-specific genetic damage whereby a cone to rod non-autonomous death pathway with intrinsically distinct cell-type death manifestations is triggered by cell-specific loss of Ranbp2. Finally, this study casts new light onto cell-death mechanisms that may be shared by human dystrophies with distinct retinal spatial signatures as well as with other etiologically distinct neurodegenerative disorders.

Department

Description

Provenance

Citation

Published Version (Please cite this version)

10.1371/journal.pgen.1003555

Publication Info

Cho, Kyoung-In, Mdemdadul Haque, Jessica Wang, Minzhong Yu, Ying Hao, Sunny Qiu, Indulekha CL Pillai, Neal S Peachey, et al. (2013). Distinct and atypical intrinsic and extrinsic cell death pathways between photoreceptor cell types upon specific ablation of Ranbp2 in cone photoreceptors. PLoS Genet, 9(6). p. e1003555. 10.1371/journal.pgen.1003555 Retrieved from https://hdl.handle.net/10161/15577.

This is constructed from limited available data and may be imprecise. To cite this article, please review & use the official citation provided by the journal.

Scholars@Duke

Ferreira

Paulo Alexandre Ferreira

Associate Professor in Ophthalmology

The long-term goal of our research program is twofold. The first is to understand the interplay between intracellular signaling, intracellular trafficking and proteostasis in health and disease; the second is to uncover molecular players and mechanisms partaking in such processes that are amenable to therapeutic intervention in a variety of disease states. Presently, our research efforts are centered on dissecting the roles of two disease-associated protein interactomes assembled by the Ran-binding protein 2 (RanBP2) and the retinitis pigmentosa GTPase regulator-interacting protein 1 (RPGRIP1) in several neuronal cell types of the retina and brain that often undergo neurodegeneration upon a multiplicity of diseases with distinct etiologies.

The RanBP2 is a large and modular 358 kDa protein scaffold, which assembles a large multifunctional complex and acts a signal integrator of molecular and subcellular signaling and trafficking pathways critical to neuronal survival or function. Mutations or deficits in RanBP2 are linked to a variety of diseases processes ranging from neurodegeneration and necrosis to stress signaling and cancer. RanBP2 modulates the assembly or disassembly of several protein complexes with apparent disparate functions and implicated in molecular processes, such as nucleocytoplasmic and microtubule-based intracellular trafficking of proteins or organelles, protein homeostasis and biogenesis, modulation of protein-protein interactions (e.g. sumoylation), and control of cell division. Interdisciplinary approaches ranging from single molecule analysis to cell-based assays and genetically modified mouse models are employed to dissect selective cell type-dependent roles of proteins modulated dynamically by RanBP2 and underlying mechanisms in healthy and disease states.

The RPGRIP1 is also a modular protein, which associates directly with molecular partners, such as the retinitis pigmentosa GTPase regulator (RPGR) and nephrocystin-4 (NPHP4). Human mutations in the genes encoding RPGRIP1, RPGR and NPHP4 lead to severe ocular-renal, syndromic and non-syndromic retinal or renal diseases. These lead ultimately to blindness, loss of kidney function or both. Emerging data from our laboratory implicate the RPGRIP1 interactome in the regulation of the tethering, targeting, exiting and/or transport of selective retinal-renal and pre-ciliary components from the endoplasmic reticulum compartment to cilia. These processes serve as molecular determinants to the formation of subcellular structures/compartments that are critical to photoreceptor or tubular kidney cell functions . Current work is directed at dissecting: i) the biological and pathological roles of components of the RPGRIP1 interactome in retinal and kidney functions; ii) the molecular, cellular and pathophysiological bases of allelic-specific mutations and genetic heterogeneity affecting components of the RPGRIP1 interactome; iii) the identification of therapeutic targets and mechanisms dependent on the functions of the RPGRIP1 assembly complex and therapeutic approaches to delay the onset or progression of degeneration of photoreceptor, tubular kidney cells or both.


Unless otherwise indicated, scholarly articles published by Duke faculty members are made available here with a CC-BY-NC (Creative Commons Attribution Non-Commercial) license, as enabled by the Duke Open Access Policy. If you wish to use the materials in ways not already permitted under CC-BY-NC, please consult the copyright owner. Other materials are made available here through the author’s grant of a non-exclusive license to make their work openly accessible.