Dynamic and non-uniform expression of key transcription factors provides novel insights into the emergence of neural crest cells at the neural plate border

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Researchers investigated the dynamic and non-uniform expression of transcription factors to understand how neural crest cells emerge at the neural plate border.

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The paper investigates how transcription factor gene regulatory network components coordinate to generate neural crest cells at the neural plate border in Xenopus laevis embryos. Using high-resolution HCR-FISH, it quantifies spatiotemporal and axial (anterior-posterior and medio-lateral) dynamics of neural crest markers snai2, sox8, and foxd3, finding that their onset during late gastrulation is broad, heterogeneous, and only partially overlapping before converging into a shared neural crest domain by neurulation. Computational mapping links persistent relative differences in neural crest marker intensity to dynamic, layered expression of neural plate border factors pax3 and zic1, with functional experiments showing these factors can differentially regulate snai2 and sox8; later stages show an inverse relationship between neural crest and neural plate border gene expression consistent with a “handoff” downregulation mechanism. The paper’s limitation is that it is focused on developmental lineage specification in Xenopus embryos rather than direct modeling of human disease contexts. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

The neural crest is a vertebrate stem cell population with broad developmental potential whose emergence requires precise regulation of gene expression at the neural plate border (NPB). While a hierarchical gene regulatory network (GRN) describing signaling pathways and transcription factors underpinning the establishment of definitive neural crest cells has been generated by integrating the work of numerous groups, much remains to be learned about the relationships of distinct GRN components to each other. Here, we use high-resolution fluorescent in situ Hybridization Chain Reaction (HCR-FISH) to quantify the spatiotemporal dynamics of neural crest gene expression in Xenopus laevis embryos. We find that the onset of snai2 , sox8 , and foxd3 expression during late gastrulation is broad, heterogeneous, and partially overlapping, with distinct anterior-posterior and medio-lateral biases. By neurulation, these markers converge on a shared neural crest domain but retain relative expression differences along axial levels that persist into migratory stages, producing stream-specific gene expression patterns. Computational surface mapping revealed that these differences correlate with dynamic, layered expression of NPB factors, particularly pax3 and zic1 . Correlating relative intensities of pax3 and zic1 with the presence or absence of nascent neural crest transcripts predicts that these NPB factors can differentially regulate snai2 and sox8 , which we confirm with functional experiments. Strikingly, later stages show an inverse correlation between neural crest and NPB gene expression, suggesting a handoff mechanism in which pax3 and zic1 initially promote neural crest gene activation but are downregulated as neural crest identity emerges and contribute to combinatorial signatures of gene expression along the A-P axis. These finding provide important new insights into the genesis of a centrally important cell type.
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Abstract The neural crest is a vertebrate stem cell population with broad developmental potential whose emergence requires precise regulation of gene expression at the neural plate border (NPB). While a hierarchical gene regulatory network (GRN) describing signaling pathways and transcription factors underpinning the establishment of definitive neural crest cells has been generated by integrating the work of numerous groups, much remains to be learned about the relationships of distinct GRN components to each other. Here, we use high-resolution fluorescent in situ Hybridization Chain Reaction (HCR-FISH) to quantify the spatiotemporal dynamics of neural crest gene expression in Xenopus laevis embryos. We find that the onset of snai2, sox8, and foxd3 expression during late gastrulation is broad, heterogeneous, and partially overlapping, with distinct anterior-posterior and medio-lateral biases. By neurulation, these markers converge on a shared neural crest domain but retain relative expression differences along axial levels that persist into migratory stages, producing stream-specific gene expression patterns. Computational surface mapping revealed that these differences correlate with dynamic, layered expression of NPB factors, particularly pax3 and zic1. Correlating relative intensities of pax3 and zic1 with the presence or absence of nascent neural crest transcripts predicts that these NPB factors can differentially regulate snai2 and sox8, which we confirm with functional experiments. Strikingly, later stages show an inverse correlation between neural crest and NPB gene expression, suggesting a handoff mechanism in which pax3 and zic1 initially promote neural crest gene activation but are downregulated as neural crest identity emerges and contribute to combinatorial signatures of gene expression along the A-P axis. These finding provide important new insights into the genesis of a centrally important cell type. Competing Interest Statement The authors have declared no competing interest.

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