Your search keyword '"Yang, Erin C."' showing total 18 results

1. Computational design of non-porous pH-responsive antibody nanoparticles

Author

Yang, Erin C., Divine, Robby, Miranda, Marcos C., Borst, Andrew J., Sheffler, Will, Zhang, Jason Z., Decarreau, Justin, Saragovi, Amijai, Abedi, Mohamad, Goldbach, Nicolas, Ahlrichs, Maggie, Dobbins, Craig, Hand, Alexis, Cheng, Suna, Lamb, Mila, Levine, Paul M., Chan, Sidney, Skotheim, Rebecca, Fallas, Jorge, Ueda, George, Lubner, Joshua, Somiya, Masaharu, Khmelinskaia, Alena, King, Neil P., and Baker, David

Published

2024

2. 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

3. Rapid and automated design of two-component protein nanomaterials using ProteinMPNN

Author

de Haas, Robbert J, Brunette, Natalie, Goodson, Alex, Dauparas, Justas, Yi, Sue Y, Yang, Erin C, Dowling, Quinton, Nguyen, Hannah, Kang, Alex, Bera, Asim K, Sankaran, Banumathi, de Vries, Renko, Baker, David, and King, Neil P

Subjects

Biochemistry and Cell Biology, Biological Sciences, Bioengineering, Biotechnology, Generic health relevance, Models, Molecular, Proteins, Amino Acid Sequence, Nanostructures, Protein Conformation, ProteinMPNN, nanomaterials, protein design

Abstract

The design of protein-protein interfaces using physics-based design methods such as Rosetta requires substantial computational resources and manual refinement by expert structural biologists. Deep learning methods promise to simplify protein-protein interface design and enable its application to a wide variety of problems by researchers from various scientific disciplines. Here, we test the ability of a deep learning method for protein sequence design, ProteinMPNN, to design two-component tetrahedral protein nanomaterials and benchmark its performance against Rosetta. ProteinMPNN had a similar success rate to Rosetta, yielding 13 new experimentally confirmed assemblies, but required orders of magnitude less computation and no manual refinement. The interfaces designed by ProteinMPNN were substantially more polar than those designed by Rosetta, which facilitated in vitro assembly of the designed nanomaterials from independently purified components. Crystal structures of several of the assemblies confirmed the accuracy of the design method at high resolution. Our results showcase the potential of deep learning-based methods to unlock the widespread application of designed protein-protein interfaces and self-assembling protein nanomaterials in biotechnology.

Published

2024

4. Accurate computational design of three-dimensional protein crystals

Author

Li, Zhe, Wang, Shunzhi, Nattermann, Una, Bera, Asim K, Borst, Andrew J, Yaman, Muammer Y, Bick, Matthew J, Yang, Erin C, Sheffler, William, Lee, Byeongdu, Seifert, Soenke, Hura, Greg L, Nguyen, Hannah, Kang, Alex, Dalal, Radhika, Lubner, Joshua M, Hsia, Yang, Haddox, Hugh, Courbet, Alexis, Dowling, Quinton, Miranda, Marcos, Favor, Andrew, Etemadi, Ali, Edman, Natasha I, Yang, Wei, Weidle, Connor, Sankaran, Banumathi, Negahdari, Babak, Ross, Michael B, Ginger, David S, and Baker, David

Subjects

Inorganic Chemistry, Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Bioengineering, Proteins, Crystallization, Nanoscience & Nanotechnology

Abstract

Protein crystallization plays a central role in structural biology. Despite this, the process of crystallization remains poorly understood and highly empirical, with crystal contacts, lattice packing arrangements and space group preferences being largely unpredictable. Programming protein crystallization through precisely engineered side-chain-side-chain interactions across protein-protein interfaces is an outstanding challenge. Here we develop a general computational approach for designing three-dimensional protein crystals with prespecified lattice architectures at atomic accuracy that hierarchically constrains the overall number of degrees of freedom of the system. We design three pairs of oligomers that can be individually purified, and upon mixing, spontaneously self-assemble into >100 µm three-dimensional crystals. The structures of these crystals are nearly identical to the computational design models, closely corresponding in both overall architecture and the specific protein-protein interactions. The dimensions of the crystal unit cell can be systematically redesigned while retaining the space group symmetry and overall architecture, and the crystals are extremely porous and highly stable. Our approach enables the computational design of protein crystals with high accuracy, and the designed protein crystals, which have both structural and assembly information encoded in their primary sequences, provide a powerful platform for biological materials engineering.

