Golconda P , Buckley KM , Reynolds CR , Romanello JP , Smith LC .

IOS-0744999 National Science Foundation, IOS-1146124 National Science Foundation

	Figure 3. The phagocyte class of coelomocytes expresses SpTrf proteins. (A) Discoidal phagocytes have radially arranged actin cables and disc shaped cytoskeletal morphology. They show SpTrf expression rarely (83). (B) Small phagocytes are smaller than the large discoidal and polygonal phagocytes and are typically observed in filopodial morphology. A subset of small phagocytes shows high levels of SpTrf proteins [see also (23)]. (C) Polygonal phagocytes have actin cables that transverse the cell and define the polygonal shape of these cells. Subsets of polygonal phagocytes have SpTrf proteins localized to vesicles that are often positioned in a perinuclear location. (D) Medium phagocytes are defined by their intermediate size, between that of large and small phagocytes, and distinct cytoskeletal morphology of somewhat pentagonal shape with a few thin filopodia (arrow in D1). These cells show high levels of SpTrf proteins throughout the cell (D2, see also Supplementary Figure 2). Scale bar in D3 indicates 10 μm and applies to all figures.
	Figure 4. CF depletion induces proliferation of phagocytes. Sea urchins (n = 6) were injected with EdU and 5% of the estimated BV was depleted by CF aspiration. CF was collected from each animal on days 0–6, and phagocytes were processed for immunofluorescence to determine phagocyte type based on size, cytoskeletal morphology, SpTrf expression, and EdU incorporation. The resulting dataset of differential cell counts of 1,000 cells/sample/animal/day was used for the analyses that are displayed in both panels. (A) The EdU− phagocyte types show minor variations in the proportions of each cell type over time. Discoidal cells are present at higher levels than polygonal cells and both are present at higher levels than the other phagocyte types. The EdU+ phagocytes show increases in all types of phagocytes, with the most notable increases in the polygonal, medium, and small phagocytes. (B) EdU incorporation for each phagocyte type is shown as the fraction of the total number of cells of each type. Both medium and small phagocyte populations show elevated EdU incorporation.
	Figure 5. EdU+ and SpTrf+ cells are present in the axial organ, ovary, esophagus, and gut. (A) A transverse section of the axial organ shows EdU+ cells (white arrows) throughout the tissue. SpTrf+ cells (arrowheads) and EdU+SpTrf+ cells (yellow arrows) are also present. (B) A transverse section of the ovary shows EdU+ cells (arrows) and SpTrf+ cells (arrowheads) dispersed throughout the ovary. SpTrf proteins are also localized along the periphery of the oocytes (oo) as reported previously (29). (C) A longitudinal section of the esophagus shows EdU+ cells (arrows) among the columnar epithelial cells that line the lumen (L) and near the basement membrane (bm) that borders the coelomic cavity (cc). (D) A longitudinal section of the gut shows EdU+ cells (arrows) within the columnar epithelia as well as near the basement membrane (bm) that that faces the coelomic cavity (cc). SpTrf+ cells (arrowheads) are dispersed throughout the columnar epithelium, as reported previously (29). Sections are stained for DNA (DAPI, blue), actin (green), EdU (red), and SpTrf (yellow). See Supplementary Figure 3 for images of these sections prior to merging. Scale bars indicate 10 μm.
	Figure 6. Expression of genes encoding transcription factors that regulate hematopoiesis are elevated in the axial organ and the pharynx. Expression of genes encoding hematopoiesis transcription factors in tissues and coelomocytes relative to the expression of SpL8 that encodes a homolog of the large ribosomal protein L8 was based on qPCR results. Data from groups of animals from which CF was depleted (0%, 5% once or twice) were combined and compared between tissues by unpaired t-test and indicate that gene expression is highest in the pharynx with similar or somewhat lower expression in the axial organ. In some cases, gene expression in individual tissues shows significant increases in animals from which 5% CF was depleted (*) (see Supplementary Table 5). Expression of the SpTrf genes, which are markers for phagocytes, is highest in the axial organ and the pharynx. Horizontal gray lines for each gene indicate significant differences in gene expression between tissues (p < 0.05) based on unpaired t-tests (Supplementary Table 6) or a Bonferroni post-test after two-factor, non-parametric ANOVA (Supplementary Table 8). Mean expression ± standard deviation are shown in horizontal and vertical black lines for each tissue.
	Figure 7. Expression of genes encoding transcription factors that control hematopoiesis are elevated in the axial organ and coelomocytes. The RNAseq dataset for adult sea urchin tissues (72) was used to analyze gene expression. Tissues were isolated from sea urchins that were not immune challenged. The pharynx was not included in the original dataset. (A) Differential expression levels of genes encoding transcription factors that function in the hematopoiesis GRN, based on results from embryos and larvae, were selected from the RNAseq dataset. Results show that different transcription factors may function in coelomocytes (Coel) compared to the axial organ (Axial O). Expression is generally lower in ovary and testes. (B) Differential expression of all genes is indicated for each tissue, which is based on read counts per transcript matching to the genome. The different tissues tend to express different sets of genes. Elevated gene expression is indicated in (A,B) by darker blue colors and diminished expression is in lighter shades of green. (C) Gene expression for the tissues is shown relative to predicted functions based on gene ontology (see Table 1 and Data Sheet 1). Significant association with function (p ≤ 0.05) is indicated by light gray, whereas all darker blue shades indicate non-significant association.

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