Stimulus-responsive self-assembly of protein-based fractals by computational design

Nancy E. Hernández; William A. Hansen; Denzel Zhu; Maria E. Shea; Marium Khalid; Viacheslav Manichev; Matthew Putnins; Muyuan Chen; Anthony G. Dodge; Lu Yang; Ileana Marrero-Berríos; Melissa Banal; Phillip Rechani; Torgny Gustafsson; Leonard C. Feldman; Sang Hyuk Lee; Lawrence P. Wackett; Wei Dai; Sagar D. Khare

doi:10.1038/s41557-019-0277-y

Stimulus-responsive self-assembly of protein-based fractals by computational design

Nancy E. Hernández
, William A. Hansen
, Denzel Zhu
, Maria E. Shea
, Marium Khalid
, Viacheslav Manichev
, Matthew Putnins
, Muyuan Chen
, Anthony G. Dodge
, Lu Yang
, Ileana Marrero-Berríos
, Melissa Banal
, Phillip Rechani
, Torgny Gustafsson
, Leonard C. Feldman
, Sang Hyuk Lee
, Lawrence P. Wackett
, Wei Dai
, Sagar D. Khare

Research output: Contribution to journal › Article › peer-review

38 Scopus citations

Abstract

Fractal topologies, which are statistically self-similar over multiple length scales, are pervasive in nature. The recurrence of patterns in fractal-shaped branched objects, such as trees, lungs and sponges, results in a high surface area to volume ratio, which provides key functional advantages including molecular trapping and exchange. Mimicking these topologies in designed protein-based assemblies could provide access to functional biomaterials. Here we describe a computational design approach for the reversible self-assembly of proteins into tunable supramolecular fractal-like topologies in response to phosphorylation. Guided by atomic-resolution models, we develop fusions of Src homology 2 (SH2) domain or a phosphorylatable SH2-binding peptide, respectively, to two symmetric, homo-oligomeric proteins. Mixing the two designed components resulted in a variety of dendritic, hyperbranched and sponge-like topologies that are phosphorylation-dependent and self-similar over three decades (~10 nm–10 μm) of length scale, in agreement with models from multiscale computational simulations. Designed assemblies perform efficient phosphorylation-dependent capture and release of cargo proteins.

Original language	English (US)
Pages (from-to)	605-614
Number of pages	10
Journal	Nature Chemistry
Volume	11
Issue number	7
DOIs	https://doi.org/10.1038/s41557-019-0277-y
State	Published - Jul 1 2019

Bibliographical note

Funding Information:
The authors acknowledge support from the NSF (1330760 to S.D.K. and L.W.; DGE-1433187 to N.E.H.; 1429062 to S.D.K.) and the NIH (R01GM080139 to M.C.). Cryoelectron microscopy was supported by the Rutgers New Jersey CryoEM/ET Core Facility. The authors thank J. Chodera for providing Src kinase and YopH phosphatase plasmids, V. Nanda, K.-B. Lee, G. Montelione, H. Cho, M. Liu, A. Permaul, O. Dineen, I. Patel and R. Patel for experimental assistance, and E. Tinberg, V. Nanda and D. Baker for helpful discussions.

Publisher Copyright:
© 2019, The Author(s), under exclusive licence to Springer Nature Limited.

Publisher link

10.1038/s41557-019-0277-y

Find It

Find It at U of M Libraries

Cite this

Hernández, N. E., Hansen, W. A., Zhu, D., Shea, M. E., Khalid, M., Manichev, V., Putnins, M., Chen, M., Dodge, A. G., Yang, L., Marrero-Berríos, I., Banal, M., Rechani, P., Gustafsson, T., Feldman, L. C., Lee, S. H., Wackett, L. P., Dai, W., & Khare, S. D. (2019). Stimulus-responsive self-assembly of protein-based fractals by computational design. Nature Chemistry, 11(7), 605-614. https://doi.org/10.1038/s41557-019-0277-y

Hernández, NE, Hansen, WA, Zhu, D, Shea, ME, Khalid, M, Manichev, V, Putnins, M, Chen, M, Dodge, AG, Yang, L, Marrero-Berríos, I, Banal, M, Rechani, P, Gustafsson, T, Feldman, LC, Lee, SH, Wackett, LP, Dai, W & Khare, SD 2019, 'Stimulus-responsive self-assembly of protein-based fractals by computational design', Nature Chemistry, vol. 11, no. 7, pp. 605-614. https://doi.org/10.1038/s41557-019-0277-y

@article{2651a0a661444c15b4b98c29bde39639,

title = "Stimulus-responsive self-assembly of protein-based fractals by computational design",

abstract = "Fractal topologies, which are statistically self-similar over multiple length scales, are pervasive in nature. The recurrence of patterns in fractal-shaped branched objects, such as trees, lungs and sponges, results in a high surface area to volume ratio, which provides key functional advantages including molecular trapping and exchange. Mimicking these topologies in designed protein-based assemblies could provide access to functional biomaterials. Here we describe a computational design approach for the reversible self-assembly of proteins into tunable supramolecular fractal-like topologies in response to phosphorylation. Guided by atomic-resolution models, we develop fusions of Src homology 2 (SH2) domain or a phosphorylatable SH2-binding peptide, respectively, to two symmetric, homo-oligomeric proteins. Mixing the two designed components resulted in a variety of dendritic, hyperbranched and sponge-like topologies that are phosphorylation-dependent and self-similar over three decades (\textasciitilde{}10 nm–10 μm) of length scale, in agreement with models from multiscale computational simulations. Designed assemblies perform efficient phosphorylation-dependent capture and release of cargo proteins.",

