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Biodiversity not a risk factor for emerging diseases and other new research from ESA journals

FOR IMMEDIATE RELEASE: Thursday 30 March 2017
Contact:   Liza Lester  202-833-8773 ext. 211, gro.asenull@retseLL

Ecological Society of America tipsheet for 30 March 2017

  • Biodiversity is not a risk factor for emerging disease
  • Understanding the underground dynamics of grassland mosaics
  • Eurasian tree sparrows feed their nestlings hoverflies, reducing biocontrol of aphids in cereals
  • Livestock grazing impact on sage-grouse depends on when and how much
  • Nest boxes not always the best way to understand or boost bird populations
  • Defusing conflict around invasive species management

 

Is biodiversity bad for your health?

Ecologists writing in ESA’s open access journal Ecosphere say the opposite is more likely true.

The specter of a dangerous new disease emerging from the dark depths of the wilderness, jumping from an animal host to people, is an oft-told horror story, though such “spillover” from wild species is not the most common mechanism through which new diseases emerge. Several recent reviews have expressed concerns that intact ecosystems rich in biodiversity pose a danger to human health by harboring an equal diversity of infectious disease agents.

Animal species do not present an equal threat of disease transmission, however, say Richard Ostfeld and Felicia Keesing, ecologists at the Cary Institute for Ecosystem Studies and Bard College. Some families, such as rodents, transmit disease relatively commonly, while others never do. People most often contract zoonotic disease from rodents encountered near houses or agricultural fields. The authors review the evidence for emerging disease risk in both relatively intact, functional ecosystems and ecosystems strongly affected by human presence.

Though high diversity in vertebrate species is sometimes correlated with a wider total pool of pathogen species, biodiversity is not linked to a larger number of pathogens with the potential to leap between species. Solid evidence does point to a correlation between biodiversity and lower prevalence of known infectious disease in people. The authors argue that there is no reason to expect that biodiversity is a risk factor for disease emergence and offer possible experiments to test their hypothesis empirically. 

  • Ostfeld, R. S., and F. Keesing. (2017). Is biodiversity bad for your health? Ecosphere 8(3):e01676. 10.1002/ecs2.1676 (OA)

Figure 1: The necessary logical steps underlying the argument that high host diversity leads to high probability of the emergence of a zoonotic disease. Although a link between host diversity and parasite diversity is relatively well established, effect of host diversity on viral and bacterial pathogens (arrow 1) is not. Evidence does not support a link between overall pathogen diversity and that of actual or potential zoonotic pathogens (arrow 2). Some evidence supports correlations between diversity of zoonotic pathogens and the likelihood of zoonotic emergence (arrow 3), but with important caveats described in the text.

Understanding the roots of grassland mosaics

Figure 1: Grasslands from nine geographically separated regions showing spatial mosaics of lawn and tall plant communities co-occurring where large herbivores are present. (A) Tundra, Arctic (source: ehow.com); (B) Steppe, Mongolia (source: fao.org); (C) Temperate heathland, United Kingdom (source: geographic.org.uk); (D) Temperate salt marsh, North-west Europe (photo: Ruth Howison); (E) Temperate grassland, North-west Europe (photo: Han Olff); (F) Mixed Prairie, south central United States, Texas (source: fao.org); (G) Semi-tropical savanna, Southern Africa (photo: Ruth Howison); (H) Dryland, Sahel (photo: Johan van de Koppel); (I) Temperate savanna, South-east Australia (source: nationalgeographic.com). Grazing ecosystems from the arctic tundra to tropical savannas are not smooth expanses but fine-scale patchworks of lawn, favored by big grazing animals, and taller vegetation. Ruth Howison and colleagues at the University of Groningen and the royal Netherlands Institute for Sea Research are interested in the environmental processes underlying the mosaic. They look to the soil in a new report in ESA’s journal Ecological Monographs. Compaction of soil under the hooves of heavy grazers promotes lawn communities. Underground animals churn the soil, engineering conditions that favor taller plant life such as bunch-forming grasses, herbs, and shrubs.

