Opposite T3 Response of ACTG1–FOS Subnetwork Differentiate Tailfin Fate in Xenopus Tadpole and Post-hatching Axolotl

Amphibian post-embryonic development and Thyroid Hormones (TH) signaling are deeply and intimately connected. In anuran amphibians, TH induce the spectacular and complex process known as metamorphosis. In paedomorphic salamanders, at similar development time, raising levels of TH fail to induce proper metamorphosis, as many “larval” tissues (e.g., gills, tailfin) are maintained. Why does the same evolutionary conserved signaling pathway leads to alternative phenotypes? We used a combination of developmental endocrinology, functional genomics and network biology to compare the transcriptional response of tailfin to TH, in the post-hatching paedormorphic Axolotl salamander and Xenopus tadpoles. We also provide a technological framework that efficiently reduces large lists of regulated genes down to a few genes of interest, which is well-suited to dissect endocrine regulations. We first show that Axolotl tailfin undergoes a strong and robust TH-dependent transcriptional response at post embryonic transition, despite the lack of visible anatomical changes. We next show that Fos and Actg1, which structure a single and dense subnetwork of cellular sensors and regulators, display opposite regulation between the two species. We finally show that TH treatments and natural variations of TH levels follow similar transcriptional dynamics. We suggest that, at the molecular level, tailfin fate correlates with the alternative transcriptional states of an fos-actg1 sub-network, which also includes transcription factors and regulators of cell fate. We propose that this subnetwork is one of the molecular switches governing the initiation of distinct TH responses, with transcriptional programs conducting alternative tailfin fate (maintenance vs. resorption) 2 weeks post-hatching.

[1]  Yunbo Shi,et al.  Dual function model revised by thyroid hormone receptor alpha knockout frogs. , 2018, General and comparative endocrinology.

[2]  V. Darras,et al.  Forever young: Endocrinology of paedomorphosis in the Mexican axolotl (Ambystoma mexicanum). , 2018, General and comparative endocrinology.

[3]  K. Miyamoto,et al.  Nuclear Actin in Development and Transcriptional Reprogramming , 2017, Front. Genet..

[4]  S. Mango,et al.  Pioneer transcription factors, chromatin dynamics, and cell fate control. , 2016, Current opinion in genetics & development.

[5]  R. Denver,et al.  A Mechanism to Enhance Cellular Responsivity to Hormone Action: Krüppel-Like Factor 9 Promotes Thyroid Hormone Receptor-β Autoinduction During Postembryonic Brain Development. , 2016, Endocrinology.

[6]  P. Vilmos,et al.  Actin, actin-binding proteins, and actin-related proteins in the nucleus , 2016, Histochemistry and Cell Biology.

[7]  Aviv Regev,et al.  Comparative analysis of gene regulatory networks: from network reconstruction to evolution. , 2015, Annual review of cell and developmental biology.

[8]  E. Liu,et al.  Xenopus tropicalis Genome Re-Scaffolding and Re-Annotation Reach the Resolution Required for In Vivo ChIA-PET Analysis , 2015, PloS one.

[9]  P. Morán,et al.  Does DNA methylation regulate metamorphosis? The case of the sea lamprey (Petromyzon marinus) as an example. , 2015, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[10]  F. Chatonnet,et al.  A temporary compendium of thyroid hormone target genes in brain. , 2015, Biochimica et biophysica acta.

[11]  B. Demeneix,et al.  TR Alpha 2 Exerts Dominant Negative Effects on Hypothalamic Trh Transcription In Vivo , 2014, PLoS ONE.

[12]  Natalio Krasnogor,et al.  JEPETTO: a Cytoscape plugin for gene set enrichment and topological analysis based on interaction networks , 2013, Bioinform..

[13]  S. Brisse,et al.  AlienTrimmer: a tool to quickly and accurately trim off multiple short contaminant sequences from high-throughput sequencing reads. , 2013, Genomics.

