Your search keyword '"Kibler, Ryan D."' showing total 11 results

1. Blueprinting extendable nanomaterials with standardized protein blocks

Author

Huddy, Timothy F, Hsia, Yang, Kibler, Ryan D, Xu, Jinwei, Bethel, Neville, Nagarajan, Deepesh, Redler, Rachel, Leung, Philip JY, Weidle, Connor, Courbet, Alexis, Yang, Erin C, Bera, Asim K, Coudray, Nicolas, Calise, S John, Davila-Hernandez, Fatima A, Han, Hannah L, Carr, Kenneth D, Li, Zhe, McHugh, Ryan, Reggiano, Gabriella, Kang, Alex, Sankaran, Banumathi, Dickinson, Miles S, Coventry, Brian, Brunette, TJ, Liu, Yulai, Dauparas, Justas, Borst, Andrew J, Ekiert, Damian, Kollman, Justin M, Bhabha, Gira, and Baker, David

Subjects

Biochemistry and Cell Biology, Engineering, Biological Sciences, Generic health relevance, Crystallography, X-Ray, Nanostructures, Proteins, Microscopy, Electron, Reproducibility of Results, General Science & Technology

Abstract

A wooden house frame consists of many different lumber pieces, but because of the regularity of these building blocks, the structure can be designed using straightforward geometrical principles. The design of multicomponent protein assemblies, in comparison, has been much more complex, largely owing to the irregular shapes of protein structures1. Here we describe extendable linear, curved and angled protein building blocks, as well as inter-block interactions, that conform to specified geometric standards; assemblies designed using these blocks inherit their extendability and regular interaction surfaces, enabling them to be expanded or contracted by varying the number of modules, and reinforced with secondary struts. Using X-ray crystallography and electron microscopy, we validate nanomaterial designs ranging from simple polygonal and circular oligomers that can be concentrically nested, up to large polyhedral nanocages and unbounded straight 'train track' assemblies with reconfigurable sizes and geometries that can be readily blueprinted. Because of the complexity of protein structures and sequence-structure relationships, it has not previously been possible to build up large protein assemblies by deliberate placement of protein backbones onto a blank three-dimensional canvas; the simplicity and geometric regularity of our design platform now enables construction of protein nanomaterials according to 'back of an envelope' architectural blueprints.

Published

2024

2. Precisely patterned nanofibres made from extendable protein multiplexes

Author

Bethel, Neville P, Borst, Andrew J, Parmeggiani, Fabio, Bick, Matthew J, Brunette, TJ, Nguyen, Hannah, Kang, Alex, Bera, Asim K, Carter, Lauren, Miranda, Marcos C, Kibler, Ryan D, Lamb, Mila, Li, Xinting, Sankaran, Banumathi, and Baker, David

Subjects

Chemical Sciences, Nanofibers, Models, Molecular, Protein Conformation, alpha-Helical, Protein Subunits, Organic Chemistry, Chemical sciences

Abstract

Molecular systems with coincident cyclic and superhelical symmetry axes have considerable advantages for materials design as they can be readily lengthened or shortened by changing the length of the constituent monomers. Among proteins, alpha-helical coiled coils have such symmetric, extendable architectures, but are limited by the relatively fixed geometry and flexibility of the helical protomers. Here we describe a systematic approach to generating modular and rigid repeat protein oligomers with coincident C2 to C8 and superhelical symmetry axes that can be readily extended by repeat propagation. From these building blocks, we demonstrate that a wide range of unbounded fibres can be systematically designed by introducing hydrophilic surface patches that force staggering of the monomers; the geometry of such fibres can be precisely tuned by varying the number of repeat units in the monomer and the placement of the hydrophilic patches.

Published

2023

3. De novo design of knotted tandem repeat proteins

Author

Doyle, Lindsey A., Takushi, Brittany, Kibler, Ryan D., Milles, Lukas F., Orozco, Carolina T., Jones, Jonathan D., Jackson, Sophie E., Stoddard, Barry L., and Bradley, Philip

Published

2023

4. Genetically Encoded XTEN‐based Hydrogels with Tunable Viscoelasticity and Biodegradability for Injectable Cell Therapies

Author

Bennett, Jennifer I., primary, Boit, Mary O'Kelly, additional, Gregorio, Nicole E., additional, Zhang, Fan, additional, Kibler, Ryan D., additional, Hoye, Jack W., additional, Prado, Olivia, additional, Rapp, Peter B., additional, Murry, Charles E., additional, Stevens, Kelly R., additional, and DeForest, Cole A., additional

