Your search keyword '"Lemey, P"' showing total 888 results

1. Infinite Mixture Models for Improved Modeling of Across-Site Evolutionary Variation

Author

Gill, Mandev S., Baele, Guy, Suchard, Marc A., and Lemey, Philippe

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Methodology

Abstract

Scientific studies in many areas of biology routinely employ evolutionary analyses based on the probabilistic inference of phylogenetic trees from molecular sequence data. Evolutionary processes that act at the molecular level are highly variable, and properly accounting for heterogeneity in evolutionary processes is crucial for more accurate phylogenetic inference. Nucleotide substitution rates and patterns are known to vary among sites in multiple sequence alignments, and such variation can be modeled by partitioning alignments into categories corresponding to different substitution models. Determining $\textit{a priori}$ appropriate partitions can be difficult, however, and better model fit can be achieved through flexible Bayesian infinite mixture models that simultaneously infer the number of partitions, the partition that each site belongs to, and the evolutionary parameters corresponding to each partition. Here, we consider several different types of infinite mixture models, including classic Dirichlet process mixtures, as well as novel approaches for modeling across-site evolutionary variation: hierarchical models for data with a natural group structure, and infinite hidden Markov models that account for spatial patterns in alignments. In analyses of several viral data sets, we find that different types of infinite mixture models emerge as the best choices in different scenarios. To enable these models to scale efficiently to large data sets, we adapt efficient Markov chain Monte Carlo algorithms and exploit opportunities for parallel computing. We implement this infinite mixture modeling framework in BEAST X, a widely-used software package for Bayesian phylogenetic inference.

Published

2024

2. Random-Effects Substitution Models for Phylogenetics via Scalable Gradient Approximations

Author

Magee, Andrew F, Holbrook, Andrew J, Pekar, Jonathan E, Caviedes-Solis, Itzue W, Matsen Iv, Fredrick A, Baele, Guy, Wertheim, Joel O, Ji, Xiang, Lemey, Philippe, and Suchard, Marc A

Subjects

Biological Sciences, Ecology, Evolutionary Biology, Genetics, Emerging Infectious Diseases, Infectious Diseases, Generic health relevance, Phylogeny, Classification, SARS-CoV-2, Influenza A Virus, H3N2 Subtype, Models, Genetic, Markov Chains, Bayes Theorem, Bayesian inference, Hamiltonian Monte Carlo, phylogeography, Evolutionary biology

Abstract

Phylogenetic and discrete-trait evolutionary inference depend heavily on an appropriate characterization of the underlying character substitution process. In this paper, we present random-effects substitution models that extend common continuous-time Markov chain models into a richer class of processes capable of capturing a wider variety of substitution dynamics. As these random-effects substitution models often require many more parameters than their usual counterparts, inference can be both statistically and computationally challenging. Thus, we also propose an efficient approach to compute an approximation to the gradient of the data likelihood with respect to all unknown substitution model parameters. We demonstrate that this approximate gradient enables scaling of sampling-based inference, namely Bayesian inference via Hamiltonian Monte Carlo, under random-effects substitution models across large trees and state-spaces. Applied to a dataset of 583 SARS-CoV-2 sequences, an HKY model with random-effects shows strong signals of nonreversibility in the substitution process, and posterior predictive model checks clearly show that it is a more adequate model than a reversible model. When analyzing the pattern of phylogeographic spread of 1441 influenza A virus (H3N2) sequences between 14 regions, a random-effects phylogeographic substitution model infers that air travel volume adequately predicts almost all dispersal rates. A random-effects state-dependent substitution model reveals no evidence for an effect of arboreality on the swimming mode in the tree frog subfamily Hylinae. Simulations reveal that random-effects substitution models can accommodate both negligible and radical departures from the underlying base substitution model. We show that our gradient-based inference approach is over an order of magnitude more time efficient than conventional approaches.

Published

2024

3. Farmed fur animals harbour viruses with zoonotic spillover potential

Author

Zhao, Jin, Wan, Wenbo, Yu, Kang, Lemey, Philippe, Pettersson, John H.-O., Bi, Yuhai, Lu, Meng, Li, Xinxin, Chen, Zhuohang, Zheng, Mengdi, Yan, Ge, Dai, JianJun, Li, Yuxing, Haerheng, Ayidana, He, Na, Tu, Changchun, Suchard, Marc A., Holmes, Edward C., He, Wan-Ting, and Su, Shuo

Published

2024

4. On the importance of assessing topological convergence in Bayesian phylogenetic inference

Author

Brusselmans, Marius, Carvalho, Luiz Max, Hong, Samuel L., Gao, Jiansi, Matsen IV, Frederick A., Rambaut, Andrew, Lemey, Philippe, Suchard, Marc A., Dudas, Gytis, and Baele, Guy

Subjects

Quantitative Biology - Populations and Evolution, Quantitative Biology - Genomics, Quantitative Biology - Quantitative Methods

Abstract

Modern phylogenetics research is often performed within a Bayesian framework, using sampling algorithms such as Markov chain Monte Carlo (MCMC) to approximate the posterior distribution. These algorithms require careful evaluation of the quality of the generated samples. Within the field of phylogenetics, one frequently adopted diagnostic approach is to evaluate the effective sample size (ESS) and to investigate trace graphs of the sampled parameters. A major limitation of these approaches is that they are developed for continuous parameters and therefore incompatible with a crucial parameter in these inferences: the tree topology. Several recent advancements have aimed at extending these diagnostics to topological space. In this reflection paper, we present two case studies - one on Ebola virus and one on HIV - illustrating how these topological diagnostics can contain information not found in standard diagnostics, and how decisions regarding which of these diagnostics to compute can impact inferences regarding MCMC convergence and mixing. Our results show the importance of running multiple replicate analyses and of carefully assessing topological convergence using the output of these replicate analyses. To this end, we illustrate different ways of assessing and visualizing the topological convergence of these replicates. Given the major importance of detecting convergence and mixing issues in Bayesian phylogenetic analyses, the lack of a unified approach to this problem warrants further action, especially now that additional tools are becoming available to researchers.

Published

2024

5. A Comprehensive Overview on UWB Radar: Applications, Standards, Signal Processing Techniques, Datasets, Radio Chips, Trends and Future Research Directions

Author

Cheraghinia, Mohammad, Shahid, Adnan, Luchie, Stijn, Gordebeke, Gert-Jan, Caytan, Olivier, Fontaine, Jaron, Van Herbruggen, Ben, Lemey, Sam, and De Poorter, Eli

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

Due to their large bandwidth, relatively low cost, and robust performance, UWB radio chips can be used for a wide variety of applications, including localization, communication, and radar. This article offers an exhaustive survey of recent progress in UWB radar technology. The goal of this survey is to provide a comprehensive view of the technical fundamentals and emerging trends in UWB radar. Our analysis is categorized into multiple parts. Firstly, we explore the fundamental concepts of UWB radar technology from a technology and standardization point of view. Secondly, we examine the most relevant UWB applications and use cases, such as device-free localization, activity recognition, presence detection, and vital sign monitoring, discussing each time the bandwidth requirements, processing techniques, algorithms, latest developments, relevant example papers, and trends. Next, we steer readers toward relevant datasets and available radio chipsets. Finally, we discuss ongoing challenges and potential future research avenues. As such, this overview paper is designed to be a cornerstone reference for researchers charting the course of UWB radar technology over the last decade., Comment: 37 pages, 4 figures, This paper has been submitted to IEEE Communications Surveys and Tutorials and is currently undergoing review

Published

2024

6. The genomic evolutionary dynamics and global circulation patterns of respiratory syncytial virus.

Author

Langedijk, Annefleur, Vrancken, Bram, Lebbink, Robert, Wilkins, Deidre, Kelly, Elizabeth, Baraldi, Eugenio, Mascareñas de Los Santos, Abiel, Danilenko, Daria, Choi, Eun, Palomino, María, Chi, Hsin, Keller, Christian, Cohen, Robert, Papenburg, Jesse, Pernica, Jeffrey, Greenough, Anne, Richmond, Peter, Martinón-Torres, Federico, Heikkinen, Terho, Stein, Renato, Hosoya, Mitsuaki, Nunes, Marta, Verwey, Charl, Evers, Anouk, Kragten-Tabatabaie, Leyla, Suchard, Marc, Kosakovsky Pond, Sergei, Poletto, Chiara, Colizza, Vittoria, Lemey, Philippe, and Bont, Louis

Subjects

Infant, Child, Humans, Child, Preschool, Respiratory Syncytial Virus Infections, Phylogeny, Respiratory Syncytial Virus, Human, Genomics, Respiratory Tract Infections

Abstract

Respiratory syncytial virus (RSV) is a leading cause of acute lower respiratory tract infection in young children and the second leading cause of infant death worldwide. While global circulation has been extensively studied for respiratory viruses such as seasonal influenza, and more recently also in great detail for SARS-CoV-2, a lack of global multi-annual sampling of complete RSV genomes limits our understanding of RSV molecular epidemiology. Here, we capitalise on the genomic surveillance by the INFORM-RSV study and apply phylodynamic approaches to uncover how selection and neutral epidemiological processes shape RSV diversity. Using complete viral genome sequences, we show similar patterns of site-specific diversifying selection among RSVA and RSVB and recover the imprint of non-neutral epidemic processes on their genealogies. Using a phylogeographic approach, we provide evidence for air travel governing the global patterns of RSVA and RSVB spread, which results in a considerable degree of phylogenetic mixing across countries. Our findings highlight the potential of systematic global RSV genomic surveillance for transforming our understanding of global RSV spread.

