Bat genomes illuminate adaptations to viral tolerance and disease resistance

Ariadna E. Morales; Yue Dong; Thomas Brown; Kaushal Baid; Dimitrios Georgios Kontopoulos; Victoria Gonzalez; Zixia Huang; Alexis Walid Ahmed; Arkadeb Bhuinya; Leon Hilgers; Sylke Winkler; Graham Hughes; Xiaomeng Li; Ping Lu; Yixin Yang; Bogdan M. Kirilenko; Paolo Devanna; Tanya M. Lama; Yomiran Nissan; Martin Pippel; Liliana M. Dávalos; Sonja C. Vernes; Sebastien J. Puechmaille; Stephen J. Rossiter; Yossi Yovel; Joseph B. Prescott; Andreas Kurth; David A. Ray; Burton K. Lim; Eugene Myers; Emma C. Teeling; Arinjay Banerjee; Aaron T. Irving; Michael Hiller

doi:10.1038/s41586-024-08471-0

Bat genomes illuminate adaptations to viral tolerance and disease resistance

Ariadna E. Morales
, Yue Dong
, Thomas Brown
, Kaushal Baid
, Dimitrios Georgios Kontopoulos
, Victoria Gonzalez
, Zixia Huang
, Alexis Walid Ahmed
, Arkadeb Bhuinya
, Leon Hilgers
, Sylke Winkler
, Graham Hughes
, Xiaomeng Li
, Ping Lu
, Yixin Yang
, Bogdan M. Kirilenko
, Paolo Devanna
, Tanya M. Lama
, Yomiran Nissan
, Martin Pippel

Liliana M. Dávalos, Sonja C. Vernes, Sebastien J. Puechmaille, Stephen J. Rossiter, Yossi Yovel, Joseph B. Prescott, Andreas Kurth, David A. Ray, Burton K. Lim, Eugene Myers, Emma C. Teeling, Arinjay Banerjee, Aaron T. Irving, Michael Hiller

Ecology and Evolution

LOEWE Centre for Translational Biodiversity Genomics
Senckenberg Gesellschaft für Naturforschung
Goethe University Frankfurt
University of Edinburgh
Zhejiang University-University of Edinburgh Institute
Max Planck Institute of Molecular Cell Biology and Genetics
Technische Universität Dresden
University of Saskatchewan
University College Dublin
Max Planck Institute for Psycholinguistics
Stony Brook University
Smith College
Tel Aviv University
University of St Andrews
Institut universitaire de France
Université de Montpellier
Queen Mary University of London
Robert Koch-Institut
Texas Tech University
Royal Ontario Museum
University of Waterloo
University of Toronto
University of British Columbia
Zhejiang University
Zhejiang University–University of Edinburgh Institute

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

39 Scopus citations

Abstract

Zoonoses are infectious diseases transmitted from animals to humans. Bats have been suggested to harbour more zoonotic viruses than any other mammalian order¹. Infections in bats are largely asymptomatic^2,3, indicating limited tissue-damaging inflammation and immunopathology. To investigate the genomic basis of disease resistance, the Bat1K project generated reference-quality genomes of ten bat species, including potential viral reservoirs. Here we describe a systematic analysis covering 115 mammalian genomes that revealed that signatures of selection in immune genes are more prevalent in bats than in other mammalian orders. We found an excess of immune gene adaptations in the ancestral chiropteran branch and in many descending bat lineages, highlighting viral entry and detection factors, and regulators of antiviral and inflammatory responses. ISG15, which is an antiviral gene contributing to hyperinflammation during COVID-19 (refs. ^4,5), exhibits key residue changes in rhinolophid and hipposiderid bats. Cellular infection experiments show species-specific antiviral differences and an essential role of protein conjugation in antiviral function of bat ISG15, separate from its role in secretion and inflammation in humans. Furthermore, in contrast to humans, ISG15 in most rhinolophid and hipposiderid bats has strong anti-SARS-CoV-2 activity. Our work reveals molecular mechanisms that contribute to viral tolerance and disease resistance in bats.

