The National Science Foundation (NSF) : Discovery.- Infectious disease transmission in fish, mammals, other animals has implications for humans .- Descubrimiento .- La transmisión de enfermedades infecciosas en peces, mamíferos y otros animales tiene implicaciones para los seres humanos

https://www.nsf.gov/discoveries/disc_summ.jsp?cntn_id=191484&WT.mc_id=USNSF_1

Researchers looked at how animals interact with each other in 43 individual species

Contact network showing male tortoises (blue nodes), females (red nodes) and burrows (gray nodes). Credit and Larger Version

April 3, 2017

Related stories on the NSF, National Institutes of Health and U.S. Department of Agriculture's Ecology and Evolution of Infectious Diseases (EEID) program are available online.

Scientists once thought that being part of a community would protect animal populations from infectious disease outbreaks, but now they've learned otherwise, according to a study published this week in the journal Proceedings of the National Academy of Sciences (PNAS).

The researchers found that the spread of infection is largely unaffected by the presence of communities.

An animal community is made up of the species of animals present and interacting in an ecosystem. For example, the animal community of Arizona's Sonoran Desert includes snakes, spiders, birds of prey, desert tortoises and many additional species. In the sea, coral reef communities like those on Australia's Great Barrier Reef include fish, sea turtles, dolphins, seabirds and others.

Georgetown University scientists Shweta Bansal and Pratha Sah, along with researchers at Pennsylvania State University and the U.S. Geological Survey, say their study has implications for disease control in humans and other animals.

"Although we know that social networks can be important for spreading diseases from one person to another, models are still needed that can predict how that spread will happen," says Sam Scheiner, a director of the National Science Foundation's (NSF) Ecology and Evolution of Infectious Diseases (EEID) program, which funded the study. "The results of these experiments have provided critical information that can be used to model disease spread in many species, including humans."

NSF's Biological Sciences and Geosciences directorates supported the research.

Using computational networks and infectious disease models, the team looked at the social interactions of 43 different animal species, including fish, insects, birds, reptiles and mammals.

"It's an important advance that the analyses in this paper extended to marine species," says Dave Garrison, an EEID program director in NSF's Division of Ocean Sciences. "This is an area where we know disease is common, but information is still scarce."

The scientists found that formation of communities is common across all animal populations, including social species such as dolphins, ants and chimpanzees, and solitary species like desert tortoises and Australian sleepy lizards.

The researchers discovered that animal societies that are highly subdivided -- or fragmented -- experience smaller but longer disease outbreaks because disease spread in these populations gets trapped in local communities.

"Our results suggest that effective animal disease management should aim to control infection spillovers between communities when populations are less subdivided, and should also aim to control local disease transmission within communities in highly subdivided animal populations," Bansal says.

For example, she says, if there is a disease outbreak at a college, control should focus on residence halls where the infection was first reported. "But in the surrounding town, control should focus on restricting travel in neighborhoods where infection has occurred."

Bansal says that scientists previously assumed that the presence of communities helped to reduce the spread of infectious diseases in social animal species while retaining the benefits of social living, such as increased mating opportunities, protection from predators and cooperative care of young.

"Our study rejects that hypothesis," Bansal says. "Our work provides insights into a fundamental question of disease ecology."

--	Cheryl Dybas, NSF (703) 292-7734  cdybas@nsf.gov
--	Nancy Robertson, Georgetown University (202) 687-4317  Nancy.Robertson@georgetown.edu

Investigators

Ken Nussear 

Peter Hudson 

Shweta Bansal 

C. Richard Tracy 

Related Institutions/Organizations

Pennsylvania State Univ University Park

Related Programs

Ecology and Evolution of Infectious Diseases 

Related Awards

#1216054 EID: Collaborative Research: Invasion and Infection: Translocation and Transmission: An Experimental Study with Mycoplasma in Desert Tortoises 

Total Grants$2,303,899

A desert tortoise that's likely infected with Mycoplasma, a contagious respiratory infection.
Credit and Larger Version

Pratha Sah, a researcher on the team, conducts field work.
Credit and Larger Version

A desert tortoise in the study population that's been fitted with a tracking device.
Credit and Larger Version

Researcher Christina Aiello takes a sample from a desert tortoise to test for infection.
Credit and Larger Version

The National Science Foundation (NSF)
Guillermo Gonzalo Sánchez Achutegui
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