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24 results on '"Evans, Jared D."'

1. MutaGAN: A Seq2seq GAN Framework to Predict Mutations of Evolving Protein Populations

Author

Berman, Daniel S., Howser, Craig, Mehoke, Thomas, and Evans, Jared D.

Subjects
Quantitative Biology - Quantitative Methods, Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

The ability to predict the evolution of a pathogen would significantly improve the ability to control, prevent, and treat disease. Despite significant progress in other problem spaces, deep learning has yet to contribute to the issue of predicting mutations of evolving populations. To address this gap, we developed a novel machine learning framework using generative adversarial networks (GANs) with recurrent neural networks (RNNs) to accurately predict genetic mutations and evolution of future biological populations. Using a generalized time-reversible phylogenetic model of protein evolution with bootstrapped maximum likelihood tree estimation, we trained a sequence-to-sequence generator within an adversarial framework, named MutaGAN, to generate complete protein sequences augmented with possible mutations of future virus populations. Influenza virus sequences were identified as an ideal test case for this deep learning framework because it is a significant human pathogen with new strains emerging annually and global surveillance efforts have generated a large amount of publicly available data from the National Center for Biotechnology Information's (NCBI) Influenza Virus Resource (IVR). MutaGAN generated "child" sequences from a given "parent" protein sequence with a median Levenshtein distance of 2.00 amino acids. Additionally, the generator was able to augment the majority of parent proteins with at least one mutation identified within the global influenza virus population. These results demonstrate the power of the MutaGAN framework to aid in pathogen forecasting with implications for broad utility in evolutionary prediction for any protein population., Comment: 28 pages, 9 figures, 2 tables, Daniel S. Berman and Craig Howser contributed equally to this work. This paper was submitted to Artificial Intelligence

Published
2020

2. Lassa Virus Infection: a Summary for Clinicians

Author

Beitscher, Adam, Bhadelia, Nahid, Brett-Major, David, Cieslak, Theodore J, Davey, Richard T, Evans, Jared D, Frank, Maria G, Iwen, Peter, Kortepeter, Mark G, Levine, Corri, McLellan, Susan, Mehta, Aneesh K, Sauer, Lauren, Shenoy, Erica S, Zachary, Kimon, Raabe, Vanessa, and Evans, Jared D.

Published
2022
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3. South American Hemorrhagic Fevers: A summary for clinicians

Author

Beitscher, Adam, Bhadelia, Nahid, Cieslak, Theodore J., Davey, Richard T., Dierberg, Kerry, Evans, Jared D., Frank, Maria G., Grein, Jonathan, Kortepeter, Mark G., Kraft, Colleen S., Kratochvil, Chris J., Martins, Karen, McLellan, Susan, Mehta, Aneesh K., Raabe, Vanessa, Risi, George, Sauer, Lauren, Shenoy, Erica S., Uyeki, Tim, and Webb, Camille M.

Published
2021
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10. South American Hemorrhagic Fevers: A summary for clinicians

Author

Frank, Maria G., primary, Beitscher, Adam, additional, Webb, Camille M., additional, Raabe, Vanessa, additional, Bhadelia, Nahid, additional, Cieslak, Theodore J., additional, Davey, Richard T., additional, Dierberg, Kerry, additional, Evans, Jared D., additional, Frank, Maria G., additional, Grein, Jonathan, additional, Kortepeter, Mark G., additional, Kraft, Colleen S., additional, Kratochvil, Chris J., additional, Martins, Karen, additional, McLellan, Susan, additional, Mehta, Aneesh K., additional, Risi, George, additional, Sauer, Lauren, additional, Shenoy, Erica S., additional, and Uyeki, Tim, additional

Published
2021
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11. Genomic diversity of SARS-CoV-2 during early introduction into the Baltimore–Washington metropolitan area

Author

Thielen, Peter M., primary, Wohl, Shirlee, additional, Mehoke, Thomas, additional, Ramakrishnan, Srividya, additional, Kirsche, Melanie, additional, Falade-Nwulia, Oluwaseun, additional, Trovão, Nídia S., additional, Ernlund, Amanda, additional, Howser, Craig, additional, Sadowski, Norah, additional, Morris, C. Paul, additional, Hopkins, Mark, additional, Schwartz, Matthew, additional, Fan, Yunfan, additional, Gniazdowski, Victoria, additional, Lessler, Justin, additional, Sauer, Lauren, additional, Schatz, Michael C., additional, Evans, Jared D., additional, Ray, Stuart C., additional, Timp, Winston, additional, and Mostafa, Heba H., additional

Published
2021
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12. Genomic Diversity of SARS-CoV-2 During Early Introduction into the United States National Capital Region

Author

Thielen, Peter M., primary, Wohl, Shirlee, additional, Mehoke, Thomas, additional, Ramakrishnan, Srividya, additional, Kirsche, Melanie, additional, Falade-Nwulia, Oluwaseun, additional, Trovão, Nídia S., additional, Ernlund, Amanda, additional, Howser, Craig, additional, Sadowski, Norah, additional, Morris, Paul, additional, Hopkins, Mark, additional, Schwartz, Matthew, additional, Fan, Yunfan, additional, Gniazdowski, Victoria, additional, Lessler, Justin, additional, Sauer, Lauren, additional, Schatz, Michael C., additional, Evans, Jared D., additional, Ray, Stuart C., additional, Timp, Winston, additional, and Mostafa, Heba H., additional

Published
2020
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24. Genomic Diversity of SARS-CoV-2 During Early Introduction into the United States National Capital Region.

Author

Thielen PM, Wohl S, Mehoke T, Ramakrishnan S, Kirsche M, Falade-Nwulia O, Trovão NS, Ernlund A, Howser C, Sadowski N, Morris P, Hopkins M, Schwartz M, Fan Y, Gniazdowski V, Lessler J, Sauer L, Schatz MC, Evans JD, Ray SC, Timp W, and Mostafa HH

Abstract

Background: The early COVID-19 pandemic has been characterized by rapid global spread. In the United States National Capital Region, over 2,000 cases were reported within three weeks of its first detection in March 2020. We aimed to use genomic sequencing to understand the initial spread of SARS-CoV-2, the virus that causes COVID-19, in the region. By correlating genetic information to disease phenotype, we also aimed to gain insight into any correlation between viral genotype and case severity or transmissibility., Methods: We performed whole genome sequencing of clinical SARS-CoV-2 samples collected in March 2020 by the Johns Hopkins Health System. We analyzed these regional SARS-CoV-2 genomes alongside detailed clinical metadata and the global phylogeny to understand early establishment of the virus within the region., Results: We analyzed 620 samples from the Johns Hopkins Health System collected between March 11-31, 2020, comprising 37.3% of the total cases in Maryland during this period. We selected 143 of these samples for sequencing, generating 114 complete viral genomes. These genomes belong to all five major Nextstrain-defined clades, suggesting multiple introductions into the region and underscoring the diversity of the regional epidemic. We also found that clinically severe cases had genomes belonging to all of these clades., Conclusions: We established a pipeline for SARS-CoV-2 sequencing within the Johns Hopkins Health system, which enabled us to capture the significant viral diversity present in the region as early as March 2020. Efforts to control local spread of the virus were likely confounded by the number of introductions into the region early in the epidemic and interconnectedness of the region as a whole.

Published
2020
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