High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark

Mark P. Khurana; Jacob Curran-Sebastian; Neil Scheidwasser; Christian Morgenstern; Morten Rasmussen; Jannik Fonager; Marc Stegger; Man-Hung Eric Tang; Jonas L. Juul; Leandro Andrés Escobar-Herrera; Frederik Trier Møller; The Danish COVID-19 Genome Consortium (dcgc); Jonas Byberg-Grauholm; Gitte Nygaard Aasbjerg; Aleksander Ring; Raphael Sieber; Tobias Nikolaj Gress Hansen; Vithiagaran Gunalan; Claus Nielsen; Kirsten Ellegaard; Nicolai Balle Larsen; Esben Mørk Hartmann; Anders Jensen; Karina Meden Sørensen; Stine K. Østergaard; Emil A. Sørensen; Thomas B. N. Jensen; Emilio Fuster-Collados; Clarisse Chiche-Lapierre; Kasper S. Andersen; Thomas Y. Michaelsen; Celine Petersen; Susan H. Hansen; Henrik Bygum Krarup; Kristian Schønning; Sarah Juel Paulsen; Uffe Vest Schneider; Martin Schou Pedersen; Jose Alfredo Samaniego Castruita; Marianne Kragh Thomsen; Svend Ellermann-Eriksen; Karina Gravgaard Thomsen; Dorte Terp Andersen; Kat Steinke; Marianne Nielsine Skov; Sanne Løkkegaard Larsen; Morten Hoppe; Thomas Sundelin; John E. Coia; Asta Lili Laugesen; Rikke Lykke Johansen; Xiaohui Nielsen; Mads Albertsen; Moritz U. G. Kraemer; Louis Du Plessis; Pikka Jokelainen; Sune Lehmann; Tyra G. Krause; Henrik Ullum; David A. Duchêne; Laust H. Mortensen; Samir Bhatt

doi:10.1038/s41467-024-51371-0

High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark

Mark P. Khurana
, Jacob Curran-Sebastian
, Neil Scheidwasser
, Christian Morgenstern
, Morten Rasmussen
, Jannik Fonager
, Marc Stegger
, Man-Hung Eric Tang
, Jonas L. Juul
, Leandro Andrés Escobar-Herrera
, Frederik Trier Møller
, The Danish COVID-19 Genome Consortium (dcgc)
, Jonas Byberg-Grauholm
, Gitte Nygaard Aasbjerg
, Aleksander Ring
, Raphael Sieber
, Tobias Nikolaj Gress Hansen
, Vithiagaran Gunalan
, Claus Nielsen
, Kirsten Ellegaard

Nicolai Balle Larsen, Esben Mørk Hartmann, Anders Jensen, Karina Meden Sørensen, Stine K. Østergaard, Emil A. Sørensen, Thomas B. N. Jensen, Emilio Fuster-Collados, Clarisse Chiche-Lapierre, Kasper S. Andersen, Thomas Y. Michaelsen, Celine Petersen, Susan H. Hansen, Henrik Bygum Krarup, Kristian Schønning, Sarah Juel Paulsen, Uffe Vest Schneider, Martin Schou Pedersen, Jose Alfredo Samaniego Castruita, Marianne Kragh Thomsen, Svend Ellermann-Eriksen, Karina Gravgaard Thomsen, Dorte Terp Andersen, Kat Steinke, Marianne Nielsine Skov, Sanne Løkkegaard Larsen, Morten Hoppe, Thomas Sundelin, John E. Coia, Asta Lili Laugesen, Rikke Lykke Johansen, Xiaohui Nielsen, Mads Albertsen, Moritz U. G. Kraemer, Louis Du Plessis, Pikka Jokelainen, Sune Lehmann, Tyra G. Krause, Henrik Ullum, David A. Duchêne, Laust H. Mortensen, Samir Bhatt

University of Copenhagen
Imperial College London
Statens Serum Institut
Murdoch University
Technical University of Denmark
Aalborg University
Aalborg University Hospital
Copenhagen University Hospital
Aarhus University Hospital
Odense University Hospital
University of Southern Denmark
Zealand University Hospital
University of Oxford
Swiss Federal Institute of Technology Zürich

