Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:We report gene expression data for FACS sorted zebrafish crestin_1kb:EGFP + cells collected at 15 somite stage (SS).

Project description:We report the distribution of H3K27Ac histone marks in a zebrafish melanoma cell line and a zebrafish primary melanoma tumor with the aim of identifying super-enhancer regions and regions of interest. We also report sox10 ChIP-Seq on the same zebrafish melanoma cell line.

Project description:We report the locations of accessible/open chromatin as assayed by ATAC-Seq on two zebrafish melanoma cell lines, zcrest 1 and zcrest 2.

Project description:We report gene expression data for human melanoma cell lines using RNAseq.

Project description:We report the distribution of H3K27Ac histone marks in multiple human melanoma cell lines with the aim of identifying super-enhancer regions and regions of interest. Also performed ChipSeq for H3K4Me1 to identify active enhancers in a representative human melanoma cell line, A375.

Project description:The “cancerized field” concept posits that cells of a given tissue share a potentially oncogenic mutation or insult and are thus cancer-prone, yet only discreet clones within the field initiate tumor formation. In melanoma, tumors frequently (~50%) carry the oncogenic BRAFV600E mutation that is also nearly always present in benign nevi that rarely become melanoma. The zebrafish crestin gene is expressed embryonically in neural crest progenitors and is then specifically re-expressed in melanoma tumors. Here, we show by live imaging transgenic zebrafish crestin reporters that single melanocytes in a cancerized field with oncogenic BRAFV600E and p53 tumor suppressor loss undergo a change that recapitulates the neural crest progenitor (NCP) state, and patches of these cells initiate early melanoma. The crestin element is regulated by the NCP transcription factor sox10. Forced sox10 overexpression in melanocytes accelerated melanoma formation, consistent with reprogramming to the NCP state and activation of super-enhancers that lead to melanoma. Our work highlights the importance of the reemergence of the NCP state as a barrier to melanoma initiation.

Project description:The “cancerized field” concept posits that cells of a given tissue share a potentially oncogenic mutation or insult and are thus cancer-prone, yet only discreet clones within the field initiate tumor formation. In melanoma, tumors frequently (~50%) carry the oncogenic BRAFV600E mutation that is also nearly always present in benign nevi that rarely become melanoma. The zebrafish crestin gene is expressed embryonically in neural crest progenitors and is then specifically re-expressed in melanoma tumors. Here, we show by live imaging transgenic zebrafish crestin reporters that single melanocytes in a cancerized field with oncogenic BRAFV600E and p53 tumor suppressor loss undergo a change that recapitulates the neural crest progenitor (NCP) state, and patches of these cells initiate early melanoma. The crestin element is regulated by the NCP transcription factor sox10. Forced sox10 overexpression in melanocytes accelerated melanoma formation, consistent with reprogramming to the NCP state and activation of super-enhancers that lead to melanoma. Our work highlights the importance of the reemergence of the NCP state as a barrier to melanoma initiation.

Project description:BackgroundAlthough the embryonic expression pattern of ADP ribosylation factor-like 6 interacting protein 1 (Arl6ip1) has been reported, its function in neural crest development is unclear.Methods/principal findingsWe found that knockdown of Arl6ip1 caused defective embryonic neural crest derivatives that were particularly severe in craniofacial cartilages. Expressions of the ectodermal patterning factors msxb, dlx3b, and pax3 were normal, but the expressions of the neural crest specifier genes foxd3, snai1b, and sox10 were greatly reduced. These findings suggest that arl6ip1 is essential for specification of neural crest derivatives, but not neural crest induction. Furthermore, we revealed that the streams of crestin- and sox10-expressing neural crest cells, which migrate ventrally from neural tube into trunk, were disrupted in arl6ip1 morphants. This migration defect was not only in the trunk neural crest, but also in the enteric tract where the vagal-derived neural crest cells failed to populate the enteric nervous system. We found that this migration defect was induced by dampened Shh signaling, which may have resulted from defective cilia. These data further suggested that arl6ip1 is required for neural crest migration. Finally, by double-staining of TUNEL and crestin, we confirmed that the loss of neural crest cells could not be attributed to apoptosis.Conclusions/significanceTherefore, we concluded that arl6ip1 is required for neural crest migration and sublineage specification.

Project description:Neural crest (NC) cells migrate throughout vertebrate embryos to give rise to a huge variety of cell types, but when and where lineages emerge and their regulation remain unclear. We have performed single-cell RNA sequencing (RNA-seq) of cranial NC cells from the first pharyngeal arch in zebrafish over several stages during migration. Computational analysis combining pseudotime and real-time data reveals that these NC cells first adopt a transitional state, becoming specified mid-migration, with the first lineage decisions being skeletal and pigment, followed by neural and glial progenitors. In addition, by computationally integrating these data with RNA-seq data from a transgenic Wnt reporter line, we identify gene cohorts with similar temporal responses to Wnts during migration and show that one, Atp6ap2, is required for melanocyte differentiation. Together, our results show that cranial NC cell lineages arise progressively and uncover a series of spatially restricted cell interactions likely to regulate such cell-fate decisions.