Erkenbrack EM , Thompson JR .

	Fig. 1. Gene regulatory network of the larval skeletogenic cell and spatial distribution of skeletogenic regulatory genes early in development of eleutherozoan echinoderms studied herein. a Gene regulatory network of the S. purpuratus larval skeletogenic cell type showing regulatory genes and their interactions. This study focuses on the evolution of the genes shown in the red dashed box, viz. alx1, erg, ets1, tbrain, and vegfr. The network is based on the GRN found at http://echinobase.org/endomes and various studies11,35. b Phylogeny of eleutherozoan echinoderms showing classes, typical indirect embryonic and larval developmental stages with skeletogenic cells and/or larval skeleton in blue, and typical adult forms. Aster, Asteroidea; Ophiur, Ophiuroidea; Holothur, Holothuroidea. Taxa in blue indicate presence of larval skeletogenic cells. c Spatial distribution of four transcription factors shown to be important for specification of euechinoid larval skeletogenic cells in early development of eleutherozoan echinoderms. Character states used for ancestral state reconstruction are shown at right along with examples of how states were scored. SM skeletogenic mesenchyme, NSM nonskeletogenic mesenchyme. Silhouette images in b were created individually or are in the public domain with the following exceptions: ophiuroid (credit Noah Shlottman, photo from Casey Dunn), clypeasteroid (credit Michelle Site), and camarodont echinoid (credit Frank Förster based on a picture by Jerry Kirkhart; modified by T. Michael Keesey), all of which are used under license http://creativecommons.org/licenses/by-sa/3.0/. No changes were made to the images
	Fig. 2. Ancestral state reconstruction of spatial gene expression data using a single-rate Markov model42 across eleutherozoan echinoderms. Ancestral states of alx1, ets1, and tbrain, three transcription factors critical to euechinoid larval skeletogenic cell specification. Geological timescale shown at bottom. Nodes are represented by boxed numbers. For each extant character state, the probability that it occurs at the ancestral node was estimated. The pie charts at each node show the mean posterior probability for each spatial expression pattern of the genes shown at right. The colors represent the character states shown in Fig. 1c. Abbreviations in the geological timescale are as follows: Ordovi Ordovician, Silur Silurian, Carbonifer Carboniferous, Paleog Paleogene, Ne Neogene
	Fig. 3. Ancestral state reconstruction of spatial gene expression data for erg and vegfr using a single-rate Markov model42 across eleutherozoan echinoderms. a Ancestral state reconstruction of spatial expression patterns of the transcription factor erg. b Ancestral state reconstruction of spatial expression patterns of the signaling gene vegfr. Geological timescale shown at bottom. Nodes are represented by boxed numbers. For each extant character state, the probability that it occurs at the ancestral node was estimated. The pie charts at each node show the mean posterior probability for each spatial expression pattern of the genes shown at right. The colors represent the character states shown in Fig. 1c. Abbreviations in the geological timescale are as follows: Ordovi Ordovician, Silur Silurian, Carbonifer Carboniferous, Paleog Paleogene, Ne Neogene
	Fig. 4. Cell-type evolution of echinoderm larval skeletogenic cells. a A cell-type duplication event resulted in activation of the adult skeletogenic cell-type identity network in early development, and thus the presence of skeletogenic cells in ancestral embryonic mesodermal territories (Node 1). Alx1 and vegfr are components of a cell-type specific identity network of larval skeletogenic cells across all extant eleutherozoans. The combination of alx1, erg, ets1, and vegfr comprise the cell-type identity network of skeletogenic cells across this clade. After the duplication event, at least one transcription factor that was ancestrally