Published

2024

5. Blueprinting expandable nanomaterials with standardized protein building blocks

Author

Huddy, Timothy F., primary, Hsia, Yang, additional, Kibler, Ryan D., additional, Xu, Jinwei, additional, Bethel, Neville, additional, Nagarajan, Deepesh, additional, Redler, Rachel, additional, Leung, Philip J. Y., additional, Courbet, Alexis, additional, Yang, Erin C., additional, Bera, Asim K., additional, Coudray, Nicolas, additional, Calise, S. John, additional, Davila-Hernandez, Fatima A., additional, Weidle, Connor, additional, Han, Hannah L., additional, Li, Zhe, additional, McHugh, Ryan, additional, Reggiano, Gabriella, additional, Kang, Alex, additional, Sankaran, Banumathi, additional, Dickinson, Miles S., additional, Coventry, Brian, additional, Brunette, TJ, additional, Liu, Yulai, additional, Dauparas, Justas, additional, Borst, Andrew J., additional, Ekiert, Damian, additional, Kollman, Justin M., additional, Bhabha, Gira, additional, and Baker, David, additional

Published

2023

6. Blueprinting expandable nanomaterials with standardized protein building blocks

Author

Huddy, Timothy F., Hsia, Yang, Kibler, Ryan D., Xu, Jinwei, Bethel, Neville, Nagarajan, Deepesh, Redler, Rachel, Leung, Philip J. Y., Courbet, Alexis, Yang, Erin C., Bera, Asim K., Coudray, Nicolas, Calise, S. John, Davila-Hernandez, Fatima A., Weidle, Connor, Han, Hannah L., Li, Zhe, McHugh, Ryan, Reggiano, Gabriella, Kang, Alex, Sankaran, Banumathi, Dickinson, Miles S., Coventry, Brian, Brunette, TJ, Liu, Yulai, Dauparas, Justas, Borst, Andrew J., Ekiert, Damian, Kollman, Justin M., Bhabha, Gira, and Baker, David

Subjects

Article

Abstract

A wooden house frame consists of many different lumber pieces, but because of the regularity of these building blocks, the structure can be designed using straightforward geometrical principles. The design of multicomponent protein assemblies in comparison has been much more complex, largely due to the irregular shapes of protein structures (1) . Here we describe extendable linear, curved, and angled protein building blocks, as well as inter-block interactions that conform to specified geometric standards; assemblies designed using these blocks inherit their extendability and regular interaction surfaces, enabling them to be expanded or contracted by varying the number of modules, and reinforced with secondary struts. Using X-ray crystallography and electron microscopy, we validate nanomaterial designs ranging from simple polygonal and circular oligomers that can be concentrically nested, up to large polyhedral nanocages and unbounded straight “train track” assemblies with reconfigurable sizes and geometries that can be readily blueprinted. Because of the complexity of protein structures and sequence-structure relationships, it has not been previously possible to build up large protein assemblies by deliberate placement of protein backbones onto a blank 3D canvas; the simplicity and geometric regularity of our design platform now enables construction of protein nanomaterials according to “back of an envelope” architectural blueprints.

Published

2023

7. De novo design of protein logic gates

Author

Chen, Zibo, primary, Kibler, Ryan D., additional, Hunt, Andrew, additional, Busch, Florian, additional, Pearl, Jocelynn, additional, Jia, Mengxuan, additional, VanAernum, Zachary L., additional, Wicky, Basile I. M., additional, Dods, Galen, additional, Liao, Hanna, additional, Wilken, Matthew S., additional, Ciarlo, Christie, additional, Green, Shon, additional, El-Samad, Hana, additional, Stamatoyannopoulos, John, additional, Wysocki, Vicki H., additional, Jewett, Michael C., additional, Boyken, Scott E., additional, and Baker, David, additional

Published

2020

8. De novo design of protein logic gates.

Author

Zibo Chen, Kibler, Ryan D., Hunt, Andrew, Busch, Florian, Pearl, Jocelynn, Mengxuan Jia, VanAernum, Zachary L., Wicky, Basile I. M., Dods, Galen, Liao, Hanna, Wilken, Matthew S., Ciarlo, Christie, Green, Shon, El-Samad, Hana, Stamatoyannopoulos, John, Wysocki, Vicki H., Jewett, Michael C., Boyken, Scott E., and Baker, David

Subjects

*SYNTHETIC biology, *T cells, *MASS spectrometry, *POST-translational modification, *GENETIC transcription

Abstract

The design of modular protein logic for regulating protein function at the posttranscriptional level is a challenge for synthetic biology. Here, we describe the design of two-input AND, OR, NAND, NOR, XNOR, and NOT gates built from de novoÐdesigned proteins. These gates regulate the association of arbitrary protein units ranging from split enzymes to transcriptional machinery in vitro, in yeast and in primary human T cells, where they control the expression of the TIM3 gene related to T cell exhaustion. Designed binding interaction cooperativity, confirmed by native mass spectrometry, makes the gates largely insensitive to stoichiometric imbalances in the inputs, and the modularity of the approach enables ready extension to three-input OR, AND, and disjunctive normal form gates. The modularity and cooperativity of the control elements, coupled with the ability to de novo design an essentially unlimited number of protein components, should enable the design of sophisticated posttranslational control logic over a wide range of biological functions. [ABSTRACT FROM AUTHOR]

