Outbreak: Ecology and Evolution of Infectious Disease grants support research on disease transmission
Awards fund studies of how diseases spread among humans, other animals and the environment
Tasmanian devil facial disease; infection with antibiotic-resistant staphylococcus; foot-and-mouth disease; malaria: Is our interaction with the environment somehow responsible for the increased incidence of these diseases?
The joint National Science Foundation (NSF) and National Institutes of Health (NIH) Ecology and Evolution of Infectious Diseases (EEID) program is providing answers.
The EEID program supports efforts to understand the ecological and biological mechanisms behind human-induced environmental changes and the emergence and transmission of infectious diseases.
NSF and NIH--in collaboration with the U.S. Department of Agriculture National Institute of Food and Agriculture (NIFA) and the U.K.'s Biotechnology and Biological Sciences Research Council (BBSRC)--have awarded more than $16 million in new EEID grants.
"Our understanding of the ecology and evolution of pathogens comes from knitting together information from many different sources," says Sam Scheiner, NSF EEID program director. At NSF, EEID is funded by the Directorates for Biological Sciences, Geosciences, and Social, Economic & Behavioral Sciences.
"They include diseases of humans, frogs, honeybees and plants," says Scheiner. "Each system provides a different piece of the puzzle that helps us protect human health, the health of our agricultural systems and that of our natural world."
Projects funded through the EEID program allow scientists to study how large-scale environmental events--such as habitat destruction, invasions of non-native species and pollution--alter the risks of emergence of viral, parasitic and bacterial diseases in humans and other animals.
"This year's EEID projects bring together multiple scientific fields to address how human and natural processes influence infectious diseases in humans and other animals, including diseases that affect wildlife and agriculture, as well as those of significant public health concern in the developing world," says Christine Jessup, EEID program director at NIH's Fogarty Center.
"Findings from EEID-supported research are improving public health interventions and management decisions."
Researchers supported by the EEID program are advancing basic theory related to infectious diseases, and improving understanding of how pathogens spread through populations at a time of increasing environmental change.
The benefits of research on the ecology and evolution of infectious diseases include development of theories about how diseases are transmitted, improved understanding of unintended health effects of development projects, increased capacity to forecast disease outbreaks, and knowledge of how infectious diseases emerge and reemerge.
"Animal and plant diseases cause significant losses in food production around the globe and pose risks to human health," says Sonny Ramaswamy, NIFA director.
"As NIFA and the scientific community work toward solutions that ensure our food security, research on the evolution and spread of infectious diseases will help us understand how best to prevent, predict and respond to these threats."
This year's EEID awardees will conduct research on such topics as the emergence of Tasmanian devil facial tumor disease, honeybees and their parasites, the evolution and spread of virulent infectious diseases, the macroecology of infectious disease, and the persistence of foot-and-mouth disease.
"Tackling the infectious diseases that threaten the health of humans and livestock is a critical need, especially in the face of a growing global human population expected to reach 9 billion by 2050," says Douglas Kell, BBSRC chief executive.
"We face many challenges related to food security and health. These EEID projects will combine international expertise to help us find solutions."
EEID 2013 Grants
Andrew T. Storfer, Washington State University, Emergence, transmission and evolution of Tasmanian devil facial tumor disease
Additional Collaborators: Hamish McCallum, Griffith University; Menna Jones, University of Tasmania; Elizabeth Murchison, Wellcome Trust Sanger Institute; Paul Hohenlohe, University of Idaho
Patrick Stephens, University of Georgia, RCN Proposal: Macroecology of infectious disease
Additional Collaborators: Robert Poulin, University of Otago; Sonia Altizer, University of Georgia; Katherine Smith, Brown University; Alonso Aguirre, Smithsonian-Mason School of Conservation
Jill Stewart, University of North Carolina at Chapel Hill, The impact of intensive livestock production on the disease ecology of antibiotic resistant staphylococcus
Additional Collaborators: Jacqueline A. MacDonald, Rachel T. Noble, Marc L. Serre, Steven B. Wing, University of North Carolina at Chapel Hill
Bret Elderd, Louisiana State University, Scaling up epizootic dynamics--Linking individual infection to spatial spread of a disease using Bayesian hierarchical approaches
Additional Collaborators: Kelli Hoover, Penn State University; Michael Stout, Louisiana State University AgCenter; Vanja Dukic, University of Colorado
Cheryl Briggs, University of California-Santa Barbara, Disease in complex communities: How multi-host, multi-pathogen interactions drive infection dynamics
Additional Collaborators: Andrew R. Blaustein, Oregon State University, Jason T. Hoverman, Perdue University, Pieter T. Johnson, University of Colorado, Jason R. Rohr, University of South Florida
Additional Collaborators: Berry J. Brosi, Emory University; Keith Delaplane, University of Georgia
Wayne K. Potts, University of Utah, The evolution and spread of virulent infectious disease
Additional Collaborators: Frederick R. Adler, University of Utah; Henry D. Hunt, Michigan State University
Mercedes Pascual, University of Michigan, The impact of seasonality and vector control on the population structure of Plasmodium falciparum
Additional Collaborators: Karen P. Day, New York University, Kwadwo A. Koram, University of Ghana
Anna E. Jolles, Oregon State University, US-UK collaboration: Persistence of a highly contagious pathogen: ecological and evolutionary mechanisms in foot-and-mouth disease virus
Additional Collaborators: Jan Medlock, Oregon State University
The National Science Foundation (NSF) is an independent federal agency that supports fundamental research and education across all fields of science and engineering. In fiscal year (FY) 2016, its budget is $7.5 billion. NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and other institutions. Each year, NSF receives more than 48,000 competitive proposals for funding and makes about 12,000 new funding awards. NSF also awards about $626 million in professional and service contracts yearly.
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