Role of N343 glycosylation on the SARS-CoV-2 S RBD structure and co-receptor binding across variants of concern
Role of N343 glycosylation on the SARS-CoV-2 S RBD structure and co-receptor binding across variants of concern
Glycosylation of the SARS-CoV-2 spike (S) protein represents a key target for viral evolution because it affects both viral evasion and fitness. Successful variations in the glycan shield are difficult to achieve though, as protein glycosylation is also critical to folding and structural stability. Within this framework, the identification of glycosylation sites that are structurally dispensable can provide insight into the evolutionary mechanisms of the shield and inform immune surveillance. In this work, we show through over 45 μs of cumulative sampling from conventional and enhanced molecular dynamics (MD) simulations, how the structure of the immunodominant S receptor binding domain (RBD) is regulated by N-glycosylation at N343 and how this glycan's structural role changes from WHu-1, alpha (B.1.1.7), and beta (B.1.351), to the delta (B.1.617.2), and omicron (BA.1 and BA.2.86) variants. More specifically, we find that the amphipathic nature of the N-glycan is instrumental to preserve the structural integrity of the RBD hydrophobic core and that loss of glycosylation at N343 triggers a specific and consistent conformational change. We show how this change allosterically regulates the conformation of the receptor binding motif (RBM) in the WHu-1, alpha, and beta RBDs, but not in the delta and omicron variants, due to mutations that reinforce the RBD architecture. In support of these findings, we show that the binding of the RBD to monosialylated ganglioside co-receptors is highly dependent on N343 glycosylation in the WHu-1, but not in the delta RBD, and that affinity changes significantly across VoCs. Ultimately, the molecular and functional insight we provide in this work reinforces our understanding of the role of glycosylation in protein structure and function and it also allows us to identify the structural constraints within which the glycosylation site at N343 can become a hotspot for mutations in the SARS-CoV-2 S glycan shield.
COVID-19, RBD, SARS-CoV-2, glycosylation, human, molecular biophysics, receptor binding domain, spike, structural biology, variants
Ives, Callum M.
b8c798a7-ddf0-40ac-8194-c757032b85e2
Nguyen, Linh
145a12e0-c5d9-40a1-bb62-fd2d4b963e89
Fogarty, Carl A.
33e6619c-776e-4c6c-9161-bd0128e1d5ac
Harbison, Aoife M.
bc5281e0-038d-4b73-b15b-b60396a88e9c
Durocher, Yves
834f2701-3e32-4a41-ab6a-f2d3549d1970
Klassen, John
e24763a3-e792-45d0-abdf-a7d30fa3ba5e
Fadda, Elisa
11ba1755-9585-44aa-a38e-a8bcfd766abb
12 June 2024
Ives, Callum M.
b8c798a7-ddf0-40ac-8194-c757032b85e2
Nguyen, Linh
145a12e0-c5d9-40a1-bb62-fd2d4b963e89
Fogarty, Carl A.
33e6619c-776e-4c6c-9161-bd0128e1d5ac
Harbison, Aoife M.
bc5281e0-038d-4b73-b15b-b60396a88e9c
Durocher, Yves
834f2701-3e32-4a41-ab6a-f2d3549d1970
Klassen, John
e24763a3-e792-45d0-abdf-a7d30fa3ba5e
Fadda, Elisa
11ba1755-9585-44aa-a38e-a8bcfd766abb
Ives, Callum M., Nguyen, Linh, Fogarty, Carl A., Harbison, Aoife M., Durocher, Yves, Klassen, John and Fadda, Elisa
(2024)
Role of N343 glycosylation on the SARS-CoV-2 S RBD structure and co-receptor binding across variants of concern.
eLife, 13, [95708].
(doi:10.7554/eLife.95708).
Abstract
Glycosylation of the SARS-CoV-2 spike (S) protein represents a key target for viral evolution because it affects both viral evasion and fitness. Successful variations in the glycan shield are difficult to achieve though, as protein glycosylation is also critical to folding and structural stability. Within this framework, the identification of glycosylation sites that are structurally dispensable can provide insight into the evolutionary mechanisms of the shield and inform immune surveillance. In this work, we show through over 45 μs of cumulative sampling from conventional and enhanced molecular dynamics (MD) simulations, how the structure of the immunodominant S receptor binding domain (RBD) is regulated by N-glycosylation at N343 and how this glycan's structural role changes from WHu-1, alpha (B.1.1.7), and beta (B.1.351), to the delta (B.1.617.2), and omicron (BA.1 and BA.2.86) variants. More specifically, we find that the amphipathic nature of the N-glycan is instrumental to preserve the structural integrity of the RBD hydrophobic core and that loss of glycosylation at N343 triggers a specific and consistent conformational change. We show how this change allosterically regulates the conformation of the receptor binding motif (RBM) in the WHu-1, alpha, and beta RBDs, but not in the delta and omicron variants, due to mutations that reinforce the RBD architecture. In support of these findings, we show that the binding of the RBD to monosialylated ganglioside co-receptors is highly dependent on N343 glycosylation in the WHu-1, but not in the delta RBD, and that affinity changes significantly across VoCs. Ultimately, the molecular and functional insight we provide in this work reinforces our understanding of the role of glycosylation in protein structure and function and it also allows us to identify the structural constraints within which the glycosylation site at N343 can become a hotspot for mutations in the SARS-CoV-2 S glycan shield.
Text
elife-95708-v1
- Version of Record
More information
Published date: 12 June 2024
Keywords:
COVID-19, RBD, SARS-CoV-2, glycosylation, human, molecular biophysics, receptor binding domain, spike, structural biology, variants
Identifiers
Local EPrints ID: 491752
URI: http://eprints.soton.ac.uk/id/eprint/491752
ISSN: 2050-084X
PURE UUID: 47225716-e29a-49c9-b6f1-7cf60b140773
Catalogue record
Date deposited: 03 Jul 2024 17:09
Last modified: 12 Jul 2024 02:16
Export record
Altmetrics
Contributors
Author:
Callum M. Ives
Author:
Linh Nguyen
Author:
Carl A. Fogarty
Author:
Aoife M. Harbison
Author:
Yves Durocher
Author:
John Klassen
Author:
Elisa Fadda
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics