Tissue-like multicellular development triggere by mechanical compression in archaea

Theopi Rados; Olivia S. Leland; Pedro Escudeiro; John Mallon; Katherine Andre; Ido Caspy; Andriko von Kügelgen; Elad Stolovicki; Sinead Nguyen; Inés Lucía Patop; L. Thiberio Rangel; Sebastian Kadener; Lars D. Renner; Vera Thiel; Yoav Soen; Tanmay A.M. Bharat; Vikram Alva; Alex Bisson

doi:10.1126/science.adu0047

Tissue-like multicellular development triggere by mechanical compression in archaea

Theopi Rados, Olivia S. Leland, Pedro Escudeiro, John Mallon, Katherine Andre, Ido Caspy, Andriko von Kügelgen, Elad Stolovicki, Sinead Nguyen, Inés Lucía Patop, L. Thiberio Rangel, Sebastian Kadener, Lars D. Renner, Vera Thiel, Yoav Soen, Tanmay A.M. Bharat, Vikram Alva, Alex Bisson

Department of Biomolecular Sciences

Weizmann Institute of Science

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

Abstract

The advent of clonal multicellularity is a critical evolutionary milestone, seen often in eukaryotes, rarely in bacteria, and only once in archaea. We show that uniaxial compression induces clonal multicellularity in haloarchaea, forming tissue-like structures. These archaeal tissues are mechanically and molecularly distinct from their unicellular lifestyle, mimicking several eukaryotic features. Archaeal tissues undergo a multinucleate stage followed by tubulin-independent cellularization, orchestrated by active membrane tension at a critical cell size. After cellularization, tissue junction elasticity becomes akin to that of animal tissues, giving rise to two cell types—peripheral (Per) and central scutoid (Scu) cells—with distinct actin and protein glycosylation polarity patterns. Our findings highlight the potential convergent evolution of a biophysical mechanism in the emergence of multicellular systems across domains of life.

Original language	English
Pages (from-to)	109-115
Number of pages	7
Journal	Science
Volume	388
Issue number	6742
DOIs	https://doi.org/10.1126/science.adu0047
State	Published - 4 Apr 2025

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Rados, T., Leland, O. S., Escudeiro, P., Mallon, J., Andre, K., Caspy, I., von Kügelgen, A., Stolovicki, E., Nguyen, S., Patop, I. L., Thiberio Rangel, L., Kadener, S., Renner, L. D., Thiel, V., Soen, Y., Bharat, T. A. M., Alva, V., & Bisson, A. (2025). Tissue-like multicellular development triggere by mechanical compression in archaea. Science, 388(6742), 109-115. https://doi.org/10.1126/science.adu0047

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title = "Tissue-like multicellular development triggere by mechanical compression in archaea",

abstract = "The advent of clonal multicellularity is a critical evolutionary milestone, seen often in eukaryotes, rarely in bacteria, and only once in archaea. We show that uniaxial compression induces clonal multicellularity in haloarchaea, forming tissue-like structures. These archaeal tissues are mechanically and molecularly distinct from their unicellular lifestyle, mimicking several eukaryotic features. Archaeal tissues undergo a multinucleate stage followed by tubulin-independent cellularization, orchestrated by active membrane tension at a critical cell size. After cellularization, tissue junction elasticity becomes akin to that of animal tissues, giving rise to two cell types—peripheral (Per) and central scutoid (Scu) cells—with distinct actin and protein glycosylation polarity patterns. Our findings highlight the potential convergent evolution of a biophysical mechanism in the emergence of multicellular systems across domains of life.",

author = "Theopi Rados and Leland, \{Olivia S.\} and Pedro Escudeiro and John Mallon and Katherine Andre and Ido Caspy and \{von K{\"u}gelgen\}, Andriko and Elad Stolovicki and Sinead Nguyen and Patop, \{In{\'e}s Luc{\'i}a\} and \{Thiberio Rangel\}, L. and Sebastian Kadener and Renner, \{Lars D.\} and Vera Thiel and Yoav Soen and Bharat, \{Tanmay A.M.\} and Vikram Alva and Alex Bisson",

year = "2025",

month = apr,

day = "4",

doi = "10.1126/science.adu0047",

language = "الإنجليزيّة",

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Rados, T, Leland, OS, Escudeiro, P, Mallon, J, Andre, K, Caspy, I, von Kügelgen, A, Stolovicki, E, Nguyen, S, Patop, IL, Thiberio Rangel, L, Kadener, S, Renner, LD, Thiel, V, Soen, Y, Bharat, TAM, Alva, V & Bisson, A 2025, 'Tissue-like multicellular development triggere by mechanical compression in archaea', Science, vol. 388, no. 6742, pp. 109-115. https://doi.org/10.1126/science.adu0047

TY - JOUR

T1 - Tissue-like multicellular development triggere by mechanical compression in archaea

AU - Rados, Theopi

AU - Leland, Olivia S.

AU - Escudeiro, Pedro

AU - Mallon, John

AU - Andre, Katherine

AU - Caspy, Ido

AU - von Kügelgen, Andriko

AU - Stolovicki, Elad

AU - Nguyen, Sinead

AU - Patop, Inés Lucía

AU - Thiberio Rangel, L.

AU - Kadener, Sebastian

AU - Renner, Lars D.

AU - Thiel, Vera

AU - Soen, Yoav

AU - Bharat, Tanmay A.M.

AU - Alva, Vikram

AU - Bisson, Alex

PY - 2025/4/4

Y1 - 2025/4/4

N2 - The advent of clonal multicellularity is a critical evolutionary milestone, seen often in eukaryotes, rarely in bacteria, and only once in archaea. We show that uniaxial compression induces clonal multicellularity in haloarchaea, forming tissue-like structures. These archaeal tissues are mechanically and molecularly distinct from their unicellular lifestyle, mimicking several eukaryotic features. Archaeal tissues undergo a multinucleate stage followed by tubulin-independent cellularization, orchestrated by active membrane tension at a critical cell size. After cellularization, tissue junction elasticity becomes akin to that of animal tissues, giving rise to two cell types—peripheral (Per) and central scutoid (Scu) cells—with distinct actin and protein glycosylation polarity patterns. Our findings highlight the potential convergent evolution of a biophysical mechanism in the emergence of multicellular systems across domains of life.

AB - The advent of clonal multicellularity is a critical evolutionary milestone, seen often in eukaryotes, rarely in bacteria, and only once in archaea. We show that uniaxial compression induces clonal multicellularity in haloarchaea, forming tissue-like structures. These archaeal tissues are mechanically and molecularly distinct from their unicellular lifestyle, mimicking several eukaryotic features. Archaeal tissues undergo a multinucleate stage followed by tubulin-independent cellularization, orchestrated by active membrane tension at a critical cell size. After cellularization, tissue junction elasticity becomes akin to that of animal tissues, giving rise to two cell types—peripheral (Per) and central scutoid (Scu) cells—with distinct actin and protein glycosylation polarity patterns. Our findings highlight the potential convergent evolution of a biophysical mechanism in the emergence of multicellular systems across domains of life.

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U2 - 10.1126/science.adu0047

DO - 10.1126/science.adu0047

M3 - مقالة

C2 - 40179183

SN - 0036-8075

VL - 388

SP - 109

EP - 115

JO - Science

JF - Science

IS - 6742

ER -

Tissue-like multicellular development triggere by mechanical compression in archaea

Abstract

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