CORVALLIS, Ore. – Research using time-lapse photography in the Galapagos Marine Reserve suggests the presence of a key multilevel “trophic cascade” involving top- and mid-level predators as well as urchins and algae.
The findings are important because they include detailed information about interactions in a complex food web. Such information is crucial to knowing how to cause, prevent or reverse population changes within the web.
In the rocky, species-rich subtidal area off the Galapagos Islands, scientists from Oregon State University and Brown University examined the relationships among predatory fishes, urchins, the algae that the urchins graze on, and how the interactions among them were influenced by sea lions and sharks at the top of the food chain.
The key question: Do predators high up in the chain affect the abundance of the “primary producers” at the bottom – in this case algae – thus causing a trophic cascade?
Trophic level refers to a species’ position in the chain, and the cascade describes the series of effects that can occur.
Using GoPro cameras, the researchers made a number of key findings regarding triggerfish, Spanish hogfish, pencil urchins, the larger green urchins and algae, including:
- Among a diverse guild of predatory fishes, triggerfish can control the abundance of pencil urchins and thus also the abundance of algae the urchins eat; the experiments showed grazing on algae was eliminated when the pencil urchins were exposed to triggerfish predation, meaning triggerfish are a candidate for protection because of their strong effects on ecosystem function.
- Green urchins eat more algae than pencil urchins yet are not the urchin prey of choice for predatory fish. That suggests those fish aren’t controlling green urchin populations and thus that green-urchin barrens in the Galapagos – areas where the urchins have stripped the sea floor of algae – are not the result of the overfishing of predatory fish.
- Spanish hogfish are not major predators of urchins as earlier, survey-based research had suggested. Hogfish mainly eat the smaller pencil urchins and also interfere with triggerfish feeding on large pencil urchins; the hassling hogfish cause triggerfish to spend more time to eat an urchin and in some cases force a fumble.
- Statistical modeling of predation on pencil urchins indicates that two types of interference behavior – the hogfish harassing the triggerfish, and sea lions and sharks startling the triggerfish – could slow the rate of triggerfish predation on pencil urchins.
The researcher who did the modeling, Mark Novak of the College of Science at Oregon State, noted that historically, ecologists believed complex food webs typical of the tropics were more immune to trophic cascades than the simpler food webs of higher latitudes; the Galapagos straddle the equator.
Studies such as this one now suggest that is not the case, and that the dynamics of complex food webs can be as predictable as simpler ones provided you understand who the relevant players are.
“When the backbone of the system is strong, you can connect the top of the food chain to the bottom despite all of the indirect effects and the complexities of the system,” said Novak, assistant professor of integrative biology.
“It’s important to know individual species identity when you’ve got a suite of consumers,” Novak said. “The hogfish, the triggerfish, they all feed on very similar things, yet one of the two is most important, the one that drove that first link. And an urchin isn’t just an urchin – one was more immune to consumption from triggerfish, the other more susceptible. And one urchin was important for grazing, and another was not.”
Merely lumping species together at trophic levels would have caused researchers to miss a lot of the subtleties that the photographic study uncovered.
“If you just put urchins out and see how quickly they disappear, you can’t attribute that to any given predator,” Novak said. “We were able to identify those species that were responsible for transmitting the cascade.”
Findings were recently published in PLOS One. The National Science Foundation supported this research.