Protein Frameworks with Thiacalixarene and Zinc

Controlled protein assembly provides a means to generate biomaterials. Synthetic macrocycles such as the water-soluble sulfonato-calix­[n]­arenes are useful mediators of protein assembly. Sulfonato-thiacalix[4]­arene (tsclx 4 ), with its metal-binding capacity, affords the potential for simultaneous...

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Veröffentlicht in:Crystal growth & design 2022-05, Vol.22 (5), p.3271-3276
Hauptverfasser: Flood, Ronan J, Ramberg, Kiefer O, Mengel, Darius B, Guagnini, Francesca, Crowley, Peter B
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container_end_page 3276
container_issue 5
container_start_page 3271
container_title Crystal growth & design
container_volume 22
creator Flood, Ronan J
Ramberg, Kiefer O
Mengel, Darius B
Guagnini, Francesca
Crowley, Peter B
description Controlled protein assembly provides a means to generate biomaterials. Synthetic macrocycles such as the water-soluble sulfonato-calix­[n]­arenes are useful mediators of protein assembly. Sulfonato-thiacalix[4]­arene (tsclx 4 ), with its metal-binding capacity, affords the potential for simultaneous macrocycle- and metal-mediated protein assembly. Here, we describe the tsclx 4 -/Zn-directed assembly of two proteins: cationic α-helical cytochrome c (cyt c) and neutral β-propeller Ralstonia solanacearum lectin (RSL). Two co-crystal forms were obtained with cyt c, each involving multinuclear zinc sites supported by the cone conformation of tsclx 4 . The tsclx 4 /Zn cluster acted as an assembly node via both lysine encapsulation and metal-mediated protein–protein contacts. In the case of RSL, tsclx 4 adopted the 1,2-alternate conformation and supported a dinuclear zinc site with concomitant encapsulation and metal-binding of two histidine side chains. These results, together with the knowledge of thiacalixarene/metal nanoclusters, suggest promising applications for thiacalixarenes in biomaterials and MOF fabrication.
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