School of Integrative Biological & Chemical Sciences Faculty Publications

Document Type

Article

Publication Date

1-19-2026

Abstract

The ‘French flag’ model has long served as the prevailing framework for explaining how morphogen gradients generate spatial domains during embryonic development. However, recent evidence indicates that many tissues establish patterns by translating the sequential activation of genes into spatial domains. While the sequential nature of this process is becoming clear, the mechanisms that mediate these temporal dynamics and translate them into stable spatial boundaries remain debated. Using the gap gene network in the flour beetle Tribolium castaneum [which mediates the regionalization of the anterior-posterior (AP) axis into different axial fates through the regulation of downstream Hox genes] as a model, we combined hybridization chain reaction in situ hybridization, parental RNA interference (RNAi), and computational modeling to dissect these mechanisms. Our high-resolution spatiotemporal analysis indicates that gap genes initially function as a genetic cascade in the posterior growth zone. Specifically, RNAi perturbations reveal that the disruption of upstream genes prevents the initiation of downstream targets in the posterior rather than merely affecting their anterior maintenance. Conversely, the knockdown of downstream repressors leads to the posterior persistence of upstream genes. Furthermore, we investigated the relationship between this dynamic initiation phase and anterior maintenance. We observe that in milles-pattes (mlpt) RNAi embryos, the gap gene shavenbaby (svb) fails to propagate anteriorly out of the growth zone, indicating that the anterior maintenance of svb is actively mediated by other genes in the network. Computational simulations demonstrate that a gene network switching framework, where regulatory interactions reconfigure across the AP axis, successfully reproduces these complex phenotypes. These findings provide definitive spatiotemporal evidence that Tribolium gap gene initialization is driven by a genetic cascade, and support a model in which dynamic network rewiring converts this cascade into stable spatial patterns more anteriorly.

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© 2026. Published by The Company of Biologists This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution and reproduction in any medium provided that the original work is properly attributed.

Creative Commons License

Creative Commons Attribution 4.0 International License
This work is licensed under a Creative Commons Attribution 4.0 International License.

Publication Title

Biology Open

DOI

10.1242/bio.062391

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