Peptide Tectonics: Encoded Structural Complementarity Dictates Programmable Self‐Assembly

Programmable self‐assembly of peptides into well‐defined nanostructures represents one promising approach for bioinspired and biomimetic synthesis of artificial complex systems and functional materials. Despite the progress made over the past two decades in the development of strategies for precise manipulation of the self‐assembly of peptides, there is a remarkable gap between current peptide assemblies and biological systems in terms of structural complexity and functions. Here, the concept of peptide tectonics for the creation of well‐defined nanostructures predominately driven by the complementary association at the interacting interfaces of tectons is introduced. Peptide tectons are defined as peptide building blocks exhibiting structural complementarity at the interacting interfaces of commensurate domains and undergoing programmable self‐assembly into defined supramolecular structures promoted by complementary interactions. Peptide tectons are categorized based on their conformational entropy and the underlying mechanism for the programmable self‐assembly of peptide tectons is highlighted focusing on the approaches for incorporating the structural complementarity within tectons. Peptide tectonics not only provides an alternative perspective to understand the self‐assembly of peptides, but also allows for precise manipulation of peptide interactions, thus leading to artificial systems with advanced complexity and functions and paves the way toward peptide‐related functional materials resembling natural systems. Peptide tectons, referred to as peptide building blocks with structural complementarity, undergo programmable self‐assembly driven by complementary interactions at predictable interfaces between incorporated domains. The concept of peptide tectonics is introduced for the creation of well‐defined peptide nanostructures with rationally tailored structural features, thus potentially paving the way for developing functional materials resembling natural systems.