MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats

Dominik W. Schmid; Magdalena Meyer; Kerstin Wilhelm; Tatiana Tilley; Thomas Link-Hessing; Ramona Fleischer; Ebenezer K. Badu; Evans Ewald Nkrumah; Samuel Kingsley Oppong; Nina Schwensow; Marco Tschapka; Heather J. Baldwin; Peter Vallo; Victor M. Corman; Christian Drosten; Simone Sommer

doi:10.1111/mec.16983

MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats

Dominik W. Schmid^*, Magdalena Meyer, Kerstin Wilhelm, Tatiana Tilley, Thomas Link-Hessing, Ramona Fleischer, Ebenezer K. Badu, Evans Ewald Nkrumah, Samuel Kingsley Oppong, Nina Schwensow, Marco Tschapka, Heather J. Baldwin, Peter Vallo, Victor M. Corman, Christian Drosten, Simone Sommer

^*Corresponding author for this work

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

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Abstract

Understanding the immunogenetic basis of coronavirus (CoV) susceptibility in major pathogen reservoirs, such as bats, is central to inferring their zoonotic potential. Members of the cryptic Hipposideros bat species complex differ in CoV susceptibility, but the underlying mechanisms remain unclear. The genes of the major histocompatibility complex (MHC) are the best understood genetic basis of pathogen resistance, and differences in MHC diversity are one possible reason for asymmetrical infection patterns among closely related species. Here, we aimed to link asymmetries in observed CoV (CoV-229E, CoV-2B and CoV-2Bbasal) susceptibility to immunogenetic differences amongst four Hipposideros bat species. From the 2072 bats assigned to their respective species using the mtDNA cytochrome b gene, members of the most numerous and ubiquitous species, Hipposideros caffer D, were most infected with CoV-229E and SARS-related CoV-2B. Using a subset of 569 bats, we determined that much of the existent allelic and functional (i.e. supertype) MHC DRB class II diversity originated from common ancestry. One MHC supertype shared amongst all species, ST12, was consistently linked to susceptibility with CoV-229E, which is closely related to the common cold agent HCoV-229E, and infected bats and those carrying ST12 had a lower body condition. The same MHC supertype was connected to resistance to CoV-2B, and bats with ST12 were less likely be co-infected with CoV-229E and CoV-2B. Our work suggests a role of immunogenetics in determining CoV susceptibility in bats. We advocate for the preservation of functional genetic and species diversity in reservoirs as a means of mitigating the risk of disease spillover.

Original language	English
Pages (from-to)	3989-4002
Number of pages	14
Journal	Molecular Ecology
Volume	32
Issue number	14
Early online date	19 May 2023
DOIs	https://doi.org/10.1111/mec.16983
Publication status	Published - Jul 2023

Bibliographical note

Copyright the Author(s) 2023. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

Keywords

coronavirus
CoV-229E
cryptic diversity
Hipposideros bat species complex
major histocompatibility complex
pathogen resistance

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10.1111/mec.16983

Publisher version (open access)Final published version, 1.9 MBLicence: CC BY

Cite this

Schmid, D. W., Meyer, M., Wilhelm, K., Tilley, T., Link-Hessing, T., Fleischer, R., Badu, E. K., Nkrumah, E. E., Oppong, S. K., Schwensow, N., Tschapka, M., Baldwin, H. J., Vallo, P., Corman, V. M., Drosten, C., & Sommer, S. (2023). MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats. Molecular Ecology, 32(14), 3989-4002. https://doi.org/10.1111/mec.16983

@article{b32732ba542f42e2ae743dac98b301fc,

title = "MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats",

abstract = "Understanding the immunogenetic basis of coronavirus (CoV) susceptibility in major pathogen reservoirs, such as bats, is central to inferring their zoonotic potential. Members of the cryptic Hipposideros bat species complex differ in CoV susceptibility, but the underlying mechanisms remain unclear. The genes of the major histocompatibility complex (MHC) are the best understood genetic basis of pathogen resistance, and differences in MHC diversity are one possible reason for asymmetrical infection patterns among closely related species. Here, we aimed to link asymmetries in observed CoV (CoV-229E, CoV-2B and CoV-2Bbasal) susceptibility to immunogenetic differences amongst four Hipposideros bat species. From the 2072 bats assigned to their respective species using the mtDNA cytochrome b gene, members of the most numerous and ubiquitous species, Hipposideros caffer D, were most infected with CoV-229E and SARS-related CoV-2B. Using a subset of 569 bats, we determined that much of the existent allelic and functional (i.e. supertype) MHC DRB class II diversity originated from common ancestry. One MHC supertype shared amongst all species, ST12, was consistently linked to susceptibility with CoV-229E, which is closely related to the common cold agent HCoV-229E, and infected bats and those carrying ST12 had a lower body condition. The same MHC supertype was connected to resistance to CoV-2B, and bats with ST12 were less likely be co-infected with CoV-229E and CoV-2B. Our work suggests a role of immunogenetics in determining CoV susceptibility in bats. We advocate for the preservation of functional genetic and species diversity in reservoirs as a means of mitigating the risk of disease spillover.",

