Self-Assembling Supramolecular Nanostructures Constructed from de Novo Extender Protein Nanobuilding Blocks.

The design of novel proteins that self-assemble into supramolecular complexes is important for development in nanobiotechnology and synthetic biology. Recently, we designed and created a protein nanobuilding block (PN-Block), WA20-foldon, by fusing an intermolecularly folded dimeric de novo WA20 protein and a trimeric foldon domain of T4 phage fibritin (Kobayashi et al., J. Am. Chem. Soc. 2015, 137, 11285). WA20-foldon formed several types of self-assembling nanoarchitectures in multiples of 6-mers, including a barrel-like hexamer and a tetrahedron-like dodecamer. In this study, to construct chain-like polymeric nanostructures, we designed de novo extender protein nanobuilding blocks (ePN-Blocks) by tandemly fusing two de novo binary-patterned WA20 proteins with various linkers. The ePN-Blocks with long helical linkers or flexible linkers were expressed in soluble fractions of Escherichia coli, and the purified ePN-Blocks were analyzed by native PAGE, size exclusion chromatography-multiangle light scattering (SEC-MALS), small-angle X-ray scattering (SAXS), and transmission electron microscopy. These results suggest formation of various structural homo-oligomers. Subsequently, we reconstructed hetero-oligomeric complexes from extender and stopper PN-Blocks by denaturation and refolding. The present SEC-MALS and SAXS analyses show that extender and stopper PN-Block (esPN-Block) heterocomplexes formed different types of extended chain-like conformations depending on their linker types. Moreover, atomic force microscopy imaging in liquid suggests that the esPN-Block heterocomplexes with metal ions further self-assembled into supramolecular nanostructures on mica surfaces. Taken together, the present data demonstrate that the design and construction of self-assembling PN-Blocks using de novo proteins is a useful strategy for building polymeric nanoarchitectures of supramolecular protein complexes.

[1]  Rebecca E A Gwyther,et al.  Better together: building protein oligomers naturally and by design , 2019, Biochemical Society transactions.

[2]  R. Pappu,et al.  Covalently-assembled single-chain protein nanostructures with ultra-high stability , 2019, Nature Communications.

[3]  J. Hirabayashi,et al.  Lectin engineering: the possible and the actual , 2019, Journal of the Royal Society Interface Focus.

[4]  Tanja Weil,et al.  Functional protein nanostructures: a chemical toolbox , 2018, Chemical Society reviews.

[5]  Christina Karas,et al.  Are natural proteins special? Can we do that? , 2018, Current opinion in structural biology.

[6]  Michael H Hecht,et al.  A de novo enzyme catalyzes a life-sustaining reaction in Escherichia coli. , 2018, Nature chemical biology.

[7]  Ryoichi Arai,et al.  Hierarchical design of artificial proteins and complexes toward synthetic structural biology , 2017, Biophysical Reviews.

[8]  Sota Yagi,et al.  Creation of artificial protein–protein interactions using α-helices as interfaces , 2017, Biophysical Reviews.

[9]  A. Keating,et al.  Modular assembly of a protein nanotriangle using orthogonally interacting coiled coils , 2017, Scientific Reports.

[10]  Dmitri I. Svergun,et al.  2017 publication guidelines for structural modelling of small-angle scattering data from biomolecules in solution: an update , 2017, Acta crystallographica. Section D, Structural biology.

[11]  R. Arai,et al.  Design and construction of self-assembling supramolecular protein complexes using artificial and fusion proteins as nanoscale building blocks. , 2017, Current opinion in biotechnology.

[12]  P. V. Konarev,et al.  ATSAS 2.8: a comprehensive data analysis suite for small-angle scattering from macromolecular solutions , 2017, Journal of applied crystallography.

[13]  David Baker,et al.  Foldit Standalone: a video game-derived protein structure manipulation interface using Rosetta , 2017, Bioinform..

[14]  Michael H Hecht,et al.  A Non-natural Protein Rescues Cells Deleted for a Key Enzyme in Central Metabolism. , 2017, ACS synthetic biology.

[15]  P. Besenius,et al.  Controlling supramolecular polymerization through multicomponent self‐assembly , 2017 .

