Growing Glycans in Rosetta: Accurate de novo glycan modeling, density fitting, and rational sequon design

Jared Adolf-Bryfogle; Jason W Labonte; John C Kraft; Maxim Shapovalov; Sebastian Raemisch; Thomas Lütteke; Frank DiMaio; Christopher D Bahl; Jesper Pallesen; Neil P King; Jeffrey J Gray; Daniel W Kulp; William R Schief

Growing Glycans in Rosetta: Accurate de novo glycan modeling, density fitting, and rational sequon design

Jared Adolf-Bryfogle
, Jason W Labonte
, John C Kraft
, Maxim Shapovalov
, Sebastian Raemisch
, Thomas Lütteke
, Frank DiMaio
, Christopher D Bahl
, Jesper Pallesen
, Neil P King
, Jeffrey J Gray
, Daniel W Kulp
, William R Schief

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

7 Scopus citations

Abstract

Carbohydrates and glycoproteins modulate key biological functions. However, experimental structure determination of sugar polymers is notoriously difficult. Computational approaches can aid in carbohydrate structure prediction, structure determination, and design. In this work, we developed a glycan-modeling algorithm, GlycanTreeModeler, that computationally builds glycans layer-by-layer, using adaptive kernel density estimates (KDE) of common glycan conformations derived from data in the Protein Data Bank (PDB) and from quantum mechanics (QM) calculations. GlycanTreeModeler was benchmarked on a test set of glycan structures of varying lengths, or "trees". Structures predicted by GlycanTreeModeler agreed with native structures at high accuracy for both de novo modeling and experimental density-guided building. We employed these tools to design de novo glycan trees into a protein nanoparticle vaccine to shield regions of the scaffold from antibody recognition, and experimentally verified shielding. This work will inform glycoprotein model prediction, glycan masking, and further aid computational methods in experimental structure determination and refinement.

Original language	English
Article number	e1011895
Pages (from-to)	e1011895
Journal	PLoS Computational Biology
Volume	20
Issue number	6
State	Published - Jun 2024
Externally published	Yes

Keywords

Polysaccharides/chemistry
Algorithms
Computational Biology/methods
Models, Molecular
Glycoproteins/chemistry
Databases, Protein
Software
Carbohydrate Conformation

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

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title = "Growing Glycans in Rosetta: Accurate de novo glycan modeling, density fitting, and rational sequon design",

abstract = "Carbohydrates and glycoproteins modulate key biological functions. However, experimental structure determination of sugar polymers is notoriously difficult. Computational approaches can aid in carbohydrate structure prediction, structure determination, and design. In this work, we developed a glycan-modeling algorithm, GlycanTreeModeler, that computationally builds glycans layer-by-layer, using adaptive kernel density estimates (KDE) of common glycan conformations derived from data in the Protein Data Bank (PDB) and from quantum mechanics (QM) calculations. GlycanTreeModeler was benchmarked on a test set of glycan structures of varying lengths, or {"}trees{"}. Structures predicted by GlycanTreeModeler agreed with native structures at high accuracy for both de novo modeling and experimental density-guided building. We employed these tools to design de novo glycan trees into a protein nanoparticle vaccine to shield regions of the scaffold from antibody recognition, and experimentally verified shielding. This work will inform glycoprotein model prediction, glycan masking, and further aid computational methods in experimental structure determination and refinement.",

keywords = "Polysaccharides/chemistry, Algorithms, Computational Biology/methods, Models, Molecular, Glycoproteins/chemistry, Databases, Protein, Software, Carbohydrate Conformation",

author = "Jared Adolf-Bryfogle and Labonte, \{Jason W\} and Kraft, \{John C\} and Maxim Shapovalov and Sebastian Raemisch and Thomas L{\"u}tteke and Frank DiMaio and Bahl, \{Christopher D\} and Jesper Pallesen and King, \{Neil P\} and Gray, \{Jeffrey J\} and Kulp, \{Daniel W\} and Schief, \{William R\}",

note = "Copyright: {\textcopyright} 2024 Adolf-Bryfogle et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.",

year = "2024",

month = jun,

language = "English",

volume = "20",

pages = "e1011895",

journal = "PLoS Computational Biology",

issn = "1553-734X",

publisher = "Public Library of Science",

number = "6",

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TY - JOUR

T1 - Growing Glycans in Rosetta

T2 - Accurate de novo glycan modeling, density fitting, and rational sequon design

AU - Adolf-Bryfogle, Jared

AU - Labonte, Jason W

AU - Kraft, John C

AU - Shapovalov, Maxim

AU - Raemisch, Sebastian

AU - Lütteke, Thomas

AU - DiMaio, Frank

AU - Bahl, Christopher D

AU - Pallesen, Jesper

AU - King, Neil P

AU - Gray, Jeffrey J

AU - Kulp, Daniel W

AU - Schief, William R

N1 - Copyright: © 2024 Adolf-Bryfogle et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

PY - 2024/6

Y1 - 2024/6

N2 - Carbohydrates and glycoproteins modulate key biological functions. However, experimental structure determination of sugar polymers is notoriously difficult. Computational approaches can aid in carbohydrate structure prediction, structure determination, and design. In this work, we developed a glycan-modeling algorithm, GlycanTreeModeler, that computationally builds glycans layer-by-layer, using adaptive kernel density estimates (KDE) of common glycan conformations derived from data in the Protein Data Bank (PDB) and from quantum mechanics (QM) calculations. GlycanTreeModeler was benchmarked on a test set of glycan structures of varying lengths, or "trees". Structures predicted by GlycanTreeModeler agreed with native structures at high accuracy for both de novo modeling and experimental density-guided building. We employed these tools to design de novo glycan trees into a protein nanoparticle vaccine to shield regions of the scaffold from antibody recognition, and experimentally verified shielding. This work will inform glycoprotein model prediction, glycan masking, and further aid computational methods in experimental structure determination and refinement.

AB - Carbohydrates and glycoproteins modulate key biological functions. However, experimental structure determination of sugar polymers is notoriously difficult. Computational approaches can aid in carbohydrate structure prediction, structure determination, and design. In this work, we developed a glycan-modeling algorithm, GlycanTreeModeler, that computationally builds glycans layer-by-layer, using adaptive kernel density estimates (KDE) of common glycan conformations derived from data in the Protein Data Bank (PDB) and from quantum mechanics (QM) calculations. GlycanTreeModeler was benchmarked on a test set of glycan structures of varying lengths, or "trees". Structures predicted by GlycanTreeModeler agreed with native structures at high accuracy for both de novo modeling and experimental density-guided building. We employed these tools to design de novo glycan trees into a protein nanoparticle vaccine to shield regions of the scaffold from antibody recognition, and experimentally verified shielding. This work will inform glycoprotein model prediction, glycan masking, and further aid computational methods in experimental structure determination and refinement.

KW - Polysaccharides/chemistry

KW - Algorithms

KW - Computational Biology/methods

KW - Models, Molecular

KW - Glycoproteins/chemistry

KW - Databases, Protein

KW - Software

KW - Carbohydrate Conformation

M3 - Article

C2 - 38913746

SN - 1553-734X

VL - 20

SP - e1011895

JO - PLoS Computational Biology

JF - PLoS Computational Biology

IS - 6

M1 - e1011895

ER -

Growing Glycans in Rosetta: Accurate de novo glycan modeling, density fitting, and rational sequon design

Abstract

Keywords

UN SDGs

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