Published

2024

7. More Quantum Speedups for Multiproposal MCMC

Author

Lin, Chin-Yi, Chen, Kuo-Chin, Lemey, Philippe, Suchard, Marc A., Holbrook, Andrew J., and Hsieh, Min-Hsiu

Subjects

Quantum Physics

Abstract

Multiproposal Markov chain Monte Carlo (MCMC) algorithms choose from multiple proposals at each iteration in order to sample from challenging target distributions more efficiently. Recent work demonstrates the possibility of quadratic quantum speedups for one such multiproposal MCMC algorithm. Using $P$ proposals, this quantum parallel MCMC QPMCMC algorithm requires only $\mathcal{O}(\sqrt{P})$ target evaluations at each step. Here, we present a fast new quantum multiproposal MCMC strategy, QPMCMC2, that only requires $\mathcal{O}(1)$ target evaluations and $\mathcal{O}(\log P)$ qubits. Unlike its slower predecessor, the QPMCMC2 Markov kernel (1) maintains detailed balance exactly and (2) is fully explicit for a large class of graphical models. We demonstrate this flexibility by applying QPMCMC2 to novel Ising-type models built on bacterial evolutionary networks and obtain significant speedups for Bayesian ancestral trait reconstruction for 248 observed salmonella bacteria.

Published

2023

8. Many-core algorithms for high-dimensional gradients on phylogenetic trees.

Author

Gangavarapu, Karthik, Ji, Xiang, Baele, Guy, Fourment, Mathieu, Lemey, Philippe, Matsen, Frederick, and Suchard, Marc

Subjects

Phylogeny, Software, Bayes Theorem, Algorithms, Codon, Nucleotides

Abstract

MOTIVATION: Advancements in high-throughput genomic sequencing are delivering genomic pathogen data at an unprecedented rate, positioning statistical phylogenetics as a critical tool to monitor infectious diseases globally. This rapid growth spurs the need for efficient inference techniques, such as Hamiltonian Monte Carlo (HMC) in a Bayesian framework, to estimate parameters of these phylogenetic models where the dimensions of the parameters increase with the number of sequences N. HMC requires repeated calculation of the gradient of the data log-likelihood with respect to (wrt) all branch-length-specific (BLS) parameters that traditionally takes O(N2) operations using the standard pruning algorithm. A recent study proposes an approach to calculate this gradient in O(N), enabling researchers to take advantage of gradient-based samplers such as HMC. The CPU implementation of this approach makes the calculation of the gradient computationally tractable for nucleotide-based models but falls short in performance for larger state-space size models, such as Markov-modulated and codon models. Here, we describe novel massively parallel algorithms to calculate the gradient of the log-likelihood wrt all BLS parameters that take advantage of graphics processing units (GPUs) and result in many fold higher speedups over previous CPU implementations. RESULTS: We benchmark these GPU algorithms on three computing systems using three evolutionary inference examples exploring complete genomes from 997 dengue viruses, 62 carnivore mitochondria and 49 yeasts, and observe a >128-fold speedup over the CPU implementation for codon-based models and >8-fold speedup for nucleotide-based models. As a practical demonstration, we also estimate the timing of the first introduction of West Nile virus into the continental Unites States under a codon model with a relaxed molecular clock from 104 full viral genomes, an inference task previously intractable. AVAILABILITY AND IMPLEMENTATION: We provide an implementation of our GPU algorithms in BEAGLE v4.0.0 (https://github.com/beagle-dev/beagle-lib), an open-source library for statistical phylogenetics that enables parallel calculations on multi-core CPUs and GPUs. We employ a BEAGLE-implementation using the Bayesian phylogenetics framework BEAST (https://github.com/beast-dev/beast-mcmc).

Published

2024

9. Evolutionary genomics of Leishmania braziliensis across the neotropical realm

Author

Heeren, Senne, Sanders, Mandy, Shaw, Jeffrey Jon, Pinto Brandão-Filho, Sinval, Côrtes Boité, Mariana, Motta Cantanhêde, Lilian, Chourabi, Khaled, Maes, Ilse, Llanos-Cuentas, Alejandro, Arevalo, Jorge, Marco, Jorge D., Lemey, Philippe, Cotton, James A., Dujardin, Jean-Claude, Cupolillo, Elisa, and Van den Broeck, Frederik

Published

2024

10. Epidemiological data of an influenza A/H5N1 outbreak in elephant seals in Argentina indicates mammal-to-mammal transmission

Author

Uhart, Marcela M., Vanstreels, Ralph E. T., Nelson, Martha I., Olivera, Valeria, Campagna, Julieta, Zavattieri, Victoria, Lemey, Philippe, Campagna, Claudio, Falabella, Valeria, and Rimondi, Agustina

Published

2024

11. Drivers and impact of the early silent invasion of SARS-CoV-2 Alpha

Author

Faucher, Benjamin, Sabbatini, Chiara E., Czuppon, Peter, Kraemer, Moritz U. G., Lemey, Philippe, Colizza, Vittoria, Blanquart, François, Boëlle, Pierre-Yves, and Poletto, Chiara

Published

2024

12. Dispersion patterns of SARS-CoV-2 variants Gamma, Lambda and Mu in Latin America and the Caribbean

Author

Gräf, Tiago, Martinez, Alexander A., Bello, Gonzalo, Dellicour, Simon, Lemey, Philippe, Colizza, Vittoria, Mazzoli, Mattia, Poletto, Chiara, Cardoso, Vanessa Leiko Oikawa, da Silva, Alexandre Freitas, Motta, Fernando Couto, Resende, Paola Cristina, Siqueira, Marilda M., Franco, Leticia, Gresh, Lionel, Gabastou, Jean-Marc, Rodriguez, Angel, Vicari, Andrea, Aldighieri, Sylvain, Mendez-Rico, Jairo, and Leite, Juliana Almeida

Published

2024

13. Evolutionary genomics of Leishmania braziliensis across the neotropical realm

Author

Senne Heeren, Mandy Sanders, Jeffrey Jon Shaw, Sinval Pinto Brandão-Filho, Mariana Côrtes Boité, Lilian Motta Cantanhêde, Khaled Chourabi, Ilse Maes, Alejandro Llanos-Cuentas, Jorge Arevalo, Jorge D. Marco, Philippe Lemey, James A. Cotton, Jean-Claude Dujardin, Elisa Cupolillo, and Frederik Van den Broeck

Subjects

Biology (General), QH301-705.5

Abstract

Abstract The Neotropical realm, one of the most biodiverse regions on Earth, houses a broad range of zoonoses that pose serious public health threats. Protozoan parasites of the Leishmania (Viannia) braziliensis clade cause zoonotic leishmaniasis in Latin America with clinical symptoms ranging from simple cutaneous to destructive, disfiguring mucosal lesions. We present the first comprehensive genome-wide continental study including 257 cultivated isolates representing most of the geographical distribution of this major human pathogen. The L. braziliensis clade is genetically highly heterogeneous, consisting of divergent parasite groups that are associated with different environments and vary greatly in diversity. Apart from several small ecologically isolated groups with little diversity, our sampling identifies two major parasite groups, one associated with the Amazon and the other with the Atlantic Forest biomes. These groups show different recombination histories, as suggested by high levels of heterozygosity and effective population sizes in the Amazonian group in contrast to high levels of linkage and clonality in the Atlantic group. We argue that these differences are linked to strong eco-epidemiological differences between the two regions. In contrast to geographically focused studies, our study provides a broad understanding of the molecular epidemiology of zoonotic parasites circulating in tropical America.

Published

2024

14. Epidemiological data of an influenza A/H5N1 outbreak in elephant seals in Argentina indicates mammal-to-mammal transmission

Author

Marcela M. Uhart, Ralph E. T. Vanstreels, Martha I. Nelson, Valeria Olivera, Julieta Campagna, Victoria Zavattieri, Philippe Lemey, Claudio Campagna, Valeria Falabella, and Agustina Rimondi

Subjects

Science

Abstract

Abstract H5N1 high pathogenicity avian influenza virus has killed thousands of marine mammals in South America since 2022. Here we report epidemiological data and full genome characterization of clade 2.3.4.4b H5N1 HPAI viruses associated with a massive outbreak in southern elephant seals (Mirounga leonina) at Península Valdés, Argentina, in October 2023. We also report on H5N1 viruses in concurrently dead terns. Our genomic analysis shows that viruses from pinnipeds and terns in Argentina form a distinct clade with marine mammal viruses from Peru, Chile, Brazil and Uruguay. Additionally, these marine mammal clade viruses share an identical set of mammalian adaptation mutations which were also present in tern viruses. Our combined ecological and phylogenetic data support mammal-to-mammal transmission and occasional mammal-to-bird spillover and suggest multinational transmission of H5N1 viruses in mammals. We reflect that H5N1 viruses becoming more evolutionary flexible and adapting to mammals in new ways could have global consequences for wildlife, humans, and/or livestock.

Published

2024

15. Researchers' Responsibilities in Resource-Constrained Settings: Experiences of Implementing an Ancillary Care Policy in a Vaccine Trial in the Democratic Republic of the Congo

Author

Gwen Lemey, Trésor Zola, Ynke Larivière, Solange Milolo, Engbu Danoff, Lazarre Bakonga, Emmanuel Esanga, Peter Vermeiren, Vivi Maketa, Junior Matangila, Patrick Mitashi, Pierre Van Damme, Jean-Pierre Van geertruyden, Raffaella Ravinetto, and Hypolite Muhindo-Mavoko

Abstract

In this paper, we discuss challenges associated with implementing a policy for Ancillary Care (AC) for related and unrelated (serious) adverse events during an Ebola vaccine trial conducted in a remote area of the Democratic Republic of the Congo. Conducting clinical trials in resource-constrained settings can raise context-related challenges that have implications for study participants' health and wellbeing. During the Ebola vaccine study, three participants were injured in road traffic accidents, but there were unexpected difficulties when trying to apply the AC policy. First, because of the nature of the adverse events, the insurer refused to cover the costs. Second, the AC policy did not address treatments by traditional medicine, even though traditional medicines are frequently used and highly trusted in the study community. This highlighted a contrast between the researchers' well-intentioned AC approach and the participants' legitimate preferences. The way in which researchers should address their responsibility to provide AC is not straightforward; it requires contextualization. Our experience highlights the importance of involving community representatives and the local ethics committee to ensure development of an AC policy that is culturally and ethically appropriate. Additionally, the insurance contract should clearly stipulate which adverse events are linked to the trial participation, and thus eligible for coverage, to avoid controversies when claims are made.

