Nonlethal parasites reduce how much their wild hosts eat, leading to ecosystem effects
Written by Jim Erickson
Deer, caribou, bison and other similar animals are often infected by a range of internal parasites, including worms called helminths. Although many of these infections are not lethal, they can still impact health or animal behavior.
For example, infected animals can eat less grass or other vegetation than they normally would. In an interesting twist, this means that a world with more sublethal parasitic infections is a greener world.
A new study, led by Washington University in St. Louis and including a University of Michigan co-author, uses a mathematical model and a global meta-analysis to highlight the cascading consequences of common parasitic infections in wild animals on terrestrial ecosystems.
“Parasites are well known for their negative impacts on the physiology and behavior of individual hosts and host populations, but these effects are rarely considered within the context of the broader ecosystems they inhabit,” said Amanda Koltz, a Washington University biologist and first author of the study published online May 9 in Proceedings of the National Academy of Sciences.
“In this study, we show that pervasive parasitic infections reduce herbivory rates and can therefore trigger trophic cascades that impact plant communities,” Koltz said. “This work helps fill a recognized knowledge gap regarding the ecological consequences of parasitic infections in natural ecosystems.”
U-M biologist Aimée Classen is a co-author of the new study. She provided ecosystem context to the working group and modeling effort, and she collected data as part of the meta-analysis.
“While ecosystem ecologists typically think large-scale, our work highlights how the little things that can be unseen, like herbivore parasites, can shape large-scale processes like plant biomass across landscapes,” said Classen, professor in the Department of Ecology and Evolutionary Biology and director of the U-M Biological Station. “As our climate warms and ecosystems become more stressed, these unseen interactions are likely to become even more important.”
The research effort was conducted by an interdisciplinary and international working group funded by the Living Earth Collaborative, a partnership among Washington University, the Missouri Botanical Garden and the Saint Louis Zoo. The team included biologists, wildlife veterinarians and epidemiologists, ecosystem ecologists, modelers and infectious disease specialists.
Deer, bison, giraffes, gazelles and antelopes are hoofed animals known as ruminants: they’re vegetarians whose eating habits have measurable impacts on local ecosystems. Just picture how much greenery one grazing deer could consume in an unfenced garden.
But each wild ruminant is a world unto itself for the multitude of parasites that occupy its gut and tissues as it goes about its regular grass-munching business.
While other recent studies suggest that the kinds of parasites that eventually kill their hosts can trigger cascading effects on ecosystems in somewhat similar ways to predators, this study also considered the impacts of nonlethal parasitic infections.
The researchers used a mathematical model and global meta-analysis to test the potential for helminth parasites—any of a group of common parasitic worms—to set off trophic cascades through both their lethal and sublethal effects on ruminant hosts.
“The potential for lethal infections that dramatically increase host mortality to have ecosystem-level effects is somewhat intuitive, especially when the hosts that are killed play a key role in the ecosystem. For example, rinderpest, a virus that killed millions of ruminants in sub-Saharan Africa prior to the 1960s, changed tree densities in the Serengeti ecosystem through its effect on wildebeest mortality,” said Vanessa Ezenwa, professor of ecology and evolutionary biology at Yale University, a senior author of the study.
“Our model suggests that sublethal infections, although more cryptic, can have equally important effects on ecosystems; and our meta-analysis shows how pervasive the sublethal effects of helminth parasites are in nature.”
Modeling led by Dave Civitello at Emory University took advantage of well-documented examples of caribou and reindeer and their parasites. Caribou and their helminths are among the best-studied wild ruminant-parasite systems, due to the ecological, economic and cultural importance of caribou in tundra ecosystems and the ongoing disease threats to the system posed by climate change.
“Cold tundra ecosystems, where caribou live, are becoming stressed as the climate warms,” U-M’s Classen said. “Our models enabled us to test how parasites—and in particular non-lethal parasites—change ecosystem productivity. The results underscore that parasites reduce herbivore feeding rates, an impact that shapes plant and lichen biomass.”
Next, the scientists turned to data from more than 59 published, peer-reviewed studies to investigate the links between helminth infections and those same key traits of free-living ruminant hosts in nature.
Their analysis revealed that helminth infections significantly reduce the feeding rates of hosts but are not, on average, associated with host survival or fecundity.
“Taken together, the broader relevance of these results is that there are likely widespread—yet overlooked—ecological consequences of sublethal parasitic infections,” Koltz said.
“Given that helminth parasites are ubiquitous within free-living populations of ruminants, our findings suggest that global herbivory rates by ruminants are lower than they otherwise would be due to pervasive helminth infections. By reducing ruminant herbivory, these common infections may contribute to a greener world.”
Written by Talia Ogliore, Washington University in St. Louis