Published

2020

9. Computational design of bifaceted protein nanomaterials with tailorable properties.

Author

Rankovic S, Carr KD, Decarreau J, Skotheim R, Kibler RD, Ols S, Lee S, Chun J, Tooley M, Dauparas J, Eisenach HE, Glögl M, Weidle C, Borst AJ, Baker D, and King NP

Abstract

Recent advances in computational methods have led to considerable progress in the design of self-assembling protein nanoparticles. However, nearly all nanoparticles designed to date exhibit strict point group symmetry, with each subunit occupying an identical, symmetrically related environment. This property limits the structural diversity that can be achieved and precludes anisotropic functionalization. Here, we describe a general computational strategy for designing multi-component bifaceted protein nanomaterials with two distinctly addressable sides. The method centers on docking pseudosymmetric heterooligomeric building blocks in architectures with dihedral symmetry and designing an asymmetric protein-protein interface between them. We used this approach to obtain an initial 30-subunit assembly with pseudo-D5 symmetry, and then generated an additional 15 variants in which we controllably altered the size and morphology of the bifaceted nanoparticles by designing de novo extensions to one of the subunits. Functionalization of the two distinct faces of the nanoparticles with de novo protein minibinders enabled specific colocalization of two populations of polystyrene microparticles coated with target protein receptors. The ability to accurately design anisotropic protein nanomaterials with precisely tunable structures and functions will be broadly useful in applications that require colocalizing two or more distinct target moieties., Competing Interests: Competing interests The authors declare no competing interests.

Published

2024

10. Blueprinting expandable nanomaterials with standardized protein building blocks.

Author

Huddy TF, Hsia Y, Kibler RD, Xu J, Bethel N, Nagarajan D, Redler R, Leung PJY, Courbet A, Yang EC, Bera AK, Coudray N, Calise SJ, Davila-Hernandez FA, Weidle C, Han HL, Li Z, McHugh R, Reggiano G, Kang A, Sankaran B, Dickinson MS, Coventry B, Brunette TJ, Liu Y, Dauparas J, Borst AJ, Ekiert D, Kollman JM, Bhabha G, and Baker D

Abstract

A wooden house frame consists of many different lumber pieces, but because of the regularity of these building blocks, the structure can be designed using straightforward geometrical principles. The design of multicomponent protein assemblies in comparison has been much more complex, largely due to the irregular shapes of protein structures 1 . Here we describe extendable linear, curved, and angled protein building blocks, as well as inter-block interactions that conform to specified geometric standards; assemblies designed using these blocks inherit their extendability and regular interaction surfaces, enabling them to be expanded or contracted by varying the number of modules, and reinforced with secondary struts. Using X-ray crystallography and electron microscopy, we validate nanomaterial designs ranging from simple polygonal and circular oligomers that can be concentrically nested, up to large polyhedral nanocages and unbounded straight "train track" assemblies with reconfigurable sizes and geometries that can be readily blueprinted. Because of the complexity of protein structures and sequence-structure relationships, it has not been previously possible to build up large protein assemblies by deliberate placement of protein backbones onto a blank 3D canvas; the simplicity and geometric regularity of our design platform now enables construction of protein nanomaterials according to "back of an envelope" architectural blueprints.

Published

2023

11. Stepwise design of pseudosymmetric protein hetero-oligomers.

Author

Kibler RD, Lee S, Kennedy MA, Wicky BIM, Lai SM, Kostelic MM, Li X, Chow CM, Carter L, Wysocki VH, Stoddard BL, and Baker D

Abstract

Pseudosymmetric hetero-oligomers with three or more unique subunits with overall structural (but not sequence) symmetry play key roles in biology, and systematic approaches for generating such proteins de novo would provide new routes to controlling cell signaling and designing complex protein materials. However, the de novo design of protein hetero-oligomers with three or more distinct chains with nearly identical structures is a challenging problem because it requires the accurate design of multiple protein-protein interfaces simultaneously. Here, we describe a divide-and-conquer approach that breaks the multiple-interface design challenge into a set of more tractable symmetric single-interface redesign problems, followed by structural recombination of the validated homo-oligomers into pseudosymmetric hetero-oligomers. Starting from de novo designed circular homo-oligomers composed of 9 or 24 tandemly repeated units, we redesigned the inter-subunit interfaces to generate 15 new homo-oligomers and recombined them to make 17 new hetero-oligomers, including ABC heterotrimers, A2B2 heterotetramers, and A3B3 and A2B2C2 heterohexamers which assemble with high structural specificity. The symmetric homo-oligomers and pseudosymmetric hetero-oligomers generated for each system share a common backbone, and hence are ideal building blocks for generating and functionalizing larger symmetric assemblies., Competing Interests: Competing interests A provisional patent application has been filed (63/486,872) by the University of Washington, listing R.D.K., Nicholas Woodall, B.I.M.W., B.L.S., S.L., and D.B. as inventors or contributors.

Published

2023