  • Howison, R. A., Olff, H., van de Koppel, J. and Smit, C. (2017), Biotically driven vegetation mosaics in grazing ecosystems: the battle between bioturbation and biocompaction. Ecol Monogr. Accepted Author Manuscript. doi:10.1002/ecm.1259

 

 

Tree sparrows eat the aphid-eaters

Figure 1 The agricultural food web of our experiment. Arrows indicate the direction from the consumer to the prey. Dashed arrows indicate weak effects, full lines and doubled organisms indicate strong effects. For further explanations see text. Control of agricultural pests by their natural predators saves an estimated $627 per hectare of cropland annually. Abetting these natural crop protectors is of interest to economists and ecologists. But some pest-eating insects have their own predators, Ingo Grass and colleagues at the University of Göttingen point out in ESA’s journal Ecology. During peak aphid season, European tree sparrows fed their nestlings a diet of 77 percent hoverflies and ladybugs (ladybird beetles). Hoverfly caterpillars are the most abundant aphid predators. When the birds were not around (thanks to protective nets set up by experimenting ecologists), aphid density fell by 24 percent in wheat fields and 26 percent in oat fields.

  • Grass, I., Lehmann, K., Thies, C. and Tscharntke, T. (2017), Insectivorous birds disrupt biological control of cereal aphids. Ecology. Accepted Author Manuscript. doi:10.1002/ecy.1814

 

Livestock grazing effects on sage-grouse

Sage grouse strutting near Boar's Tusk in the Red Desert, Great Divide Basin area of Wyoming, with grazing cattle in the background. Credit USDA?NRCS.How do grazing livestock affect their greater sage-grouse neighbors in Wyoming’s sagebrush country? Positively or negatively, depending on the amount of grazing and when grazing occurs, according to research published in ESA’s journal Ecological Applications by scientists from the U.S. Geological Survey (USGS), Colorado State University, and Utah State University.

Higher levels of grazing occurring early in the growing season – that is, before peak plant productivity – was associated with declining sage-grouse population trends, whereas similar levels of grazing that occurred later in the growing season corresponded with sage-grouse population increases.

“This study breaks new ground by evaluating multiple, real-world livestock grazing operations across an entire state,” said USGS ecologist and study coauthor David Pyke. “The study not only revealed the complex interactions among plant growth, when and how much livestock graze, and the resulting effect on wildlife, but most importantly, it also provides hope for a way to help sustain ranching while simultaneously sustaining wildlife populations.”

  • Monroe, A. P., Aldridge, C. L., Assal, T. J., Veblen, K. E., Pyke, D. A. and Casazza, M. L. (2017), Patterns in Greater Sage-grouse population dynamics correspond with public grazing records at broad scales. Ecol Appl. doi:10.1002/eap.1512

 

Power and peril of nest boxes

Scientists often use artificial breeding sites such as nest boxes, bat houses, and human-made burrows to study and manage numerous species of animals including bats, insects, lizards, fish, and birds. The addition of human-made nest sites to an ecosystem does not always benefit populations or help researchers to monitor species, such as the American Kestrel, which regularly use nest boxes, ecologists from The Peregrine Fund’s American Kestrel Partnership (AKP) and the Department of Biological Sciences and Raptor Research Center at Boise State University warn in ESA’s journal Ecological Applications.

  • McClure, C. J.W., Pauli, B. P. and Heath, J. A. (2017), Simulations reveal the power and peril of artificial breeding sites for monitoring and managing animals. Ecol Appl. (Early View) doi:1002/eap.1509

 

Conflict around invasive species management

FEE1471 Protesters demonstrate their opposition to the lethal control of European hedgehogs (Erinaceus europaeus) on the islands of Uist, Scotland. © H Warwick

© H Warwick

Invasive species management often generates social conflict. Sarah Crowley and colleagues at the University of Exeter consider why some management approaches may be more prone to conflict than others and offer approaches for anticipating disagreements, communicating, and including local communities in ESA’s journal Frontiers in Ecology and the Environment.

  • Crowley SL, Hinchliffe S, and McDonald RA. (2017) Conflict in invasive species management. Front Ecol Environ(Early View); doi:1002/fee.1471

 


The Ecological Society of America, founded in 1915, is the world’s largest community of professional ecologists and a trusted source of ecological knowledge, committed to advancing the understanding of life on Earth. The 10,000 member Society publishes five journals and a membership bulletin and broadly shares ecological information through policy, media outreach, and education initiatives. The Society’s Annual Meeting attracts 4,000 attendees and features the most recent advances in ecological science. Visit the ESA website at https://www.esa.org.