Laura I. Arbanas, Emanuel Cura Costa, Osvaldo Chara, Leo Otsuki, Elly M. Tanaka
{"title":"再生腋龙脊髓中Shh+底板细胞的系谱追踪和背腹基因表达的动态变化。","authors":"Laura I. Arbanas, Emanuel Cura Costa, Osvaldo Chara, Leo Otsuki, Elly M. Tanaka","doi":"10.1111/dgd.12945","DOIUrl":null,"url":null,"abstract":"<p>Both development and regeneration depend on signaling centers, which are sources of locally secreted tissue-patterning molecules. As many signaling centers are decommissioned before the end of embryogenesis, a fundamental question is how signaling centers can be re-induced later in life to promote regeneration after injury. Here, we use the axolotl salamander model (<i>Ambystoma mexicanum</i>) to address how the floor plate is assembled for spinal cord regeneration. The floor plate is an archetypal vertebrate signaling center that secretes <i>Shh</i> ligand and patterns neural progenitor cells during embryogenesis. Unlike mammals, axolotls continue to express floor plate genes (including <i>Shh</i>) and downstream dorsal–ventral patterning genes in their spinal cord throughout life, including at steady state. The parsimonious hypothesis that <i>Shh+</i> cells give rise to functional floor plate cells for regeneration had not been tested. Using HCR in situ hybridization and mathematical modeling, we first quantified the behaviors of dorsal–ventral spinal cord domains, identifying significant increases in gene expression level and floor plate size during regeneration. Next, we established a transgenic axolotl to specifically label and fate map <i>Shh+</i> cells in vivo. We found that labeled <i>Shh+</i> cells gave rise to regeneration floor plate, and not to other neural progenitor domains, after tail amputation. Thus, despite changes in domain size and downstream patterning gene expression, <i>Shh+</i> cells retain their floor plate identity during regeneration, acting as a stable cellular source for this regeneration signaling center in the axolotl spinal cord.</p>","PeriodicalId":50589,"journal":{"name":"Development Growth & Differentiation","volume":"66 8","pages":"414-425"},"PeriodicalIF":1.7000,"publicationDate":"2024-10-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/dgd.12945","citationCount":"0","resultStr":"{\"title\":\"Lineage tracing of Shh+ floor plate cells and dynamics of dorsal–ventral gene expression in the regenerating axolotl spinal cord\",\"authors\":\"Laura I. Arbanas, Emanuel Cura Costa, Osvaldo Chara, Leo Otsuki, Elly M. Tanaka\",\"doi\":\"10.1111/dgd.12945\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Both development and regeneration depend on signaling centers, which are sources of locally secreted tissue-patterning molecules. As many signaling centers are decommissioned before the end of embryogenesis, a fundamental question is how signaling centers can be re-induced later in life to promote regeneration after injury. Here, we use the axolotl salamander model (<i>Ambystoma mexicanum</i>) to address how the floor plate is assembled for spinal cord regeneration. The floor plate is an archetypal vertebrate signaling center that secretes <i>Shh</i> ligand and patterns neural progenitor cells during embryogenesis. Unlike mammals, axolotls continue to express floor plate genes (including <i>Shh</i>) and downstream dorsal–ventral patterning genes in their spinal cord throughout life, including at steady state. The parsimonious hypothesis that <i>Shh+</i> cells give rise to functional floor plate cells for regeneration had not been tested. Using HCR in situ hybridization and mathematical modeling, we first quantified the behaviors of dorsal–ventral spinal cord domains, identifying significant increases in gene expression level and floor plate size during regeneration. Next, we established a transgenic axolotl to specifically label and fate map <i>Shh+</i> cells in vivo. We found that labeled <i>Shh+</i> cells gave rise to regeneration floor plate, and not to other neural progenitor domains, after tail amputation. 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Lineage tracing of Shh+ floor plate cells and dynamics of dorsal–ventral gene expression in the regenerating axolotl spinal cord
Both development and regeneration depend on signaling centers, which are sources of locally secreted tissue-patterning molecules. As many signaling centers are decommissioned before the end of embryogenesis, a fundamental question is how signaling centers can be re-induced later in life to promote regeneration after injury. Here, we use the axolotl salamander model (Ambystoma mexicanum) to address how the floor plate is assembled for spinal cord regeneration. The floor plate is an archetypal vertebrate signaling center that secretes Shh ligand and patterns neural progenitor cells during embryogenesis. Unlike mammals, axolotls continue to express floor plate genes (including Shh) and downstream dorsal–ventral patterning genes in their spinal cord throughout life, including at steady state. The parsimonious hypothesis that Shh+ cells give rise to functional floor plate cells for regeneration had not been tested. Using HCR in situ hybridization and mathematical modeling, we first quantified the behaviors of dorsal–ventral spinal cord domains, identifying significant increases in gene expression level and floor plate size during regeneration. Next, we established a transgenic axolotl to specifically label and fate map Shh+ cells in vivo. We found that labeled Shh+ cells gave rise to regeneration floor plate, and not to other neural progenitor domains, after tail amputation. Thus, despite changes in domain size and downstream patterning gene expression, Shh+ cells retain their floor plate identity during regeneration, acting as a stable cellular source for this regeneration signaling center in the axolotl spinal cord.
期刊介绍:
Development Growth & Differentiation (DGD) publishes three types of articles: original, resource, and review papers.
Original papers are on any subjects having a context in development, growth, and differentiation processes in animals, plants, and microorganisms, dealing with molecular, genetic, cellular and organismal phenomena including metamorphosis and regeneration, while using experimental, theoretical, and bioinformatic approaches. Papers on other related fields are also welcome, such as stem cell biology, genomics, neuroscience, Evodevo, Ecodevo, and medical science as well as related methodology (new or revised techniques) and bioresources.
Resource papers describe a dataset, such as whole genome sequences and expressed sequence tags (ESTs), with some biological insights, which should be valuable for studying the subjects as mentioned above.
Submission of review papers is also encouraged, especially those providing a new scope based on the authors’ own study, or a summarization of their study series.