Papers associated with retinal neural layer

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	Novel laser model of optic nerve transection provides valuable insights about the dynamics of optic nerve regeneration., Moulin C., Sci Rep. November 9, 2024; 14 (1): 27412.
	Neuroinflammation as a cause of differential Müller cell regenerative responses to retinal injury., García-García D., Sci Adv. October 4, 2024; 10 (40): eadp7916.
	Prominin-1 null Xenopus laevis develop subretinal drusenoid-like deposits, cone-rod dystrophy, and RPE atrophy., Carr BJ., J Cell Sci. October 2, 2024;
	Regeneration from three cellular sources and ectopic mini-retina formation upon neurotoxic retinal degeneration in Xenopus., Parain K., Glia. April 1, 2024; 72 (4): 759-776.
	Mass spectrometry dataset of LC-MS lipidomics analysis of Xenopus laevis optic nerve., Neag E., Data Brief. August 1, 2023; 49 109313.
	Photoreceptor disc incisures form as an adaptive mechanism ensuring the completion of disc enclosure., Lewis TR., Elife. July 14, 2023; 12
	Dual leucine zipper kinase is necessary for retinal ganglion cell axonal regeneration in Xenopus laevis., Fague L., PNAS Nexus. May 1, 2023; 2 (5): pgad109.
	BDNF signaling in correlation-dependent structural plasticity in the developing visual system., Kutsarova E., PLoS Biol. April 1, 2023; 21 (4): e3002070.
	Ocular microvasculature in adult Xenopus laevis: Scanning electron microscopy of vascular casts., Lametschwandtner A., J Morphol. March 1, 2023; 284 (3): e21561.
	Surgical Methods in Postmetamorphic Xenopus laevis: Optic Nerve Crush Injury Model., Feidler AM., Methods Mol Biol. January 1, 2023; 2636 205-219.
	Cell-autonomous and differential endocannabinoid signaling impacts the development of presynaptic retinal ganglion cell axon connectivity in vivo., Del Rio R., Front Synaptic Neurosci. January 1, 2023; 15 1176864.
	Cell-type expression and activation by light of neuropsins in the developing and mature Xenopus retina., Man LLH., Front Cell Neurosci. January 1, 2023; 17 1266945.
	Xenopus retinal ganglion cell axon extension is unaffected by 5-HT 1B/D receptor activation during visual system development., Basakis P., MicroPubl Biol. January 1, 2023; 2023
	Development and Degeneration of Retinal Ganglion Cell Axons in Xenopus tropicalis., Choi B., Mol Cells. November 30, 2022; 45 (11): 846-854.
	Multi-omics approach dissects cis-regulatory mechanisms underlying North Carolina macular dystrophy, a retinal enhanceropathy., Van de Sompele S., Am J Hum Genet. October 3, 2022; 109 (11): 2029-2048.
	DSCAM is differentially patterned along the optic axon pathway in the developing Xenopus visual system and guides axon termination at the target., Santos RA., Neural Dev. April 15, 2022; 17 (1): 5.
	Influence of Sox protein SUMOylation on neural development and regeneration., Chang KC., Neural Regen Res. March 1, 2022; 17 (3): 477-481.
	Topographic map formation and the effects of NMDA receptor blockade in the developing visual system., Li VJ., Proc Natl Acad Sci U S A. February 22, 2022; 119 (8):
	Cannabinoid Receptor Type 1 regulates growth cone filopodia and axon dispersion in the optic tract of Xenopus laevis tadpoles., Elul T., Eur J Neurosci. February 1, 2022; 55 (4): 989-1001.
	Proteomic screen reveals diverse protein transport between connected neurons in the visual system., Schiapparelli LM., Cell Rep. January 25, 2022; 38 (4): 110287.
	Electrophysiological Approaches to Studying Normal and Abnormal Retinotectal Circuit Development in the Xenopus Tadpole., Pratt KG., Cold Spring Harb Protoc. November 1, 2021; 2021 (11):
	Sodium-calcium exchanger mediates sensory-evoked glial calcium transients in the developing retinotectal system., Benfey NJ., Cell Rep. October 5, 2021; 37 (1): 109791.
	Stochastic combinations of actin regulatory proteins are sufficient to drive filopodia formation., Dobramysl U., J Cell Biol. April 5, 2021; 220 (4):
	Microglial trogocytosis and the complement system regulate axonal pruning in vivo., Lim TK., Elife. March 16, 2021; 10
	Precisely controlled visual stimulation to study experience-dependent neural plasticity in Xenopus tadpoles., Hiramoto M., STAR Protoc. January 8, 2021; 2 (1): 100252.
