Hydra morphogenesis as phase transition dynamics

Oded Agam; Erez Braun

doi:10.1209/0295-5075/ace4f0

Hydra morphogenesis as phase transition dynamics

Oded Agam, Erez Braun

The Hebrew University of Jerusalem, Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

We utilize whole-body Hydra regeneration from a small tissue segment to develop a physics framework for animal morphogenesis. Introducing experimental controls over this process, an external electric field and a drug that blocks gap junctions, allows us to characterize the essential step in the morphological transition —from a spherical shape to an elongated spheroid. We find that spatial fluctuations of the Ca²⁺ distribution in the Hydra's tissue drive this transition and construct a field-theoretic model that explains the morphological transition as a first-order-like phase transition resulting from the coupling of the Ca²⁺ field and the tissue's local curvature. Various predictions of this model are verified experimentally.

Original language	English
Article number	27001
Journal	Lettere Al Nuovo Cimento
Volume	143
Issue number	2
DOIs	https://doi.org/10.1209/0295-5075/ace4f0
State	Published - Jul 2023

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1209/0295-5075/ace4f0

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abstract = "We utilize whole-body Hydra regeneration from a small tissue segment to develop a physics framework for animal morphogenesis. Introducing experimental controls over this process, an external electric field and a drug that blocks gap junctions, allows us to characterize the essential step in the morphological transition —from a spherical shape to an elongated spheroid. We find that spatial fluctuations of the Ca2+ distribution in the Hydra's tissue drive this transition and construct a field-theoretic model that explains the morphological transition as a first-order-like phase transition resulting from the coupling of the Ca2+ field and the tissue's local curvature. Various predictions of this model are verified experimentally.",

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AB - We utilize whole-body Hydra regeneration from a small tissue segment to develop a physics framework for animal morphogenesis. Introducing experimental controls over this process, an external electric field and a drug that blocks gap junctions, allows us to characterize the essential step in the morphological transition —from a spherical shape to an elongated spheroid. We find that spatial fluctuations of the Ca2+ distribution in the Hydra's tissue drive this transition and construct a field-theoretic model that explains the morphological transition as a first-order-like phase transition resulting from the coupling of the Ca2+ field and the tissue's local curvature. Various predictions of this model are verified experimentally.

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Hydra morphogenesis as phase transition dynamics

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