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1. Bridging the gap: Using reservoir ecology and human serosurveys to estimate Lassa virus spillover in West Africa

Author

Basinski, Andrew J, Fichet-Calvet, Elisabeth, Sjodin, Anna R, Varrelman, Tanner J, Remien, Christopher H, Layman, Nathan C, Bird, Brian H, Wolking, David J, Monagin, Corina, Ghersi, Bruno M, Barry, Peter A, Jarvis, Michael A, Gessler, Paul E, and Nuismer, Scott L

Subjects
Climate Change Impacts and Adaptation, Environmental Sciences, Emerging Infectious Diseases, Clinical Research, Infectious Diseases, Prevention, 2.2 Factors relating to the physical environment, Aetiology, Infection, Africa, Western, Animals, Animals, Wild, Computational Biology, Disease Reservoirs, Ecology, Humans, Lassa Fever, Lassa virus, Machine Learning, Models, Biological, Models, Statistical, Risk, Rodentia, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics
Abstract

Forecasting the risk of pathogen spillover from reservoir populations of wild or domestic animals is essential for the effective deployment of interventions such as wildlife vaccination or culling. Due to the sporadic nature of spillover events and limited availability of data, developing and validating robust, spatially explicit, predictions is challenging. Recent efforts have begun to make progress in this direction by capitalizing on machine learning methodologies. An important weakness of existing approaches, however, is that they generally rely on combining human and reservoir infection data during the training process and thus conflate risk attributable to the prevalence of the pathogen in the reservoir population with the risk attributed to the realized rate of spillover into the human population. Because effective planning of interventions requires that these components of risk be disentangled, we developed a multi-layer machine learning framework that separates these processes. Our approach begins by training models to predict the geographic range of the primary reservoir and the subset of this range in which the pathogen occurs. The spillover risk predicted by the product of these reservoir specific models is then fit to data on realized patterns of historical spillover into the human population. The result is a geographically specific spillover risk forecast that can be easily decomposed and used to guide effective intervention. Applying our method to Lassa virus, a zoonotic pathogen that regularly spills over into the human population across West Africa, results in a model that explains a modest but statistically significant portion of geographic variation in historical patterns of spillover. When combined with a mechanistic mathematical model of infection dynamics, our spillover risk model predicts that 897,700 humans are infected by Lassa virus each year across West Africa, with Nigeria accounting for more than half of these human infections.

Published
2021

3. Quantifying the risk of spillover reduction programs for human health.

Author

Nuismer, Scott L., Basinski, Andrew J., Schreiner, Courtney L., Eskew, Evan A., Fichet-Calvet, Elisabeth, and Remien, Christopher H.

Subjects
COMPUTER simulation, AGE factors in disease, MATHEMATICAL models, RABIES, HEALTH programs
Abstract

Reducing spillover of zoonotic pathogens is an appealing approach to preventing human disease and minimizing the risk of future epidemics and pandemics. Although the immediate human health benefit of reducing spillover is clear, over time, spillover reduction could lead to counterintuitive negative consequences for human health. Here, we use mathematical models and computer simulations to explore the conditions under which unanticipated consequences of spillover reduction can occur in systems where the severity of disease increases with age at infection. Our results demonstrate that, because the average age at infection increases as spillover is reduced, programs that reduce spillover can actually increase population-level disease burden if the clinical severity of infection increases sufficiently rapidly with age. If, however, immunity wanes over time and reinfection is possible, our results reveal that negative health impacts of spillover reduction become substantially less likely. When our model is parameterized using published data on Lassa virus in West Africa, it predicts that negative health outcomes are possible, but likely to be restricted to a small subset of populations where spillover is unusually intense. Together, our results suggest that adverse consequences of spillover reduction programs are unlikely but that the public health gains observed immediately after spillover reduction may fade over time as the age structure of immunity gradually re-equilibrates to a reduced force of infection. Author summary: Many pathogens, such as rabies, coronaviruses, and hantaviruses primarily circulate within wild animals but can infect humans when the opportunity arises. This pervasive challenge to public health has motivated the development of new methods designed to reduce the frequency of these spillover events. Although reducing spillover infection of humans appears to be an obvious win for public health, it is conceivable that altering historical patterns of spillover could change the age structure of human immunity in a way that undermines human health. Using mathematical and computational models we evaluate the conditions required for these counterintuitive impacts to occur. Our analyses demonstrate that reducing spillover from wild animals will generally improve public health and that negative outcomes can occur in only rare and unusual circumstances. Although negative impacts of spillover reduction are likely to be rare, our results show that the public health benefits of spillover reduction may fade over time unless a near total elimination of spillover can be achieved. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Correction: Microbial phenotypic heterogeneity in response to a metabolic toxin: Continuous, dynamically shifting distribution of formaldehyde tolerance in Methylobacterium extorquens populations

