Unraveling the impact of SARS-CoV-2 mutations on immunity: insights from innate immune recognition to antibody and T cell responses

Rafael Bayarri-Olmos; Adrian Sutta; Anne Rosbjerg; Mie Mandal Mortensen; Charlotte Helgstrand; Per Franklin Nielsen; Laura Pérez-Alós; Beatriz González-García; Laust Bruun Johnsen; Finn Matthiesen; Thomas Egebjerg; Cecilie Bo Hansen; Alessandro Sette; Alba Grifoni; Ricardo da Silva Antunes; Peter Garred

doi:10.3389/fimmu.2024.1412873

Unraveling the impact of SARS-CoV-2 mutations on immunity: insights from innate immune recognition to antibody and T cell responses

Rafael Bayarri-Olmos^*, Adrian Sutta, Anne Rosbjerg, Mie Mandal Mortensen, Charlotte Helgstrand, Per Franklin Nielsen, Laura Pérez-Alós, Beatriz González-García, Laust Bruun Johnsen, Finn Matthiesen, Thomas Egebjerg, Cecilie Bo Hansen, Alessandro Sette, Alba Grifoni, Ricardo da Silva Antunes, Peter Garred

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › peer-review

Abstract

Throughout the COVID-19 pandemic, the emergence of new viral variants has challenged public health efforts, often evading antibody responses generated by infections and vaccinations. This immune escape has led to waves of breakthrough infections, raising questions about the efficacy and durability of immune protection. Here we focus on the impact of SARS-CoV-2 Delta and Omicron spike mutations on ACE-2 receptor binding, protein stability, and immune response evasion. Delta and Omicron variants had 3–5 times higher binding affinities to ACE-2 than the ancestral strain (KD_wt = 23.4 nM, KD_Delta = 8.08 nM, KD_BA.1 = 4.77 nM, KD_BA.2 = 4.47 nM). The pattern recognition molecule mannose-binding lectin (MBL) has been shown to recognize the spike protein. Here we found that MBL binding remained largely unchanged across the variants, even after introducing mutations at single glycan sites. Although MBL binding decreased post-vaccination, it increased by 2.6-fold upon IgG depletion, suggesting a compensatory or redundant role in immune recognition. Notably, we identified two glycan sites (N717 and N801) as potentially essential for the structural integrity of the spike protein. We also evaluated the antibody and T cell responses. Neutralization by serum immunoglobulins was predominantly mediated by IgG rather than IgA and was markedly impaired against the Delta (5.8-fold decrease) and Omicron variants BA.1 (17.4-fold) and BA.2 (14.2-fold). T cell responses, initially conserved, waned rapidly within 3 months post-Omicron infection. Our data suggests that immune imprinting may have hindered antibody and T cell responses toward the variants. Overall, despite decreased antibody neutralization, MBL recognition and T cell responses were generally unaffected by the variants. These findings extend our understanding of the complex interplay between viral adaptation and immune response, underscoring the importance of considering MBL interactions, immune imprinting, and viral evolution dynamics in developing new vaccine and treatment strategies.

Original language	English
Article number	1412873
Journal	Frontiers in Immunology
Volume	15
Number of pages	23
ISSN	1664-3224
DOIs	https://doi.org/10.3389/fimmu.2024.1412873
Publication status	Published - 2024

Bibliographical note

Publisher Copyright:
Copyright © 2024 Bayarri-Olmos, Sutta, Rosbjerg, Mortensen, Helgstrand, Nielsen, Pérez-Alós, González-García, Johnsen, Matthiesen, Egebjerg, Hansen, Sette, Grifoni, Antunes and Garred.

