Viral pathogens are an enduring threat to global public health. This project aims use viral genomic data to improve understanding of ongoing virus evolution and to make actionable inferences to reduce the global burden of viral infectious disease. In order to be relevant for public health interventions, analyses of viral sequence data need to be incredibly rapid, both in terms of computation and in terms of dissemination. To accomplish these goals, this project will create novel methodological tools to analyze evolutionary dynamics from in?uenza genetic sequence data and to analyze transmission patterns from outbreak sequence data. These methods will result in a real-time analysis platform, realized via the website nextstrain.org, that provides constantly up-to-date analyses of a variety of viruses, including in?uenza virus, Ebola virus and Middle East respiratory syndrome coronavirus (MERS-CoV). This website would provide public health of?cials and other stakeholders an intuitive view of ongoing viral evolution and help to pinpoint targeted interventions. In the case of in?uenza, monitoring antigenic evolution of viral strains is of paramount importance. New antigenic variants of in?uenza that partially escape from prior human immunity emerge and rapidly sweep through the viral population. Such strains are less susceptible to vaccine-derived immunity and so antigenic evolution results in the need to frequently update the seasonal in?uenza vaccine. This project aims to develop tools to characterize circulating antigenic phenotypes from genetic and serological assay data and to develop methods to forecast strain dynamics and predict the makeup of the future in?uenza population. This forecasting is especially relevant to in?uenza vaccine strain selection, as a vaccine strain is chosen for the Northern Hemisphere in February for deployment the following winter. Accurate projections will aid in vaccine match for seasonal in?uenza viruses and result in improved vaccine ef?cacy. All predictions will be made in a public fashion on the website nextstrain.org, allowing wide distribution and rapid dissemination to public health of?cials. In an outbreak scenario such as the 2014?2015 West African Ebola epidemic or the 2013?2015 MERS-CoV outbreak, the focus of public health interventions shifts from vaccination to early diagnosis, contact tracing, isolation and treatment. Viral genomic data can reveal otherwise hidden transmission patterns and aid in ef?cient contact tracing. Geographic spread is especially amenable to genomic inferences. This project will develop tools to make epidemiological inferences from outbreak sequence data. These inferences will be deployed on the website nextstrain.org in real-time, allowing ?eld epidemiologists to put samples into the great epidemic context and understand the transmission history leading to the case at hand. Such a system stands to make a real contribution to global public health and outbreak response.

Public Health Relevance

This project will create tools that use viral genome data to make actionable public health inferences. Through analysis of evolutionary patterns in the seasonal in?uenza virus, I will streamline the process of vaccine strain selection and thereby improve vaccine ef?cacy. Additionally, I will use sequence data from viral outbreaks to aid contact tracing and epidemiological investigation of epidemic spread.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Unknown (R35)
Project #
5R35GM119774-02
Application #
9336324
Study Section
Special Emphasis Panel (ZRG1-CB-E (50)R)
Program Officer
Janes, Daniel E
Project Start
2016-08-23
Project End
2021-05-31
Budget Start
2017-06-01
Budget End
2018-05-31
Support Year
2
Fiscal Year
2017
Total Cost
$408,327
Indirect Cost
$172,522
Name
Fred Hutchinson Cancer Research Center
Department
Type
Research Institutes
DUNS #
078200995
City
Seattle
State
WA
Country
United States
Zip Code
98109
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