Research output: Journal Article or Conference Article in Journal › Journal article › Research › peer-review

Abstract

Vast amounts of pathogen genomic, demographic and spatial data are transforming our understanding of SARS-CoV-2 emergence and spread. We examined the drivers of molecular evolution and spread of 291,791 SARS-CoV-2 genomes from Denmark in 2021. With a sequencing rate consistently exceeding 60%, and up to 80% of PCR-positive samples between March and November, the viral genome set is broadly whole-epidemic representative. We identify a consistent rise in viral diversity over time, with notable spikes upon the importation of novel variants (e.g., Delta and Omicron). By linking genomic data with rich individual-level demographic data from national registers, we find that individuals aged < 15 and > 75 years had a lower contribution to molecular change (i.e., branch lengths) compared to other age groups, but similar molecular evolutionary rates, suggesting a lower likelihood of introducing novel variants. Similarly, we find greater molecular change among vaccinated individuals, suggestive of immune evasion. We also observe evidence of transmission in rural areas to follow predictable diffusion processes. Conversely, urban areas are expectedly more complex due to their high mobility, emphasising the role of population structure in driving virus spread. Our analyses highlight the added value of integrating genomic data with detailed demographic and spatial information, particularly in the absence of structured infection surveys.

Original language	English
Article number	7123
Journal	Nature Communications
Volume	15
Issue number	1
ISSN	2041-1723
DOIs	https://doi.org/10.1038/s41467-024-51371-0
Publication status	Published - 20 Aug 2024

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Khurana, M. P., Curran-Sebastian, J., Scheidwasser, N., Morgenstern, C., Rasmussen, M., Fonager, J., Stegger, M., Tang, M.-H. E., Juul, J. L., Escobar-Herrera, L. A., Møller, F. T., (dcgc), T. D. COVID. G. C., Byberg-Grauholm, J., Aasbjerg, G. N., Ring, A., Sieber, R., Hansen, T. N. G., Gunalan, V., Nielsen, C., ... Bhatt, S. (2024). High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark. Nature Communications, 15(1), Article 7123. https://doi.org/10.1038/s41467-024-51371-0

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title = "High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark",

abstract = "Vast amounts of pathogen genomic, demographic and spatial data are transforming our understanding of SARS-CoV-2 emergence and spread. We examined the drivers of molecular evolution and spread of 291,791 SARS-CoV-2 genomes from Denmark in 2021. With a sequencing rate consistently exceeding 60\%, and up to 80\% of PCR-positive samples between March and November, the viral genome set is broadly whole-epidemic representative. We identify a consistent rise in viral diversity over time, with notable spikes upon the importation of novel variants (e.g., Delta and Omicron). By linking genomic data with rich individual-level demographic data from national registers, we find that individuals aged < 15 and > 75 years had a lower contribution to molecular change (i.e., branch lengths) compared to other age groups, but similar molecular evolutionary rates, suggesting a lower likelihood of introducing novel variants. Similarly, we find greater molecular change among vaccinated individuals, suggestive of immune evasion. We also observe evidence of transmission in rural areas to follow predictable diffusion processes. Conversely, urban areas are expectedly more complex due to their high mobility, emphasising the role of population structure in driving virus spread. Our analyses highlight the added value of integrating genomic data with detailed demographic and spatial information, particularly in the absence of structured infection surveys.",