Author

Lee, Jessica A., primary, Riazi, Siavash, additional, Nemati, Shahla, additional, Bazurto, Jannell V., additional, Vasdekis, Andreas E., additional, Ridenhour, Benjamin J., additional, Remien, Christopher H., additional, and Marx, Christopher J., additional

Published
2023
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11. Identifying the genetic basis of viral spillover using Lassa virus as a test case

Author

Whitlock, Alexander O. B., primary, Bird, Brian H., additional, Ghersi, Bruno, additional, Davison, Andrew J., additional, Hughes, Joseph, additional, Nichols, Jenna, additional, Vučak, Matej, additional, Amara, Emmanuel, additional, Bangura, James, additional, Lavalie, Edwin G., additional, Kanu, Marilyn C., additional, Kanu, Osman T., additional, Sjodin, Anna, additional, Remien, Christopher H., additional, and Nuismer, Scott L., additional

Published
2023
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12. Developing transmissible vaccines for animal infections.

Author

Streicker, Daniel G., Griffiths, Megan E., Antia, Rustom, Bergner, Laura, Bowman, Peter, dos Santos de Moraes, Maria Vitoria, Esvelt, Kevin, Famulare, Mike, Gilbert, Amy, He, Biao, Jarvis, Michael A., Kennedy, David A., Kuzma, Jennifer, Wanyonyi, Carolyne Nasimiyu, Remien, Christopher, Rocke, Tonie, Rosenke, Kyle, Schreiner, Courtney, Sheen, Justin, and Simons, David

Published
2024
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13. Predicting the fine‐scale spatial distribution of zoonotic reservoirs using computer vision.

Author

Layman, Nathan C., Basinski, Andrew J., Zhang, Boyu, Eskew, Evan A., Bird, Brian H., Ghersi, Bruno M., Bangura, James, Fichet‐Calvet, Elisabeth, Remien, Christopher H., Vandi, Mohamed, Bah, Mohamed, and Nuismer, Scott L.

Subjects
ZOONOSES, REGRESSION trees, EMERGING infectious diseases, FORECASTING
Abstract

Zoonotic diseases threaten human health worldwide and are often associated with anthropogenic disturbance. Predicting how disturbance influences spillover risk is critical for effective disease intervention but difficult to achieve at fine spatial scales. Here, we develop a method that learns the spatial distribution of a reservoir species from aerial imagery. Our approach uses neural networks to extract features of known or hypothesized importance from images. The spatial distribution of these features is then summarized and linked to spatially explicit reservoir presence/absence data using boosted regression trees. We demonstrate the utility of our method by applying it to the reservoir of Lassa virus, Mastomys natalensis, within the West African nations of Sierra Leone and Guinea. We show that, when trained using reservoir trapping data and publicly available aerial imagery, our framework learns relationships between environmental features and reservoir occurrence and accurately ranks areas according to the likelihood of reservoir presence. [ABSTRACT FROM AUTHOR]

Published
2023
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17. How Interactions during Viral–Viral Coinfection Can Shape Infection Kinetics.

Author

Pinky, Lubna, DeAguero, Joseph R., Remien, Christopher H., and Smith, Amber M.

Subjects
MIXED infections, RESPIRATORY syncytial virus, VIRUS diseases, INFECTION, VIRAL load, PLANT viruses, INFLUENZA A virus
Abstract

Respiratory viral infections are a leading global cause of disease with multiple viruses detected in 20–30% of cases, and several viruses simultaneously circulating. Some infections with unique viral copathogens result in reduced pathogenicity, while other viral pairings can worsen disease. The mechanisms driving these dichotomous outcomes are likely variable and have only begun to be examined in the laboratory and clinic. To better understand viral–viral coinfections and predict potential mechanisms that result in distinct disease outcomes, we first systematically fit mathematical models to viral load data from ferrets infected with respiratory syncytial virus (RSV), followed by influenza A virus (IAV) after 3 days. The results suggest that IAV reduced the rate of RSV production, while RSV reduced the rate of IAV infected cell clearance. We then explored the realm of possible dynamics for scenarios that had not been examined experimentally, including a different infection order, coinfection timing, interaction mechanisms, and viral pairings. IAV coinfection with rhinovirus (RV) or SARS-CoV-2 (CoV2) was examined by using human viral load data from single infections together with murine weight-loss data from IAV-RV, RV-IAV, and IAV-CoV2 coinfections to guide the interpretation of the model results. Similar to the results with RSV-IAV coinfection, this analysis shows that the increased disease severity observed during murine IAV-RV or IAV-CoV2 coinfection was likely due to the slower clearance of IAV-infected cells by the other viruses. The improved outcome when IAV followed RV, on the other hand, could be replicated when the rate of RV infected cell clearance was reduced by IAV. Simulating viral–viral coinfections in this way provides new insights about how viral–viral interactions can regulate disease severity during coinfection and yields testable hypotheses ripe for experimental evaluation. [ABSTRACT FROM AUTHOR]

Published
2023
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18. Quantifying the effectiveness of betaherpesvirus-vectored transmissible vaccines

Author

Varrelman, Tanner J., Remien, Christopher H., Basinski, Andrew J., Gorman, Shelley, Redwood, Alec, and Nuismer, Scott L.

