AI Article Synopsis
- The quaternary structure of proteins enhances the functionality of individual proteins, and self-assembled protein nanostructures (SPrNs) aim to further improve protein capabilities but are challenging to create.
- To simplify SPrN fabrication, a strategy involving three steps is proposed: forming equilibrated self-assembled peptide nanostructures (SPeNs), covalently capturing these SPeNs, and then assembling them into SPrNs through protein-peptide interactions.
- This approach resulted in SPrNs that are significantly larger than the initial peptides and demonstrated that irreversible SPeNs can serve as effective building blocks for creating more complex superstructures, making it a broadly applicable technique for soluble proteins.
Article Abstract
The quaternary structure of proteins extends the functionality of monomeric proteins. Similarly, self-assembled protein nanostructures (SPrNs) have great potential to improve the functionality and complexity of proteins; however, the difficulty associated with the fabrication of SPrNs is far greater than that associated with the fabrication of self-assembled peptides or polymers and often requires sophisticated computational design. To make the process of SPrN formation simpler and more intuitive, herein, we devise a strategy to adopt an irreversible self-assembled peptide nanostructure (SPeN) process en route to the formation of SPrNs. The strategy employs three sequential steps: first, the formation of SPeNs (an equilibrium process); second, covalent capture of SPeNs (an irreversible process); third, the final assembly of SPrNs via protein-peptide interactions (an equilibrium process). This strategy allowed us to fabricate SPrNs in which the size of the protein was approximately 9 times higher than that of the self-assembling peptide. Furthermore, we demonstrated that the irreversible SPeN could be used as a primary building block for assembly into superstructures. Overall, this strategy is conceptually as simple as SPeN fabrication and is potentially applicable to any soluble protein.
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| http://dx.doi.org/10.1021/acsmacrolett.3c00550 | DOI Listing |
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