Published

2024

16. APOBEC3 deaminase editing in mpox virus as evidence for sustained human transmission since at least 2016.

Author

OToole, Áine, Neher, Richard, Ndodo, Nnaemeka, Borges, Vitor, Gannon, Ben, Gomes, João, Groves, Natalie, King, David, Maloney, Daniel, Lemey, Philippe, Lewandowski, Kuiama, Loman, Nicholas, Myers, Richard, Omah, Ifeanyi, Worobey, Michael, Chand, Meera, Ihekweazu, Chikwe, Ulaeto, David, Adetifa, Ifedayo, Rambaut, Andrew, and Suchard, Marc

Subjects

Animals, Humans, Africa, Central, Africa, Western, APOBEC Deaminases, Disease Outbreaks, Mpox (monkeypox), Monkeypox virus, Mutation, Phylogeny, Viral Zoonoses, RNA Editing

Abstract

Historically, mpox has been characterized as an endemic zoonotic disease that transmits through contact with the reservoir rodent host in West and Central Africa. However, in May 2022, human cases of mpox were detected spreading internationally beyond countries with known endemic reservoirs. When the first cases from 2022 were sequenced, they shared 42 nucleotide differences from the closest mpox virus (MPXV) previously sampled. Nearly all these mutations are characteristic of the action of APOBEC3 deaminases, host enzymes with antiviral function. Assuming APOBEC3 editing is characteristic of human MPXV infection, we developed a dual-process phylogenetic molecular clock that-inferring a rate of ~6 APOBEC3 mutations per year-estimates that MPXV has been circulating in humans since 2016. These observations of sustained MPXV transmission present a fundamental shift to the perceived paradigm of MPXV epidemiology as a zoonosis and highlight the need for revising public health messaging around MPXV as well as outbreak management and control.

Published

2023

17. Shrinkage-based Random Local Clocks with Scalable Inference.

Author

Fisher, Alexander, Ji, Xiang, Nishimura, Akihiko, Baele, Guy, Lemey, Philippe, and Suchard, Marc

Subjects

Bayesian phylogenetics, Hamiltonian Monte Carlo, divergence time estimation, random local clock, shrinkage clock, Animals, Phylogeny, Bayes Theorem, Evolution, Molecular, Mammals, Time Factors, Models, Genetic

Abstract

Molecular clock models undergird modern methods of divergence-time estimation. Local clock models propose that the rate of molecular evolution is constant within phylogenetic subtrees. Current local clock inference procedures exhibit one or more weaknesses, namely they achieve limited scalability to trees with large numbers of taxa, impose model misspecification, or require a priori knowledge of the existence and location of clocks. To overcome these challenges, we present an autocorrelated, Bayesian model of heritable clock rate evolution that leverages heavy-tailed priors with mean zero to shrink increments of change between branch-specific clocks. We further develop an efficient Hamiltonian Monte Carlo sampler that exploits closed form gradient computations to scale our model to large trees. Inference under our shrinkage clock exhibits a speed-up compared to the popular random local clock when estimating branch-specific clock rates on a variety of simulated datasets. This speed-up increases with the size of the problem. We further show our shrinkage clock recovers known local clocks within a rodent and mammalian phylogeny. Finally, in a problem that once appeared computationally impractical, we investigate the heritable clock structure of various surface glycoproteins of influenza A virus in the absence of prior knowledge about clock placement. We implement our shrinkage clock and make it publicly available in the BEAST software package.

Published

2023

18. Scalable Bayesian Divergence Time Estimation With Ratio Transformations.

Author

Ji, Xiang, Fisher, Alexander, Su, Shuo, Thorne, Jeffrey, Potter, Barney, Lemey, Philippe, Baele, Guy, and Suchard, Marc

Subjects

Bayesian inference, Hamiltonian Monte Carlo, divergence time estimation, effective sample size, pathogens, phylogenetics, ratio transformation, Phylogeny, Bayes Theorem, Algorithms, Time Factors, Monte Carlo Method

Abstract

Divergence time estimation is crucial to provide temporal signals for dating biologically important events from species divergence to viral transmissions in space and time. With the advent of high-throughput sequencing, recent Bayesian phylogenetic studies have analyzed hundreds to thousands of sequences. Such large-scale analyses challenge divergence time reconstruction by requiring inference on highly correlated internal node heights that often become computationally infeasible. To overcome this limitation, we explore a ratio transformation that maps the original $N-1$ internal node heights into a space of one height parameter and $N-2$ ratio parameters. To make the analyses scalable, we develop a collection of linear-time algorithms to compute the gradient and Jacobian-associated terms of the log-likelihood with respect to these ratios. We then apply Hamiltonian Monte Carlo sampling with the ratio transform in a Bayesian framework to learn the divergence times in 4 pathogenic viruses (West Nile virus, rabies virus, Lassa virus, and Ebola virus) and the coralline red algae. Our method both resolves a mixing issue in the West Nile virus example and improves inference efficiency by at least 5-fold for the Lassa and rabies virus examples as well as for the algae example. Our method now also makes it computationally feasible to incorporate mixed-effects molecular clock models for the Ebola virus example, confirms the findings from the original study, and reveals clearer multimodal distributions of the divergence times of some clades of interest.

Published

2023

19. Accelerated evolution of SARS-CoV-2 in free-ranging white-tailed deer.

Author

McBride, Dillon, Garushyants, Sofya, Franks, John, Magee, Andrew, Overend, Steven, Huey, Devra, Williams, Amanda, Faith, Seth, Kandeil, Ahmed, Trifkovic, Sanja, Miller, Lance, Jeevan, Trushar, Patel, Anami, Nolting, Jacqueline, Tonkovich, Michael, Genders, J, Montoney, Andrew, Kasnyik, Kevin, Linder, Timothy, Bevins, Sarah, Lenoch, Julianna, Chandler, Jeffrey, DeLiberto, Thomas, Koonin, Eugene, Suchard, Marc, Lemey, Philippe, Webby, Richard, Nelson, Martha, and Bowman, Andrew

Subjects

Animals, Humans, SARS-CoV-2, COVID-19, Bayes Theorem, Deer, Pandemics, Phylogeny

Abstract

The zoonotic origin of the COVID-19 pandemic virus highlights the need to fill the vast gaps in our knowledge of SARS-CoV-2 ecology and evolution in non-human hosts. Here, we detected that SARS-CoV-2 was introduced from humans into white-tailed deer more than 30 times in Ohio, USA during November 2021-March 2022. Subsequently, deer-to-deer transmission persisted for 2-8 months, disseminating across hundreds of kilometers. Newly developed Bayesian phylogenetic methods quantified how SARS-CoV-2 evolution is not only three-times faster in white-tailed deer compared to the rate observed in humans but also driven by different mutational biases and selection pressures. The long-term effect of this accelerated evolutionary rate remains to be seen as no critical phenotypic changes were observed in our animal models using white-tailed deer origin viruses. Still, SARS-CoV-2 has transmitted in white-tailed deer populations for a relatively short duration, and the risk of future changes may have serious consequences for humans and livestock.

Published

2023

20. Accelerating Bayesian inference of dependency between mixed-type biological traits.

Author

Zhang, Zhenyu, Nishimura, Akihiko, Trovão, Nídia, Cherry, Joshua, Holbrook, Andrew, Ji, Xiang, Lemey, Philippe, and Suchard, Marc

Subjects

Bayes Theorem, Influenza A Virus, H1N1 Subtype, Phylogeny, Flowers, Glycosylation

Abstract

Inferring dependencies between mixed-type biological traits while accounting for evolutionary relationships between specimens is of great scientific interest yet remains infeasible when trait and specimen counts grow large. The state-of-the-art approach uses a phylogenetic multivariate probit model to accommodate binary and continuous traits via a latent variable framework, and utilizes an efficient bouncy particle sampler (BPS) to tackle the computational bottleneck-integrating many latent variables from a high-dimensional truncated normal distribution. This approach breaks down as the number of specimens grows and fails to reliably characterize conditional dependencies between traits. Here, we propose an inference pipeline for phylogenetic probit models that greatly outperforms BPS. The novelty lies in 1) a combination of the recent Zigzag Hamiltonian Monte Carlo (Zigzag-HMC) with linear-time gradient evaluations and 2) a joint sampling scheme for highly correlated latent variables and correlation matrix elements. In an application exploring HIV-1 evolution from 535 viruses, the inference requires joint sampling from an 11,235-dimensional truncated normal and a 24-dimensional covariance matrix. Our method yields a 5-fold speedup compared to BPS and makes it possible to learn partial correlations between candidate viral mutations and virulence. Computational speedup now enables us to tackle even larger problems: we study the evolution of influenza H1N1 glycosylations on around 900 viruses. For broader applicability, we extend the phylogenetic probit model to incorporate categorical traits, and demonstrate its use to study Aquilegia flower and pollinator co-evolution.

Published

2023

21. Genomic assessment of invasion dynamics of SARS-CoV-2 Omicron BA.1.

Author

Tsui, Joseph, McCrone, John, Lambert, Ben, Bajaj, Sumali, Inward, Rhys, Bosetti, Paolo, Pena, Rosario, Tegally, Houriiyah, Hill, Verity, Zarebski, Alexander, Peacock, Thomas, Liu, Luyang, Wu, Neo, Davis, Megan, Bogoch, Isaac, Khan, Kamran, Kall, Meaghan, Abdul Aziz, Nurin, Colquhoun, Rachel, OToole, Áine, Jackson, Ben, Dasgupta, Abhishek, Wilkinson, Eduan, de Oliveira, Tulio, Connor, Thomas, Loman, Nicholas, Colizza, Vittoria, Fraser, Christophe, Volz, Erik, Ji, Xiang, Gutierrez, Bernardo, Chand, Meera, Dellicour, Simon, Cauchemez, Simon, Raghwani, Jayna, Suchard, Marc, Lemey, Philippe, Rambaut, Andrew, Pybus, Oliver, and Kraemer, Moritz

Subjects

Humans, Africa, Southern, COVID-19, Genomics, SARS-CoV-2, Phylogeny

Abstract

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) variants of concern (VOCs) now arise in the context of heterogeneous human connectivity and population immunity. Through a large-scale phylodynamic analysis of 115,622 Omicron BA.1 genomes, we identified >6,000 introductions of the antigenically distinct VOC into England and analyzed their local transmission and dispersal history. We find that six of the eight largest English Omicron lineages were already transmitting when Omicron was first reported in southern Africa (22 November 2021). Multiple datasets show that importation of Omicron continued despite subsequent restrictions on travel from southern Africa as a result of export from well-connected secondary locations. Initiation and dispersal of Omicron transmission lineages in England was a two-stage process that can be explained by models of the countrys human geography and hierarchical travel network. Our results enable a comparison of the processes that drive the invasion of Omicron and other VOCs across multiple spatial scales.