author = "Khurana, \{Mark P.\} and Jacob Curran-Sebastian and Neil Scheidwasser and Christian Morgenstern and Morten Rasmussen and Jannik Fonager and Marc Stegger and Tang, \{Man-Hung Eric\} and Juul, \{Jonas L.\} and Escobar-Herrera, \{Leandro Andr{\'e}s\} and M{\o}ller, \{Frederik Trier\} and (dcgc), \{The Danish COVID-19 Genome Consortium\} and Jonas Byberg-Grauholm and Aasbjerg, \{Gitte Nygaard\} and Aleksander Ring and Raphael Sieber and Hansen, \{Tobias Nikolaj Gress\} and Vithiagaran Gunalan and Claus Nielsen and Kirsten Ellegaard and Larsen, \{Nicolai Balle\} and Hartmann, \{Esben M{\o}rk\} and Anders Jensen and S{\o}rensen, \{Karina Meden\} and {\O}stergaard, \{Stine K.\} and S{\o}rensen, \{Emil A.\} and Jensen, \{Thomas B. N.\} and Emilio Fuster-Collados and Clarisse Chiche-Lapierre and Andersen, \{Kasper S.\} and Michaelsen, \{Thomas Y.\} and Celine Petersen and Hansen, \{Susan H.\} and Krarup, \{Henrik Bygum\} and Kristian Sch{\o}nning and Paulsen, \{Sarah Juel\} and Schneider, \{Uffe Vest\} and Pedersen, \{Martin Schou\} and Castruita, \{Jose Alfredo Samaniego\} and Thomsen, \{Marianne Kragh\} and Svend Ellermann-Eriksen and Thomsen, \{Karina Gravgaard\} and Andersen, \{Dorte Terp\} and Kat Steinke and Skov, \{Marianne Nielsine\} and Larsen, \{Sanne L{\o}kkegaard\} and Morten Hoppe and Thomas Sundelin and Coia, \{John E.\} and Laugesen, \{Asta Lili\} and Johansen, \{Rikke Lykke\} and Xiaohui Nielsen and Mads Albertsen and Kraemer, \{Moritz U. G.\} and \{Du Plessis\}, Louis and Pikka Jokelainen and Sune Lehmann and Krause, \{Tyra G.\} and Henrik Ullum and Duch{\^e}ne, \{David A.\} and Mortensen, \{Laust H.\} and Samir Bhatt",

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Khurana, MP, Curran-Sebastian, J, Scheidwasser, N, Morgenstern, C, Rasmussen, M, Fonager, J, Stegger, M, Tang, M-HE, Juul, JL, Escobar-Herrera, LA, Møller, FT, (dcgc), TDCOVIDGC, Byberg-Grauholm, J, Aasbjerg, GN, Ring, A, Sieber, R, Hansen, TNG, Gunalan, V, Nielsen, C, Ellegaard, K, Larsen, NB, Hartmann, EM, Jensen, A, Sørensen, KM, Østergaard, SK, Sørensen, EA, Jensen, TBN, Fuster-Collados, E, Chiche-Lapierre, C, Andersen, KS, Michaelsen, TY, Petersen, C, Hansen, SH, Krarup, HB, Schønning, K, Paulsen, SJ, Schneider, UV, Pedersen, MS, Castruita, JAS, Thomsen, MK, Ellermann-Eriksen, S, Thomsen, KG, Andersen, DT, Steinke, K, Skov, MN, Larsen, SL, Hoppe, M, Sundelin, T, Coia, JE, Laugesen, AL, Johansen, RL, Nielsen, X, Albertsen, M, Kraemer, MUG, Du Plessis, L, Jokelainen, P, Lehmann, S, Krause, TG, Ullum, H, Duchêne, DA, Mortensen, LH & Bhatt, S 2024, 'High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark', Nature Communications, vol. 15, no. 1, 7123. https://doi.org/10.1038/s41467-024-51371-0

TY - JOUR

T1 - High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark

AU - Khurana, Mark P.

AU - Curran-Sebastian, Jacob

AU - Scheidwasser, Neil

AU - Morgenstern, Christian

AU - Rasmussen, Morten

AU - Fonager, Jannik

AU - Stegger, Marc

AU - Tang, Man-Hung Eric

AU - Juul, Jonas L.

AU - Escobar-Herrera, Leandro Andrés

AU - Møller, Frederik Trier

AU - (dcgc), The Danish COVID-19 Genome Consortium

AU - Byberg-Grauholm, Jonas

AU - Aasbjerg, Gitte Nygaard

AU - Ring, Aleksander

AU - Sieber, Raphael

AU - Hansen, Tobias Nikolaj Gress

AU - Gunalan, Vithiagaran

AU - Nielsen, Claus

AU - Ellegaard, Kirsten

AU - Larsen, Nicolai Balle

AU - Hartmann, Esben Mørk

AU - Jensen, Anders

AU - Sørensen, Karina Meden

AU - Østergaard, Stine K.

