Functional aggregation of cell-free proteins enables fungal ice nucleation

Biological ice nucleation plays a key role in the survival of cold-adapted organisms. Several species of bacteria, fungi, and insects produce ice nucleators (INs) that enable ice formation at temperatures above -10 °C. Bacteria and fungi produce particularly potent INs that can promote water crystal...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2023-11, Vol.120 (46), p.e2303243120
Main Authors: Schwidetzky, Ralph, de Almeida Ribeiro, Ingrid, Bothen, Nadine, Backes, Anna T, DeVries, Arthur L, Bonn, Mischa, Fröhlich-Nowoisky, Janine, Molinero, Valeria, Meister, Konrad
Format: Article
Language:English
Subjects:
Aqueous environments
Bacteria
Bacterial Outer Membrane Proteins - metabolism
Crystallization
Freezing
Fungi
Fusarium
Ice
Ice formation
Ice nucleation
Insects
Nucleation
Numerical models
Proteins
Robustness (mathematics)
Temperature
Water
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Summary:Biological ice nucleation plays a key role in the survival of cold-adapted organisms. Several species of bacteria, fungi, and insects produce ice nucleators (INs) that enable ice formation at temperatures above -10 °C. Bacteria and fungi produce particularly potent INs that can promote water crystallization above -5 °C. Bacterial INs consist of extended protein units that aggregate to achieve superior functionality. Despite decades of research, the nature and identity of fungal INs remain elusive. Here, we combine ice nucleation measurements, physicochemical characterization, numerical modeling, and nucleation theory to shed light on the size and nature of the INs from the fungus . We find ice-binding and ice-shaping activity of IN, suggesting a potential connection between ice growth promotion and inhibition. We demonstrate that fungal INs are composed of small 5.3 kDa protein subunits that assemble into ice-nucleating complexes that can contain more than 100 subunits. INs retain high ice-nucleation activity even when only the ~12 kDa fraction of size-excluded proteins are initially present, suggesting robust pathways for their functional aggregation in cell-free aqueous environments. We conclude that the use of small proteins to build large assemblies is a common strategy among organisms to create potent biological INs.
ISSN:0027-8424
1091-6490
1091-6490
DOI:10.1073/pnas.2303243120