Subjects
Muromegalovirus, Vaccines, transmissible vaccines, Multidisciplinary, Ecology, spillover, Genetic Vectors, Bayes Theorem, emerging infectious disease, Herpesviridae Infections, Biological Sciences, Disease Vectors, Models, Theoretical, zoonoses, Animal Diseases, Mice, Immunogenicity, Vaccine, Betaherpesvirinae, Prevalence, emergence, Animals, Algorithms, Disease Reservoirs, Nucleic Acid-Based Vaccines
Abstract

Significance Spillover of infectious diseases from wildlife populations into humans is an increasing threat to human health and welfare. Current approaches to manage these emerging infectious diseases are largely reactive, leading to deadly and costly time lags between emergence and control. Here, we use mathematical models and data from previously published experimental and field studies to evaluate the scope for a more proactive approach based on transmissible vaccines that eliminates pathogens from wild animal populations before spillover can occur. Our models are focused on transmissible vaccines designed using herpes virus vectors and demonstrate that these vaccines—currently under development for several important human pathogens—may have the potential to rapidly control zoonotic pathogens within the reservoir hosts., Transmissible vaccines have the potential to revolutionize how zoonotic pathogens are controlled within wildlife reservoirs. A key challenge that must be overcome is identifying viral vectors that can rapidly spread immunity through a reservoir population. Because they are broadly distributed taxonomically, species specific, and stable to genetic manipulation, betaherpesviruses are leading candidates for use as transmissible vaccine vectors. Here we evaluate the likely effectiveness of betaherpesvirus-vectored transmissible vaccines by developing and parameterizing a mathematical model using data from captive and free-living mouse populations infected with murine cytomegalovirus (MCMV). Simulations of our parameterized model demonstrate rapid and effective control for a range of pathogens, with pathogen elimination frequently occurring within a year of vaccine introduction. Our results also suggest, however, that the effectiveness of transmissible vaccines may vary across reservoir populations and with respect to the specific vector strain used to construct the vaccine.

Published
2022

19. Appendices from Reservoir population ecology, viral evolution and the risk of emerging infectious disease

Author

Nuismer, Scott L., Basinski, Andrew J., Schreiner, Courtney, Whitlock, Alexander, and Remien, Christopher H.

Abstract

The ecology and life history of wild animals influences their potential to harbour infectious disease. This observation has motivated studies identifying empirical relationships between traits of wild animals and historical patterns of spillover and emergence into humans. Although these studies have identified compelling broad-scale patterns, they are generally agnostic with respect to underlying mechanisms. Here, we develop mathematical models that couple reservoir population ecology with viral epidemiology and evolution to clarify existing verbal arguments and pinpoint the conditions that favour spillover and emergence. Our results support the idea that average lifespan influences the likelihood of an animal serving as a reservoir for human infectious disease. At the same time, however, our results show that the magnitude of this effect is sensitive to the rate of viral mutation. Our results also demonstrate that viral pathogens causing persistent infections or a transient immune response within the reservoir are more likely to fuel emergence. Genetically explicit stochastic simulations enrich these mathematical results by identifying relationships between the genetic basis of transmission and the risk of spillover and emergence. Together, our results clarify the scope of applicability for existing hypotheses and refine our understanding of emergence risk.

Published
2022
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23. Woody cover and hominin environments in the past 6 million years

Author

Cerling, Thure E., Wynn, Jonathan G., Andanje, Samuel A., Bird, Michael I., Korir, David Kimutai, Levin, Naomi E., Mace, William, Macharia, Anthony N., Quade, Jay, and Remien, Christopher H.

Subjects
Savannas -- Environmental aspects -- Natural history, Evolution -- Environmental aspects, Hominids -- Environmental aspects -- Natural history, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The role of African savannahs in the evolution of early hominins has been debated for nearly a century. Resolution of this issue has been hindered by difficulty in quantifying the fraction of woody cover in the fossil record. Here we show that the fraction of woody cover in tropical ecosystems can be quantified using stable carbon isotopes in soils. Furthermore, we use fossil soils from hominin sites in the Awash and Omo-Turkana basins in eastern Africa to reconstruct the fraction of woody cover since the Late Miocene epoch (about 7 million years ago). [sup.13]C/[sup.12]C ratio data from 1,300 palaeosols at or adjacent to hominin sites dating to at least 6 million years ago show that woody cover was predominantly less than ~40 % at most sites. These data point to the prevalence of open environments at the majority of hominin fossil sites in eastern Africa over the past 6 million years., There is long-standing debate as to the importance of woody versus herbaceous cover in the evolution of humans over the past 6 million years (Myr) (1-5). Despite uncertainty as to [...]

