Briggs JA , Weinreb C , Wagner DE , Megason S , Peshkin L , Kirschner MW , Klein AM .

R01 HD073104 NICHD NIH HHS , R21 HD087723 NICHD NIH HHS , R33 CA212697 NCI NIH HHS , Wellcome Trust , T32 GM080177 NIGMS NIH HHS , K99 GM121852 NIGMS NIH HHS

	Fig. 1 Dissection of early Xenopus tropicalis development by scRNA-seq. (A) Single-cell transcriptomes represent points in a high-dimensional gene expression space. By collecting single-cell transcriptomes over time of embryo development, it is possible to infer a continuum gene expression manifold connecting cell states across all lineages. (B) Summary of scRNA-seq developmental timecourse including 136,966 single-cell transcriptomes sampled over ten embryonic stages (S8-22). tSNE plots show increasing cell population structure over time. Colors indicate major tissues grouped by germ layer.
	Fig. 4 Similarities and differences in developmental cell state hierarchies and gene expression between frog and fish. (A) Xenopus and Zebrafish cell state trees aligned by orthologous cell states (red shading). Gray/white stripes provide a visual guide. (B) Single-cell visualization of matched epidermal subtrees in frog and fish showcase similarities and differences in developmental hierarchy. SCC, small secretory cell; NE, neuroendocrine cell. Unidentified zebrafish cell types are labeled by marker genes. (C) Ortholog genes across species have variable conservation of cell state specific expression. Just 30% of self-similar orthologs are conserved at a 95% FDR compared to random gene pairs. Right panels: examples of highly (Sox2) and poorly (Gata5) correlated TFs across species. (D and E) Function, not sequence, predicts gene expression conservation: (D) Orthologs with highly conserved expression patterns across species are enriched in TF-associated GO terms. P-values show Bonferroni-corrected binomial test results. (E) Protein sequence conservation is not correlated with gene expression conservation (r = 0.01; P = 0.6).
	Fig. 7 Assessing the retention of pluripotency during neural crest development. (A) Contrasting models of neural crest development. Model 1: neural crest emerges from an intermediate population that retains blastula pluripotency (29). Model 2: neural crest emerges from ectoderm and reactivates pluripotency. (B) Ancestors inferred from scRNA-seq support model 2, where neural crest derives from neural cells at the neural plate border. (C) Single-cell visualization (SPRING) of neuroectoderm, non-neural ectoderm, and neural crest also indicates that neural crest derives from the neural plate border. (D) Neural crest differentiation involves hundreds of >3-fold dynamic marker genes. (E) At stage 11, the shared pluripotency circuit proposed by Buitrago-Delgado et al. (30) - foxd3, c-myc (myca), id3, tfap2a, ventx2.1, ets1, and snai1 and pou3f5.2 - is expressed broadly in nonpluripotent cells. Score shows normalized aggregate expression; see fig. S18 for individual genes.

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