Your search keyword '"Ma, Eric J."' showing total 8 results

1. Forecasting SARS-CoV-2 spike protein evolution from small data by deep learning and regression.

Author

King, Samuel, Chen, Xinyi E., Ng, Sarah W. S., Rostin, Kimia, Hahn, Samuel V., Roberts, Tylo, Schwab, Janella C., Sekhon, Parneet, Kagieva, Madina, Reilly, Taylor, Ruo Chen Qi, Salman, Paarsa, Hong, Ryan J., Ma, Eric J., and Hallam, Steven J.

Subjects

DEEP learning, ARTIFICIAL neural networks, VIRAL proteins, SARS-CoV-2, COVID-19 pandemic, AMINO acid sequence

Abstract

The emergence of SARS-CoV-2 variants during the COVID-19 pandemic caused frequent global outbreaks that confounded public health efforts across many jurisdictions, highlighting the need for better understanding and prediction of viral evolution. Predictive models have been shown to support disease prevention efforts, such as with the seasonal influenza vaccine, but they require abundant data. For emerging viruses of concern, such models should ideally function with relatively sparse data typically encountered at the early stages of a viral outbreak. Conventional discrete approaches have proven difficult to develop due to the spurious and reversible nature of amino acid mutations and the overwhelming number of possible protein sequences adding computational complexity. We hypothesized that these challenges could be addressed by encoding discrete protein sequences into continuous numbers, effectively reducing the data size while enhancing the resolution of evolutionarily relevant differences. To this end, we developed a viral protein evolution prediction model (VPRE), which reduces amino acid sequences into continuous numbers by using an artificial neural network called a variational autoencoder (VAE) and models their most statistically likely evolutionary trajectories over time using Gaussian process (GP) regression. To demonstrate VPRE, we used a small amount of early SARS-CoV-2 spike protein sequences. We show that the VAE can be trained on a synthetic dataset based on this data. To recapitulate evolution along a phylogenetic path, we used only 104 spike protein sequences and trained the GP regression with the numerical variables to project evolution up to 5 months into the future. Our predictions contained novel variants and the most frequent prediction mapped primarily to a sequence that differed by only a single amino acid from the most reported spike protein within the prediction timeframe. Novel variants in the spike receptor binding domain (RBD) were capable of binding human angiotensin-converting enzyme 2 (ACE2) in silico, with comparable or better binding than previously resolved RBD-ACE2 complexes. Together, these results indicate the utility and tractability of combining deep learning and regression to model viral protein evolution with relatively sparse datasets, toward developing more effective medical interventions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Design of potent antimalarials with generative chemistry.

Author

Godinez, William J., Ma, Eric J., Chao, Alexander T., Pei, Luying, Skewes-Cox, Peter, Canham, Stephen M., Jenkins, Jeremy L., Young, Joseph M., Martin, Eric J., and Guiguemde, W. Armand

Published

2022

3. Reassortment of Influenza A Viruses in Wild Birds in Alaska before H5 Clade 2.3.4.4 Outbreaks.

Author

Hill, Nichola J., Hussein, Islam T. M., Davis, Kimberly R., Ma, Eric J., Spivey, Timothy J., Ramey, Andrew M., Puryear, Wendy Blay, Das, Suman R., Halpin, Rebecca A., Xudong Lin, Fedorova, Nadia B., Suarez, David L., Boyce, Walter M., Runstadler, Jonathan A., and Lin, Xudong

Subjects

INFLUENZA A virus, BIRDS as carriers of disease, DISEASE outbreaks, DIAGNOSIS, THERAPEUTICS, PREVENTION, AVIAN influenza epidemiology, ANIMAL populations, ANIMALS, AVIAN influenza, EPIDEMIOLOGY, POULTRY, VIRUSES

Abstract

Sampling of mallards in Alaska during September 2014-April 2015 identified low pathogenic avian influenza A virus (subtypes H5N2 and H1N1) that shared ancestry with highly pathogenic reassortant H5N2 and H5N1 viruses. Molecular dating indicated reassortment soon after interhemispheric movement of H5N8 clade 2.3.4.4, suggesting genetic exchange in Alaska or surrounds before outbreaks. [ABSTRACT FROM AUTHOR]

Published

2017

4. Transmission of influenza reflects seasonality of wild birds across the annual cycle.

Author

Hill, Nichola J., Ma, Eric J., Meixell, Brandt W., Lindberg, Mark S., Boyce, Walter M., Runstadler, Jonathan A., and Blasius, Bernd

Subjects

INFLUENZA A virus, INFLUENZA transmission, BIRD breeding, BIRD migration, BIOLOGICAL rhythms

