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04/10/2025 14:04

When the pressure is on, Archaea go multicellular

Beatriz Lucas Presse- und Öffentlichkeitsarbeit
Max-Planck-Institut für Biologie Tübingen

Mechanical compression induces multicellular organization in archaea

In a discovery that reframes our understanding of life’s fundamental organization, researchers at Brandeis University, the MRC Laboratory of Molecular Biology, and the Max Planck Institute for Biology Tübingen have found that mechanical compression can induce the formation of tissue-like multicellular structures in archaea. This novel finding, focusing on the haloarchaeon Haloferax volcanii, reveals a previously unknown pathway for the emergence of multicellularity within this domain of life, offering new insights into the evolutionary origins of multicellular complexity across all living organisms.

In brief
• Induction of Multicellularity: Researchers found that when mechanically compressed, the salt-loving archaeon Haloferax volcanii can shift from being single-celled to forming tissue-like clusters, displaying new mechanical and biological properties.

• Insights into Evolution: This study challenges current thinking about evolution by showing that physical forces and genetic changes can work together to promote the development of complex life forms, suggesting that multicellularity might arise more easily than we previously imagined.

• Revisiting the building blocks of life: The findings highlight how archaea, often seen as simple organisms, can demonstrate remarkable adaptability, potentially providing clues about how multicellular life originated and evolved in response to environmental pressures.

Archaea—one of the three primary domains of life alongside Bacteria and Eukaryota—are often overlooked and sometimes mistaken for bacteria due to their single-celled nature and lack of a nucleus. Yet, archaea are found across diverse environments, from oceanic plankton to the human microbiome. Despite their superficial similarity to bacteria, their genetic makeup has long suggested a closer evolutionary relationship with eukaryotes, the domain encompassing plants and animals. This new research uncovers a remarkable capacity within archaea to organize beyond their single-celled existence under specific physical conditions.

Intrigued by the unique combination of genetic and structural traits in archaeal cells—particularly their proteinaceous surface layer instead of a rigid cell wall—researchers from Brandeis University, the MRC Laboratory of Molecular Biology in Cambridge, and the Max Planck Institute for Biology in Tübingen sought to explore the mechanobiology of these ancient organisms. This collaborative work was supported by a Human Frontier Science Program (HFSP) grant. Lead researcher Alex Bisson from Brandeis University explains, “The absence of a covalent-bound cell wall suggests a more dynamic, but less rigid structure, leading to the hypothesis that archaea might be 'squishy' and sensitive to mechanical stimuli.” This initial curiosity led to an unexpected and significant discovery.

Their research resulted in the accidental identification of multicellularity across all three domains of life and demonstrated the importance of mechanical forces in shaping archaeal tissues. “Our work shows that the emergence of complexity in life isn’t limited to a few special branches on the tree of life—it’s a deeper property, present even in lineages we’ve long overlooked,” noted Vikram Alva, co-lead author from Max Planck Institute for Biology Tübingen. Pedro Escudeiro, a postdoctoral researcher in the Alva group, added, “This work also underscores the power of combining comparative genomics with observable traits to uncover genes behind novel behaviors—an approach that has long driven discoveries in plants and animals.”

The Role of Mechanical Forces in Multicellularity

Working with Haloferax volcanii, a resilient archaeon that thrives in extreme environments like salt flats, the team observed an astonishing transformation. Instead of undergoing typical cell division, when subjected to mechanical compression, the cells grew larger and organized in tissue-like arrangements containing multiple sets of genetic material.
Their study describes how the flexible outer protein layer contributes to adaptive growth strategies. “It was Theopi Rados, the first author leading the project, who first observed and described this remarkable behavior,” said Alex Bisson. “As Olivia Leland, co-first author, aptly put it —it's as if the cells were squished down and then encouraged to grow wider and taller, more like a rising sourdough loaf than traditional cell division,” explained Alex Bisson.

As cells were subjected to specific pressures, they transitioned from solitary organisms to interconnected cellular communities. “That such behavior can be triggered by a simple physical constraint and involves cytoskeletal remodeling, and coordinated cellularization suggests that the capacity for structural organization runs deeper in biology than previously thought,” remarked Theopi Rados.

“The fact that archaea can orchestrate complex from tissue-like structures suggests that nature can emerge complex traits from seemingly unsophisticated raw materials,” adds Alex Bisson. “By revealing just a fraction of natural diversity, we could advance our intellectual and medical needs.”

Tanmay Bharat, a co-lead author from the MRC Laboratory of Molecular Biology in Cambridge, underscores the broader implications of research in archaea on multicellularity: “We found that mechanical compression induces multicellularity, a surprising finding, to say the least!” He further suggests that this discovery raises questions about whether other unicellular organisms might possess a similar latent ability to develop multicellularity in response to environmental cues.

Although it is common knowledge that archaea don’t like to be confined, likely because their cell envelope structure is more fragile than that of other microbes, archaeal tissues have now added another facet to our understanding of multicellularity. This research encourages other scientists to explore whether applying similar stimuli could prompt other ordinarily unicellular organisms to transition to multicellularity. How many more developmental pathways can we discover?

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Contact for scientific information:

Dr. Alex Bisson
Bisson Lab
Brandeis University—Biology Department
bisson@brandeis.edu

Dr. Tanmay Bharat
Structural Studies Division
MRC Laboratory of Molecular Biology
tbharat@mrc-lmb.cam.ac.uk

Dr. Vikram Alva
Department of Protein Evolution—Protein Bioinformatics
Max Planck Institute for Biology Tübingen
vikram.alva@tuebingen.mpg.de

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Original publication:

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

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More information:

https://www.bio.mpg.de/465581/news_publication_24504890_transferred?c=2923
https://keeper.mpdl.mpg.de/d/ff6c04c84fa14836bd49/

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Criteria of this press release:
Journalists, Scientists and scholars, all interested persons
Biology
transregional, national
Research results
English

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