Published

2023

22. Random-effects substitution models for phylogenetics via scalable gradient approximations

Author

Magee, Andrew F., Holbrook, Andrew J., Pekar, Jonathan E., Caviedes-Solis, Itzue W., Matsen IV, Fredrick A., Baele, Guy, Wertheim, Joel O., Ji, Xiang, Lemey, Philippe, and Suchard, Marc A.

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Phylogenetic and discrete-trait evolutionary inference depend heavily on an appropriate characterization of the underlying character substitution process. In this paper, we present random-effects substitution models that extend common continuous-time Markov chain models into a richer class of processes capable of capturing a wider variety of substitution dynamics. As these random-effects substitution models often require many more parameters than their usual counterparts, inference can be both statistically and computationally challenging. Thus, we also propose an efficient approach to compute an approximation to the gradient of the data likelihood with respect to all unknown substitution model parameters. We demonstrate that this approximate gradient enables scaling of sampling-based inference, namely Bayesian inference via Hamiltonian Monte Carlo, under random-effects substitution models across large trees and state-spaces. Applied to a dataset of 583 SARS-CoV-2 sequences, an HKY model with random-effects shows strong signals of nonreversibility in the substitution process, and posterior predictive model checks clearly show that it is a more adequate model than a reversible model. When analyzing the pattern of phylogeographic spread of 1441 influenza A virus (H3N2) sequences between 14 regions, a random-effects phylogeographic substitution model infers that air travel volume adequately predicts almost all dispersal rates. A random-effects state-dependent substitution model reveals no evidence for an effect of arboreality on the swimming mode in the tree frog subfamily Hylinae. Simulations reveal that random-effects substitution models can accommodate both negligible and radical departures from the underlying base substitution model. We show that our gradient-based inference approach is over an order of magnitude more time efficient than conventional approaches.

Published

2023

23. Many-core algorithms for high-dimensional gradients on phylogenetic trees

Author

Gangavarapu, Karthik, Ji, Xiang, Baele, Guy, Fourment, Mathieu, Lemey, Philippe, Matsen IV, Frederick A., and Suchard, Marc A.

Subjects

Statistics - Computation, Quantitative Biology - Populations and Evolution

Abstract

The rapid growth in genomic pathogen data spurs the need for efficient inference techniques, such as Hamiltonian Monte Carlo (HMC) in a Bayesian framework, to estimate parameters of these phylogenetic models where the dimensions of the parameters increase with the number of sequences $N$. HMC requires repeated calculation of the gradient of the data log-likelihood with respect to (wrt) all branch-length-specific (BLS) parameters that traditionally takes $\mathcal{O}(N^2)$ operations using the standard pruning algorithm. A recent study proposes an approach to calculate this gradient in $\mathcal{O}(N)$, enabling researchers to take advantage of gradient-based samplers such as HMC. The CPU implementation of this approach makes the calculation of the gradient computationally tractable for nucleotide-based models but falls short in performance for larger state-space size models, such as codon models. Here, we describe novel massively parallel algorithms to calculate the gradient of the log-likelihood wrt all BLS parameters that take advantage of graphics processing units (GPUs) and result in many fold higher speedups over previous CPU implementations. We benchmark these GPU algorithms on three computing systems using three evolutionary inference examples: carnivores, dengue and yeast, and observe a greater than 128-fold speedup over the CPU implementation for codon-based models and greater than 8-fold speedup for nucleotide-based models. As a practical demonstration, we also estimate the timing of the first introduction of West Nile virus into the continental Unites States under a codon model with a relaxed molecular clock from 104 full viral genomes, an inference task previously intractable. We provide an implementation of our GPU algorithms in BEAGLE v4.0.0, an open source library for statistical phylogenetics that enables parallel calculations on multi-core CPUs and GPUs.

Published

2023

24. How fast are viruses spreading in the wild?

Author

Simon Dellicour, Paul Bastide, Pauline Rocu, Denis Fargette, Olivier J Hardy, Marc A Suchard, Stéphane Guindon, and Philippe Lemey

Subjects

Biology (General), QH301-705.5

Abstract

Genomic data collected from viral outbreaks can be exploited to reconstruct the dispersal history of viral lineages in a two-dimensional space using continuous phylogeographic inference. These spatially explicit reconstructions can subsequently be used to estimate dispersal metrics that can be informative of the dispersal dynamics and the capacity to spread among hosts. Heterogeneous sampling efforts of genomic sequences can however impact the accuracy of phylogeographic dispersal metrics. While the impact of spatial sampling bias on the outcomes of continuous phylogeographic inference has previously been explored, the impact of sampling intensity (i.e., sampling size) when aiming to characterise dispersal patterns through continuous phylogeographic reconstructions has not yet been thoroughly evaluated. In our study, we use simulations to evaluate the robustness of 3 dispersal metrics - a lineage dispersal velocity, a diffusion coefficient, and an isolation-by-distance (IBD) signal metric - to the sampling intensity. Our results reveal that both the diffusion coefficient and IBD signal metrics appear to be the most robust to the number of samples considered for the phylogeographic reconstruction. We then use these 2 dispersal metrics to compare the dispersal pattern and capacity of various viruses spreading in animal populations. Our comparative analysis reveals a broad range of IBD patterns and diffusion coefficients mostly reflecting the dispersal capacity of the main infected host species but also, in some cases, the likely signature of rapid and/or long-distance dispersal events driven by human-mediated movements through animal trade. Overall, our study provides key recommendations for the use of lineage dispersal metrics to consider in future studies and illustrates their application to compare the spread of viruses in various settings.

Published

2024

25. The genomic evolutionary dynamics and global circulation patterns of respiratory syncytial virus

Author

Annefleur C. Langedijk, Bram Vrancken, Robert Jan Lebbink, Deidre Wilkins, Elizabeth J. Kelly, Eugenio Baraldi, Abiel Homero Mascareñas de Los Santos, Daria M. Danilenko, Eun Hwa Choi, María Angélica Palomino, Hsin Chi, Christian Keller, Robert Cohen, Jesse Papenburg, Jeffrey Pernica, Anne Greenough, Peter Richmond, Federico Martinón-Torres, Terho Heikkinen, Renato T. Stein, Mitsuaki Hosoya, Marta C. Nunes, Charl Verwey, Anouk Evers, Leyla Kragten-Tabatabaie, Marc A. Suchard, Sergei L. Kosakovsky Pond, Chiara Poletto, Vittoria Colizza, Philippe Lemey, Louis J. Bont, and on behalf of the INFORM-RSV Study Group

Subjects

Science

Abstract

Abstract Respiratory syncytial virus (RSV) is a leading cause of acute lower respiratory tract infection in young children and the second leading cause of infant death worldwide. While global circulation has been extensively studied for respiratory viruses such as seasonal influenza, and more recently also in great detail for SARS-CoV-2, a lack of global multi-annual sampling of complete RSV genomes limits our understanding of RSV molecular epidemiology. Here, we capitalise on the genomic surveillance by the INFORM-RSV study and apply phylodynamic approaches to uncover how selection and neutral epidemiological processes shape RSV diversity. Using complete viral genome sequences, we show similar patterns of site-specific diversifying selection among RSVA and RSVB and recover the imprint of non-neutral epidemic processes on their genealogies. Using a phylogeographic approach, we provide evidence for air travel governing the global patterns of RSVA and RSVB spread, which results in a considerable degree of phylogenetic mixing across countries. Our findings highlight the potential of systematic global RSV genomic surveillance for transforming our understanding of global RSV spread.

Published

2024

26. Data Integration in Bayesian Phylogenetics

Author

Hassler, Gabriel W, Magee, Andrew, Zhang, Zhenyu, Baele, Guy, Lemey, Philippe, Ji, Xiang, Fourment, Mathieu, and Suchard, Marc A

Subjects

Mathematical Sciences, Statistics, Genetics, Networking and Information Technology R&D (NITRD), Bioengineering, Infection, Generic health relevance, Bayesian networks, continuous-time Markov processes, Gaussian processes, phylogenetic comparative methods, phylogeography, Numerical and Computational Mathematics

Abstract

Researchers studying the evolution of viral pathogens and other organisms increasingly encounter and use large and complex data sets from multiple different sources. Statistical research in Bayesian phylogenetics has risen to this challenge. Researchers use phylogenetics not only to reconstruct the evolutionary history of a group of organisms, but also to understand the processes that guide its evolution and spread through space and time. To this end, it is now the norm to integrate numerous sources of data. For example, epidemiologists studying the spread of a virus through a region incorporate data including genetic sequences (e.g. DNA), time, location (both continuous and discrete) and environmental covariates (e.g. social connectivity between regions) into a coherent statistical model. Evolutionary biologists routinely do the same with genetic sequences, location, time, fossil and modern phenotypes, and ecological covariates. These complex, hierarchical models readily accommodate both discrete and continuous data and have enormous combined discrete/continuous parameter spaces including, at a minimum, phylogenetic tree topologies and branch lengths. The increased size and complexity of these statistical models have spurred advances in computational methods to make them tractable. We discuss both the modeling and computational advances below, as well as unsolved problems and areas of active research.

Published

2023

27. Early Genomic Surveillance and Phylogeographic Analysis of Getah Virus, a Reemerging Arbovirus, in Livestock in China.