[16]  John A Tainer,et al.  Designing and defining dynamic protein cage nanoassemblies in solution , 2016, Science Advances.

[17]  D. Baker,et al.  The coming of age of de novo protein design , 2016, Nature.

[18]  Q. Luo,et al.  Protein Assembly: Versatile Approaches to Construct Highly Ordered Nanostructures. , 2016, Chemical reviews.

[19]  H. Taguchi,et al.  Supramolecular Nanotube of Chaperonin GroEL: Length Control for Cellular Uptake Using Single-Ring GroEL Mutant as End-Capper. , 2016, Journal of the American Chemical Society.

[20]  T. Yeates,et al.  The design of symmetric protein nanomaterials comes of age in theory and practice. , 2016, Current opinion in structural biology.

[21]  David Baker,et al.  Accurate design of megadalton-scale two-component icosahedral protein complexes , 2016, Science.

[22]  G. Skiniotis,et al.  Flexible, symmetry-directed approach to assembling protein cages , 2016, Proceedings of the National Academy of Sciences.

[23]  Michael H Hecht,et al.  A de novo protein confers copper resistance in Escherichia coli , 2016, Protein science : a publication of the Protein Society.

[24]  David Baker,et al.  Design of a hyperstable 60-subunit protein icosahedron , 2016, Nature.

[25]  Andrej Sali,et al.  FoXS, FoXSDock and MultiFoXS: Single-state and multi-state structural modeling of proteins and their complexes based on SAXS profiles , 2016, Nucleic Acids Res..

[26]  S. Akanuma,et al.  De novo design of protein-protein interactions through modification of inter-molecular helix-helix interface residues. , 2016, Biochimica et biophysica acta.

[27]  Michael H Hecht,et al.  A protein constructed de novo enables cell growth by altering gene regulation , 2016, Proceedings of the National Academy of Sciences.

[28]  J B Bailey,et al.  Metal-Directed Design of Supramolecular Protein Assemblies. , 2016, Methods in enzymology.

[29]  S. Nagao,et al.  Domain-swapped cytochrome cb562 dimer and its nanocage encapsulating a Zn-SO4 cluster in the internal cavity. , 2015, Chemical science.

[30]  D. Svergun,et al.  A practical guide to small angle X‐ray scattering (SAXS) of flexible and intrinsically disordered proteins , 2015, FEBS letters.

[31]  F. Tezcan,et al.  A Metal Organic Framework with Spherical Protein Nodes: Rational Chemical Design of 3D Protein Crystals. , 2015, Journal of the American Chemical Society.

[32]  Hiroki Noguchi,et al.  Biomineralization of a Cadmium Chloride Nanocrystal by a Designed Symmetrical Protein. , 2015, Angewandte Chemie.

[33]  M. Hecht,et al.  Self-Assembling Nano-Architectures Created from a Protein Nano-Building Block Using an Intermolecularly Folded Dimeric de Novo Protein. , 2015, Journal of the American Chemical Society.

[34]  Yongwon Jung,et al.  Green fluorescent protein nanopolygons as monodisperse supramolecular assemblies of functional proteins with defined valency , 2015, Nature Communications.

[35]  M. Hecht,et al.  Divergent evolution of a bifunctional de novo protein , 2015, Protein science : a publication of the Protein Society.

[36]  Dmitri I. Svergun,et al.  SASBDB, a repository for biological small-angle scattering data , 2014, Nucleic Acids Res..

[37]  Greg L. Hura,et al.  Structure of a Designed Protein Cage that Self-Assembles into a Highly Porous Cube , 2014, Nature chemistry.

[38]  Hiroki Noguchi,et al.  Computational design of a self-assembling symmetrical β-propeller protein , 2014, Proceedings of the National Academy of Sciences.

[39]  Q. Luo,et al.  Protein-Based Supramolecular Polymers: Progress and Prospect , 2014 .

[40]  David Baker,et al.  Accurate design of co-assembling multi-component protein nanomaterials , 2014, Nature.

[41]  N. Linden,et al.  Self-Assembling Cages from Coiled-Coil Peptide Modules , 2013, Science.