expressed in embryonic mesoderm domains, tbrain, was subsequently integrated into the larval skeletogenic GRN (Node 2), giving rise to two sister cell types. The larval skeletogenic cell type was lost in asteroids after the divergence with ophiuroids (Node 3). In the lineage leading to extant camarodont euechinoids, tbrain was decoupled from and no longer participated in specification of non-skeletogenic mesodermal cell types through Erg-mediated repression. Different colors represent cell-type lineages. Adult skeletogenic cells, purple. Larval skeletogenic cells, red. b Two competing hypotheses for the origin of larval skeletogenic cells in eleutherozoan echinoderms. The common ancestry hypothesis suggests that all larval skeletogenic cells in eleutherozoans are the result of a cell-type duplication event in the stem lineage of eleutherozoans. These cells would be lost in the lineage leading to extant asteroids. The convergent evolution hypothesis posits that larval skeletogenic cells are the result of at least two evolutionary events, one in the stem lineage of echinozoans and one other in the stem lineage of ophiuroids. Our results support the common ancestry hypothesis

Adomako-Ankomah, Growth factors and early mesoderm morphogenesis: insights from the sea urchin embryo. 2014, Pubmed, Echinobase

Adomako-Ankomah, Growth factors and early mesoderm morphogenesis: insights from the sea urchin embryo. 2014, Pubmed , Echinobase
Arendt, The origin and evolution of cell types. 2016, Pubmed
Arendt, The evolution of cell types in animals: emerging principles from molecular studies. 2008, Pubmed
Bottjer, Paleogenomics of echinoderms. 2006, Pubmed , Echinobase
Bouckaert, BEAST 2: a software platform for Bayesian evolutionary analysis. 2014, Pubmed
Cary, Genome-wide use of high- and low-affinity Tbrain transcription factor binding sites during echinoderm development. 2017, Pubmed , Echinobase
Cheatle Jarvela, Modular evolution of DNA-binding preference of a Tbrain transcription factor provides a mechanism for modifying gene regulatory networks. 2014, Pubmed , Echinobase
Croce, ske-T, a T-box gene expressed in the skeletogenic mesenchyme lineage of the sea urchin embryo. 2001, Pubmed , Echinobase
Czarkwiani, Expression of skeletogenic genes during arm regeneration in the brittle star Amphiura filiformis. 2013, Pubmed , Echinobase
Davidson, A genomic regulatory network for development. 2002, Pubmed , Echinobase
Drummond, Relaxed phylogenetics and dating with confidence. 2006, Pubmed
Duloquin, Localized VEGF signaling from ectoderm to mesenchyme cells controls morphogenesis of the sea urchin embryo skeleton. 2007, Pubmed , Echinobase
Dunn, Pairwise comparisons across species are problematic when analyzing functional genomic data. 2018, Pubmed
Dylus, Large-scale gene expression study in the ophiuroid Amphiura filiformis provides insights into evolution of gene regulatory networks. 2016, Pubmed , Echinobase
Dylus, Developmental transcriptomics of the brittle star Amphiura filiformis reveals gene regulatory network rewiring in echinoderm larval skeleton evolution. 2018, Pubmed , Echinobase
Emlet, Larval spicules, cilia, and symmetry as remnants of indirect development in the direct developing sea urchin Heliocidaris erythrogramma. 1995, Pubmed , Echinobase
Erkenbrack, The mammalian decidual cell evolved from a cellular stress response. 2018, Pubmed
Erkenbrack, Evolutionary rewiring of gene regulatory network linkages at divergence of the echinoid subclasses. 2015, Pubmed , Echinobase
Erkenbrack, Ancestral state reconstruction by comparative analysis of a GRN kernel operating in echinoderms. 2016, Pubmed , Echinobase
Erkenbrack, A Conserved Role for VEGF Signaling in Specification of Homologous Mesenchymal Cell Types Positioned at Spatially Distinct Developmental Addresses in Early Development of Sea Urchins. 2017, Pubmed , Echinobase
Erkenbrack, Conserved regulatory state expression controlled by divergent developmental gene regulatory networks in echinoids. 2018, Pubmed , Echinobase
