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Literature DB >> 28102835

Spinal cord regeneration in Xenopus laevis.

Gabriela Edwards-Faret¹, Rosana Muñoz¹, Emilio E Méndez-Olivos¹, Dasfne Lee-Liu¹, Victor S Tapia¹, Juan Larraín¹.

Abstract

Here we present a protocol for the husbandry of Xenopus laevis tadpoles and froglets, and procedures to study spinal cord regeneration. This includes methods to induce spinal cord injury (SCI); DNA and morpholino electroporation for genetic studies; in vivo imaging for cell analysis; a swimming test to measure functional recovery; and a convenient model for screening for new compounds that promote neural regeneration. These protocols establish X. laevis as a unique model organism for understanding spinal cord regeneration by comparing regenerative and nonregenerative stages. This protocol can be used to understand the molecular and cellular mechanisms involved in nervous system regeneration, including neural stem and progenitor cell (NSPC) proliferation and neurogenesis, extrinsic and intrinsic mechanisms involved in axon regeneration, glial response and scar formation, and trophic factors. For experienced personnel, husbandry takes 1-2 months; SCI can be achieved in 5-15 min; and swimming recovery takes 20-30 d.

Entities: Disease Species

Mesh：

Year: 2017 PMID： 28102835 DOI： 10.1038/nprot.2016.177

Source DB: PubMed Journal: Nat Protoc ISSN： 1750-2799 Impact factor: 13.491

47 in total

1. Reorganization of the ependyma during axolotl spinal cord regeneration: changes in intermediate filament and fibronectin expression.

Authors: C M O'Hara; M W Egar; E A Chernoff
Journal: Dev Dyn Date: 1992-02 Impact factor: 3.780

Review 2. Spinal cord regeneration: lessons for mammals from non-mammalian vertebrates.

Authors: Dasfne Lee-Liu; Gabriela Edwards-Faret; Víctor S Tapia; Juan Larraín
Journal: Genesis Date: 2013-07-17 Impact factor: 2.487

3. Coordinated motor neuron axon growth and neuromuscular synaptogenesis are promoted by CPG15 in vivo.

Authors: Ashkan Javaherian; Hollis T Cline
Journal: Neuron Date: 2005-02-17 Impact factor: 17.173

Review 4. Xenopus research: metamorphosed by genetics and genomics.

Authors: Richard M Harland; Robert M Grainger
Journal: Trends Genet Date: 2011-10-01 Impact factor: 11.639

5. Regeneration of Xenopus laevis spinal cord requires Sox2/3 expressing cells.

Authors: Rosana Muñoz; Gabriela Edwards-Faret; Mauricio Moreno; Nikole Zuñiga; Hollis Cline; Juan Larraín
Journal: Dev Biol Date: 2015-03-19 Impact factor: 3.582

6. Cell lineage tracing during Xenopus tail regeneration.

Authors: Cesare Gargioli; Jonathan M W Slack
Journal: Development Date: 2004-06 Impact factor: 6.868

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Authors: T Cheriyan; D J Ryan; J H Weinreb; J Cheriyan; J C Paul; V Lafage; T Kirsch; T J Errico
Journal: Spinal Cord Date: 2014-06-10 Impact factor: 2.772

8. Motor neuron regeneration in adult zebrafish.

Authors: Michell M Reimer; Inga Sörensen; Veronika Kuscha; Rebecca E Frank; Chong Liu; Catherina G Becker; Thomas Becker
Journal: J Neurosci Date: 2008-08-20 Impact factor: 6.167

9. Complete rat spinal cord transection as a faithful model of spinal cord injury for translational cell transplantation.

Authors: Dunja Lukovic; Victoria Moreno-Manzano; Eric Lopez-Mocholi; Francisco Javier Rodriguez-Jiménez; Pavla Jendelova; Eva Sykova; Marc Oria; Miodrag Stojkovic; Slaven Erceg
Journal: Sci Rep Date: 2015-04-10 Impact factor: 4.379

10. Genome-wide expression profile of the response to spinal cord injury in Xenopus laevis reveals extensive differences between regenerative and non-regenerative stages.

Authors: Dasfne Lee-Liu; Mauricio Moreno; Leonardo I Almonacid; Víctor S Tapia; Rosana Muñoz; Javier von Marées; Marcia Gaete; Francisco Melo; Juan Larraín
Journal: Neural Dev Date: 2014-05-22 Impact factor: 3.842

11 in total

1. Melanocortin Receptor 4 Signaling Regulates Vertebrate Limb Regeneration.

Authors: Mengshi Zhang; Youwei Chen; Hanqian Xu; Li Yang; Feng Yuan; Lei Li; Ying Xu; Ying Chen; Chao Zhang; Gufa Lin
Journal: Dev Cell Date: 2018-08-20 Impact factor: 12.270

2. Spinal Cord Cells from Pre-metamorphic Stages Differentiate into Neurons and Promote Axon Growth and Regeneration after Transplantation into the Injured Spinal Cord of Non-regenerative Xenopus laevis Froglets.

Authors: Emilio E Méndez-Olivos; Rosana Muñoz; Juan Larraín
Journal: Front Cell Neurosci Date: 2017-12-13 Impact factor: 5.505

3. Temporally distinct transcriptional regulation of myocyte dedifferentiation and Myofiber growth during muscle regeneration.

Authors: Ke'ale W Louie; Alfonso Saera-Vila; Phillip E Kish; Justin A Colacino; Alon Kahana
Journal: BMC Genomics Date: 2017-11-09 Impact factor: 3.969

4. Quantitative Proteomics After Spinal Cord Injury (SCI) in a Regenerative and a Nonregenerative Stage in the Frog Xenopus laevis.

Authors: Dasfne Lee-Liu; Liangliang Sun; Norman J Dovichi; Juan Larraín
Journal: Mol Cell Proteomics Date: 2018-01-22 Impact factor: 5.911

5. JAK-STAT pathway activation in response to spinal cord injury in regenerative and non-regenerative stages of Xenopus laevis.

Authors: Victor S Tapia; Mauricio Herrera-Rojas; Juan Larrain
Journal: Regeneration (Oxf) Date: 2017-03-14