Author

Zhao, Jin, Dellicour, Simon, Yan, Ziqing, Veit, Michael, Gill, Mandev, He, Wan-Ting, Zhai, Xiaofeng, Ji, Xiang, Suchard, Marc, Lemey, Philippe, and Su, Shuo

Subjects

Getah virus, genomic surveillance, next-generation sequencing, phylodynamics, phylogeography, zoonotic pathogens, Animals, Humans, Mice, Arboviruses, China, Genomics, Livestock, Phylogeny, Genome, Viral

Abstract

Getah virus (GETV) mainly causes disease in livestock and may pose an epidemic risk due to its expanding host range and the potential of long-distance dispersal through animal trade. Here, we used metagenomic next-generation sequencing (mNGS) to identify GETV as the pathogen responsible for reemerging swine disease in China and subsequently estimated key epidemiological parameters using phylodynamic and spatially-explicit phylogeographic approaches. The GETV isolates were able to replicate in a variety of cell lines, including human cells, and showed high pathogenicity in a mouse model, suggesting the potential for more mammal hosts. We obtained 16 complete genomes and 79 E2 gene sequences from viral strains collected in China from 2016 to 2021 through large-scale surveillance among livestock, pets, and mosquitoes. Our phylogenetic analysis revealed that three major GETV lineages are responsible for the current epidemic in livestock in China. We identified three potential positively selected sites and mutations of interest in E2, which may impact the transmissibility and pathogenicity of the virus. Phylodynamic inference of the GETV demographic dynamics identified an association between livestock meat consumption and the evolution of viral genetic diversity. Finally, phylogeographic reconstruction of GETV dispersal indicated that the sampled lineages have preferentially circulated within areas associated with relatively higher mean annual temperature and pig population density. Our results highlight the importance of continuous surveillance of GETV among livestock in southern Chinese regions associated with relatively high temperatures. IMPORTANCE Although livestock is known to be the primary reservoir of Getah virus (GETV) in Asian countries, where identification is largely based on serology, the evolutionary history and spatial epidemiology of GETV in these regions remain largely unknown. Through our sequencing efforts, we provided robust support for lineage delineation of GETV and identified three major lineages that are responsible for the current epidemic in livestock in China. We further analyzed genomic and epidemiological data to reconstruct the recent demographic and dispersal history of GETV in domestic animals in China and to explore the impact of environmental factors on its genetic diversity and its diffusion. Notably, except for livestock meat consumption, other pig-related factors such as the evolution of live pig transport and pork production do not show a significant association with the evolution of viral genetic diversity, pointing out that further studies should investigate the potential contribution of other host species to the GETV outbreak. Our analysis of GETV demonstrates the need for wider animal species surveillance and provides a baseline for future studies of the molecular epidemiology and early warning of emerging arboviruses in China.

Published

2023

28. Dispersal history and bidirectional human-fish host switching of invasive, hypervirulent Streptococcus agalactiae sequence type 283.

Author

Schar, Daniel, Zhang, Zhenyu, Pires, Joao, Vrancken, Bram, Suchard, Marc, Lemey, Philippe, Ip, Margaret, Gilbert, Marius, Van Boeckel, Thomas, and Dellicour, Simon

Abstract

Human group B Streptococcus (GBS) infections attributable to an invasive, hypervirulent sequence type (ST) 283 have been associated with freshwater fish consumption in Asia. The origin, geographic dispersion pathways and host transitions of GBS ST283 remain unresolved. We gather 328 ST283 isolate whole-genome sequences collected from humans and fish between 1998 and 2021, representing eleven countries across four continents. We apply Bayesian phylogeographic analyses to reconstruct the dispersal history of ST283 and combine ST283 phylogenies with genetic markers and host association to investigate host switching and the gain and loss of antimicrobial resistance and virulence factor genes. Initial dispersal within Asia followed ST283 emergence in the early 1980s, with Singapore, Thailand and Hong Kong observed as early transmission hubs. Subsequent intercontinental dispersal originating from Vietnam began in the decade commencing 2001, demonstrating ST283 holds potential to expand geographically. Furthermore, we observe bidirectional host switching, with the detection of more frequent human-to-fish than fish-to-human transitions, suggesting that sound wastewater management, hygiene and sanitation may help to interrupt chains of transmission between hosts. We also show that antimicrobial resistance and virulence factor genes were lost more frequently than gained across the evolutionary history of ST283. Our findings highlight the need for enhanced surveillance, clinical awareness, and targeted risk mitigation to limit transmission and reduce the impact of an emerging pathogen associated with a high-growth aquaculture industry.

Published

2023

29. Newly identified lineages of porcine hemagglutinating encephalomyelitis virus exhibit respiratory phenotype.

Author

He, Wan-Ting, Li, Dongyan, Baele, Guy, Zhao, Jin, Jiang, Zhiwen, Ji, Xiang, Veit, Michael, Suchard, Marc, Holmes, Edward, Lemey, Philippe, Boni, Maciej, and Su, Shuo

Subjects

novel porcine hemagglutinating encephalomyelitis virus, recombination, swine coronavirus

Abstract

Swine pathogens have a long history of zoonotic transmission to humans, occasionally leading to sustained outbreaks or pandemics. Through a retrospective epidemiological study of swine populations in China, we describe novel lineages of porcine hemagglutinating encephalomyelitis virus (PHEV) complex coronaviruses (CoVs) that cause exclusively respiratory symptoms with no signs of the neurological symptoms typically associated with classical PHEV infection. Through large-scale epidemiological surveillance, we show that these novel lineages have circulated in at least eight provinces in southeastern China. Phylogenetic and recombination analyses of twenty-four genomes identified two major viral lineages causing respiratory symptoms with extensive recombination within them, between them, and between classical PHEV and the novel respiratory variant PHEV (rvPHEV) lineages. Divergence times among the sampled lineages in the PHEV virus complex date back to 1886-1958 (mean estimate 1928), with the two major rvPHEV lineages separating approximately 20 years later. Many rvPHEV viruses show amino acid substitutions at the carbohydrate-binding site of hemagglutinin esterase (HE) and/or have lost the cysteine required for HE dimerization. This resembles the early adaptation of human CoVs, where HE lost its hemagglutination ability to adapt to growth in the human respiratory tract. Our study represents the first report of the evolutionary history of rvPHEV circulating in swine and highlights the importance of characterizing CoV diversity and recombination in swine to identify pathogens with outbreak potential that could threaten swine farming.

Published

2023

30. SPREAD 4: online visualization of pathogen phylogeographic reconstructions

Author

Nahata, Kanika D, Bielejec, Filip, Monetta, Juan, Dellicour, Simon, Rambaut, Andrew, Suchard, Marc A, Baele, Guy, and Lemey, Philippe

Subjects

Biological Sciences, Genetics, phylogeography, viral spread, BEAST, Bayesian inference, visualisation, Evolutionary Biology, Microbiology

Abstract

Phylogeographic analyses aim to extract information about pathogen spread from genomic data, and visualising spatio-temporal reconstructions is a key aspect of this process. Here we present SPREAD 4, a feature-rich web-based application that visualises estimates of pathogen dispersal resulting from Bayesian phylogeographic inference using BEAST on a geographic map, offering zoom-and-filter functionality and smooth animation over time. SPREAD 4 takes as input phylogenies with both discrete and continuous location annotation and offers customised visualisation as well as generation of publication-ready figures. SPREAD 4 now features account-based storage and easy sharing of visualisations by means of unique web addresses. SPREAD 4 is intuitive to use and is available online at https://spreadviz.org, with an accompanying web page containing answers to frequently asked questions at https://beast.community/spread4.

Published

2022

31. Scalable Bayesian phylogenetics

Author

Fisher, Alexander A, Hassler, Gabriel W, Ji, Xiang, Baele, Guy, Suchard, Marc A, and Lemey, Philippe

Subjects

Biological Sciences, Genetics, Infectious Diseases, Bioengineering, Infection, Algorithms, Bayes Theorem, COVID-19, Humans, Markov Chains, Monte Carlo Method, Phylogeny, SARS-CoV-2, Software, Bayesian phylogenetics, scalable inference, online inference, Hamiltonian Monte Carlo, BEAST, adapative MCMC, Medical and Health Sciences, Evolutionary Biology, Biological sciences, Biomedical and clinical sciences

Abstract

Recent advances in Bayesian phylogenetics offer substantial computational savings to accommodate increased genomic sampling that challenges traditional inference methods. In this review, we begin with a brief summary of the Bayesian phylogenetic framework, and then conceptualize a variety of methods to improve posterior approximations via Markov chain Monte Carlo (MCMC) sampling. Specifically, we discuss methods to improve the speed of likelihood calculations, reduce MCMC burn-in, and generate better MCMC proposals. We apply several of these techniques to study the evolution of HIV virulence along a 1536-tip phylogeny and estimate the internal node heights of a 1000-tip SARS-CoV-2 phylogenetic tree in order to illustrate the speed-up of such analyses using current state-of-the-art approaches. We conclude our review with a discussion of promising alternatives to MCMC that approximate the phylogenetic posterior. This article is part of a discussion meeting issue 'Genomic population structures of microbial pathogens'.

Published

2022

32. Drivers and impact of the early silent invasion of SARS-CoV-2 Alpha

Author

Benjamin Faucher, Chiara E. Sabbatini, Peter Czuppon, Moritz U. G. Kraemer, Philippe Lemey, Vittoria Colizza, François Blanquart, Pierre-Yves Boëlle, and Chiara Poletto

Subjects

Science

Abstract

Abstract SARS-CoV-2 variants of concern (VOCs) circulated cryptically before being identified as a threat, delaying interventions. Here we studied the drivers of such silent spread and its epidemic impact to inform future response planning. We focused on Alpha spread out of the UK. We integrated spatio-temporal records of international mobility, local epidemic growth and genomic surveillance into a Bayesian framework to reconstruct the first three months after Alpha emergence. We found that silent circulation lasted from days to months and decreased with the logarithm of sequencing coverage. Social restrictions in some countries likely delayed the establishment of local transmission, mitigating the negative consequences of late detection. Revisiting the initial spread of Alpha supports local mitigation at the destination in case of emerging events.

