HIV continues to spread, episodically, among minority groups, and mostly from people unaware of their infection. To more efficiently locate undiagnosed people living with HIV for treatment, as well as to monitor prevention efforts, better epidemiological techniques are needed. Our project brings together a team of experienced researchers from clinical, molecular biology, epidemiological, mathematical, and evolutionary fields. We will develop innovative epidemiological methods by combining evolutionary theory, multi-scale dynamic modeling, artificial intelligence, and large-scale clinical and sequence data. In this renewal, we will expand on our previous work on how HIV within-host evolutionary processes interact with epidemiological dynamics. Having quantified the link between transmission history and the resulting HIV phylogeny among hosts, we conceptualize the relationship between the evolution and epidemiology of HIV into three levels: within-host, at transmission, and on the population epidemic level. Because essential processes of HIV biology and evolution have been largely ignored when modeling the epidemic level, in aim 1 we examine within-host processes that affect diversification. We will include recombination, selection, and latency in a new coalescent within-host model to evaluate the impact on the epidemiological level. We will also quantify potential within- host multi-directional selection pressures.
In aim 2, we focus on mechanisms that occur around the time of transmission. We will develop a new maximum likelihood method based on a forward-time probabilistic model of transmission that improves the inference of transmission direction and time of transmission among multiple hosts, and develop a transmission heterogeneity detection method to both assess overall possible transmission heterogeneity among infected persons, as well as to detect where in a phylogeny super- spreading may have occurred.
In aim 3, we will develop machine learning methods to handle very large data sets (103-106 patients), and use additional clinical and demographic data to augment phylogenies in order to reconstruct the underlying transmission history. All three aims will involve advancements aimed at developing and improving methods for the next generation of phylodynamic applications.

Public Health Relevance

Combining evolutionary theory, multi-scale dynamic modeling, and large-scale clinical and sequence data will transform how epidemics are investigated and prevented. Melding these resources, we will develop innovative methods for HIV epidemiological analyses and prevention efforts.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
2R01AI087520-10A1
Application #
10160559
Study Section
HIV Comorbidities and Clinical Studies Study Section (HCCS)
Program Officer
Novak, Leia Kaye
Project Start
2010-06-15
Project End
2025-06-30
Budget Start
2020-09-15
Budget End
2021-08-31
Support Year
10
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Triad National Security, LLC
Department
Type
DUNS #
080961356
City
Los Alamos
State
NM
Country
United States
Zip Code
87545
Song, Hongshuo; Giorgi, Elena E; Ganusov, Vitaly V et al. (2018) Tracking HIV-1 recombination to resolve its contribution to HIV-1 evolution in natural infection. Nat Commun 9:1928
Fun, Axel; Leitner, Thomas; Vandekerckhove, Linos et al. (2018) Impact of the HIV-1 genetic background and HIV-1 population size on the evolution of raltegravir resistance. Retrovirology 15:1
Le Vu, Stéphane; Ratmann, Oliver; Delpech, Valerie et al. (2018) Comparison of cluster-based and source-attribution methods for estimating transmission risk using large HIV sequence databases. Epidemics 23:1-10
Goyal, Ashish; Romero-Severson, Ethan Obie (2018) Screening for hepatitis D and PEG-Interferon over Tenofovir enhance general hepatitis control efforts in Brazil. PLoS One 13:e0203831
Romero-Severson, Ethan O; Ribeiro, Ruy M; Castro, Mario (2018) Noise Is Not Error: Detecting Parametric Heterogeneity Between Epidemiologic Time Series. Front Microbiol 9:1529
Volz, Erik M; Romero-Severson, Ethan; Leitner, Thomas (2017) Phylodynamic Inference across Epidemic Scales. Mol Biol Evol 34:1276-1288
Giardina, Federica; Romero-Severson, Ethan Obie; Albert, Jan et al. (2017) Inference of Transmission Network Structure from HIV Phylogenetic Trees. PLoS Comput Biol 13:e1005316
Romero-Severson, Ethan O; Bulla, Ingo; Hengartner, Nick et al. (2017) Donor-Recipient Identification in Para- and Poly-phyletic Trees Under Alternative HIV-1 Transmission Hypotheses Using Approximate Bayesian Computation. Genetics 207:1089-1101
Ratmann, Oliver; Hodcroft, Emma B; Pickles, Michael et al. (2017) Phylogenetic Tools for Generalized HIV-1 Epidemics: Findings from the PANGEA-HIV Methods Comparison. Mol Biol Evol 34:185-203
Pineda-Peña, Andrea-Clemencia; Varanda, Jorge; Sousa, João Dinis et al. (2016) On the contribution of Angola to the initial spread of HIV-1. Infect Genet Evol 46:219-222

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