Published
2011
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31. Bayesian estimation of Lassa virus epidemiological parameters: Implications for spillover prevention using wildlife vaccination

Author

Nuismer, Scott L., primary, Remien, Christopher H., additional, Basinski, Andrew J., additional, Varrelman, Tanner, additional, Layman, Nathan, additional, Rosenke, Kyle, additional, Bird, Brian, additional, Jarvis, Michael, additional, Barry, Peter, additional, Hanley, Patrick W., additional, and Fichet-Calvet, Elisabeth, additional

Published
2020
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35. Bridging the gap: Using reservoir ecology and human serosurveys to estimate Lassa virus spillover in West Africa

Author

Basinski, Andrew J., primary, Fichet-Calvet, Elisabeth, additional, Sjodin, Anna R., additional, Varrelman, Tanner J., additional, Remien, Christopher H., additional, Layman, Nathan C., additional, Bird, Brian H., additional, Wolking, David J., additional, Monagin, Corina, additional, Ghersi, Bruno M., additional, Barry, Peter A., additional, Jarvis, Michael A., additional, Gessler, Paul E., additional, and Nuismer, Scott L., additional

Published
2020
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45. Suppressing evolution in genetically engineered systems through repeated supplementation.

Author

Layman, Nathan C., Tuschhoff, Beth M., Basinski, Andrew J., Remien, Christopher H., Bull, James J., and Nuismer, Scott L.

Subjects
TRANSGENIC organisms, GENES, FLOW meters, GENETIC engineering, GENE flow, REVERSE genetics
Abstract

Genetically engineered organisms are prone to evolve in response to the engineering. This evolution is often undesirable and can negatively affect the purpose of the engineering. Methods that maintain the stability of engineered genomes are therefore critical to the successful design and use of genetically engineered organisms. One potential method to limit unwanted evolution is by taking advantage of the ability of gene flow to counter local adaption, a process of supplementation. Here, we investigate the feasibility of supplementation as a mechanism to offset the evolutionary degradation of a transgene in three model systems: a bioreactor, a gene drive, and a transmissible vaccine. In each model, continual introduction from a stock is used to balance mutation and selection against the transgene. Each system has its unique features. The bioreactor system is especially tractable and has a simple answer: The level of supplementation required to maintain the transgene at a frequency p^ is approximately p^s, where s is the selective disadvantage of the transgene. Supplementation is also feasible in the transmissible vaccine case but is probably not practical to prevent the evolution of resistance against a gene drive. We note, however, that the continual replacement of even a small fraction of a large population can be challenging, limiting the usefulness of supplementation as a means of controlling unwanted evolution. [ABSTRACT FROM AUTHOR]

Published
2021
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46. Vector dynamics influence spatially imperfect genetic interventions against disease.

Author

Yuksel, Mete K, Remien, Christopher H, Karki, Bandita, Bull, James J, and Krone, Stephen M

Subjects
DISEASE vectors, MOSQUITO vectors, MATHEMATICAL models, PEST control, GENE drive (Genetic engineering)
Abstract

Background and objectives Genetic engineering and similar technologies offer promising new approaches to controlling human diseases by blocking transmission from vectors. However, in spatially structured populations, imperfect coverage of the vector will leave pockets in which the parasite may persist. Movement by humans may disrupt this local persistence and facilitate eradication when these pockets are small, spreading parasite reproduction outside unprotected areas and into areas that block its reproduction. Here, we consider the sensitivity of this process to biological details: do simple generalities emerge that may facilitate interventions? Methodology We develop formal mathematical models of this process similar to standard Ross–Macdonald models, but (i) specifying spatial structure of two patches, with vector transmission blocked in one patch but not in the other, (ii) allowing temporary human movement (travel instead of migration) and (iii) considering two different modes of mosquito biting. Results We find that there is no invariant effect of disrupting spatial structure with travel. For both biting models, travel out of the unprotected patch has different consequences than travel by visitors into the patch, but the effects are reversed between the two biting models. Conclusions and implications Overall, the effect of human travel on the maintenance of vector-borne diseases in structured habitats must be considered in light of the actual biology of mosquito abundances, biting dynamics and human movement patterns. Lay summary: Genetic interventions against pathogens transmitted by insect vectors are promising methods of controlling infectious diseases. These interventions may be imperfect, leaving pockets where the parasite persists. How will human movement between protected and unprotected areas affect persistence? Mathematical models developed here show that the answer is ecology-dependent, depending on vector biting behavior. [ABSTRACT FROM AUTHOR]

Published
2021
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