[14]  D. Grzanka,et al.  Actin is required for cellular death. , 2013, Acta histochemica.

[15]  L. Sachs,et al.  Mechanisms of thyroid hormone receptor action during development: lessons from amphibian studies. , 2013, Biochimica et biophysica acta.

[16]  G. Brent,et al.  Mechanisms of thyroid hormone action. , 2012, The Journal of clinical investigation.

[17]  Miquel Salicru,et al.  Comparison of lists of genes based on functional profiles , 2011, BMC Bioinformatics.

[18]  Vincent Laudet,et al.  The Origins and Evolution of Vertebrate Metamorphosis , 2011, Current Biology.

[19]  N. Friedman,et al.  Trinity: reconstructing a full-length transcriptome without a genome from RNA-Seq data , 2011, Nature Biotechnology.

[20]  L. Sachs,et al.  Specific histone lysine 4 methylation patterns define TR-binding capacity and differentiate direct T3 responses. , 2011, Molecular endocrinology.

[21]  J. Ervasti,et al.  Delayed embryonic development and impaired cell growth and survival in Actg1 null mice , 2010, Cytoskeleton.

[22]  W. Huber,et al.  which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. MAnorm: a robust model for quantitative comparison of ChIP-Seq data sets , 2011 .

[23]  Ning Ma,et al.  BLAST+: architecture and applications , 2009, BMC Bioinformatics.

[24]  S. Voss,et al.  Induction of metamorphosis in axolotls (Ambystoma mexicanum). , 2009, Cold Spring Harbor protocols.

[25]  Cole Trapnell,et al.  Ultrafast and memory-efficient alignment of short DNA sequences to the human genome , 2009, Genome Biology.

[26]  V. Laudet,et al.  The history of a developmental stage: Metamorphosis in chordates , 2008, Genesis.

[27]  Hiroaki Kitano,et al.  Biological robustness , 2008, Nature Reviews Genetics.

[28]  A. Bianco,et al.  Cellular and molecular basis of deiodinase-regulated thyroid hormone signaling. , 2008, Endocrine reviews.

[29]  M. Gerstein,et al.  Getting connected: analysis and principles of biological networks. , 2007, Genes & development.

[30]  Vincent Laudet,et al.  Overview of Nomenclature of Nuclear Receptors , 2006, Pharmacological Reviews.

[31]  L. Sachs,et al.  Unliganded thyroid hormone receptor is essential for Xenopus laevis eye development , 2006, The EMBO journal.

[32]  A. Sharov,et al.  Gene expression changes at metamorphosis induced by thyroid hormone in Xenopus laevis tadpoles. , 2006, Developmental biology.

[33]  E. Davidson,et al.  Gene Regulatory Networks and the Evolution of Animal Body Plans , 2006, Science.

[34]  Claus Lindbjerg Andersen,et al.  Normalization of Real-Time Quantitative Reverse Transcription-PCR Data: A Model-Based Variance Estimation Approach to Identify Genes Suited for Normalization, Applied to Bladder and Colon Cancer Data Sets , 2004, Cancer Research.

[35]  V. Laudet,et al.  The axolotl (Ambystoma mexicanum), a neotenic amphibian, expresses functional thyroid hormone receptors. , 2004, Endocrinology.

[36]  P. Shannon,et al.  Cytoscape: a software environment for integrated models of biomolecular interaction networks. , 2003, Genome research.

[37]  V. Darras,et al.  Dynamics and regulation of intracellular thyroid hormone concentrations in embryonic chicken liver, kidney, brain, and blood. , 2003, General and comparative endocrinology.

[38]  Stephen M. Mount,et al.  Improving the Arabidopsis genome annotation using maximal transcript alignment assemblies. , 2003, Nucleic acids research.

[39]  L. Sachs,et al.  Metamorphic T3‐response genes have specific co‐regulator requirements , 2003, EMBO reports.

