Papers associated with optic tract

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	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.
	Amphibian thalamic nuclear organization during larval development and in the adult frog Xenopus laevis: Genoarchitecture and hodological analysis., Morona R., J Comp Neurol. October 1, 2020; 528 (14): 2361-2403.
	Mechanosensing is critical for axon growth in the developing brain., Koser DE., Nat Neurosci. December 1, 2016; 19 (12): 1592-1598.
	Tumor protein Tctp regulates axon development in the embryonic visual system., Roque CG., Development. April 1, 2016; 143 (7): 1134-48.
	Microtubule-associated protein tau promotes neuronal class II β-tubulin microtubule formation and axon elongation in embryonic Xenopus laevis., Liu Y., Eur J Neurosci. May 1, 2015; 41 (10): 1263-75.
	Rab5 and Rab4 regulate axon elongation in the Xenopus visual system., Falk J., J Neurosci. January 8, 2014; 34 (2): 373-91.
	RNA-binding protein Hermes/RBPMS inversely affects synapse density and axon arbor formation in retinal ganglion cells in vivo., Hörnberg H., J Neurosci. June 19, 2013; 33 (25): 10384-95.
	Coupling of NF-protocadherin signaling to axon guidance by cue-induced translation., Leung LC., Nat Neurosci. February 1, 2013; 16 (2): 166-73.
	Local translation of extranuclear lamin B promotes axon maintenance., Yoon BC., Cell. February 17, 2012; 148 (4): 752-64.
	Nitric oxide as a putative retinal axon pathfinding and target recognition cue in Xenopus laevis., Berman S., Impulse (Columbia). January 1, 2011; 2010 1-12.
	Xenopus sonic hedgehog guides retinal axons along the optic tract., Gordon L., Dev Dyn. November 1, 2010; 239 (11): 2921-32.
	E3 ligase Nedd4 promotes axon branching by downregulating PTEN., Drinjakovic J., Neuron. February 11, 2010; 65 (3): 341-57.
	Dynamic expression of axon guidance cues required for optic tract development is controlled by fibroblast growth factor signaling., Atkinson-Leadbeater K., J Neurosci. January 13, 2010; 30 (2): 685-93.
	Distinct roles for Robo2 in the regulation of axon and dendrite growth by retinal ganglion cells., Hocking JC., Mech Dev. January 1, 2010; 127 (1-2): 36-48.
	LIMK1 acts downstream of BMP signaling in developing retinal ganglion cell axons but not dendrites., Hocking JC., Dev Biol. June 15, 2009; 330 (2): 273-85.
	Cytoplasmic polyadenylation and cytoplasmic polyadenylation element-dependent mRNA regulation are involved in Xenopus retinal axon development., Lin AC., Neural Dev. March 2, 2009; 4 8.
	Bone morphogenetic proteins, eye patterning, and retinocollicular map formation in the mouse., Plas DT., J Neurosci. July 9, 2008; 28 (28): 7057-67.
	Development of the retinotectal system in the direct-developing frog Eleutherodactylus coqui in comparison with other anurans., Schlosser G., Front Zool. June 23, 2008; 5 9.
	NF-protocadherin and TAF1 regulate retinal axon initiation and elongation in vivo., Piper M., J Neurosci. January 2, 2008; 28 (1): 100-5.
	Targeting of retinal axons requires the metalloproteinase ADAM10., Chen YY., J Neurosci. August 1, 2007; 27 (31): 8448-56.
	Ena/VASP function in retinal axons is required for terminal arborization but not pathway navigation., Dwivedy A., Development. June 1, 2007; 134 (11): 2137-46.
	Electroporation-based methods for in vivo, whole mount and primary culture analysis of zebrafish brain development., Hendricks M., Neural Dev. March 15, 2007; 2 6.
	Neogenin interacts with RGMa and netrin-1 to guide axons within the embryonic vertebrate forebrain., Wilson NH., Dev Biol. August 15, 2006; 296 (2): 485-98.
	Presynaptic protein kinase C controls maturation and branch dynamics of developing retinotectal arbors: possible role in activity-driven sharpening., Schmidt JT., J Neurobiol. February 15, 2004; 58 (3): 328-40.
	Fibroblast growth factors redirect retinal axons in vitro and in vivo., Webber CA., Dev Biol. November 1, 2003; 263 (1): 24-34.