Original language	English
Pages (from-to)	449-458
Number of pages	10
Journal	Nature
Volume	638
Issue number	8050
DOIs	https://doi.org/10.1038/s41586-024-08471-0
State	Published - Feb 13 2025

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Morales, A. E., Dong, Y., Brown, T., Baid, K., Kontopoulos, D. G., Gonzalez, V., Huang, Z., Ahmed, A. W., Bhuinya, A., Hilgers, L., Winkler, S., Hughes, G., Li, X., Lu, P., Yang, Y., Kirilenko, B. M., Devanna, P., Lama, T. M., Nissan, Y., ... Hiller, M. (2025). Bat genomes illuminate adaptations to viral tolerance and disease resistance. Nature, 638(8050), 449-458. https://doi.org/10.1038/s41586-024-08471-0

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title = "Bat genomes illuminate adaptations to viral tolerance and disease resistance",

abstract = "Zoonoses are infectious diseases transmitted from animals to humans. Bats have been suggested to harbour more zoonotic viruses than any other mammalian order1. Infections in bats are largely asymptomatic2,3, indicating limited tissue-damaging inflammation and immunopathology. To investigate the genomic basis of disease resistance, the Bat1K project generated reference-quality genomes of ten bat species, including potential viral reservoirs. Here we describe a systematic analysis covering 115 mammalian genomes that revealed that signatures of selection in immune genes are more prevalent in bats than in other mammalian orders. We found an excess of immune gene adaptations in the ancestral chiropteran branch and in many descending bat lineages, highlighting viral entry and detection factors, and regulators of antiviral and inflammatory responses. ISG15, which is an antiviral gene contributing to hyperinflammation during COVID-19 (refs. 4,5), exhibits key residue changes in rhinolophid and hipposiderid bats. Cellular infection experiments show species-specific antiviral differences and an essential role of protein conjugation in antiviral function of bat ISG15, separate from its role in secretion and inflammation in humans. Furthermore, in contrast to humans, ISG15 in most rhinolophid and hipposiderid bats has strong anti-SARS-CoV-2 activity. Our work reveals molecular mechanisms that contribute to viral tolerance and disease resistance in bats.",

author = "Morales, \{Ariadna E.\} and Yue Dong and Thomas Brown and Kaushal Baid and Kontopoulos, \{Dimitrios Georgios\} and Victoria Gonzalez and Zixia Huang and Ahmed, \{Alexis Walid\} and Arkadeb Bhuinya and Leon Hilgers and Sylke Winkler and Graham Hughes and Xiaomeng Li and Ping Lu and Yixin Yang and Kirilenko, \{Bogdan M.\} and Paolo Devanna and Lama, \{Tanya M.\} and Yomiran Nissan and Martin Pippel and D{\'a}valos, \{Liliana M.\} and Vernes, \{Sonja C.\} and Puechmaille, \{Sebastien J.\} and Rossiter, \{Stephen J.\} and Yossi Yovel and Prescott, \{Joseph B.\} and Andreas Kurth and Ray, \{David A.\} and Lim, \{Burton K.\} and Eugene Myers and Teeling, \{Emma C.\} and Arinjay Banerjee and Irving, \{Aaron T.\} and Michael Hiller",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = feb,

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doi = "10.1038/s41586-024-08471-0",

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Morales, AE, Dong, Y, Brown, T, Baid, K, Kontopoulos, DG, Gonzalez, V, Huang, Z, Ahmed, AW, Bhuinya, A, Hilgers, L, Winkler, S, Hughes, G, Li, X, Lu, P, Yang, Y, Kirilenko, BM, Devanna, P, Lama, TM, Nissan, Y, Pippel, M, Dávalos, LM, Vernes, SC, Puechmaille, SJ, Rossiter, SJ, Yovel, Y, Prescott, JB, Kurth, A, Ray, DA, Lim, BK, Myers, E, Teeling, EC, Banerjee, A, Irving, AT & Hiller, M 2025, 'Bat genomes illuminate adaptations to viral tolerance and disease resistance', Nature, vol. 638, no. 8050, pp. 449-458. https://doi.org/10.1038/s41586-024-08471-0

TY - JOUR

T1 - Bat genomes illuminate adaptations to viral tolerance and disease resistance

AU - Morales, Ariadna E.

