Emerging zoonoses are a significant threat to global public health and our economies. The majority are caused by pathogens that emerge with increasing frequency from wildlife hosts (e.g. HIV-1 from chimpanzees, SARS CoV from bats and civets, Nipah virus from fruit bats). This group of diseases alone causes tens of thousands of deaths each year, and some outbreaks (e.g. SARS) have cost the global economy tens of billions of dollars. However, despite the huge social, demographic and economic impact of EIDs, there has been little advance in our understanding of the underlying process of how these wildlife zoonoses emerge, and in developing predictive approaches to prevent future emergence. Developing predictive and proactive approaches to zoonotic emergence is a key challenge to medical science. New zoonoses emerge regularly from wildlife in a seemingly random way, from disparate regions of the globe, and from a wide diversity of wildlife species. Our ability to understand what drives this process is hampered by a lack of rigorous analyses of the processes that cause emergence;our lack of knowledge of the diversity of microbes in wildlife (the `zoonotic pool') from which new zoonoses regularly emerge;and our poor understanding of pathogenic factors that explain why some viruses are able to cross the species barrier while others are not. In this application, we bring together a multidisciplinary team of emerging disease ecologists and modelers, viral bioinformaticists, and molecular virologists who are leaders in their fields, and who have already collaborated together to study zoonotic disease emergence. Building on preliminary data that demonstrates bats are a key wildlife reservoir, and that emergence is due to a range of anthropogenic drivers, this team will 1) develop predictive models of global `hotspots'for the future emergence of bat viruses;2) use a large repository of bat biological samples to conduct targeted surveillance in these `hotspots'for known and undiscovered bat pathogens, elucidating the unknown diversity of the bat `virome'and;3) using a range of in vitro techniques (including infection in bat cell culture), examine the pathogenesis of these new viruses, and a pool of available bat viruses which have not yet emerged in humans. This multidisciplinary approach represents the first, concerted effort to understand the depth and breadth of the process of emergence within a key group of wildlife hosts associated with the recent emergence of SARS, Nipah, Hendra, Ebola and Marburg viruses.

Public Health Relevance

Emerging zoonoses (e.g. HIV/AIDS, Influenza) are a major threat to health globally, causing tens of thousands of deaths each year in the USA and abroad and a number of these have emerged from bats recently (SARS, Ebola, Nipah). This research provides a way to predict the regions where the next new emerging zoonoses from bats is most likely to emerge, and proposes targeted surveillance of these animals using state-of-the- art molecular techniques in those regions. It will characterize new viruses, and study the pathogenesis of these, and a bank of known bat viruses that have not yet emerged in the human population: It is therefore a predictive, proactive approach to combating the most high profile group of emerging pathogens.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI079231-02
Application #
7688507
Study Section
Infectious Diseases, Reproductive Health, Asthma and Pulmonary Conditions Study Section (IRAP)
Program Officer
Park, Eun-Chung
Project Start
2008-09-18
Project End
2013-06-30
Budget Start
2009-09-01
Budget End
2010-08-31
Support Year
2
Fiscal Year
2009
Total Cost
$535,156
Indirect Cost
Name
Ecohealth Alliance, Inc.
Department
Type
DUNS #
077090066
City
New York
State
NY
Country
United States
Zip Code
10001
Olival, Kevin J; Hosseini, Parviez R; Zambrana-Torrelio, Carlos et al. (2017) Host and viral traits predict zoonotic spillover from mammals. Nature 546:646-650
Young, Cristin C W; Olival, Kevin J (2016) Optimizing Viral Discovery in Bats. PLoS One 11:e0149237
Brierley, Liam; Vonhof, Maarten J; Olival, Kevin J et al. (2016) Quantifying Global Drivers of Zoonotic Bat Viruses: A Process-Based Perspective. Am Nat 187:E53-64
Wray, Amy K; Olival, Kevin J; MorĂ¡n, David et al. (2016) Viral Diversity, Prey Preference, and Bartonella Prevalence in Desmodus rotundus in Guatemala. Ecohealth 13:761-774
Schaer, Juliane; Reeder, DeeAnn M; Vodzak, Megan E et al. (2015) Nycteria parasites of Afrotropical insectivorous bats. Int J Parasitol 45:375-84
Loh, Elizabeth H; Zambrana-Torrelio, Carlos; Olival, Kevin J et al. (2015) Targeting Transmission Pathways for Emerging Zoonotic Disease Surveillance and Control. Vector Borne Zoonotic Dis 15:432-7
Jayme, Sarah I; Field, Hume E; de Jong, Carol et al. (2015) Molecular evidence of Ebola Reston virus infection in Philippine bats. Virol J 12:107
Olival, Kevin J; Dittmar, Katharina; Bai, Ying et al. (2015) Bartonella spp. in a Puerto Rican bat community. J Wildl Dis 51:274-8
Gay, Noellie; Olival, Kevin J; Bumrungsri, Sara et al. (2014) Parasite and viral species richness of Southeast Asian bats: Fragmentation of area distribution matters. Int J Parasitol Parasites Wildl 3:161-70
Lei, Bonnie R; Olival, Kevin J (2014) Contrasting patterns in mammal-bacteria coevolution: bartonella and leptospira in bats and rodents. PLoS Negl Trop Dis 8:e2738

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