Published

2024

33. Dispersion patterns of SARS-CoV-2 variants Gamma, Lambda and Mu in Latin America and the Caribbean

Author

Tiago Gräf, Alexander A. Martinez, Gonzalo Bello, Simon Dellicour, Philippe Lemey, Vittoria Colizza, Mattia Mazzoli, Chiara Poletto, Vanessa Leiko Oikawa Cardoso, Alexandre Freitas da Silva, COVIGEN, Fernando Couto Motta, Paola Cristina Resende, Marilda M. Siqueira, Leticia Franco, Lionel Gresh, Jean-Marc Gabastou, Angel Rodriguez, Andrea Vicari, Sylvain Aldighieri, Jairo Mendez-Rico, and Juliana Almeida Leite

Subjects

Science

Abstract

Abstract Latin America and Caribbean (LAC) regions were an important epicenter of the COVID-19 pandemic and SARS-CoV-2 evolution. Through the COVID-19 Genomic Surveillance Regional Network (COVIGEN), LAC countries produced an important number of genomic sequencing data that made possible an enhanced SARS-CoV-2 genomic surveillance capacity in the Americas, paving the way for characterization of emerging variants and helping to guide the public health response. In this study we analyzed approximately 300,000 SARS-CoV-2 sequences generated between February 2020 and March 2022 by multiple genomic surveillance efforts in LAC and reconstructed the diffusion patterns of the main variants of concern (VOCs) and of interest (VOIs) possibly originated in the Region. Our phylogenetic analysis revealed that the spread of variants Gamma, Lambda and Mu reflects human mobility patterns due to variations of international air passenger transportation and gradual lifting of social distance measures previously implemented in countries. Our results highlight the potential of genetic data to reconstruct viral spread and unveil preferential routes of viral migrations that are shaped by human mobility patterns.

Published

2024

34. Synchrony of Bird Migration with Global Dispersal of Avian Influenza Reveals Exposed Bird Orders

Author

Qiqi Yang, Ben Wang, Phillipe Lemey, Lu Dong, Tong Mu, R. Alex Wiebe, Fengyi Guo, Nídia Sequeira Trovão, Sang Woo Park, Nicola Lewis, Joseph L.-H. Tsui, Sumali Bajaj, Yachang Cheng, Luojun Yang, Yuki Haba, Bingying Li, Guogang Zhang, Oliver G. Pybus, Huaiyu Tian, and Bryan Grenfell

Subjects

Science

Abstract

Abstract Highly pathogenic avian influenza virus (HPAIV) A H5, particularly clade 2.3.4.4, has caused worldwide outbreaks in domestic poultry, occasional spillover to humans, and increasing deaths of diverse species of wild birds since 2014. Wild bird migration is currently acknowledged as an important ecological process contributing to the global dispersal of HPAIV H5. However, this mechanism has not been quantified using bird movement data from different species, and the timing and location of exposure of different species is unclear. We sought to explore these questions through phylodynamic analyses based on empirical data of bird movement tracking and virus genome sequences of clade 2.3.4.4 and 2.3.2.1. First, we demonstrate that seasonal bird migration can explain salient features of the global dispersal of clade 2.3.4.4. Second, we detect synchrony between the seasonality of bird annual cycle phases and virus lineage movements. We reveal the differing exposed bird orders at geographical origins and destinations of HPAIV H5 clade 2.3.4.4 lineage movements, including relatively under-discussed orders. Our study provides a phylodynamic framework that links the bird movement ecology and genomic epidemiology of avian influenza; it highlights the importance of integrating bird behavior and life history in avian influenza studies.

Published

2024

35. An Overview of Ultra-WideBand (UWB) Standards and Organizations (IEEE 802.15.4, FiRa, Apple): Interoperability Aspects and Future Research Directions

Author

Coppens, Dieter, Shahid, Adnan, Lemey, Sam, Marshall, Ben Van Herbruggen Chris, and De Poorter, Eli

Subjects

Electrical Engineering and Systems Science - Signal Processing, Computer Science - Information Theory

Abstract

The increasing popularity of ultra-wideband (UWB) technology for location-based services, such as access control and real-time indoor track&tracing, as well as UWB support in new consumer devices such as smartphones, has resulted in the availability of multiple new UWB radio chips. However, due to this increase in UWB device availability, the question of which (industry) standards and configuration factors impact UWB interoperability and compatibility becomes increasingly important. In this paper, the fundamentals of UWB compatibility are investigated by first giving an overview of different UWB radio chips on the market. After that, an overview of UWB standards and organizations is given. Next, this overview is used to discuss the focus of these different standards and to identify the differences between them. We describe compatibility issues and associated interoperability aspects related to physical (PHY), medium-access-control (MAC) and upper layers. For the PHY layer, compatibility is possible for all UWB radio chips if the correct settings are configured. For the MAC layer, the implementation of the multiple access scheme as well as the localization technique is mostly proprietary. For the device discovery, several standards are currently being drafted. Finally, future challenges related to UWB interoperability are discussed., Comment: 23 pages, 20 figures, 15 tables

Published

2022

36. Accelerating Bayesian inference of dependency between complex biological traits

Author

Zhang, Zhenyu, Nishimura, Akihiko, Trovão, Nídia S., Cherry, Joshua L., Holbrook, Andrew J., Ji, Xiang, Lemey, Philippe, and Suchard, Marc A.

Subjects

Statistics - Methodology, Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Inferring dependencies between complex biological traits while accounting for evolutionary relationships between specimens is of great scientific interest yet remains infeasible when trait and specimen counts grow large. The state-of-the-art approach uses a phylogenetic multivariate probit model to accommodate binary and continuous traits via a latent variable framework, and utilizes an efficient bouncy particle sampler (BPS) to tackle the computational bottleneck -- integrating many latent variables from a high-dimensional truncated normal distribution. This approach breaks down as the number of specimens grows and fails to reliably characterize conditional dependencies between traits. Here, we propose an inference pipeline for phylogenetic probit models that greatly outperforms BPS. The novelty lies in 1) a combination of the recent Zigzag Hamiltonian Monte Carlo (Zigzag-HMC) with linear-time gradient evaluations and 2) a joint sampling scheme for highly correlated latent variables and correlation matrix elements. In an application exploring HIV-1 evolution from 535 viruses, the inference requires joint sampling from an 11,235-dimensional truncated normal and a 24-dimensional covariance matrix. Our method yields a 5-fold speedup compared to BPS and makes it possible to learn partial correlations between candidate viral mutations and virulence. Computational speedup now enables us to tackle even larger problems: we study the evolution of influenza H1N1 glycosylations on around 900 viruses. For broader applicability, we extend the phylogenetic probit model to incorporate categorical traits, and demonstrate its use to study Aquilegia flower and pollinator co-evolution., Comment: 39 pages, 5 figures, 3 tables

Published

2022

37. The Huanan Seafood Wholesale Market in Wuhan was the early epicenter of the COVID-19 pandemic

Author

Worobey, Michael, Levy, Joshua I, Serrano, Lorena Malpica, Crits-Christoph, Alexander, Pekar, Jonathan E, Goldstein, Stephen A, Rasmussen, Angela L, Kraemer, Moritz UG, Newman, Chris, Koopmans, Marion PG, Suchard, Marc A, Wertheim, Joel O, Lemey, Philippe, Robertson, David L, Garry, Robert F, Holmes, Edward C, Rambaut, Andrew, and Andersen, Kristian G

Subjects

Prevention, Emerging Infectious Diseases, Biodefense, Vaccine Related, Lung, Good Health and Well Being, Animals, COVID-19, China, Humans, Pandemics, SARS-CoV-2, Seafood, Viral Zoonoses, General Science & Technology

Abstract

Understanding how severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) emerged in 2019 is critical to preventing future zoonotic outbreaks before they become the next pandemic. The Huanan Seafood Wholesale Market in Wuhan, China, was identified as a likely source of cases in early reports, but later this conclusion became controversial. We show here that the earliest known COVID-19 cases from December 2019, including those without reported direct links, were geographically centered on this market. We report that live SARS-CoV-2-susceptible mammals were sold at the market in late 2019 and that within the market, SARS-CoV-2-positive environmental samples were spatially associated with vendors selling live mammals. Although there is insufficient evidence to define upstream events, and exact circumstances remain obscure, our analyses indicate that the emergence of SARS-CoV-2 occurred through the live wildlife trade in China and show that the Huanan market was the epicenter of the COVID-19 pandemic.

Published

2022

38. Scalable Bayesian divergence time estimation with ratio transformations

Author

Ji, Xiang, Fisher, Alexander A., Su, Shuo, Thorne, Jeffrey L., Potter, Barney, Lemey, Philippe, Baele, Guy, and Suchard, Marc A.

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Divergence time estimation is crucial to provide temporal signals for dating biologically important events, from species divergence to viral transmissions in space and time. With the advent of high-throughput sequencing, recent Bayesian phylogenetic studies have analyzed hundreds to thousands of sequences. Such large-scale analyses challenge divergence time reconstruction by requiring inference on highly-correlated internal node heights that often become computationally infeasible. To overcome this limitation, we explore a ratio transformation that maps the original N - 1 internal node heights into a space of one height parameter and N - 2 ratio parameters. To make analyses scalable, we develop a collection of linear-time algorithms to compute the gradient and Jacobian-associated terms of the log-likelihood with respect to these ratios. We then apply Hamiltonian Monte Carlo sampling with the ratio transform in a Bayesian framework to learn the divergence times in four pathogenic virus phylogenies: West Nile virus, rabies virus, Lassa virus and Ebola virus. Our method both resolves a mixing issue in the West Nile virus example and improves inference efficiency by at least 5-fold for the Lassa and rabies virus examples. Our method also makes it now computationally feasible to incorporate mixed-effects molecular clock models for the Ebola virus example, confirms the findings from the original study and reveals clearer multimodal distributions of the divergence times of some clades of interest., Comment: 34 pages, 6 figures

Published

2021

39. An ancillary care policy in a vaccine trial conducted in a resource-constrained setting: evaluation and policy recommendations

Author

Raffaella Ravinetto, Jean-Pierre Van Geertruyden, Pierre Van Damme, Gwen Lemey, Ynke Larivière, Vivi Maketa, Patrick Mitashi, Trésor Zola, Hypolite Muhindo-Mavoko, Bernard Isekah Osang'ir, Primo Kimbulu, Solange Milolo, Engbu Danoff, and Yves Tchuma