[42]  D. Baker,et al.  Principles for designing ideal protein structures , 2012, Nature.

[43]  W. S. Horne,et al.  A modular synthetic platform for the construction of protein-based supramolecular polymers via coiled-coil self-assembly , 2012 .

[44]  A. Urvoas,et al.  Artificial proteins from combinatorial approaches. , 2012, Trends in biotechnology.

[45]  Gail J. Bartlett,et al.  Squaring the circle in peptide assembly: from fibers to discrete nanostructures by de novo design. , 2012, Journal of the American Chemical Society.

[46]  Michael H Hecht,et al.  Directed evolution of the peroxidase activity of a de novo-designed protein. , 2012, Protein engineering, design & selection : PEDS.

[47]  Andrew R Thomson,et al.  Cryo-transmission electron microscopy structure of a gigadalton peptide fiber of de novo design , 2012, Proceedings of the National Academy of Sciences.

[48]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[49]  Duilio Cascio,et al.  Structure of a 16-nm Cage Designed by Using Protein Oligomers , 2012, Science.

[50]  D. Baker,et al.  Computational Design of Self-Assembling Protein Nanomaterials with Atomic Level Accuracy , 2012, Science.

[51]  Ryoichi Arai,et al.  Domain-swapped dimeric structure of a stable and functional de novo four-helix bundle protein, WA20. , 2012, The journal of physical chemistry. B.

[52]  M. Hecht,et al.  Proteins from an unevolved library of de novo designed sequences bind a range of small molecules. , 2012, ACS synthetic biology.

[53]  Kristin N. Parent,et al.  Metal-directed, chemically-tunable assembly of one-, two- and three-dimensional crystalline protein arrays , 2012, Nature chemistry.

[54]  Dominique Durand,et al.  How Random are Intrinsically Disordered Proteins? A Small Angle Scattering Perspective , 2012, Current protein & peptide science.

[55]  J. Sinclair,et al.  Generation of protein lattices by fusing proteins with matching rotational symmetry. , 2011, Nature nanotechnology.

[56]  Michael H. Hecht,et al.  De Novo Designed Proteins from a Library of Artificial Sequences Function in Escherichia Coli and Enable Cell Growth , 2011, PloS one.

[57]  S. Nagao,et al.  Cytochrome c polymerization by successive domain swapping at the C-terminal helix , 2010, Proceedings of the National Academy of Sciences.

[58]  P. Emsley,et al.  Features and development of Coot , 2010, Acta crystallographica. Section D, Biological crystallography.

[59]  P. Vachette,et al.  NADPH oxidase activator p67(phox) behaves in solution as a multidomain protein with semi-flexible linkers. , 2010, Journal of structural biology.

[60]  Michael H Hecht,et al.  Cofactor binding and enzymatic activity in an unevolved superfamily of de novo designed 4‐helix bundle proteins , 2009, Protein science : a publication of the Protein Society.

[61]  H. Yamaguchi,et al.  Self-assembly of one- and two-dimensional hemoprotein systems by polymerization through heme-heme pocket interactions. , 2009, Angewandte Chemie.

[62]  T. Yamazaki,et al.  Selection and structural analysis of de novo proteins from an α3β3 genetic library , 2009, Protein science : a publication of the Protein Society.

[63]  Dmitri I. Svergun,et al.  Electronic Reprint Applied Crystallography Dammif, a Program for Rapid Ab-initio Shape Determination in Small-angle Scattering Applied Crystallography Dammif, a Program for Rapid Ab-initio Shape Determination in Small-angle Scattering , 2022 .

[64]  F. Tezcan,et al.  Controlling protein-protein interactions through metal coordination: assembly of a 16-helix bundle protein. , 2007, Journal of the American Chemical Society.

[65]  H. Yamaguchi,et al.  Supramolecular hemoprotein linear assembly by successive interprotein heme-heme pocket interactions. , 2007, Journal of the American Chemical Society.

[66]  Derek N. Woolfson,et al.  Engineering nanoscale order into a designed protein fiber , 2007, Proceedings of the National Academy of Sciences.