Abstract

Influenza A Viruses (IAV) in nature must overcome shifting transmission barriers caused by the mobility of their primary host, migratory wild birds, that change throughout the annual cycle. Using a phylogenetic network of viral sequences from North American wild birds (2008-2011) we demonstrate a shift from intraspecific to interspecific transmission that along with reassortment, allows IAV to achieve viral flow across successive seasons from summer to winter. Our study supports amplification of IAV during summer breeding seeded by overwintering virus persisting locally and virus introduced from a wide range of latitudes. As birds migrate from breeding sites to lower latitudes, they become involved in transmission networks with greater connectivity to other bird species, with interspecies transmission of reassortant viruses peaking during the winter. We propose that switching transmission dynamics may be a critical strategy for pathogens that infect mobile hosts inhabiting regions with strong seasonality. [ABSTRACT FROM AUTHOR]

Published

2016

5. Ecosystem Interactions Underlie the Spread of Avian Influenza A Viruses with Pandemic Potential.

Author

Bahl, Justin, Pham, Truc T., Hill, Nichola J., Hussein, Islam T. M., Ma, Eric J., Easterday, Bernard C., Halpin, Rebecca A., Stockwell, Timothy B., Wentworth, David E., Kayali, Ghazi, Krauss, Scott, Schultz-Cherry, Stacey, Webster, Robert G., Webby, Richard J., Swartz, Michael D., Smith, Gavin J. D., and Runstadler, Jonathan A.

Subjects

ECOSYSTEMS, AVIAN influenza A virus, BIRD migration, PANDEMICS, VIRUS diseases in poultry

Abstract

Despite evidence for avian influenza A virus (AIV) transmission between wild and domestic ecosystems, the roles of bird migration and poultry trade in the spread of viruses remain enigmatic. In this study, we integrate ecosystem interactions into a phylogeographic model to assess the contribution of wild and domestic hosts to AIV distribution and persistence. Analysis of globally sampled AIV datasets shows frequent two-way transmission between wild and domestic ecosystems. In general, viral flow from domestic to wild bird populations was restricted to within a geographic region. In contrast, spillover from wild to domestic populations occurred both within and between regions. Wild birds mediated long-distance dispersal at intercontinental scales whereas viral spread among poultry populations was a major driver of regional spread. Viral spread between poultry flocks frequently originated from persistent lineages circulating in regions of intensive poultry production. Our analysis of long-term surveillance data demonstrates that meaningful insights can be inferred from integrating ecosystem into phylogeographic reconstructions that may be consequential for pandemic preparedness and livestock protection. [ABSTRACT FROM AUTHOR]

Published

2016

6. Reticulate evolution is favored in influenza niche switching.

Author

Ma, Eric J., Hill, Nichola J., Zabilansky, Justin, Yuan, Kyle, and Runstadler, Jonathan A.

Subjects

GENETIC drift, INFLUENZA, NUCLEOTIDE sequencing, EVOLUTION research, GENE frequency, GENETICS

Abstract

Reticulate evolution is thought to accelerate the process of evolution beyond simple genetic drift and selection, helping to rapidly generate novel hybrids with combinations of adaptive traits. However, the long-standing dogma that reticulate evolutionary processes are likewise advantageous for switching ecological niches, as in microbial pathogen host switch events, has not been explicitly tested. We use data from the influenza genome sequencing project and a phylogenetic heuristic approach to show that reassortment, a reticulate evolutionary mechanism, predominates over mutational drift in transmission between different host species. Moreover, as host evolutionary distance increases, reassortment is increasingly favored. We conclude that the greater the quantitative difference between ecological niches, the greater the importance of reticulate evolutionary processes in overcoming niche barriers. [ABSTRACT FROM AUTHOR]

Published

2016

7. Peak Power And Body Mass As Indices Of Bone Loading In A Healthy Adult Population.

Author

Juhala, Candace C., Denys, Andrew T., Bugayong, Jastine C., Ma, Eric J., Kwong, Sarah M., Carvalho, Katelyn E., and Yingling, Vanessa R.

Published

2021

8. Principled Decision-Making Workflow with Hierarchical Bayesian Models of High-Throughput Dose-Response Measurements.

Author

Ma, Eric J. and Kummer, Arkadij

Subjects

WORKFLOW, DECISION making, HIERARCHICAL Bayes model, MEASUREMENT

Abstract

We present a case study applying hierarchical Bayesian estimation on high-throughput protein melting-point data measured across the tree of life. We show that the model is able to impute reasonable melting temperatures even in the face of unreasonably noisy data. Additionally, we demonstrate how to use the variance in melting-temperature posterior-distribution estimates to enable principled decision-making in common high-throughput measurement tasks, and contrast the decision-making workflow against simple maximum-likelihood curve-fitting. We conclude with a discussion of the relative merits of each workflow. [ABSTRACT FROM AUTHOR]

Published

2021