AU - Sørensen, Emil A.

AU - Jensen, Thomas B. N.

AU - Fuster-Collados, Emilio

AU - Chiche-Lapierre, Clarisse

AU - Andersen, Kasper S.

AU - Michaelsen, Thomas Y.

AU - Petersen, Celine

AU - Hansen, Susan H.

AU - Krarup, Henrik Bygum

AU - Schønning, Kristian

AU - Paulsen, Sarah Juel

AU - Schneider, Uffe Vest

AU - Pedersen, Martin Schou

AU - Castruita, Jose Alfredo Samaniego

AU - Thomsen, Marianne Kragh

AU - Ellermann-Eriksen, Svend

AU - Thomsen, Karina Gravgaard

AU - Andersen, Dorte Terp

AU - Steinke, Kat

AU - Skov, Marianne Nielsine

AU - Larsen, Sanne Løkkegaard

AU - Hoppe, Morten

AU - Sundelin, Thomas

AU - Coia, John E.

AU - Laugesen, Asta Lili

AU - Johansen, Rikke Lykke

AU - Nielsen, Xiaohui

AU - Albertsen, Mads

AU - Kraemer, Moritz U. G.

AU - Du Plessis, Louis

AU - Jokelainen, Pikka

AU - Lehmann, Sune

AU - Krause, Tyra G.

AU - Ullum, Henrik

AU - Duchêne, David A.

AU - Mortensen, Laust H.

AU - Bhatt, Samir

PY - 2024/8/20

Y1 - 2024/8/20

N2 - Vast amounts of pathogen genomic, demographic and spatial data are transforming our understanding of SARS-CoV-2 emergence and spread. We examined the drivers of molecular evolution and spread of 291,791 SARS-CoV-2 genomes from Denmark in 2021. With a sequencing rate consistently exceeding 60%, and up to 80% of PCR-positive samples between March and November, the viral genome set is broadly whole-epidemic representative. We identify a consistent rise in viral diversity over time, with notable spikes upon the importation of novel variants (e.g., Delta and Omicron). By linking genomic data with rich individual-level demographic data from national registers, we find that individuals aged < 15 and > 75 years had a lower contribution to molecular change (i.e., branch lengths) compared to other age groups, but similar molecular evolutionary rates, suggesting a lower likelihood of introducing novel variants. Similarly, we find greater molecular change among vaccinated individuals, suggestive of immune evasion. We also observe evidence of transmission in rural areas to follow predictable diffusion processes. Conversely, urban areas are expectedly more complex due to their high mobility, emphasising the role of population structure in driving virus spread. Our analyses highlight the added value of integrating genomic data with detailed demographic and spatial information, particularly in the absence of structured infection surveys.

AB - Vast amounts of pathogen genomic, demographic and spatial data are transforming our understanding of SARS-CoV-2 emergence and spread. We examined the drivers of molecular evolution and spread of 291,791 SARS-CoV-2 genomes from Denmark in 2021. With a sequencing rate consistently exceeding 60%, and up to 80% of PCR-positive samples between March and November, the viral genome set is broadly whole-epidemic representative. We identify a consistent rise in viral diversity over time, with notable spikes upon the importation of novel variants (e.g., Delta and Omicron). By linking genomic data with rich individual-level demographic data from national registers, we find that individuals aged < 15 and > 75 years had a lower contribution to molecular change (i.e., branch lengths) compared to other age groups, but similar molecular evolutionary rates, suggesting a lower likelihood of introducing novel variants. Similarly, we find greater molecular change among vaccinated individuals, suggestive of immune evasion. We also observe evidence of transmission in rural areas to follow predictable diffusion processes. Conversely, urban areas are expectedly more complex due to their high mobility, emphasising the role of population structure in driving virus spread. Our analyses highlight the added value of integrating genomic data with detailed demographic and spatial information, particularly in the absence of structured infection surveys.

U2 - 10.1038/s41467-024-51371-0

DO - 10.1038/s41467-024-51371-0

M3 - Journal article

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 7123

ER -

High-resolution epidemiological landscape from textasciitilde290,000 SARS-CoV-2 genomes from Denmark

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