Subjects

Medicine (General), R5-920, Infectious and parasitic diseases, RC109-216

Abstract

Introduction Clear guidelines to implement ancillary care (AC) in clinical trials conducted in resource-constrained settings are lacking. Here, we evaluate an AC policy developed for a vaccine trial in the Democratic Republic of the Congo and formulate policy recommendations.Methods To evaluate the AC policy, we performed a longitudinal cohort study, nested in an open-label, single-centre, randomised Ebola vaccine trial conducted among healthcare personnel. Participants’ demographic information, residence distance to the study site and details on the financial and/or medical support provided for any (serious) adverse events ((S)AE) were combined and analysed. To assess the feasibility of the AC policy, an expenditure analysis of the costs related to AC support outcomes was performed.Results Enrolment in this evaluation study started on 29 November 2021. The study lasted 11 months and included 655 participants from the Ebola vaccine trial. In total, 393 participants used the AC policy, mostly for AE management (703 AE and 94 SAE) via medication provided by the study pharmacy (75.3%). Men had a 35.2% (95% CI 4.0% to 56.6%) lower likelihood of reporting AE compared with women. Likewise, this was 32.3% lower (95% CI 5.8% to 51.4%) for facility-based compared with community-based healthcare providers. The daily AE reporting was 78.8% lower during the passive vs the active trial stage, and 97.4% lower during unscheduled vs scheduled visits (p

Published

2024

40. Accommodating sampling location uncertainty in continuous phylogeography

Author

Dellicour, Simon, Lemey, Philippe, Suchard, Marc A, Gilbert, Marius, and Baele, Guy

Subjects

Biological Sciences, Genetics, virus, host species, continuous phylogeography, sampling precision, Bayesian inference, BEAST, Evolutionary Biology, Microbiology

Abstract

Phylogeographic inference of the dispersal history of viral lineages offers key opportunities to tackle epidemiological questions about the spread of fast-evolving pathogens across human, animal and plant populations. In continuous space, i.e. when locations are specified by longitude and latitude, these reconstructions are however often limited by the availability or accessibility of precise sampling locations required for such spatially explicit analyses. We here review the different approaches that can be considered when genomic sequences are associated with a geographic area of sampling instead of precise coordinates. In particular, we describe and compare the approaches to define homogeneous and heterogeneous prior ranges of sampling coordinates.

Published

2022

41. Inferring Phenotypic Trait Evolution on Large Trees With Many Incomplete Measurements

Author

Hassler, Gabriel, Tolkoff, Max R, Allen, William L, Ho, Lam Si Tung, Lemey, Philippe, and Suchard, Marc A

Subjects

Economics, Statistics, Econometrics, Mathematical Sciences, Bioengineering, 1.4 Methodologies and measurements, Aetiology, 2.5 Research design and methodologies (aetiology), Underpinning research, Generic health relevance, Bayesian inference, Matrix-normal, Missing data, Phylogenetics, matrix-normal, missing data, phylogenetics, stat.ME, stat.CO, Demography, Statistics & Probability

Abstract

Comparative biologists are often interested in inferring covariation between multiple biological traits sampled across numerous related taxa. To properly study these relationships, we must control for the shared evolutionary history of the taxa to avoid spurious inference. An additional challenge arises as obtaining a full suite of measurements becomes increasingly difficult with increasing taxa. This generally necessitates data imputation or integration, and existing control techniques typically scale poorly as the number of taxa increases. We propose an inference technique that integrates out missing measurements analytically and scales linearly with the number of taxa by using a post-order traversal algorithm under a multivariate Brownian diffusion (MBD) model to characterize trait evolution. We further exploit this technique to extend the MBD model to account for sampling error or non-heritable residual variance. We test these methods to examine mammalian life history traits, prokaryotic genomic and phenotypic traits, and HIV infection traits. We find computational efficiency increases that top two orders-of-magnitude over current best practices. While we focus on the utility of this algorithm in phylogenetic comparative methods, our approach generalizes to solve long-standing challenges in computing the likelihood for matrix-normal and multivariate normal distributions with missing data at scale.

Published

2022

42. Unlocking capacities of genomics for the COVID-19 response and future pandemics

Author

Knyazev, Sergey, Chhugani, Karishma, Sarwal, Varuni, Ayyala, Ram, Singh, Harman, Karthikeyan, Smruthi, Deshpande, Dhrithi, Baykal, Pelin Icer, Comarova, Zoia, Lu, Angela, Porozov, Yuri, Vasylyeva, Tetyana I, Wertheim, Joel O, Tierney, Braden T, Chiu, Charles Y, Sun, Ren, Wu, Aiping, Abedalthagafi, Malak S, Pak, Victoria M, Nagaraj, Shivashankar H, Smith, Adam L, Skums, Pavel, Pasaniuc, Bogdan, Komissarov, Andrey, Mason, Christopher E, Bortz, Eric, Lemey, Philippe, Kondrashov, Fyodor, Beerenwinkel, Niko, Lam, Tommy Tsan-Yuk, Wu, Nicholas C, Zelikovsky, Alex, Knight, Rob, Crandall, Keith A, and Mangul, Serghei

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, Networking and Information Technology R&D (NITRD), Vaccine Related, Infectious Diseases, Emerging Infectious Diseases, Biotechnology, Prevention, Biodefense, Generic health relevance, Infection, Good Health and Well Being, COVID-19, Genomics, Humans, Pandemics, SARS-CoV-2, Technology, Medical and Health Sciences, Developmental Biology, Biological sciences

Abstract

During the COVID-19 pandemic, genomics and bioinformatics have emerged as essential public health tools. The genomic data acquired using these methods have supported the global health response, facilitated development of testing methods, and allowed timely tracking of novel SARS-CoV-2 variants. Yet the virtually unlimited potential for rapid generation and analysis of genomic data is also coupled with unique technical, scientific, and organizational challenges. Here, we discuss the application of genomic and computational methods for the efficient data driven COVID-19 response, advantages of democratization of viral sequencing around the world, and challenges associated with viral genome data collection and processing.

Published

2022

43. Principled, practical, flexible, fast: a new approach to phylogenetic factor analysis

Author

Hassler, Gabriel W., Gallone, Brigida, Aristide, Leandro, Allen, William L., Tolkoff, Max R., Holbrook, Andrew J., Baele, Guy, Lemey, Philippe, and Suchard, Marc A.

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Applications, Statistics - Methodology

Abstract

Biological phenotypes are products of complex evolutionary processes in which selective forces influence multiple biological trait measurements in unknown ways. Phylogenetic factor analysis disentangles these relationships across the evolutionary history of a group of organisms. Scientists seeking to employ this modeling framework confront numerous modeling and implementation decisions, the details of which pose computational and replicability challenges. General and impactful community employment requires a data scientific analysis plan that balances flexibility, speed and ease of use, while minimizing model and algorithm tuning. Even in the presence of non-trivial phylogenetic model constraints, we show that one may analytically address latent factor uncertainty in a way that (a) aids model flexibility, (b) accelerates computation (by as much as 500-fold) and (c) decreases required tuning. We further present practical guidance on inference and modeling decisions as well as diagnosing and solving common problems in these analyses. We codify this analysis plan in an automated pipeline that distills the potentially overwhelming array of modeling decisions into a small handful of (typically binary) choices. We demonstrate the utility of these methods and analysis plan in four real-world problems of varying scales., Comment: 27 pages, 7 figures, 1 table

Published

2021

44. Diversity and dissemination of viruses in pathogenic protozoa

Author

Senne Heeren, Ilse Maes, Mandy Sanders, Lon-Fye Lye, Vanessa Adaui, Jorge Arevalo, Alejandro Llanos-Cuentas, Lineth Garcia, Philippe Lemey, Stephen M. Beverley, James A. Cotton, Jean-Claude Dujardin, and Frederik Van den Broeck

Subjects

Science

Abstract

Abstract Viruses are the most abundant biological entities on Earth and play a significant role in the evolution of many organisms and ecosystems. In pathogenic protozoa, the presence of viruses has been linked to an increased risk of treatment failure and severe clinical outcome. Here, we studied the molecular epidemiology of the zoonotic disease cutaneous leishmaniasis in Peru and Bolivia through a joint evolutionary analysis of Leishmania braziliensis and their dsRNA Leishmania virus 1. We show that parasite populations circulate in tropical rainforests and are associated with single viral lineages that appear in low prevalence. In contrast, groups of hybrid parasites are geographically and ecologically more dispersed and associated with an increased prevalence, diversity and spread of viruses. Our results suggest that parasite gene flow and hybridization increased the frequency of parasite-virus symbioses, a process that may change the epidemiology of leishmaniasis in the region.

Published

2023

45. A compact SiGe D-band power amplifier for scalable photonic-enabled phased antenna arrays

Author

Reinier Broucke, Nishant Singh, Michiel Van Osta, Joris Van Kerrebrouck, Piet Demeester, Sam Lemey, and Guy Torfs

Subjects

Medicine, Science

Abstract

Abstract To address the rising demand for high-speed wireless data links, communication systems operating at frequencies beyond $${100}\,\hbox {GHz}$$ 100 GHz are being targeted. A key enabling technology in the development of these wireless systems is the phased antenna array. Yet, the design and implementation of such steerable antenna arrays at frequencies over $${100}\,\hbox {GHz}$$ 100 GHz comes with a multitude of challenges. In particular, the cointegration of active electronics at each antenna element poses a major hurdle due to the inherent space constraints in the array. This article proposes a novel scalable concept for opto-electronic phased antenna arrays operating at 140 GHz. It details the system architecture of a transmitter that enables the implementation of large scale, wideband, 2D steerable phased antenna arrays and presents the design and measurement of a compact SiGe power amplifier (PA) chip to be used as one of its key building blocks. The amplifier achieves a gain of 20 dB at 135 GHz, features a $$P_{1dB}$$ P 1 d B of 14.6 dBm and can support data rates up to 45 Gbps in a limited footprint of only 540μm × 550μm. This makes it one of the fastest, most powerful D-band power amplifiers in literature with a footprint compatible with $$\frac{\lambda }{2}$$ λ 2 -spaced phased array integration.

