Literature DB >> 32193208

Model systems for regeneration: Xenopus.

Lauren S Phipps1, Lindsey Marshall1, Karel Dorey2, Enrique Amaya3.   

Abstract

Understanding how to promote organ and appendage regeneration is a key goal of regenerative medicine. The frog, Xenopus, can achieve both scar-free healing and tissue regeneration during its larval stages, although it predominantly loses these abilities during metamorphosis and adulthood. This transient regenerative capacity, alongside their close evolutionary relationship with humans, makes Xenopus an attractive model to uncover the mechanisms underlying functional regeneration. Here, we present an overview of Xenopus as a key model organism for regeneration research and highlight how studies of Xenopus have led to new insights into the mechanisms governing regeneration.
© 2020. Published by The Company of Biologists Ltd.

Entities:  

Keywords:  Appendage; Heart; Regeneration; Spinal cord; Tail; Xenopus

Year:  2020        PMID: 32193208     DOI: 10.1242/dev.180844

Source DB:  PubMed          Journal:  Development        ISSN: 0950-1991            Impact factor:   6.868


  9 in total

1.  Hif1α and Wnt are required for posterior gene expression during Xenopus tropicalis tail regeneration.

Authors:  Jeet H Patel; Preston A Schattinger; Evan E Takayoshi; Andrea E Wills
Journal:  Dev Biol       Date:  2022-01-20       Impact factor: 3.582

2.  TGF-β1 signaling is essential for tissue regeneration in the Xenopus tadpole tail.

Authors:  Makoto Nakamura; Hitoshi Yoshida; Yuka Moriyama; Itsuki Kawakita; Marcin Wlizla; Kimiko Takebayashi-Suzuki; Marko E Horb; Atsushi Suzuki
Journal:  Biochem Biophys Res Commun       Date:  2021-06-05       Impact factor: 3.322

3.  Tissue disaggregation and isolation of specific cell types from transgenic Xenopus appendages for transcriptional analysis by FACS.

Authors:  Anneke Dixie Kakebeen; Alexander Daniel Chitsazan; Andrea Elizabeth Wills
Journal:  Dev Dyn       Date:  2020-11-12       Impact factor: 2.842

4.  Cellular response to spinal cord injury in regenerative and non-regenerative stages in Xenopus laevis.

Authors:  Gabriela Edwards-Faret; Karina González-Pinto; Arantxa Cebrián-Silla; Johany Peñailillo; José Manuel García-Verdugo; Juan Larraín
Journal:  Neural Dev       Date:  2021-02-02       Impact factor: 3.842

5.  Complete Genome Sequences of Kinneretia sp. Strain XES5, Shinella sp. Strain XGS7, and Vogesella sp. Strain XCS3, Isolated from Xenopus laevis Skin.

Authors:  D T Hudson; P A Chapman; R C Day; X C Morgan; C W Beck
Journal:  Microbiol Resour Announc       Date:  2021-12-16

Review 6.  Mechanisms Underlying Influence of Bioelectricity in Development.

Authors:  Laura Faith George; Emily Anne Bates
Journal:  Front Cell Dev Biol       Date:  2022-02-14

Review 7.  A Model of Discovery: The Role of Imaging Established and Emerging Non-mammalian Models in Neuroscience.

Authors:  Elizabeth M Haynes; Tyler K Ulland; Kevin W Eliceiri
Journal:  Front Mol Neurosci       Date:  2022-04-14       Impact factor: 6.261

8.  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.

Authors:  Jamie L Belrose; Aparna Prasad; Morgan A Sammons; Kurt M Gibbs; Ben G Szaro
Journal:  BMC Genomics       Date:  2020-08-05       Impact factor: 3.969

9.  Xenopus laevis il11ra.L is an experimentally proven interleukin-11 receptor component that is required for tadpole tail regeneration.

Authors:  Shunya Suzuki; Kayo Sasaki; Taro Fukazawa; Takeo Kubo
Journal:  Sci Rep       Date:  2022-02-03       Impact factor: 4.379
  9 in total

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