Labile assembly of a tardigrade protein induces biostasis

Sanchez‐Martinez, S.; Nguyen, K.; Biswas, S.; Nicholson, V.; Romanyuk, A. V.; Ramirez, J.; Kc, S.; Akter, A.; Childs, C.; Meese, E. K.; Usher, E. T.; Ginell, G. M.; Yu, F.; Gollub, E.; Malferrari, M.; Francia, F.; Venturoli, G.; Martin, E. W.; Caporaletti, F.; Giubertoni, G.; Woutersen, S.; Sukenik, S.; Woolfson, D. N.; Holehouse, A. S.; Boothby, T. C.

doi:10.1002/pro.4941

Cited by 3 publications

References 120 publications

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Structural adaptability and surface activity of peptides derived from tardigrade proteins

Giubertoni,

Chagri,

Argudo

et al. 2024

Protein Science

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Tardigrades are unique micro‐organisms with a high tolerance to desiccation. The protection of their cells against desiccation involves tardigrade‐specific proteins, which include the so‐called cytoplasmic abundant heat soluble (CAHS) proteins. As a first step towards the design of peptides capable of mimicking the cytoprotective properties of CAHS proteins, we have synthesized several model peptides with sequences selected from conserved CAHS motifs and investigated to what extent they exhibit the desiccation‐induced structural changes of the full‐length proteins. Using circular dichroism spectroscopy, two‐dimensional infrared spectroscopy, and molecular dynamics simulations, we have found that the CAHS model peptides are mostly disordered, but adopt a more ‐helical structure upon addition of 2,2,2‐trifluoroethanol, which mimics desiccation. This structural behavior is similar to that of full‐length CAHS proteins, which also adopt more ordered conformations upon desiccation. We also have investigated the surface activity of the peptides at the air/water interface, which also mimics partial desiccation. Interestingly, sum‐frequency generation spectroscopy shows that all model peptides are surface active and adopt a helical structure at the air/water interface. Our results suggest that amino acids with high helix‐forming propensities might contribute to the propensity of these peptides to adopt a helical structure when fully or partially dehydrated. Thus, the selected sequences retain part of the CAHS structural behavior upon desiccation, and might be used as a basis for the design of new synthetic peptide‐based cryoprotective materials.

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Structural adaptability and surface activity of peptides derived from tardigrade proteins

Giubertoni,

Chagri,

Argudo

et al. 2024

Protein Science

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Osmolyte-IDP interactions during desiccation

Nicholson,

Meese,

Boothby

2024

Progress in Molecular Biology and Translational Science

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Protein surface chemistry encodes an adaptive tolerance to desiccation

Romero-Pérez,

Moran,

Horani

et al. 2024

Preprint

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Proteins must be hydrated to function. Desiccation, a common event in an increasing number of ecosystems, can drive proteome-wide unfolding and aggregation. For cells to survive, proteins must disaggregate and retain their function upon rehydration. The molecular determinants that underlie protein desiccation resistance remain unknown. Here, we use mass spectrometry to show that some proteins possess an innate ability to survive dehydration and subsequent rehydration. Structural analysis correlates the ability of proteins to resist desiccation with their surface area chemistry. Remarkably, highly resistant proteins are responsible for the production of the cell's building blocks - amino acids, metabolites, and sugars. Conversely, those proteins that are desiccation-sensitive are responsible for ribosome biogenesis. As a result, the rehydrated proteome is preferentially enriched with metabolite and small molecule producers and depleted of ribosomes - the cell's heaviest consumers. We propose this functional bias allows cells to kickstart their metabolism and promote cell survival upon rehydration.

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Labile assembly of a tardigrade protein induces biostasis

Cited by 3 publications

References 120 publications

Structural adaptability and surface activity of peptides derived from tardigrade proteins

Structural adaptability and surface activity of peptides derived from tardigrade proteins

Osmolyte-IDP interactions during desiccation

Protein surface chemistry encodes an adaptive tolerance to desiccation

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