Ettensohn, Alx1, a member of the Cart1/Alx3/Alx4 subfamily of Paired-class homeodomain proteins, is an essential component of the gene network controlling skeletogenic fate specification in the sea urchin embryo. 2003, Pubmed , Echinobase
Felsenstein, DISTANCE METHODS FOR INFERRING PHYLOGENIES: A JUSTIFICATION. 1984, Pubmed
Fuchikami, T-brain homologue (HpTb) is involved in the archenteron induction signals of micromere descendant cells in the sea urchin embryo. 2002, Pubmed , Echinobase
Gao, Transfer of a large gene regulatory apparatus to a new developmental address in echinoid evolution. 2008, Pubmed , Echinobase
Gao, Juvenile skeletogenesis in anciently diverged sea urchin clades. 2015, Pubmed , Echinobase
Heinz, The selection and function of cell type-specific enhancers. 2015, Pubmed
Hinman, Developmental gene regulatory network evolution: insights from comparative studies in echinoderms. 2014, Pubmed , Echinobase
Hinman, Caught in the evolutionary act: precise cis-regulatory basis of difference in the organization of gene networks of sea stars and sea urchins. 2007, Pubmed , Echinobase
Hinman, Evolutionary plasticity of developmental gene regulatory network architecture. 2007, Pubmed , Echinobase
Hinman, Developmental gene regulatory network architecture across 500 million years of echinoderm evolution. 2003, Pubmed , Echinobase
Khor, Functional divergence of paralogous transcription factors supported the evolution of biomineralization in echinoderms. 2017, Pubmed , Echinobase
Kin, Cell-type phylogenetics and the origin of endometrial stromal cells. 2015, Pubmed
Knapp, Recombinant sea urchin vascular endothelial growth factor directs single-crystal growth and branching in vitro. 2012, Pubmed , Echinobase
Koga, Functional evolution of Ets in echinoderms with focus on the evolution of echinoderm larval skeletons. 2010, Pubmed , Echinobase
Koga, Experimental Approach Reveals the Role of alx1 in the Evolution of the Echinoderm Larval Skeleton. 2016, Pubmed , Echinobase
Kurokawa, HpEts, an ets-related transcription factor implicated in primary mesenchyme cell differentiation in the sea urchin embryo. 1999, Pubmed , Echinobase
Larkin, Clustal W and Clustal X version 2.0. 2007, Pubmed
Maruyama, A Sea Cucumber Homolog of the Mouse T-Brain-1 is Expressed in the Invaginated Cells of the Early Gastrula in Holothuria leucospilota. 2000, Pubmed , Echinobase
Materna, Diversification of oral and aboral mesodermal regulatory states in pregastrular sea urchin embryos. 2013, Pubmed , Echinobase
McCauley, Development of an embryonic skeletogenic mesenchyme lineage in a sea cucumber reveals the trajectory of change for the evolution of novel structures in echinoderms. 2012, Pubmed , Echinobase
McCauley, A conserved gene regulatory network subcircuit drives different developmental fates in the vegetal pole of highly divergent echinoderm embryos. 2010, Pubmed , Echinobase
Miller, Molecular phylogeny of extant Holothuroidea (Echinodermata). 2017, Pubmed , Echinobase
Minemura, Evolutionary modification of T-brain (tbr) expression patterns in sand dollar. 2009, Pubmed , Echinobase
Minokawa, Comparative studies on the skeletogenic mesenchyme of echinoids. 2017, Pubmed , Echinobase
Morino, The conserved genetic background for pluteus arm development in brittle stars and sea urchin. 2016, Pubmed , Echinobase
Morino, Heterochronic activation of VEGF signaling and the evolution of the skeleton in echinoderm pluteus larvae. 2012, Pubmed , Echinobase
Ochiai, Analysis of cis-regulatory elements controlling spatio-temporal expression of T-brain gene in sea urchin, Hemicentrotus pulcherrimus. 2008, Pubmed , Echinobase
Oliveri, A regulatory gene network that directs micromere specification in the sea urchin embryo. 2002, Pubmed , Echinobase
Oliveri, Global regulatory logic for specification of an embryonic cell lineage. 2008, Pubmed , Echinobase
Pagel, Inferring the historical patterns of biological evolution. 1999, Pubmed
