Short peptides self-assemble to produce catalytic amyloids

Rufo, Caroline M.; Moroz, Yurii S.; Moroz, Olesia V.; Stöhr, Jan; Smith, Tyler A.; Hu, Xiaozhen; DeGrado, William F.; Korendovych, Ivan V.

doi:10.1038/nchem.1894

Cited by 574 publications

(596 citation statements)

References 38 publications

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“…7,9−11 To date, amyloid fibers have been functionalized for applications in tissue engineering, 12,13 drug delivery, 14−16 enzyme immobilization, 17 metal nanowires, 18−20 protein films, 21 light-harvesting nanodevices, 8,22 retroviral gene transfer enhancer, 23 environmental carbon dioxide capture, 24 and enzyme-like catalysis. 25 Although first identified as pathological entities, amyloid fibers have evolved in living organisms from prokaryotes to eukaryotes to perform diverse functions, including signal transduction, 26 RNA granule formation, 27 memory persistence, 28 hormone storage, 29 and cell surface adhesion. 30 The distinctive properties of amyloid fibers and their diverse functions in nature suggest that research on amyloid materials could contribute significantly to bio-nanotechnology.…”

Section: ■ Introductionmentioning

confidence: 99%

Structure-Based Design of Functional Amyloid Materials

et al. 2014

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Amyloid fibers, once exclusively associated with disease, are acquiring utility as a class of biological nanomaterials.Here we introduce a method that utilizes the atomic structures of amyloid peptides, to design materials with versatile applications. As a model application, we designed amyloid fibers capable of capturing carbon dioxide from flue gas, to address the global problem of excess anthropogenic carbon dioxide. By measuring dynamic separation of carbon dioxide from nitrogen, we show that fibers with designed amino acid sequences double the carbon dioxide binding capacity of the previously reported fiber formed by VQIVYK from Tau protein. In a second application, we designed fibers that facilitate retroviral gene transfer. By measuring lentiviral transduction, we show that designed fibers exceed the efficiency of polybrene, a commonly used enhancer of transduction. The same procedures can be adapted to the design of countless other amyloid materials with a variety of properties and uses.

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Section: ■ Introductionmentioning

confidence: 99%

Structure-Based Design of Functional Amyloid Materials

et al. 2014

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“…[20][21][22] Although more challenging, this would carry advantages over redesign approaches: firstly, the designer could select and control all, or at least many of the residues, and so engineer the complete construct predictably; secondly, the resulting proteins could be made to function under conditions away from those required by natural proteins; and finally, success in this area would provide the acid test of our understanding of enzyme structure and function. Towards this fully de novo effort, successful designs of hydrolases have included: the decoration of small protein-folding motifs with His residues; 23,24 the employment of Zn 2+ cations as Lewisacidic cofactors; [25][26][27][28] and the identification of catalytically active proteins in combinatorial libraries of sequences patterned to form to all- or all- protein folds. 29 One of the most productive areas in the de novo design of protein structure has been for coiled-coil assemblies.…”

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confidence: 99%

Installing hydrolytic activity into a completely de novo protein framework

et al. 2016

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Designing enzyme-like catalysts tests our understanding of sequence-tostructure/function relationships in proteins. Here, we install hydrolytic activity predictably into a completely de novo and thermo-stable -helical barrel, which comprises 7 helices arranged around an accessible channel. We show that the lumen of the barrel accepts 21 mutations to functional polar residues. The resulting variant, which has cysteine-histidine-glutamic acid triads on each helix, hydrolyses pnitrophenyl acetate with catalytic efficiencies matching the most-efficient redesigned hydrolases based on natural protein scaffolds. This is the first report of a functional catalytic triad engineered into a de novo protein framework. The flexibility of our system also allows the facile incorporation of unnatural side chains to improve activity and probe the catalytic mechanism. Such predictable and robust construction of truly de novo biocatalysts holds promise for applications in chemical and biochemical synthesis.(134 words)

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“…Several studies have demonstrated that natural amyloidogenic and designed amphiphilic peptides are capable of self-assembling into nanostructures with topographies including fibril, film, nanotube, hydrogel, and liquid crystals (15)(16)(17)(18)(19)(20)(21), and these nanostructures have been used for nanowires, biosensors, 3D culturing, environmental carbon capture, retroviral gene transfer, light harvesting, and catalysis (22)(23)(24)(25)(26). Amyloid fibrils were also hybridized with other nanomaterials such as graphene and DNA origami in hopes of creating new properties and functions (27)(28)(29).…”

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confidence: 99%

Tunable assembly of amyloid-forming peptides into nanosheets as a retrovirus carrier

Dai

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

137

118

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Using and engineering amyloid as nanomaterials are blossoming trends in bionanotechnology. Here, we show our discovery of an amyloid structure, termed "amyloid-like nanosheet," formed by a key amyloid-forming segment of Alzheimer's Aβ. Combining multiple biophysical and computational approaches, we proposed a structural model for the nanosheet that is formed by stacking the amyloid fibril spines perpendicular to the fibril axis. We further used the nanosheet for laboratorial retroviral transduction enhancement and directly visualized the presence of virus on the nanosheet surface by electron microscopy. Furthermore, based on our structural model, we designed nanosheet-forming peptides with different functionalities, elucidating the potential of rational design for amyloid-based materials with novel architecture and function.functional amyloid material | peptide self-assembly | nanosheet | retrovirus transduction | beta-amyloid N umerous proteins and polypeptides have been found to selfassemble into amyloid fibrils under certain conditions (1). They are associated not only with dozens of devastating diseases including Alzheimer's and Parkinson's diseases (2) but are integral to many biological processes such as hormone storage, signal transduction, and cell surface adhesion (3-5). Separate from the context of their parent proteins, synthesized peptide segments can self-assemble into amyloid-like fibrils in vitro as well (6, 7). Fibrils formed by diverse proteins and peptides all share a common cross-β structure, composed of interdigitated β-sheets termed "the zipper-like fibril spine" (8, 9). The self-assembly process is a consequence of backbone hydrogen bonding for the single β-sheet layer formation and side-chain interaction (e.g., hydrophobic interaction, π-stacking, and van der Waals) for pairing β-sheet layers together (10). Their highly repetitive and ordered architecture, in particular for the short peptide fibrils, exhibits favorable properties including high thermal stability and stiffness, biocompatibility, controllable self-assembly, surface patterning and integration of functionality, and inexpensive production by chemical synthesis (11-13). These exceptional properties promote the exploitation of amyloid fibril as an emerging class of bionanomaterials (14).Several studies have demonstrated that natural amyloidogenic and designed amphiphilic peptides are capable of self-assembling into nanostructures with topographies including fibril, film, nanotube, hydrogel, and liquid crystals (15-21), and these nanostructures have been used for nanowires, biosensors, 3D culturing, environmental carbon capture, retroviral gene transfer, light harvesting, and catalysis (22-26). Amyloid fibrils were also hybridized with other nanomaterials such as graphene and DNA origami in hopes of creating new properties and functions (27)(28)(29). In this study, we expand the amyloid material field's scope by the finding, structure characterization, and functionalization of a previously unidentified architecture-the amyloid-lik...

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Short peptides self-assemble to produce catalytic amyloids

Cited by 574 publications

References 38 publications

Structure-Based Design of Functional Amyloid Materials

Structure-Based Design of Functional Amyloid Materials

Installing hydrolytic activity into a completely de novo protein framework

Tunable assembly of amyloid-forming peptides into nanosheets as a retrovirus carrier

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