keywords = "coronavirus, CoV-229E, cryptic diversity, Hipposideros bat species complex, major histocompatibility complex, pathogen resistance",

author = "Schmid, {Dominik W.} and Magdalena Meyer and Kerstin Wilhelm and Tatiana Tilley and Thomas Link-Hessing and Ramona Fleischer and Badu, {Ebenezer K.} and Nkrumah, {Evans Ewald} and Oppong, {Samuel Kingsley} and Nina Schwensow and Marco Tschapka and Baldwin, {Heather J.} and Peter Vallo and Corman, {Victor M.} and Christian Drosten and Simone Sommer",

note = "Copyright the Author(s) 2023. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher. ",

year = "2023",

month = jul,

doi = "10.1111/mec.16983",

language = "English",

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Schmid, DW, Meyer, M, Wilhelm, K, Tilley, T, Link-Hessing, T, Fleischer, R, Badu, EK, Nkrumah, EE, Oppong, SK, Schwensow, N, Tschapka, M, Baldwin, HJ, Vallo, P, Corman, VM, Drosten, C & Sommer, S 2023, 'MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats', Molecular Ecology, vol. 32, no. 14, pp. 3989-4002. https://doi.org/10.1111/mec.16983

TY - JOUR

T1 - MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats

AU - Schmid, Dominik W.

AU - Meyer, Magdalena

AU - Wilhelm, Kerstin

AU - Tilley, Tatiana

AU - Link-Hessing, Thomas

AU - Fleischer, Ramona

AU - Badu, Ebenezer K.

AU - Nkrumah, Evans Ewald

AU - Oppong, Samuel Kingsley

AU - Schwensow, Nina

AU - Tschapka, Marco

AU - Baldwin, Heather J.

AU - Vallo, Peter

AU - Corman, Victor M.

AU - Drosten, Christian

AU - Sommer, Simone

N1 - Copyright the Author(s) 2023. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

PY - 2023/7

Y1 - 2023/7

N2 - Understanding the immunogenetic basis of coronavirus (CoV) susceptibility in major pathogen reservoirs, such as bats, is central to inferring their zoonotic potential. Members of the cryptic Hipposideros bat species complex differ in CoV susceptibility, but the underlying mechanisms remain unclear. The genes of the major histocompatibility complex (MHC) are the best understood genetic basis of pathogen resistance, and differences in MHC diversity are one possible reason for asymmetrical infection patterns among closely related species. Here, we aimed to link asymmetries in observed CoV (CoV-229E, CoV-2B and CoV-2Bbasal) susceptibility to immunogenetic differences amongst four Hipposideros bat species. From the 2072 bats assigned to their respective species using the mtDNA cytochrome b gene, members of the most numerous and ubiquitous species, Hipposideros caffer D, were most infected with CoV-229E and SARS-related CoV-2B. Using a subset of 569 bats, we determined that much of the existent allelic and functional (i.e. supertype) MHC DRB class II diversity originated from common ancestry. One MHC supertype shared amongst all species, ST12, was consistently linked to susceptibility with CoV-229E, which is closely related to the common cold agent HCoV-229E, and infected bats and those carrying ST12 had a lower body condition. The same MHC supertype was connected to resistance to CoV-2B, and bats with ST12 were less likely be co-infected with CoV-229E and CoV-2B. Our work suggests a role of immunogenetics in determining CoV susceptibility in bats. We advocate for the preservation of functional genetic and species diversity in reservoirs as a means of mitigating the risk of disease spillover.

AB - Understanding the immunogenetic basis of coronavirus (CoV) susceptibility in major pathogen reservoirs, such as bats, is central to inferring their zoonotic potential. Members of the cryptic Hipposideros bat species complex differ in CoV susceptibility, but the underlying mechanisms remain unclear. The genes of the major histocompatibility complex (MHC) are the best understood genetic basis of pathogen resistance, and differences in MHC diversity are one possible reason for asymmetrical infection patterns among closely related species. Here, we aimed to link asymmetries in observed CoV (CoV-229E, CoV-2B and CoV-2Bbasal) susceptibility to immunogenetic differences amongst four Hipposideros bat species. From the 2072 bats assigned to their respective species using the mtDNA cytochrome b gene, members of the most numerous and ubiquitous species, Hipposideros caffer D, were most infected with CoV-229E and SARS-related CoV-2B. Using a subset of 569 bats, we determined that much of the existent allelic and functional (i.e. supertype) MHC DRB class II diversity originated from common ancestry. One MHC supertype shared amongst all species, ST12, was consistently linked to susceptibility with CoV-229E, which is closely related to the common cold agent HCoV-229E, and infected bats and those carrying ST12 had a lower body condition. The same MHC supertype was connected to resistance to CoV-2B, and bats with ST12 were less likely be co-infected with CoV-229E and CoV-2B. Our work suggests a role of immunogenetics in determining CoV susceptibility in bats. We advocate for the preservation of functional genetic and species diversity in reservoirs as a means of mitigating the risk of disease spillover.

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JO - Molecular Ecology

JF - Molecular Ecology

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ER -

MHC class II genes mediate susceptibility and resistance to coronavirus infections in bats

Abstract

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