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TBC1D32 variants disrupt retinal ciliogenesis and cause retinitis pigmentosa. , Bocquet B., JCI Insight. November 8, 2023; 8 (21):
Metamorphic gene regulation programs in Xenopus tropicalis tadpole brain. , Raj S., PLoS One. January 1, 2023; 18 (6): e0287858.
A Focal Impact Model of Traumatic Brain Injury in Xenopus Tadpoles Reveals Behavioral Alterations, Neuroinflammation, and an Astroglial Response. , Spruiell Eldridge SL., Int J Mol Sci. July 8, 2022; 23 (14):
Temporal and spatial transcriptomic dynamics across brain development in Xenopus laevis tadpoles. , Ta AC ., G3 (Bethesda). January 4, 2022; 12 (1):
Developmental and Injury-induced Changes in DNA Methylation in Regenerative versus Non-regenerative Regions of the Vertebrate Central Nervous System. , Reverdatto S., BMC Genomics. January 4, 2022; 23 (1): 2.
Cellular response to spinal cord injury in regenerative and non-regenerative stages in Xenopus laevis. , Edwards-Faret G., Neural Dev. February 2, 2021; 16 (1): 2.
Rapid changes in tissue mechanics regulate cell behaviour in the developing embryonic brain. , Thompson AJ., Elife. January 15, 2019; 8
Development of an Acute Method to Deliver Transgenes Into the Brains of Adult Xenopus laevis. , Yamaguchi A ., Front Neural Circuits. October 26, 2018; 12 92.
Serine Threonine Kinase Receptor-Associated Protein Deficiency Impairs Mouse Embryonic Stem Cells Lineage Commitment Through CYP26A1-Mediated Retinoic Acid Homeostasis. , Jin L., Stem Cells. September 1, 2018; 36 (9): 1368-1379.
Role of the visual experience-dependent nascent proteome in neuronal plasticity. , Liu HH ., Elife. February 7, 2018; 7
Similarity in gene-regulatory networks suggests that cancer cells share characteristics of embryonic neural cells. , Zhang Z ., J Biol Chem. August 4, 2017; 292 (31): 12842-12859.
In Vivo Analysis of the Neurovascular Niche in the Developing Xenopus Brain. , Lau M., eNeuro. July 31, 2017; 4 (4):
Müller glia reactivity follows retinal injury despite the absence of the glial fibrillary acidic protein gene in Xenopus. , Martinez-De Luna RI ., Dev Biol. June 15, 2017; 426 (2): 219-235.
JAK-STAT pathway activation in response to spinal cord injury in regenerative and non-regenerative stages of Xenopus laevis. , Tapia VS ., Regeneration (Oxf). March 14, 2017; 4 (1): 21-35.
Direct reprogramming of fibroblasts into renal tubular epithelial cells by defined transcription factors. , Kaminski MM., Nat Cell Biol. December 1, 2016; 18 (12): 1269-1280.
A Retinoic Acid- Hedgehog Cascade Coordinates Mesoderm-Inducing Signals and Endoderm Competence during Lung Specification. , Rankin SA , Rankin SA ., Cell Rep. June 28, 2016; 16 (1): 66-78.
Expression of the cyp19a1 gene in the adult brain of Xenopus is neuronal and not sexually dimorphic. , Coumailleau P ., Gen Comp Endocrinol. September 15, 2015; 221 203-12.
Cyp19a1 ( aromatase) expression in the Xenopus brain at different developmental stages. , Coumailleau P ., J Neuroendocrinol. April 1, 2014; .
The neurogenic factor NeuroD1 is expressed in post-mitotic cells during juvenile and adult Xenopus neurogenesis and not in progenitor or radial glial cells. , D'Amico LA., PLoS One. June 11, 2013; 8 (6): e66487.
Tcf21 regulates the specification and maturation of proepicardial cells. , Tandon P ., Development. June 1, 2013; 140 (11): 2409-21.
In vivo time-lapse imaging of cell proliferation and differentiation in the optic tectum of Xenopus laevis tadpoles. , Bestman JE ., J Comp Neurol. February 1, 2012; 520 (2): 401-33.
pTransgenesis: a cross-species, modular transgenesis resource. , Love NR ., Development. December 1, 2011; 138 (24): 5451-8.
Proliferation, migration and differentiation in juvenile and adult Xenopus laevis brains. , D'Amico LA., Dev Biol. August 8, 2011; 1405 31-48.
