Zhou, JiangtaoAssenza, SalvatoreTatli, MeltemTian, JiawenIlie, Ioana M.Starostin, Eugene L.Caflisch, AmedeoKnowles, Tuomas P. J.Dietler, GiovanniRuggeri, Francesco S.Stahlberg, HenningSekatskii, Sergey K.Mezzenga, Raffaele2024-07-032024-07-032024-07-032024-06-2010.1002/advs.202402740https://infoscience.epfl.ch/handle/20.500.14299/209124WOS:001250528600001Amyloid polymorphism is a hallmark of almost all amyloid species, yet the mechanisms underlying the formation of amyloid polymorphs and their complex architectures remain elusive. Commonly, two main mesoscopic topologies are found in amyloid polymorphs characterized by non-zero Gaussian and mean curvatures: twisted ribbons and helical fibrils, respectively. Here, a rich heterogeneity of configurations is demonstrated on insulin amyloid fibrils, where protofilament packing can occur, besides the common polymorphs, also in a combined mode forming mixed-curvature polymorphs. Through AFM statistical analysis, an extended array of heterogeneous architectures that are rationalized by mesoscopic theoretical arguments are identified. Notably, an unusual fibrillization pathway is also unraveled toward mixed-curvature polymorphs via the widespread recruitment and intertwining of protofilaments and protofibrils. The results present an original view of amyloid polymorphism and advance the fundamental understanding of the fibrillization mechanism from single protofilaments into mature amyloid fibrils.|Polymorphism is a key feature of amyloid fibrils, yet the mechanisms remain elusive. This work presents a comprehensive AFM study and proves the hierarchical intertwining mechanism from single fibrils into mature amyloid fibrils, forming the mixed-curvature amyloid polymorphs. The results advance the fundamental understanding of amyloid polymorphism and its fibrillization mechanism. imagePhysical SciencesTechnologyAmyloid PolymorphismAtomic Force MicroscopyFilament Intertwining MechanismMixed-Curvature Amyloidtext::journal::journal article::research article