[67]  V. Rybin,et al.  Crystal structure of human filamin C domain 23 and small angle scattering model for filamin C 23-24 dimer. , 2007, Journal of molecular biology.

[68]  Dmitri I. Svergun,et al.  Upgrade of the small-angle X-ray scattering beamline X33 at the European Molecular Biology Laboratory, Hamburg , 2007 .

[69]  V. Yam,et al.  Self-assembly of one- and two-dimensional coordination polymers with quinonoid backbones featuring coinage metals as nodes , 2007 .

[70]  L. H. Bradley,et al.  Protein design by binary patterning of polar and nonpolar amino acids. , 1993, Methods in molecular biology.

[71]  R. Siegel,et al.  Chemically controlled self-assembly of protein nanorings. , 2006, Journal of the American Chemical Society.

[72]  P. Vachette,et al.  Small-angle X-ray scattering reveals an extended organization for the autoinhibitory resting state of the p47(phox) modular protein. , 2006, Biochemistry.

[73]  Kei Kobayashi,et al.  Development of low noise cantilever deflection sensor for multienvironment frequency-modulation atomic force microscopy , 2005 .

[74]  David W Wood,et al.  An intein-based genetic selection allows the construction of a high-quality library of binary patterned de novo protein sequences. , 2005, Protein engineering, design & selection : PEDS.

[75]  W. Wriggers,et al.  Conformations of variably linked chimeric proteins evaluated by synchrotron X‐ray small‐angle scattering , 2004, Proteins.

[76]  L. H. Bradley,et al.  De novo proteins from designed combinatorial libraries , 2004, Protein science : a publication of the Protein Society.

[77]  S. Grzesiek,et al.  Very fast folding and association of a trimerization domain from bacteriophage T4 fibritin. , 2004, Journal of molecular biology.

[78]  D. Baker,et al.  Design of a Novel Globular Protein Fold with Atomic-Level Accuracy , 2003, Science.

[79]  Dmitri I. Svergun,et al.  Uniqueness of ab initio shape determination in small-angle scattering , 2003 .

[80]  矢野 貴人,et al.  Directed Evolution のさまざまな応用例 , 2003 .

[81]  Olivia Freeman,et al.  Talking points personal outcomes approach: practical guide. , 2012 .

[82]  Teruyuki Nagamune,et al.  Design of the linkers which effectively separate domains of a bifunctional fusion protein. , 2001, Protein engineering.

[83]  Anthony D. Keefe,et al.  Functional proteins from a random-sequence library , 2001, Nature.

[84]  Jennifer E. Padilla,et al.  Nanohedra: Using symmetry to design self assembling protein cages, layers, crystals, and filaments , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[85]  D. Eisenberg,et al.  Design of three-dimensional domain-swapped dimers and fibrous oligomers. , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[86]  Dmitri I. Svergun,et al.  Automated matching of high- and low-resolution structural models , 2001 .

[87]  M. Hecht,et al.  De novo amyloid proteins from designed combinatorial libraries. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[88]  D I Svergun,et al.  Restoring low resolution structure of biological macromolecules from solution scattering using simulated annealing. , 1999, Biophysical journal.

[89]  S. L. Mayo,et al.  De novo protein design: fully automated sequence selection. , 1997, Science.

[90]  O. Glatter,et al.  Small-Angle Scattering of Interacting Particles. I. Basic Principles of a Global Evaluation Technique , 1997 .

[91]  A. P. Hammersley,et al.  Two-dimensional detector software: From real detector to idealised image or two-theta scan , 1996 .

[92]  D. Svergun,et al.  CRYSOL : a program to evaluate X-ray solution scattering of biological macromolecules from atomic coordinates , 1995 .

[93]  R. L. Baldwin,et al.  Helix stabilization by Glu-...Lys+ salt bridges in short peptides of de novo design. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[94]  O. Glatter Evaluation of small-angle scattering data from lamellar and cylindrical particles by the indirect transformation method , 1980 .

[95]  J S Moore,et al.  Design and construction. , 1972, Hospitals.

[96]  W. Ehrenberg,et al.  Small-Angle X-Ray Scattering , 1952, Nature.