AU - Dong, Yue

AU - Brown, Thomas

AU - Baid, Kaushal

AU - Kontopoulos, Dimitrios Georgios

AU - Gonzalez, Victoria

AU - Huang, Zixia

AU - Ahmed, Alexis Walid

AU - Bhuinya, Arkadeb

AU - Hilgers, Leon

AU - Winkler, Sylke

AU - Hughes, Graham

AU - Li, Xiaomeng

AU - Lu, Ping

AU - Yang, Yixin

AU - Kirilenko, Bogdan M.

AU - Devanna, Paolo

AU - Lama, Tanya M.

AU - Nissan, Yomiran

AU - Pippel, Martin

AU - Dávalos, Liliana M.

AU - Vernes, Sonja C.

AU - Puechmaille, Sebastien J.

AU - Rossiter, Stephen J.

AU - Yovel, Yossi

AU - Prescott, Joseph B.

AU - Kurth, Andreas

AU - Ray, David A.

AU - Lim, Burton K.

AU - Myers, Eugene

AU - Teeling, Emma C.

AU - Banerjee, Arinjay

AU - Irving, Aaron T.

AU - Hiller, Michael

PY - 2025/2/13

Y1 - 2025/2/13

N2 - Zoonoses are infectious diseases transmitted from animals to humans. Bats have been suggested to harbour more zoonotic viruses than any other mammalian order1. Infections in bats are largely asymptomatic2,3, indicating limited tissue-damaging inflammation and immunopathology. To investigate the genomic basis of disease resistance, the Bat1K project generated reference-quality genomes of ten bat species, including potential viral reservoirs. Here we describe a systematic analysis covering 115 mammalian genomes that revealed that signatures of selection in immune genes are more prevalent in bats than in other mammalian orders. We found an excess of immune gene adaptations in the ancestral chiropteran branch and in many descending bat lineages, highlighting viral entry and detection factors, and regulators of antiviral and inflammatory responses. ISG15, which is an antiviral gene contributing to hyperinflammation during COVID-19 (refs. 4,5), exhibits key residue changes in rhinolophid and hipposiderid bats. Cellular infection experiments show species-specific antiviral differences and an essential role of protein conjugation in antiviral function of bat ISG15, separate from its role in secretion and inflammation in humans. Furthermore, in contrast to humans, ISG15 in most rhinolophid and hipposiderid bats has strong anti-SARS-CoV-2 activity. Our work reveals molecular mechanisms that contribute to viral tolerance and disease resistance in bats.

AB - Zoonoses are infectious diseases transmitted from animals to humans. Bats have been suggested to harbour more zoonotic viruses than any other mammalian order1. Infections in bats are largely asymptomatic2,3, indicating limited tissue-damaging inflammation and immunopathology. To investigate the genomic basis of disease resistance, the Bat1K project generated reference-quality genomes of ten bat species, including potential viral reservoirs. Here we describe a systematic analysis covering 115 mammalian genomes that revealed that signatures of selection in immune genes are more prevalent in bats than in other mammalian orders. We found an excess of immune gene adaptations in the ancestral chiropteran branch and in many descending bat lineages, highlighting viral entry and detection factors, and regulators of antiviral and inflammatory responses. ISG15, which is an antiviral gene contributing to hyperinflammation during COVID-19 (refs. 4,5), exhibits key residue changes in rhinolophid and hipposiderid bats. Cellular infection experiments show species-specific antiviral differences and an essential role of protein conjugation in antiviral function of bat ISG15, separate from its role in secretion and inflammation in humans. Furthermore, in contrast to humans, ISG15 in most rhinolophid and hipposiderid bats has strong anti-SARS-CoV-2 activity. Our work reveals molecular mechanisms that contribute to viral tolerance and disease resistance in bats.

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U2 - 10.1038/s41586-024-08471-0

DO - 10.1038/s41586-024-08471-0

M3 - Article

C2 - 39880942

AN - SCOPUS:85217160434

SN - 0028-0836

VL - 638

SP - 449

EP - 458

JO - Nature

JF - Nature

IS - 8050

ER -

Bat genomes illuminate adaptations to viral tolerance and disease resistance

Abstract

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