	Imaging the Dynamic Branching and Synaptic Differentiation of Xenopus Optic Axons In Vivo., Santos RA., Cold Spring Harb Protoc. November 2, 2020; 2020 (11):
	Comparative gene expression profiling between optic nerve and spinal cord injury in Xenopus laevis reveals a core set of genes inherent in successful regeneration of vertebrate central nervous system axons., Belrose JL., BMC Genomics. August 5, 2020; 21 (1): 540.
	Postsynaptic and Presynaptic NMDARs Have Distinct Roles in Visual Circuit Development., Kesner P., Cell Rep. July 28, 2020; 32 (4): 107955.
	NMDARs Translate Sequential Temporal Information into Spatial Maps., Hiramoto M., iScience. June 26, 2020; 23 (6): 101130.
	Stentian structural plasticity in the developing visual system., Rahman TN., Proc Natl Acad Sci U S A. May 19, 2020; 117 (20): 10636-10638.
	Axonal precursor miRNAs hitchhike on endosomes and locally regulate the development of neural circuits., Corradi E., EMBO J. March 16, 2020; 39 (6): e102513.
	On-Site Ribosome Remodeling by Locally Synthesized Ribosomal Proteins in Axons., Shigeoka T., Cell Rep. December 10, 2019; 29 (11): 3605-3619.e10.
	Volume sensing in the transient receptor potential vanilloid 4 ion channel is cell type-specific and mediated by an N-terminal volume-sensing domain., Toft-Bertelsen TL., J Biol Chem. November 29, 2019; 294 (48): 18421-18434.
	Receptor-specific interactome as a hub for rapid cue-induced selective translation in axons., Koppers M., Elife. November 20, 2019; 8
	The Expression of Key Guidance Genes at a Forebrain Axon Turning Point Is Maintained by Distinct Fgfr Isoforms but a Common Downstream Signal Transduction Mechanism., Yang JJ., eNeuro. April 9, 2019; 6 (2):
	Noncanonical Modulation of the eIF2 Pathway Controls an Increase in Local Translation during Neural Wiring., Cagnetta R., Mol Cell. February 7, 2019; 73 (3): 474-489.e5.
	Comparisons of SOCS mRNA and protein levels in Xenopus provide insights into optic nerve regenerative success., Priscilla R., Brain Res. February 1, 2019; 1704 150-160.
	Rapid changes in tissue mechanics regulate cell behaviour in the developing embryonic brain., Thompson AJ., Elife. January 15, 2019; 8
	Late Endosomes Act as mRNA Translation Platforms and Sustain Mitochondria in Axons., Cioni JM., Cell. January 10, 2019; 176 (1-2): 56-72.e15.
	Single-molecule analysis of endogenous β-actin mRNA trafficking reveals a mechanism for compartmentalized mRNA localization in axons., Turner-Bridger B., Proc Natl Acad Sci U S A. October 9, 2018; 115 (41): E9697-E9706.
	DSCAM differentially modulates pre- and postsynaptic structural and functional central connectivity during visual system wiring., Santos RA., Neural Dev. September 15, 2018; 13 (1): 22.
	Rapid Cue-Specific Remodeling of the Nascent Axonal Proteome., Cagnetta R., Neuron. July 11, 2018; 99 (1): 29-46.e4.
	C8orf46 homolog encodes a novel protein Vexin that is required for neurogenesis in Xenopus laevis., Moore KB., Dev Biol. May 1, 2018; 437 (1): 27-40.
	Preparations and Protocols for Whole Cell Patch Clamp Recording of Xenopus laevis Tectal Neurons., Liu Z., J Vis Exp. March 15, 2018; (133):
	Axon-Axon Interactions Regulate Topographic Optic Tract Sorting via CYFIP2-Dependent WAVE Complex Function., Cioni JM., Neuron. March 7, 2018; 97 (5): 1078-1093.e6.
	Cue-Polarized Transport of β-actin mRNA Depends on 3'UTR and Microtubules in Live Growth Cones., Leung KM., Front Cell Neurosci. January 1, 2018; 12 300.
	Filopodyan: An open-source pipeline for the analysis of filopodia., Urbančič V., J Cell Biol. October 2, 2017; 216 (10): 3405-3422.
	Prdm13 forms a feedback loop with Ptf1a and is required for glycinergic amacrine cell genesis in the Xenopus Retina., Bessodes N., Neural Dev. September 1, 2017; 12 (1): 16.
	RNA Docking and Local Translation Regulate Site-Specific Axon Remodeling In Vivo., Wong HH., Neuron. August 16, 2017; 95 (4): 852-868.e8.
	Modeling Dominant and Recessive Forms of Retinitis Pigmentosa by Editing Three Rhodopsin-Encoding Genes in Xenopus Laevis Using Crispr/Cas9., Feehan JM., Sci Rep. July 31, 2017; 7 (1): 6920.

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