A dynamic, spatially periodic, micro‐pattern of HES5 underlies neurogenesis in the mouse spinal cord

Veronica Biga; Joshua Hawley; Ximena Soto; Emma Johns; Daniel Han; Hayley Bennett; Antony D Adamson; Jochen Kursawe; Paul Glendinning; Cerys S Manning; Nancy Papalopulu

doi:10.15252/msb.20209902

Molecular Systems Biology (May 2021)

A dynamic, spatially periodic, micro‐pattern of HES5 underlies neurogenesis in the mouse spinal cord

Veronica Biga,
Joshua Hawley,
Ximena Soto,
Emma Johns,
Daniel Han,
Hayley Bennett,
Antony D Adamson,
Jochen Kursawe,
Paul Glendinning,
Cerys S Manning,
Nancy Papalopulu

Affiliations

Veronica Biga: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Joshua Hawley: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Ximena Soto: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Emma Johns: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Daniel Han: Department of Mathematics School of Natural Sciences Faculty of Science and Engineering The University of Manchester Manchester UK
Hayley Bennett: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Antony D Adamson: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Jochen Kursawe: School of Mathematics and Statistics University of St Andrews St Andrews UK
Paul Glendinning: Department of Mathematics School of Natural Sciences Faculty of Science and Engineering The University of Manchester Manchester UK
Cerys S Manning: Faculty of Biology Medicine and Health The University of Manchester Manchester UK
Nancy Papalopulu: Faculty of Biology Medicine and Health The University of Manchester Manchester UK

DOI: https://doi.org/10.15252/msb.20209902
Journal volume & issue: Vol. 17, no. 5
pp. n/a – n/a

Abstract

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Abstract Ultradian oscillations of HES Transcription Factors (TFs) at the single‐cell level enable cell state transitions. However, the tissue‐level organisation of HES5 dynamics in neurogenesis is unknown. Here, we analyse the expression of HES5 ex vivo in the developing mouse ventral spinal cord and identify microclusters of 4–6 cells with positively correlated HES5 level and ultradian dynamics. These microclusters are spatially periodic along the dorsoventral axis and temporally dynamic, alternating between high and low expression with a supra‐ultradian persistence time. We show that Notch signalling is required for temporal dynamics but not the spatial periodicity of HES5. Few Neurogenin 2 cells are observed per cluster, irrespective of high or low state, suggesting that the microcluster organisation of HES5 enables the stable selection of differentiating cells. Computational modelling predicts that different cell coupling strengths underlie the HES5 spatial patterns and rate of differentiation, which is consistent with comparison between the motoneuron and interneuron progenitor domains. Our work shows a previously unrecognised spatiotemporal organisation of neurogenesis, emergent at the tissue level from the synthesis of single‐cell dynamics.

Published in Molecular Systems Biology

ISSN: 1744-4292 (Online)
Publisher: Springer Nature
Country of publisher: United Kingdom
LCC subjects: Science: Biology (General); Medicine: Medicine (General)
Website: https://www.embopress.org/journal/17444292

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