Published

2023

5. De novo design of monomeric helical bundles for pH‐controlled membrane lysis

Author

Goldbach, Nicolas, Benna, Issa, Wicky, Basile IM, Croft, Jacob T, Carter, Lauren, Bera, Asim K, Nguyen, Hannah, Kang, Alex, Sankaran, Banumathi, Yang, Erin C, Lee, Kelly K, and Baker, David

Subjects

Biochemistry and Cell Biology, Biological Sciences, Bioengineering, Generic health relevance, Histidine, Liposomes, Protein Structure, Secondary, Hydrogen-Ion Concentration, coiled-coil, endosomal escape, membrane disruption, pH responsive, protein design, Computation Theory and Mathematics, Other Information and Computing Sciences, Biophysics, Biochemistry and cell biology, Medicinal and biomolecular chemistry

Abstract

Targeted intracellular delivery via receptor-mediated endocytosis requires the delivered cargo to escape the endosome to prevent lysosomal degradation. This can in principle be achieved by membrane lysis tightly restricted to endosomal membranes upon internalization to avoid general membrane insertion and lysis. Here, we describe the design of small monomeric proteins with buried histidine containing pH-responsive hydrogen bond networks and membrane permeating amphipathic helices. Of the 30 designs that were experimentally tested, all expressed in Escherichia coli, 13 were monomeric with the expected secondary structure, and 4 designs disrupted artificial liposomes in a pH-dependent manner. Mutational analysis showed that the buried histidine hydrogen bond networks mediate pH-responsiveness and control lysis of model membranes within a very narrow range of pH (6.0-5.5) with almost no lysis occurring at neutral pH. These tightly controlled lytic monomers could help mediate endosomal escape in designed targeted delivery platforms.

Published

2023

6. Rapid and automated design of two-component protein nanomaterials using ProteinMPNN

Author

de Haas, Robbert J., primary, Brunette, Natalie, additional, Goodson, Alex, additional, Dauparas, Justas, additional, Yi, Sue Y., additional, Yang, Erin C., additional, Dowling, Quinton, additional, Nguyen, Hannah, additional, Kang, Alex, additional, Bera, Asim K., additional, Sankaran, Banumathi, additional, de Vries, Renko, additional, Baker, David, additional, and King, Neil P., additional

Published

2023

7. Hierarchical design of pseudosymmetric protein nanoparticles

Author

Dowling, Quinton M., primary, Park, Young-Jun, additional, Gerstenmaier, Neil, additional, Yang, Erin C., additional, Wargacki, Adam, additional, Hsia, Yang, additional, Fries, Chelsea N., additional, Ravichandran, Rashmi, additional, Walkey, Carl, additional, Burrell, Anika, additional, Veesler, David, additional, Baker, David, additional, and King, Neil P., additional

Published

2023

8. 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

9. 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

10. Fast and versatile sequence-independent protein docking for nanomaterials design using RPXDock

Author

Sheffler, William, primary, Yang, Erin C., additional, Dowling, Quinton, additional, Hsia, Yang, additional, Fries, Chelsea N., additional, Stanislaw, Jenna, additional, Langowski, Mark D., additional, Brandys, Marisa, additional, Li, Zhe, additional, Skotheim, Rebecca, additional, Borst, Andrew J., additional, Khmelinskaia, Alena, additional, King, Neil P., additional, and Baker, David, additional

Published

2023

11. Computational design of non-porous, pH-responsive antibody nanoparticles

Author

Yang, Erin C., primary, Divine, Robby, additional, Miranda, Marcos C., additional, Borst, Andrew J., additional, Sheffler, Will, additional, Zhang, Jason Z, additional, Decarreau, Justin, additional, Saragovi, Amijai, additional, Abedi, Mohamad, additional, Goldbach, Nicolas, additional, Ahlrichs, Maggie, additional, Dobbins, Craig, additional, Hand, Alexis, additional, Cheng, Suna, additional, Lamb, Mila, additional, Levine, Paul M., additional, Chan, Sidney, additional, Skotheim, Rebecca, additional, Fallas, Jorge, additional, Ueda, George, additional, Lubner, Joshua, additional, Somiya, Masaharu, additional, Khmelinskaia, Alena, additional, King, Neil P., additional, and Baker, David, additional

Published

2023

12. Accurate Computational Design of 3D Protein Crystals

Author

Li, Zhe, primary, Wang, Shunzhi, additional, Nattermann, Una, additional, Bera, Asim K., additional, Borst, Andrew J., additional, Bick, Matthew J., additional, Yang, Erin C., additional, Sheffler, William, additional, Lee, Byeongdu, additional, Seifert, Soenke, additional, Nguyen, Hannah, additional, Kang, Alex, additional, Dalal, Radhika, additional, Lubner, Joshua M., additional, Hsia, Yang, additional, Haddox, Hugh, additional, Courbet, Alexis, additional, Dowling, Quinton, additional, Miranda, Marcos, additional, Favor, Andrew, additional, Etemadi, Ali, additional, Edman, Natasha I., additional, Yang, Wei, additional, Sankaran, Banumathi, additional, Negahdari, Babak, additional, and Baker, David, additional

Published

2022

13. Fast and versatile sequence-independent protein docking for nanomaterials design using RPXDock

Author

Sheffler, William, primary, Yang, Erin C., additional, Dowling, Quinton, additional, Hsia, Yang, additional, Fries, Chelsea N., additional, Stanislaw, Jenna, additional, Langowski, Mark, additional, Brandys, Marisa, additional, Khmelinskaia, Alena, additional, King, Neil P., additional, and Baker, David, additional

