Infrared Laser-Mediated Gene Induction at the Single-Cell Level in the Regenerating Tail of Xenopus laevis Tadpoles.

We describe a precise and reproducible gene-induction method in the amphibian, Xenopus laevis Tetrapod amphibians are excellent models for studying the mechanisms of three-dimensional organ regeneration because they have an exceptionally high regenerative ability. However, spatial and temporal manipulation of gene expression has been difficult in amphibians, hindering studies on the molecular mechanisms of organ regeneration. Recently, however, development of a Xenopus transgenic system with a heat-shock-inducible gene has enabled the manipulation of specific genes. Here, we applied an infrared laser-evoked gene operator (IR-LEGO) system to the regenerating tail of Xenopus tadpoles. In this method, a local heat shock by laser irradiation induces gene expression at the single-cell level. After amputation, Xenopus tadpoles regenerate a functional tail, including spinal cord. The regenerating tail is flat and transparent enabling the targeting of individual cells by laser irradiation. In this protocol, a single neural progenitor cell in the spinal cord of the regenerating tail is labeled with heat-shock-inducible green fluorescent protein (GFP). Gene induction at the single-cell level provides a method for rigorous cell-lineage tracing and for analyzing gene function in both cell-autonomous and noncell-autonomous contexts. The method can be modified to study the regeneration of limbs or organs in other amphibians, including Xenopus tropicalis, newts, and salamanders.

[1]  Y. Kamei,et al.  Subtypes of hypoxia‐responsive cells differentiate into neurons in spinal cord of zebrafish embryos after hypoxic stress , 2016, Biology of the cell.

[2]  Y. Kamei,et al.  Application of local gene induction by infrared laser‐mediated microscope and temperature stimulator to amphibian regeneration study , 2015, Development, growth & differentiation.

[3]  Y. Kamei,et al.  Transcriptional regulators in the Hippo signaling pathway control organ growth in Xenopus tadpole tail regeneration. , 2014, Developmental biology.

[4]  Y. Kamei,et al.  Trunk exoskeleton in teleosts is mesodermal in origin , 2013, Nature Communications.

[5]  J. Larraín,et al.  Spinal cord regeneration in Xenopus tadpoles proceeds through activation of Sox2-positive cells , 2012, Neural Development.

[6]  P. Reddien,et al.  The cellular basis for animal regeneration. , 2011, Developmental cell.

[7]  M. Itoh,et al.  The keratin-related Ouroboros proteins function as immune antigens mediating tail regression in Xenopus metamorphosis , 2009, Proceedings of the National Academy of Sciences.

[8]  T. Todo,et al.  Infrared laser‐mediated local gene induction in medaka, zebrafish and Arabidopsis thaliana , 2009, Development, growth & differentiation.

[9]  Kenjiro Watanabe,et al.  Infrared laser–mediated gene induction in targeted single cells in vivo , 2009, Nature Methods.

[10]  J. Slack,et al.  Molecular pathways needed for regeneration of spinal cord and muscle in a vertebrate. , 2003, Developmental cell.

[11]  G. Wheeler,et al.  Inducible gene expression in transgenic Xenopus embryos , 2000, Current Biology.

[12]  J. Faber,et al.  Normal Table of Xenopus Laevis (Daudin) , 1958 .