Pagel, Bayesian estimation of ancestral character states on phylogenies. 2004, Pubmed
Pennington, Consequences of the Calcite Skeletons of Planktonic Echinoderm Larvae for Orientation, Swimming, and Shape. 1990, Pubmed
Rannala, Inferring speciation times under an episodic molecular clock. 2007, Pubmed
Revell, A new phylogenetic method for identifying exceptional phenotypic diversification. 2012, Pubmed
Revilla-i-Domingo, A missing link in the sea urchin embryo gene regulatory network: hesC and the double-negative specification of micromeres. 2007, Pubmed , Echinobase
Rizzo, Identification and developmental expression of the ets gene family in the sea urchin (Strongylocentrotus purpuratus). 2006, Pubmed , Echinobase
Röttinger, A Raf/MEK/ERK signaling pathway is required for development of the sea urchin embryo micromere lineage through phosphorylation of the transcription factor Ets. 2004, Pubmed , Echinobase
Röttinger, FGF signals guide migration of mesenchymal cells, control skeletal morphogenesis [corrected] and regulate gastrulation during sea urchin development. 2008, Pubmed , Echinobase
Saunders, Sub-circuits of a gene regulatory network control a developmental epithelial-mesenchymal transition. 2014, Pubmed , Echinobase
Schluter, LIKELIHOOD OF ANCESTOR STATES IN ADAPTIVE RADIATION. 1997, Pubmed
Selvakumaraswamy, Vestigial ophiopluteal structures in the lecithotrophic larvae of Ophionereis schayeri (Ophiuroidea). 2000, Pubmed , Echinobase
Sharma, Regulative deployment of the skeletogenic gene regulatory network during sea urchin development. 2011, Pubmed , Echinobase
Shashikant, From genome to anatomy: The architecture and evolution of the skeletogenic gene regulatory network of sea urchins and other echinoderms. 2018, Pubmed , Echinobase
Shoguchi, A starfish homolog of mouse T-brain-1 is expressed in the archenteron of Asterina pectinifera embryos: possible involvement of two T-box genes in starfish gastrulation. 2000, Pubmed , Echinobase
Smith, Testing the molecular clock: molecular and paleontological estimates of divergence times in the Echinoidea (Echinodermata). 2006, Pubmed , Echinobase
Tagawa, T-Brain expression in the apical organ of hemichordate tornaria larvae suggests its evolutionary link to the vertebrate forebrain. 2000, Pubmed
Telford, Phylogenomic analysis of echinoderm class relationships supports Asterozoa. 2014, Pubmed , Echinobase
Thompson, Paleogenomics of echinoids reveals an ancient origin for the double-negative specification of micromeres in sea urchins. 2017, Pubmed , Echinobase
Thompson, Reorganization of sea urchin gene regulatory networks at least 268 million years ago as revealed by oldest fossil cidaroid echinoid. 2015, Pubmed , Echinobase
Vaughn, Sequencing and analysis of the gastrula transcriptome of the brittle star Ophiocoma wendtii. 2012, Pubmed , Echinobase
Wagner, Stress-Induced Evolutionary Innovation: A Mechanism for the Origin of Cell Types. 2019, Pubmed
Wahl, The cis-regulatory system of the tbrain gene: Alternative use of multiple modules to promote skeletogenic expression in the sea urchin embryo. 2009, Pubmed , Echinobase
Wilt, Development of calcareous skeletal elements in invertebrates. 2003, Pubmed
Wray, The origin of spicule-forming cells in a 'primitive' sea urchin (Eucidaris tribuloides) which appears to lack primary mesenchyme cells. 1988, Pubmed , Echinobase
Xie, Improving marginal likelihood estimation for Bayesian phylogenetic model selection. 2011, Pubmed
Yamazaki, Larval mesenchyme cell specification in the primitive echinoid occurs independently of the double-negative gate. 2014, Pubmed , Echinobase
Yamazaki, Expession patterns of mesenchyme specification genes in two distantly related echinoids, Glyptocidaris crenularis and Echinocardium cordatum. 2015, Pubmed , Echinobase
Yamazaki, Conserved early expression patterns of micromere specification genes in two echinoid species belonging to the orders clypeasteroida and echinoida. 2010, Pubmed , Echinobase