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MASCOT-Skyline integrates population and migration dynamics to enhance phylogeographic reconstructions

MASCOT-Skyline integrates population and migration dynamics to enhance phylogeographic reconstructions
MASCOT-Skyline integrates population and migration dynamics to enhance phylogeographic reconstructions
The spread of infectious diseases is shaped by spatial and temporal aspects, such as host population structure or changes in the transmission rate or number of infected individuals over time. These spatiotemporal dynamics are imprinted in the genome of pathogens and can be recovered from those genomes using phylodynamics methods. However, phylodynamic methods typically quantify either the temporal or spatial transmission dynamics, which leads to unclear biases, as one can potentially not be inferred without the other. Here, we address this challenge by introducing a structured coalescent skyline approach, MASCOT-Skyline that allows us to jointly infer spatial and temporal transmission dynamics of infectious diseases using Markov chain Monte Carlo inference. To do so, we model the effective population size dynamics in different locations using a non-parametric function, allowing us to approximate a range of population size dynamics. We show, using a range of different viral outbreak datasets, potential issues with phylogeographic methods. We then use these viral datasets to motivate simulations of outbreaks that illuminate the nature of biases present in the different phylogeographic methods. We show that spatial and temporal dynamics should be modeled jointly even if one seeks to recover just one of the two. Further, we showcase conditions under which we can expect phylogeographic analyses to be biased, particularly different subsampling approaches, as well as provide recommendations of when we can expect them to perform well. We implemented MASCOT-Skyline as part of the open-source software package MASCOT for the Bayesian phylodynamics platform BEAST2.
1553-734X
Müller, Nicola F.
64d23aa7-6fe4-4f62-bcc8-33dda66b47b0
Bouckaert, Remco R.
c9067130-e7a6-4109-bdd7-8e8a3f7b8bc3
Wu, Chieh-Hsi
ace630c6-2095-4ade-b657-241692f6b4d3
Bedford, Trevor
1e40cc29-1c77-4ec0-bbf1-84d790b9c809
Müller, Nicola F.
64d23aa7-6fe4-4f62-bcc8-33dda66b47b0
Bouckaert, Remco R.
c9067130-e7a6-4109-bdd7-8e8a3f7b8bc3
Wu, Chieh-Hsi
ace630c6-2095-4ade-b657-241692f6b4d3
Bedford, Trevor
1e40cc29-1c77-4ec0-bbf1-84d790b9c809

Müller, Nicola F., Bouckaert, Remco R., Wu, Chieh-Hsi and Bedford, Trevor (2025) MASCOT-Skyline integrates population and migration dynamics to enhance phylogeographic reconstructions. PLoS Computational Biology. (doi:10.1101/2024.03.06.583734). (In Press)

Record type: Article

Abstract

The spread of infectious diseases is shaped by spatial and temporal aspects, such as host population structure or changes in the transmission rate or number of infected individuals over time. These spatiotemporal dynamics are imprinted in the genome of pathogens and can be recovered from those genomes using phylodynamics methods. However, phylodynamic methods typically quantify either the temporal or spatial transmission dynamics, which leads to unclear biases, as one can potentially not be inferred without the other. Here, we address this challenge by introducing a structured coalescent skyline approach, MASCOT-Skyline that allows us to jointly infer spatial and temporal transmission dynamics of infectious diseases using Markov chain Monte Carlo inference. To do so, we model the effective population size dynamics in different locations using a non-parametric function, allowing us to approximate a range of population size dynamics. We show, using a range of different viral outbreak datasets, potential issues with phylogeographic methods. We then use these viral datasets to motivate simulations of outbreaks that illuminate the nature of biases present in the different phylogeographic methods. We show that spatial and temporal dynamics should be modeled jointly even if one seeks to recover just one of the two. Further, we showcase conditions under which we can expect phylogeographic analyses to be biased, particularly different subsampling approaches, as well as provide recommendations of when we can expect them to perform well. We implemented MASCOT-Skyline as part of the open-source software package MASCOT for the Bayesian phylodynamics platform BEAST2.

Text
2024.03.06.583734v2.full - Author's Original
Available under License Creative Commons Attribution Non-commercial.
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Submitted date: 13 March 2024
Accepted/In Press date: 12 August 2025
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Identifiers

Local EPrints ID: 502411
URI: http://eprints.soton.ac.uk/id/eprint/502411
DOI: doi:10.1101/2024.03.06.583734
ISSN: 1553-734X
PURE UUID: f38b3bea-9ee7-45c3-b80c-7d4801fa5275
ORCID for Chieh-Hsi Wu: ORCID iD orcid.org/0000-0001-9386-725X

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Date deposited: 25 Jun 2025 16:44
Last modified: 20 Sep 2025 02:11

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Contributors

Author: Nicola F. Müller
Author: Remco R. Bouckaert
Author: Chieh-Hsi Wu ORCID iD
Author: Trevor Bedford

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