Keywords

delta
immune imprinting
mannose-binding lectin
MBL
omicron
SARS-CoV-2
vaccine
variants of concern

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10.3389/fimmu.2024.1412873Licence: CC BY

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Cite this

Bayarri-Olmos, R., Sutta, A., Rosbjerg, A., Mortensen, M. M., Helgstrand, C., Nielsen, P. F., Pérez-Alós, L., González-García, B., Johnsen, L. B., Matthiesen, F., Egebjerg, T., Hansen, C. B., Sette, A., Grifoni, A., Antunes, R. D. S., & Garred, P. (2024). Unraveling the impact of SARS-CoV-2 mutations on immunity: insights from innate immune recognition to antibody and T cell responses. Frontiers in Immunology, 15, [1412873]. https://doi.org/10.3389/fimmu.2024.1412873

Unraveling the impact of SARS-CoV-2 mutations on immunity : insights from innate immune recognition to antibody and T cell responses. / Bayarri-Olmos, Rafael; Sutta, Adrian; Rosbjerg, Anne; Mortensen, Mie Mandal; Helgstrand, Charlotte; Nielsen, Per Franklin; Pérez-Alós, Laura; González-García, Beatriz; Johnsen, Laust Bruun; Matthiesen, Finn; Egebjerg, Thomas; Hansen, Cecilie Bo; Sette, Alessandro; Grifoni, Alba; Antunes, Ricardo da Silva; Garred, Peter.

In: Frontiers in Immunology, Vol. 15, 1412873, 2024.

Research output: Contribution to journal › Journal article › peer-review

Bayarri-Olmos, R, Sutta, A, Rosbjerg, A, Mortensen, MM, Helgstrand, C, Nielsen, PF, Pérez-Alós, L, González-García, B, Johnsen, LB, Matthiesen, F, Egebjerg, T, Hansen, CB, Sette, A, Grifoni, A, Antunes, RDS & Garred, P 2024, 'Unraveling the impact of SARS-CoV-2 mutations on immunity: insights from innate immune recognition to antibody and T cell responses', Frontiers in Immunology, vol. 15, 1412873. https://doi.org/10.3389/fimmu.2024.1412873

Bayarri-Olmos, Rafael ; Sutta, Adrian ; Rosbjerg, Anne ; Mortensen, Mie Mandal ; Helgstrand, Charlotte ; Nielsen, Per Franklin ; Pérez-Alós, Laura ; González-García, Beatriz ; Johnsen, Laust Bruun ; Matthiesen, Finn ; Egebjerg, Thomas ; Hansen, Cecilie Bo ; Sette, Alessandro ; Grifoni, Alba ; Antunes, Ricardo da Silva ; Garred, Peter. / Unraveling the impact of SARS-CoV-2 mutations on immunity : insights from innate immune recognition to antibody and T cell responses. In: Frontiers in Immunology. 2024 ; Vol. 15.

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abstract = "Throughout the COVID-19 pandemic, the emergence of new viral variants has challenged public health efforts, often evading antibody responses generated by infections and vaccinations. This immune escape has led to waves of breakthrough infections, raising questions about the efficacy and durability of immune protection. Here we focus on the impact of SARS-CoV-2 Delta and Omicron spike mutations on ACE-2 receptor binding, protein stability, and immune response evasion. Delta and Omicron variants had 3–5 times higher binding affinities to ACE-2 than the ancestral strain (KDwt = 23.4 nM, KDDelta = 8.08 nM, KDBA.1 = 4.77 nM, KDBA.2 = 4.47 nM). The pattern recognition molecule mannose-binding lectin (MBL) has been shown to recognize the spike protein. Here we found that MBL binding remained largely unchanged across the variants, even after introducing mutations at single glycan sites. Although MBL binding decreased post-vaccination, it increased by 2.6-fold upon IgG depletion, suggesting a compensatory or redundant role in immune recognition. Notably, we identified two glycan sites (N717 and N801) as potentially essential for the structural integrity of the spike protein. We also evaluated the antibody and T cell responses. Neutralization by serum immunoglobulins was predominantly mediated by IgG rather than IgA and was markedly impaired against the Delta (5.8-fold decrease) and Omicron variants BA.1 (17.4-fold) and BA.2 (14.2-fold). T cell responses, initially conserved, waned rapidly within 3 months post-Omicron infection. Our data suggests that immune imprinting may have hindered antibody and T cell responses toward the variants. Overall, despite decreased antibody neutralization, MBL recognition and T cell responses were generally unaffected by the variants. These findings extend our understanding of the complex interplay between viral adaptation and immune response, underscoring the importance of considering MBL interactions, immune imprinting, and viral evolution dynamics in developing new vaccine and treatment strategies.",

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AU - Nielsen, Per Franklin

AU - Pérez-Alós, Laura

AU - González-García, Beatriz

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AU - Matthiesen, Finn

AU - Egebjerg, Thomas

AU - Hansen, Cecilie Bo

AU - Sette, Alessandro

AU - Grifoni, Alba

AU - Antunes, Ricardo da Silva

AU - Garred, Peter

N1 - Publisher Copyright: Copyright © 2024 Bayarri-Olmos, Sutta, Rosbjerg, Mortensen, Helgstrand, Nielsen, Pérez-Alós, González-García, Johnsen, Matthiesen, Egebjerg, Hansen, Sette, Grifoni, Antunes and Garred.