Published

2022

14. Increasing Computational Protein Design Literacy through Cohort-Based Learning for Undergraduate Students

Author

Yang, Erin C., primary, Divine, Robby, additional, Kang, Christine S., additional, Chan, Sidney, additional, Arenas, Elijah, additional, Subol, Zoe, additional, Tinker, Peter, additional, Manninen, Hayden, additional, Feichtenbiner, Alicia, additional, Mustafa, Talal, additional, Hallowell, Julia, additional, Orr, Isiac, additional, Haddox, Hugh, additional, Koepnick, Brian, additional, O’Connor, Jacob, additional, Haydon, Ian C., additional, Herpoldt, Karla-Luise, additional, Wormer, Kandise Van, additional, Abell, Celine, additional, Baker, David, additional, Khmelinskaia, Alena, additional, and King, Neil P., additional

Published

2022

15. Rapid and automated design of two-component protein nanomaterials using ProteinMPNN.

Author

de Haas RJ, Brunette N, Goodson A, Dauparas J, Yi SY, Yang EC, Dowling Q, Nguyen H, Kang A, Bera AK, Sankaran B, de Vries R, Baker D, and King NP

Abstract

The design of novel protein-protein interfaces using physics-based design methods such as Rosetta requires substantial computational resources and manual refinement by expert structural biologists. A new generation of deep learning methods promises to simplify protein-protein interface design and enable its application to a wide variety of problems by researchers from various scientific disciplines. Here we test the ability of a deep learning method for protein sequence design, ProteinMPNN, to design two-component tetrahedral protein nanomaterials and benchmark its performance against Rosetta. ProteinMPNN had a similar success rate to Rosetta, yielding 13 new experimentally confirmed assemblies, but required orders of magnitude less computation and no manual refinement. The interfaces designed by ProteinMPNN were substantially more polar than those designed by Rosetta, which facilitated in vitro assembly of the designed nanomaterials from independently purified components. Crystal structures of several of the assemblies confirmed the accuracy of the design method at high resolution. Our results showcase the potential of deep learning-based methods to unlock the widespread application of designed protein-protein interfaces and self-assembling protein nanomaterials in biotechnology.

Published

2023

16. Hierarchical design of pseudosymmetric protein nanoparticles.

Author

Dowling QM, Park YJ, Gerstenmaier N, Yang EC, Wargacki A, Hsia Y, Fries CN, Ravichandran R, Walkey C, Burrell A, Veesler D, Baker D, and King NP

Abstract

Discrete protein assemblies ranging from hundreds of kilodaltons to hundreds of megadaltons in size are a ubiquitous feature of biological systems and perform highly specialized functions 1-3 . Despite remarkable recent progress in accurately designing new self-assembling proteins, the size and complexity of these assemblies has been limited by a reliance on strict symmetry 4,5 . Inspired by the pseudosymmetry observed in bacterial microcompartments and viral capsids, we developed a hierarchical computational method for designing large pseudosymmetric self-assembling protein nanomaterials. We computationally designed pseudosymmetric heterooligomeric components and used them to create discrete, cage-like protein assemblies with icosahedral symmetry containing 240, 540, and 960 subunits. At 49, 71, and 96 nm diameter, these nanoparticles are the largest bounded computationally designed protein assemblies generated to date. More broadly, by moving beyond strict symmetry, our work represents an important step towards the accurate design of arbitrary self-assembling nanoscale protein objects., Competing Interests: Competing interests: N.P.K. is a cofounder, shareholder, paid consultant, and chair of the scientific advisory board of Icosavax, Inc. The King lab has received unrelated sponsored research agreements from Pfizer and GSK.

Published

2023

17. 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

18. Computational design of non-porous, pH-responsive antibody nanoparticles.

Author

Yang EC, Divine R, Miranda MC, Borst AJ, Sheffler W, Zhang JZ, Decarreau J, Saragovi A, Abedi M, Goldbach N, Ahlrichs M, Dobbins C, Hand A, Cheng S, Lamb M, Levine PM, Chan S, Skotheim R, Fallas J, Ueda G, Lubner J, Somiya M, Khmelinskaia A, King NP, and Baker D

Abstract

Programming protein nanomaterials to respond to changes in environmental conditions is a current challenge for protein design and important for targeted delivery of biologics. We describe the design of octahedral non-porous nanoparticles with the three symmetry axes (four-fold, three-fold, and two-fold) occupied by three distinct protein homooligomers: a de novo designed tetramer, an antibody of interest, and a designed trimer programmed to disassemble below a tunable pH transition point. The nanoparticles assemble cooperatively from independently purified components, and a cryo-EM density map reveals that the structure is very close to the computational design model. The designed nanoparticles can package a variety of molecular payloads, are endocytosed following antibody-mediated targeting of cell surface receptors, and undergo tunable pH-dependent disassembly at pH values ranging between to 5.9-6.7. To our knowledge, these are the first designed nanoparticles with more than two structural components and with finely tunable environmental sensitivity, and they provide new routes to antibody-directed targeted delivery., Competing Interests: Competing Interests Statement A provisional patent application has been filed (63/493,252) by the University of Washington, listing E.C.Y., R.D., J.L., W.S., G.U., J.F., N.P.K., and D.B. as inventors.

Published

2023