De novo DNA-based catch bonds
All primary chemical interactions weaken under mechanical stress, which imposes fundamental mechanical limits on the materials constructed from them. Biological materials combine plasticity with strength, for which nature has evolved a unique solution—catch bonds, supramolecular interactions that strengthen under tension. Biological catch bonds use force-gated conformational switches to convert weak bonds into strong ones. So far, catch bonds remain exclusive to nature, leaving their potential as mechanoadaptive elements in synthetic systems untapped. Here we report the design and realization of artificial catch bonds. Starting from a minimal set of thermodynamic design requirements, we created a molecular motif capable of catch bonding. It consists of a DNA duplex featuring a cryptic domain that unfolds under tension to strengthen the interaction. We show that these catch bonds recreate force-enhanced rolling adhesion, a hallmark feature of biological catch bonds in bacteria and leukocytes. This Article introduces catch bonds into the synthetic domain, and could lead to the creation of artificial catch-bonded materials. (Figure presented.).
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dig-wur-nl-wurpubs-6330662024-12-04 van Galen, Martijn Bok, Annemarie Peshkovsky, Taieesa van der Gucht, Jasper Albada, Bauke Sprakel, Joris Article/Letter to editor Nature Chemistry 16 (2024) 12 ISSN: 1755-4330 De novo DNA-based catch bonds 2024 All primary chemical interactions weaken under mechanical stress, which imposes fundamental mechanical limits on the materials constructed from them. Biological materials combine plasticity with strength, for which nature has evolved a unique solution—catch bonds, supramolecular interactions that strengthen under tension. Biological catch bonds use force-gated conformational switches to convert weak bonds into strong ones. So far, catch bonds remain exclusive to nature, leaving their potential as mechanoadaptive elements in synthetic systems untapped. Here we report the design and realization of artificial catch bonds. Starting from a minimal set of thermodynamic design requirements, we created a molecular motif capable of catch bonding. It consists of a DNA duplex featuring a cryptic domain that unfolds under tension to strengthen the interaction. We show that these catch bonds recreate force-enhanced rolling adhesion, a hallmark feature of biological catch bonds in bacteria and leukocytes. This Article introduces catch bonds into the synthetic domain, and could lead to the creation of artificial catch-bonded materials. (Figure presented.). en application/pdf https://research.wur.nl/en/publications/de-novo-dna-based-catch-bonds 10.1038/s41557-024-01571-4 https://edepot.wur.nl/670957 Life Science https://creativecommons.org/licenses/by/4.0/ https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research |
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Life Science Life Science van Galen, Martijn Bok, Annemarie Peshkovsky, Taieesa van der Gucht, Jasper Albada, Bauke Sprakel, Joris De novo DNA-based catch bonds |
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All primary chemical interactions weaken under mechanical stress, which imposes fundamental mechanical limits on the materials constructed from them. Biological materials combine plasticity with strength, for which nature has evolved a unique solution—catch bonds, supramolecular interactions that strengthen under tension. Biological catch bonds use force-gated conformational switches to convert weak bonds into strong ones. So far, catch bonds remain exclusive to nature, leaving their potential as mechanoadaptive elements in synthetic systems untapped. Here we report the design and realization of artificial catch bonds. Starting from a minimal set of thermodynamic design requirements, we created a molecular motif capable of catch bonding. It consists of a DNA duplex featuring a cryptic domain that unfolds under tension to strengthen the interaction. We show that these catch bonds recreate force-enhanced rolling adhesion, a hallmark feature of biological catch bonds in bacteria and leukocytes. This Article introduces catch bonds into the synthetic domain, and could lead to the creation of artificial catch-bonded materials. (Figure presented.). |
| format |
Article/Letter to editor |
| topic_facet |
Life Science |
| author |
van Galen, Martijn Bok, Annemarie Peshkovsky, Taieesa van der Gucht, Jasper Albada, Bauke Sprakel, Joris |
| author_facet |
van Galen, Martijn Bok, Annemarie Peshkovsky, Taieesa van der Gucht, Jasper Albada, Bauke Sprakel, Joris |
| author_sort |
van Galen, Martijn |
| title |
De novo DNA-based catch bonds |
| title_short |
De novo DNA-based catch bonds |
| title_full |
De novo DNA-based catch bonds |
| title_fullStr |
De novo DNA-based catch bonds |
| title_full_unstemmed |
De novo DNA-based catch bonds |
| title_sort |
de novo dna-based catch bonds |
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https://research.wur.nl/en/publications/de-novo-dna-based-catch-bonds |
| work_keys_str_mv |
AT vangalenmartijn denovodnabasedcatchbonds AT bokannemarie denovodnabasedcatchbonds AT peshkovskytaieesa denovodnabasedcatchbonds AT vanderguchtjasper denovodnabasedcatchbonds AT albadabauke denovodnabasedcatchbonds AT sprakeljoris denovodnabasedcatchbonds |
| _version_ |
1819140386143076352 |