author = "Hern{\'a}ndez, \{Nancy E.\} and Hansen, \{William A.\} and Denzel Zhu and Shea, \{Maria E.\} and Marium Khalid and Viacheslav Manichev and Matthew Putnins and Muyuan Chen and Dodge, \{Anthony G.\} and Lu Yang and Ileana Marrero-Berr{\'i}os and Melissa Banal and Phillip Rechani and Torgny Gustafsson and Feldman, \{Leonard C.\} and Lee, \{Sang Hyuk\} and Wackett, \{Lawrence P.\} and Wei Dai and Khare, \{Sagar D.\}",

note = "Funding Information: The authors acknowledge support from the NSF (1330760 to S.D.K. and L.W.; DGE-1433187 to N.E.H.; 1429062 to S.D.K.) and the NIH (R01GM080139 to M.C.). Cryoelectron microscopy was supported by the Rutgers New Jersey CryoEM/ET Core Facility. The authors thank J. Chodera for providing Src kinase and YopH phosphatase plasmids, V. Nanda, K.-B. Lee, G. Montelione, H. Cho, M. Liu, A. Permaul, O. Dineen, I. Patel and R. Patel for experimental assistance, and E. Tinberg, V. Nanda and D. Baker for helpful discussions. Publisher Copyright: {\textcopyright} 2019, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2019",

month = jul,

day = "1",

doi = "10.1038/s41557-019-0277-y",

language = "English (US)",

volume = "11",

pages = "605--614",

journal = "Nature Chemistry",

issn = "1755-4330",

publisher = "Nature Publishing Group",

number = "7",

}

TY - JOUR

T1 - Stimulus-responsive self-assembly of protein-based fractals by computational design

AU - Hernández, Nancy E.

AU - Hansen, William A.

AU - Zhu, Denzel

AU - Shea, Maria E.

AU - Khalid, Marium

AU - Manichev, Viacheslav

AU - Putnins, Matthew

AU - Chen, Muyuan

AU - Dodge, Anthony G.

AU - Yang, Lu

AU - Marrero-Berríos, Ileana

AU - Banal, Melissa

AU - Rechani, Phillip

AU - Gustafsson, Torgny

AU - Feldman, Leonard C.

AU - Lee, Sang Hyuk

AU - Wackett, Lawrence P.

AU - Dai, Wei

AU - Khare, Sagar D.

N1 - Funding Information: The authors acknowledge support from the NSF (1330760 to S.D.K. and L.W.; DGE-1433187 to N.E.H.; 1429062 to S.D.K.) and the NIH (R01GM080139 to M.C.). Cryoelectron microscopy was supported by the Rutgers New Jersey CryoEM/ET Core Facility. The authors thank J. Chodera for providing Src kinase and YopH phosphatase plasmids, V. Nanda, K.-B. Lee, G. Montelione, H. Cho, M. Liu, A. Permaul, O. Dineen, I. Patel and R. Patel for experimental assistance, and E. Tinberg, V. Nanda and D. Baker for helpful discussions. Publisher Copyright: © 2019, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2019/7/1

Y1 - 2019/7/1

N2 - Fractal topologies, which are statistically self-similar over multiple length scales, are pervasive in nature. The recurrence of patterns in fractal-shaped branched objects, such as trees, lungs and sponges, results in a high surface area to volume ratio, which provides key functional advantages including molecular trapping and exchange. Mimicking these topologies in designed protein-based assemblies could provide access to functional biomaterials. Here we describe a computational design approach for the reversible self-assembly of proteins into tunable supramolecular fractal-like topologies in response to phosphorylation. Guided by atomic-resolution models, we develop fusions of Src homology 2 (SH2) domain or a phosphorylatable SH2-binding peptide, respectively, to two symmetric, homo-oligomeric proteins. Mixing the two designed components resulted in a variety of dendritic, hyperbranched and sponge-like topologies that are phosphorylation-dependent and self-similar over three decades (~10 nm–10 μm) of length scale, in agreement with models from multiscale computational simulations. Designed assemblies perform efficient phosphorylation-dependent capture and release of cargo proteins.

AB - Fractal topologies, which are statistically self-similar over multiple length scales, are pervasive in nature. The recurrence of patterns in fractal-shaped branched objects, such as trees, lungs and sponges, results in a high surface area to volume ratio, which provides key functional advantages including molecular trapping and exchange. Mimicking these topologies in designed protein-based assemblies could provide access to functional biomaterials. Here we describe a computational design approach for the reversible self-assembly of proteins into tunable supramolecular fractal-like topologies in response to phosphorylation. Guided by atomic-resolution models, we develop fusions of Src homology 2 (SH2) domain or a phosphorylatable SH2-binding peptide, respectively, to two symmetric, homo-oligomeric proteins. Mixing the two designed components resulted in a variety of dendritic, hyperbranched and sponge-like topologies that are phosphorylation-dependent and self-similar over three decades (~10 nm–10 μm) of length scale, in agreement with models from multiscale computational simulations. Designed assemblies perform efficient phosphorylation-dependent capture and release of cargo proteins.

UR - https://www.scopus.com/pages/publications/85067657324

UR - https://www.scopus.com/pages/publications/85067657324#tab=citedBy

U2 - 10.1038/s41557-019-0277-y

DO - 10.1038/s41557-019-0277-y

M3 - Article

C2 - 31209296

AN - SCOPUS:85067657324

SN - 1755-4330

VL - 11

SP - 605

EP - 614

JO - Nature Chemistry

JF - Nature Chemistry

IS - 7

ER -

Stimulus-responsive self-assembly of protein-based fractals by computational design

Abstract

Bibliographical note

Publisher link

Find It

Other files and links

Fingerprint

Cite this