Published

2023

46. Air-filled SIW technology for mass-manufacturable and energy-efficient terahertz systems

Author

Laura Van Messem, Siddhartha Sinha, Ilja Ocket, Heinrich Trischler, Erich Schlaffer, Daniel Schlick, Hendrik Rogier, and Sam Lemey

Subjects

Medicine, Science

Abstract

Abstract To accommodate the ever-growing data requirements in densely populated areas and address the need for high-resolution sensing in diverse next-generation applications, there is a noticeable trend towards utilizing large unallocated frequency bands above 100 GHz. To overcome the harsh propagation conditions, large-scale antenna arrays are crucial and urge the need for cost-effective, mass-manufacturable technologies. A dedicated Any-Layer High Density Interconnect PCB technology for highly efficient wireless D-band (110–170 GHz) systems is proposed. Specifically, the adapted stack accommodates broadband air-filled substrate-integrated-waveguide components for efficient long-range signal distribution and low-loss passives. The viability of the suggested technology platform is demonstrated by designing, fabricating and measuring several essential low-loss air-filled substrate-integrated-waveguide components, such as a dual rectangular filter, with a minimal insertion loss of 0.87 dB and 10 dB-matching within the (132.8–139.2 GHz) frequency band, and an air-filled waveguide with a routing loss of only 0.08 dB/mm and a flat amplitude variation within 0.01 dB/mm over the (115–155 GHz) frequency range. A broadband transition towards stripline, with a limited loss of 1.1 dB, is described to interface these waveguides with compactly integrated chips. A tolerance analysis is included as well as a comparison to the state of the art.

Published

2023

47. Phylogeography reveals association between swine trade and the spread of porcine epidemic diarrhea virus in China and across the world

Author

He, Wan-Ting, Bollen, Nena, Xu, Yi, Zhao, Jin, Dellicour, Simon, Yan, Ziqing, Gong, Wenjie, Zhang, Cheng, Zhang, Letian, Lu, Meng, Lai, Alexander, Suchard, Marc A, Ji, Xiang, Tu, Changchun, Lemey, Philippe, Baele, Guy, and Su, Shuo

Subjects

Biochemistry and Cell Biology, Evolutionary Biology, Genetics, Biological Sciences, Emerging Infectious Diseases, Vaccine Related, Prevention, Infectious Diseases, Infection, Good Health and Well Being, Animals, China, Coronavirus, Pandemics, Phylogeny, Phylogeography, Porcine epidemic diarrhea virus, Swine, Swine Diseases, United States, porcine epidemic diarrhea virus, Coronaviridae, phylogeography, Bayesian inference, generalized linear model, BEAST, Biochemistry and cell biology, Evolutionary biology

Abstract

The ongoing SARS (severe acute respiratory syndrome)-CoV (coronavirus)-2 pandemic has exposed major gaps in our knowledge on the origin, ecology, evolution, and spread of animal coronaviruses. Porcine epidemic diarrhea virus (PEDV) is a member of the genus Alphacoronavirus in the family Coronaviridae that may have originated from bats and leads to significant hazards and widespread epidemics in the swine population. The role of local and global trade of live swine and swine-related products in disseminating PEDV remains unclear, especially in developing countries with complex swine production systems. Here, we undertake an in-depth phylogeographic analysis of PEDV sequence data (including 247 newly sequenced samples) and employ an extension of this inference framework that enables formally testing the contribution of a range of predictor variables to the geographic spread of PEDV. Within China, the provinces of Guangdong and Henan were identified as primary hubs for the spread of PEDV, for which we estimate live swine trade to play a very important role. On a global scale, the United States and China maintain the highest number of PEDV lineages. We estimate that, after an initial introduction out of China, the United States acted as an important source of PEDV introductions into Japan, Korea, China, and Mexico. Live swine trade also explains the dispersal of PEDV on a global scale. Given the increasingly global trade of live swine, our findings have important implications for designing prevention and containment measures to combat a wide range of livestock coronaviruses.

Published

2022

48. Archival influenza virus genomes from Europe reveal genomic variability during the 1918 pandemic

Author

Patrono, Livia V, Vrancken, Bram, Budt, Matthias, Düx, Ariane, Lequime, Sebastian, Boral, Sengül, Gilbert, M Thomas P, Gogarten, Jan F, Hoffmann, Luisa, Horst, David, Merkel, Kevin, Morens, David, Prepoint, Baptiste, Schlotterbeck, Jasmin, Schuenemann, Verena J, Suchard, Marc A, Taubenberger, Jeffery K, Tenkhoff, Luisa, Urban, Christian, Widulin, Navena, Winter, Eduard, Worobey, Michael, Schnalke, Thomas, Wolff, Thorsten, Lemey, Philippe, and Calvignac-Spencer, Sébastien

Subjects

Influenza, Infectious Diseases, Pneumonia & Influenza, Biodefense, Vaccine Related, Human Genome, Prevention, Emerging Infectious Diseases, Genetics, 2.2 Factors relating to the physical environment, Aetiology, Infection, Genome, Viral, Genomics, Humans, Influenza A Virus, H1N1 Subtype, Influenza A virus, Influenza, Human

Abstract

The 1918 influenza pandemic was the deadliest respiratory pandemic of the 20th century and determined the genomic make-up of subsequent human influenza A viruses (IAV). Here, we analyze both the first 1918 IAV genomes from Europe and the first from samples prior to the autumn peak. 1918 IAV genomic diversity is consistent with a combination of local transmission and long-distance dispersal events. Comparison of genomes before and during the pandemic peak shows variation at two sites in the nucleoprotein gene associated with resistance to host antiviral response, pointing at a possible adaptation of 1918 IAV to humans. Finally, local molecular clock modeling suggests a pure pandemic descent of seasonal H1N1 IAV as an alternative to the hypothesis of origination through an intrasubtype reassortment.

Published

2022

49. The phylodynamics of SARS-CoV-2 during 2020 in Finland.

Author

Truong Nguyen, Phuoc, Kant, Ravi, Van den Broeck, Frederik, Suvanto, Maija T, Alburkat, Hussein, Virtanen, Jenni, Ahvenainen, Ella, Castren, Robert, Hong, Samuel L, Baele, Guy, Ahava, Maarit J, Jarva, Hanna, Jokiranta, Suvi Tuulia, Kallio-Kokko, Hannimari, Kekäläinen, Eliisa, Kirjavainen, Vesa, Kortela, Elisa, Kurkela, Satu, Lappalainen, Maija, Liimatainen, Hanna, Suchard, Marc A, Hannula, Sari, Ellonen, Pekka, Sironen, Tarja, Lemey, Philippe, Vapalahti, Olli, and Smura, Teemu

Subjects

SARS-CoV-2, Viral epidemiology, Pneumonia & Influenza, Vaccine Related, Biodefense, Emerging Infectious Diseases, Prevention, Infectious Diseases, Infection, Good Health and Well Being

Abstract

BackgroundSevere acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has caused millions of infections and fatalities globally since its emergence in late 2019. The virus was first detected in Finland in January 2020, after which it rapidly spread among the populace in spring. However, compared to other European nations, Finland has had a low incidence of SARS-CoV-2. To gain insight into the origins and turnover of SARS-CoV-2 lineages circulating in Finland in 2020, we investigated the phylogeographic and -dynamic history of the virus.MethodsThe origins of SARS-CoV-2 introductions were inferred via Travel-aware Bayesian time-measured phylogeographic analyses. Sequences for the analyses included virus genomes belonging to the B.1 lineage and with the D614G mutation from countries of likely origin, which were determined utilizing Google mobility data. We collected all available sequences from spring and fall peaks to study lineage dynamics.ResultsWe observed rapid turnover among Finnish lineages during this period. Clade 20C became the most prevalent among sequenced cases and was replaced by other strains in fall 2020. Bayesian phylogeographic reconstructions suggested 42 independent introductions into Finland during spring 2020, mainly from Italy, Austria, and Spain.ConclusionsA single introduction from Spain might have seeded one-third of cases in Finland during spring in 2020. The investigations of the original introductions of SARS-CoV-2 to Finland during the early stages of the pandemic and of the subsequent lineage dynamics could be utilized to assess the role of transboundary movements and the effects of early intervention and public health measures.

Published

2022

50. Predicting the evolution of the Lassa virus endemic area and population at risk over the next decades

Author

Klitting, Raphaëlle, Kafetzopoulou, Liana E, Thiery, Wim, Dudas, Gytis, Gryseels, Sophie, Kotamarthi, Anjali, Vrancken, Bram, Gangavarapu, Karthik, Momoh, Mambu, Sandi, John Demby, Goba, Augustine, Alhasan, Foday, Grant, Donald S, Okogbenin, Sylvanus, Ogbaini-Emovo, Ephraim, Garry, Robert F, Smither, Allison R, Zeller, Mark, Pauthner, Matthias G, McGraw, Michelle, Hughes, Laura D, Duraffour, Sophie, Günther, Stephan, Suchard, Marc A, Lemey, Philippe, Andersen, Kristian G, and Dellicour, Simon

Subjects

Infectious Diseases, Emerging Infectious Diseases, Rare Diseases, Aetiology, 2.2 Factors relating to the physical environment, Infection, Life on Land, Animals, Humans, Lassa Fever, Lassa virus, Phylogeography, Risk Factors, Rodentia

Abstract

Lassa fever is a severe viral hemorrhagic fever caused by a zoonotic virus that repeatedly spills over to humans from its rodent reservoirs. It is currently not known how climate and land use changes could affect the endemic area of this virus, currently limited to parts of West Africa. By exploring the environmental data associated with virus occurrence using ecological niche modelling, we show how temperature, precipitation and the presence of pastures determine ecological suitability for virus circulation. Based on projections of climate, land use, and population changes, we find that regions in Central and East Africa will likely become suitable for Lassa virus over the next decades and estimate that the total population living in ecological conditions that are suitable for Lassa virus circulation may drastically increase by 2070. By analysing geotagged viral genomes using spatially-explicit phylogeography and simulating virus dispersal, we find that in the event of Lassa virus being introduced into a new suitable region, its spread might remain spatially limited over the first decades.

Published

2022