	Increased expression of multiple neurofilament mRNAs during regeneration of vertebrate central nervous system axons., Gervasi C., J Comp Neurol. June 23, 2003; 461 (2): 262-75.
	Chondroitin sulfate disrupts axon pathfinding in the optic tract and alters growth cone dynamics., Walz A., J Neurobiol. November 15, 2002; 53 (3): 330-42.
	Metalloproteases and guidance of retinal axons in the developing visual system., Webber CA., J Neurosci. September 15, 2002; 22 (18): 8091-100.
	GABA and development of the Xenopus optic projection., Ferguson SC., J Neurobiol. June 15, 2002; 51 (4): 272-84.
	Specific heparan sulfate structures involved in retinal axon targeting., Irie A., Development. January 1, 2002; 129 (1): 61-70.
	Semaphorin 3A elicits stage-dependent collapse, turning, and branching in Xenopus retinal growth cones., Campbell DS., J Neurosci. November 1, 2001; 21 (21): 8538-47.
	A role for voltage-gated potassium channels in the outgrowth of retinal axons in the developing visual system., McFarlane S., J Neurosci. February 1, 2000; 20 (3): 1020-9.
	Xefiltin, a Xenopus laevis neuronal intermediate filament protein, is expressed in actively growing optic axons during development and regeneration., Zhao Y., J Neurobiol. November 20, 1997; 33 (6): 811-24.
	Myosin functions in Xenopus retinal ganglion cell growth cone motility in vivo., Ruchhoeft ML., J Neurobiol. June 5, 1997; 32 (6): 567-78.
	Essential role of heparan sulfates in axon navigation and targeting in the developing visual system., Walz A., Development. June 1, 1997; 124 (12): 2421-30.
	Perturbation of the developing Xenopus retinotectal projection following injections of antibodies against beta1 integrin receptors and N-cadherin., Stone KE., Dev Biol. November 25, 1996; 180 (1): 297-310.
	Expression of a novel N-CAM glycoform (NOC-1) on axon tracts in embryonic Xenopus brain., Anderson RB., Dev Dyn. November 1, 1996; 207 (3): 263-9.
	The cellular patterns of BDNF and trkB expression suggest multiple roles for BDNF during Xenopus visual system development., Cohen-Cory S., Dev Biol. October 10, 1996; 179 (1): 102-15.
	Expression and herbimycin A-sensitive localization of pp125FAK in retinal growth cones., Worley TL., Neuroreport. April 26, 1996; 7 (6): 1133-7.
	Inhibition of protein tyrosine kinases impairs axon extension in the embryonic optic tract., Worley T., J Neurosci. April 1, 1996; 16 (7): 2294-306.
	FGF signaling and target recognition in the developing Xenopus visual system., McFarlane S., Neuron. November 1, 1995; 15 (5): 1017-28.
	Absence of topography in precociously innervated tecta., Chien CB., Development. August 1, 1995; 121 (8): 2621-31.
	The optic tract and tectal ablation influence the composition of neurofilaments in regenerating optic axons of Xenopus laevis., Zhao Y., J Neurosci. June 1, 1995; 15 (6): 4629-40.
	CNS myelin and oligodendrocytes of the Xenopus spinal cord--but not optic nerve--are nonpermissive for axon growth., Lang DM., J Neurosci. January 1, 1995; 15 (1 Pt 1): 99-109.
	Retinal specificity in eye fragments: investigations on the retinotectal projections of different quarter-eyes in Xenopus laevis., Brändle K., Exp Brain Res. January 1, 1994; 102 (2): 272-86.
	Identification and developmental expression of a novel low molecular weight neuronal intermediate filament protein expressed in Xenopus laevis., Charnas LR., J Neurosci. August 1, 1992; 12 (8): 3010-24.
	Development of the tectum and diencephalon in relation to the time of arrival of the earliest optic fibres in Xenopus., Gaze RM., Anat Embryol (Berl). January 1, 1992; 185 (6): 599-612.
	Distribution of galanin-like immunoreactivity in the brain of Rana esculenta and Xenopus laevis., Lázár GY., J Comp Neurol. August 1, 1991; 310 (1): 45-67.
	Cephalic expression and molecular characterization of Xenopus En-2., Hemmati-Brivanlou A., Development. March 1, 1991; 111 (3): 715-24.
	Microglia in tadpoles of Xenopus laevis: normal distribution and the response to optic nerve injury., Goodbrand IA., Anat Embryol (Berl). January 1, 1991; 184 (1): 71-82.

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