[40]  V. Darras,et al.  Glucocorticoids, thyroid hormones, and iodothyronine deiodinases in embryonic saltwater crocodiles. , 2002, American journal of physiology. Regulatory, integrative and comparative physiology.

[41]  Eric D. Hoopfer,et al.  Basic transcription element binding protein is a thyroid hormone‐regulated transcription factor expressed during metamorphosis in Xenopus laevis , 2002, Development, growth & differentiation.

[42]  M. Karin,et al.  AP-1 as a regulator of cell life and death , 2002, Nature Cell Biology.

[43]  B. Demeneix,et al.  Hypothyroidism prolongs mitotic activity in the post-natal mouse brain , 2000, Neuroscience Letters.

[44]  Yunbo Shi Amphibian Metamorphosis: From Morphology to Molecular Biology , 1999 .

[45]  D. D. Brown,et al.  The role of thyroid hormone in zebrafish and axolotl development. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[46]  C. Dehay,et al.  The T3Rα gene encoding a thyroid hormone receptor is essential for post‐natal development and thyroid hormone production , 1997, The EMBO journal.

[47]  A. Schönthal,et al.  Repression of c-fos gene expression by thyroid hormone and retinoic acid receptors. , 1993, The Journal of biological chemistry.

[48]  M. Pfahl,et al.  Novel pathway for thyroid hormone receptor action through interaction with jun and fos oncogene activities , 1991, Molecular and cellular biology.

[49]  J. Samarut,et al.  A novel mechanism of action for v-ErbA: Abrogation of the inactivation of transcription factor AP-1 by retinoic acid and thyroid hormone receptors , 1991, Cell.

[50]  R. Treisman,et al.  Xenopus cytoskeletal actin and human c‐fos gene promoters share a conserved protein‐binding site. , 1987, The EMBO journal.

[51]  V. Darras,et al.  Effects of TRH, bovine TSH, and pituitary extracts on thyroidal T4 release in Ambystoma mexicanum. , 1983, General and comparative endocrinology.

[52]  O. Jørgensen,et al.  Peaks of neuronal membrane antigen and thyroxine in larval development of the Mexican axolotl. , 1982, General and comparative endocrinology.

[53]  Kurt E. Johnson,et al.  Normal Table of Xenopus Laevis , 1968, The Yale Journal of Biology and Medicine.

[54]  L. Delanney,et al.  A study of induced metamorphosis in the axolotl. , 1965, The Journal of experimental zoology.

[55]  L. Sachs,et al.  De Novo Transcriptomic Approach to Study Thyroid Hormone Receptor Action in Non-mammalian Models. , 2018, Methods in molecular biology.

[56]  V. Laudet,et al.  Thyroid hormones and postembryonic development in amniotes. , 2013, Current topics in developmental biology.

[57]  A. M. Schreiber Flatfish: an asymmetric perspective on metamorphosis. , 2013, Current topics in developmental biology.

[58]  S. Voss,et al.  Salamander paedomorphosis: linking thyroid hormone to life history and life cycle evolution. , 2013, Current topics in developmental biology.

[59]  Yunbo Shi,et al.  Molecular and developmental analyses of thyroid hormone receptor function in Xenopus laevis, the African clawed frog. , 2006, General and comparative endocrinology.

[60]  Susumu Goto,et al.  KEGG: Kyoto Encyclopedia of Genes and Genomes , 2000, Nucleic Acids Res..

[61]  W. P. Hayes,et al.  Transcriptional activation of the matrix metalloproteinase gene stromelysin-3 coincides with thyroid hormone-induced cell death during frog metamorphosis. , 1995, Developmental biology.

[62]  V. Galton Thyroid hormone receptors and iodothyronine deiodinases in the developing Mexican axolotl, Ambystoma mexicanum. , 1992, General and comparative endocrinology.

[63]  Supplemental Information 2: Kyoto Encyclopedia of genes and genomes. , 2022 .