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Unlocking the mechanics of life: Enzymes as soft, programmable nanobots

03.31.25 | Ulsan National Institute of Science and Technology(UNIST)

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Professor Tsvi Tlusty
Professor Tsvi Tlusty (Department of Physics, UNIST) Credit: UNIST

Living cells are bustling with molecular machines that constantly process energy, matter, and information. Among these machines, proteins stand out, with enzymes being the most notable. These catalytic entities dramatically accelerate essential metabolic reactions by many orders of magnitude, facilitating the very process that sustain life. While it has long been acknowledged that enzymes undergo movements during their catalytic cycles, measuring and predicting these internal motions and forces has proven extremely challenging.

This study addresses that challenge. It is the result of an international collaboration, led by Professor Tsvi Tlusty from the Department of Physics at Ulsan National Institute of Science and Technology (UNIST), South Korea, and Professor Elisha Moses from the Physics Department at the Weizmann Institute of Science, Israel.

The collaboration integrated artificial intelligence (AI) models with molecular dynamics simulations to predict the internal dynamics of enzymes, along side an innovative “nano-rheology” technique to measure these dynamics with unprecedented accuracy. The computational and experimental results culminated in the development of a new viscoelastic model of enzymes, elucidating the intertwined effects of elastic forces arising from stretching or twisting molecular bonds and friction forces (viscosity) associated with bond breaking and reforming.

“Finally, this novel physical model can explain how subtle, nanoscale motions and forces within enzymes impact their biological functions. It allows us to perceive proteins as soft robots or programmable active matter,” said Professor Tlusty.

The findings of this research have been published in Nature Physics on March 28, 2025.

Tsvi Tlusty
Distinguished Professor, Department of Physics, UNIST
E: tsvitlusty@gmail.com

JooHyeon Heo
Public Relations Officer, UNIST
T: +82-52-217-1223
E: joohyeonheo@unist.ac.kr

Journal Reference
Eyal Weinreb, John M. McBride, Marta Siek, et al. , "Enzymes as Viscoelastic Catalytic Machines," Nature Physics , (2025).

Nature Physics

Enzymes as Viscoelastic Catalytic Machines

28-Mar-2025

Keywords

Artificial Intelligence Biological Models Catalysis Cell Biology Chemical Bonding Computational Physics Developmental Genetics Elastic Deformation Enzymatic Reactions Enzymes Genetic Methods Genetic Technology Information Technology International Relations Mechanical Energy Molecular Dynamics Molecular Genetics Motion Nanorobots Scientific Collaboration

Article Information

Journal
Nature Physics
Article Publication Date
2025-03-28
Article Title
Enzymes as Viscoelastic Catalytic Machines

Contact Information

JooHyeon Heo
Ulsan National Institute of Science and Technology(UNIST)
joohyeonheo@unist.ac.kr

Source

Original Source
https://news.unist.ac.kr/unlocking-the-mechanics-of-life-enzymes-as-soft-programmable-nanobots/

How to Cite This Article

APA:
Ulsan National Institute of Science and Technology(UNIST). (2025, March 31). Unlocking the mechanics of life: Enzymes as soft, programmable nanobots. Brightsurf News. https://www.brightsurf.com/news/80ER7NE8/unlocking-the-mechanics-of-life-enzymes-as-soft-programmable-nanobots.html
MLA:
"Unlocking the mechanics of life: Enzymes as soft, programmable nanobots." Brightsurf News, Mar. 31 2025, https://www.brightsurf.com/news/80ER7NE8/unlocking-the-mechanics-of-life-enzymes-as-soft-programmable-nanobots.html.