Germinal sites and migrating routes of cells in the mesencephalic and diencephalic auditory areas in the African clawed frog (Xenopus laevis). , Huang YF., Dev Biol. February 10, 2011; 1373 67-78.
Expression characteristics of dual-promoter lentiviral vectors targeting retinal photoreceptors and Müller cells. , Semple-Rowland SL., Mol Vis. May 27, 2010; 16 916-34.
Regulation of radial glial motility by visual experience. , Tremblay M., J Neurosci. November 11, 2009; 29 (45): 14066-76.
Muscular dystrophy candidate gene FRG1 is critical for muscle development. , Hanel ML., Dev Dyn. June 1, 2009; 238 (6): 1502-12.
The POU homeobox protein Oct-1 regulates radial glia formation downstream of Notch signaling. , Kiyota T., Dev Biol. March 15, 2008; 315 (2): 579-92.
Ets-1 regulates radial glia formation during vertebrate embryogenesis. , Kiyota T., Organogenesis. October 1, 2007; 3 (2): 93-101.
Expression patterns of chick Musashi-1 in the developing nervous system. , Wilson JM., Gene Expr Patterns. August 1, 2007; 7 (7): 817-25.
Connexin 43 expression in glial cells of developing rhombomeres of Xenopus laevis. , Katbamna B., Int J Dev Neurosci. February 1, 2004; 22 (1): 47-55.
A novel p21-activated kinase binds the actin and microtubule networks and induces microtubule stabilization. , Cau J., J Cell Biol. December 10, 2001; 155 (6): 1029-42.
Intermediate filament proteins define different glial subpopulations. , Yoshida M., J Neurosci Res. February 1, 2001; 63 (3): 284-9.
Glial-defined boundaries in Xenopus CNS. , Yoshida M., Dev Neurosci. January 1, 2001; 23 (4-5): 299-306.
Glial-defined rhombomere boundaries in developing Xenopus hindbrain. , Yoshida M., J Comp Neurol. August 14, 2000; 424 (1): 47-57.
Xenopus laevis peripherin ( XIF3) is expressed in radial glia and proliferating neural epithelial cells as well as in neurons. , Gervasi C ., J Comp Neurol. July 31, 2000; 423 (3): 512-31.
Neural development in the marsupial frog Gastrotheca riobambae. , Del Pino EM ., Int J Dev Biol. July 1, 1998; 42 (5): 723-31.
A Xenopus DAZ-like gene encodes an RNA component of germ plasm and is a functional homologue of Drosophila boule. , Houston DW ., Development. January 1, 1998; 125 (2): 171-80.
Morphogenesis and the cytoskeleton: studies of the Xenopus embryo. , Klymkowsky MW ., Dev Biol. October 1, 1994; 165 (2): 372-84.
Cloning of multiple forms of goldfish vimentin: differential expression in CNS. , Glasgow E., J Neurochem. August 1, 1994; 63 (2): 470-81.
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.
Neuroanatomical and functional analysis of neural tube formation in notochordless Xenopus embryos; laterality of the ventral spinal cord is lost. , Clarke JD., Development. June 1, 1991; 112 (2): 499-516.
The appearance of neural and glial cell markers during early development of the nervous system in the amphibian embryo. , Messenger NJ., Development. September 1, 1989; 107 (1): 43-54.
An epithelium-type cytoskeleton in a glial cell: astrocytes of amphibian optic nerves contain cytokeratin filaments and are connected by desmosomes. , Rungger-Brändle E., J Cell Biol. August 1, 1989; 109 (2): 705-16.
Growth cone interactions with a glial cell line from embryonic Xenopus retina. , Sakaguchi DS ., Dev Biol. July 1, 1989; 134 (1): 158-74.
Cytokeratin filaments and desmosomes in the epithelioid cells of the perineurial and arachnoidal sheaths of some vertebrate species. , Achtstätter T., Differentiation. May 1, 1989; 40 (2): 129-49.
A whole-mount immunocytochemical analysis of the expression of the intermediate filament protein vimentin in Xenopus. , Dent JA., Development. January 1, 1989; 105 (1): 61-74.
Immunocytochemical identification of non-neuronal intermediate filament proteins in the developing Xenopus laevis nervous system. , Szaro BG ., Dev Biol. October 1, 1988; 471 (2): 207-24.
The appearance and distribution of intermediate filament proteins during differentiation of the central nervous system, skin and notochord of Xenopus laevis. , Godsave SF., J Embryol Exp Morphol. September 1, 1986; 97 201-23.