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N2 - Throughout the COVID-19 pandemic, the emergence of new viral variants has challenged public health efforts, often evading antibody responses generated by infections and vaccinations. This immune escape has led to waves of breakthrough infections, raising questions about the efficacy and durability of immune protection. Here we focus on the impact of SARS-CoV-2 Delta and Omicron spike mutations on ACE-2 receptor binding, protein stability, and immune response evasion. Delta and Omicron variants had 3–5 times higher binding affinities to ACE-2 than the ancestral strain (KDwt = 23.4 nM, KDDelta = 8.08 nM, KDBA.1 = 4.77 nM, KDBA.2 = 4.47 nM). The pattern recognition molecule mannose-binding lectin (MBL) has been shown to recognize the spike protein. Here we found that MBL binding remained largely unchanged across the variants, even after introducing mutations at single glycan sites. Although MBL binding decreased post-vaccination, it increased by 2.6-fold upon IgG depletion, suggesting a compensatory or redundant role in immune recognition. Notably, we identified two glycan sites (N717 and N801) as potentially essential for the structural integrity of the spike protein. We also evaluated the antibody and T cell responses. Neutralization by serum immunoglobulins was predominantly mediated by IgG rather than IgA and was markedly impaired against the Delta (5.8-fold decrease) and Omicron variants BA.1 (17.4-fold) and BA.2 (14.2-fold). T cell responses, initially conserved, waned rapidly within 3 months post-Omicron infection. Our data suggests that immune imprinting may have hindered antibody and T cell responses toward the variants. Overall, despite decreased antibody neutralization, MBL recognition and T cell responses were generally unaffected by the variants. These findings extend our understanding of the complex interplay between viral adaptation and immune response, underscoring the importance of considering MBL interactions, immune imprinting, and viral evolution dynamics in developing new vaccine and treatment strategies.

AB - Throughout the COVID-19 pandemic, the emergence of new viral variants has challenged public health efforts, often evading antibody responses generated by infections and vaccinations. This immune escape has led to waves of breakthrough infections, raising questions about the efficacy and durability of immune protection. Here we focus on the impact of SARS-CoV-2 Delta and Omicron spike mutations on ACE-2 receptor binding, protein stability, and immune response evasion. Delta and Omicron variants had 3–5 times higher binding affinities to ACE-2 than the ancestral strain (KDwt = 23.4 nM, KDDelta = 8.08 nM, KDBA.1 = 4.77 nM, KDBA.2 = 4.47 nM). The pattern recognition molecule mannose-binding lectin (MBL) has been shown to recognize the spike protein. Here we found that MBL binding remained largely unchanged across the variants, even after introducing mutations at single glycan sites. Although MBL binding decreased post-vaccination, it increased by 2.6-fold upon IgG depletion, suggesting a compensatory or redundant role in immune recognition. Notably, we identified two glycan sites (N717 and N801) as potentially essential for the structural integrity of the spike protein. We also evaluated the antibody and T cell responses. Neutralization by serum immunoglobulins was predominantly mediated by IgG rather than IgA and was markedly impaired against the Delta (5.8-fold decrease) and Omicron variants BA.1 (17.4-fold) and BA.2 (14.2-fold). T cell responses, initially conserved, waned rapidly within 3 months post-Omicron infection. Our data suggests that immune imprinting may have hindered antibody and T cell responses toward the variants. Overall, despite decreased antibody neutralization, MBL recognition and T cell responses were generally unaffected by the variants. These findings extend our understanding of the complex interplay between viral adaptation and immune response, underscoring the importance of considering MBL interactions, immune imprinting, and viral evolution dynamics in developing new vaccine and treatment strategies.

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