Segment-Specific Adhesion as a Driver of Convergent Extension

Publication date

2015

Authors

Vroomans, Renske M. A.ISNI 0000000395136543
Hogeweg, PISNI 0000000392149074
Ten Tusscher, KirstenISNI 0000000396729287

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Document Type

Article
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Abstract

Convergent extension, the simultaneous extension and narrowing of tissues, is a crucial event in the formation of the main body axis during embryonic development. It involves processes on multiple scales: the sub-cellular, cellular and tissue level, which interact via explicit or intrinsic feedback mechanisms. Computational modelling studies play an important role in unravelling the multiscale feedbacks underlying convergent extension. Convergent extension usually operates in tissue which has been patterned or is currently being patterned into distinct domains of gene expression. How such tissue patterns are maintained during the large scale tissue movements of convergent extension has thus far not been investigated. Intriguingly, experimental data indicate that in certain cases these tissue patterns may drive convergent extension rather than requiring safeguarding against convergent extension. Here we use a 2D Cellular Potts Model (CPM) of a tissue prepatterned into segments, to show that convergent extension tends to disrupt this pre-existing segmental pattern. However, when cells preferentially adhere to cells of the same segment type, segment integrity is maintained without any reduction in tissue extension. Strikingly, we demonstrate that this segment-specific adhesion is by itself sufficient to drive convergent extension. Convergent extension is enhanced when we endow our in silico cells with persistence of motion, which in vivo would naturally follow from cytoskeletal dynamics. Finally, we extend our model to confirm the generality of our results. We demonstrate a similar effect of differential adhesion on convergent extension in tissues that can only extend in a single direction (as often occurs due to the inertia of the head region of the embryo), and in tissues prepatterned into a sequence of domains resulting in two opposing adhesive gradients, rather than alternating segments.

Keywords

Computational Theory and Mathematics, Modelling and Simulation, Ecology, Evolution, Behavior and Systematics, Genetics, Molecular Biology, Ecology, Cellular and Molecular Neuroscience

Citation

Vroomans, R M A, Hogeweg, P & ten Tusscher, K H W J 2015, 'Segment-Specific Adhesion as a Driver of Convergent Extension', PLoS Computational Biology, vol. 11, no. 2, e1004092. https://doi.org/10.1371/journal.pcbi.1004092