Researchers identify movement patterns of a parrotfish that rotationally harvests its favorite algae

September 12, 2017 by Julie Cohen, University of California - Santa Barbara
Steephead parrotfish (Chlorurus microrhinos) rotationally harvest their favorite food and then defend their feeding territory. Credit: Katie Davis

Steephead parrotfish (Chlorurus microrhinos) are picky eaters. In the central Pacific, however, they appear to have taken matters into their own hands—er, fins.

A new study by UC Santa Barbara marine biologists shows for the first time that these large algae-eaters rotationally harvest their favorite food and then defend their feeding territory while the food patches recuperate sufficiently for the fleshy to return. The team's findings—along with another paper by the same authors, describing movement patterns of C. microrhinos—appear in the Marine Ecology Progress Series.

"Herbivores are really important for coral reef ecology because there's a constant battle between coral and algae," explained Peter Carlson, lead author of the first paper. Carlson is a researcher in the Caselle Lab at UCSB's Marine Science Institute (MSI). "Anything that can remove algae is essentially considered a net positive for coral growth."

Working on Palmyra atoll, 1,000 miles south of Hawaii, the researchers noticed an abundance of bite scars in very small areas of algae growing on dead coral. They followed these patches through time and found parrotfish were feeding heavily in each patch for a short period of time. Then, the fish would allow that exact location to recover before returning to harvest the algae again.

"The fish would come back to the same area and defend it against other individuals of the same species," Carlson said. "Essentially, they're farming by using their environment very strategically."

It turns out these parrotfishes are doing a service to the coral reef. Turf algae have been shown to be harmful, even lethal, to juvenile corals. When the parrotfish bites scrape the coral, they create pockets of space without the algae, which may enable tiny coral larvae to settle and grow.

"In the habitat dominated by this low-lying turf algae, we saw this intensive feeding behavior of the parrotfish," Carlson noted. "But in coral-dominated areas, their feeding, while still concentrated, was spread over a much greater area."

On Palmyra atoll, steephead parrotfish allow areas where they leave bite scars to recover before reharvesting their favorite turf algae. Credit: Katie Davis

This research clearly demonstrates that the movement patterns of these parrotfish are influenced by the available food in a particular habitat. It also highlights the importance of variation in food availability to their social structure.

"In places where there was lots of the turf that they like to eat, we saw only big males," said co-author Katie Davis, a researcher in the Caselle Lab. "There were hardly any smaller individuals or females. However, in coral-dominated sites, we saw more of a haremic social structure, with one or two large males accompanying a group of smaller females."

The second paper took a multiscale approach to tracking parrotfish movements, which is important information for conservation purposes. Because herbivores support coral reef health, many are safeguarded in marine protected areas. But to properly create and manage adequate space for these fish, managers need to know the range of their movements.

To make that determination, the researchers used long-term acoustic monitoring to track patterns over the years. They also monitored the animals from a boat to document their daily space use and employed fine-scale GPS tracking to measure their meter-scale movements over a couple of hours. Taken together, these different scales and varied tools confirm that the impact of individual feeding is confined to small areas, even though their overall range is quite large.

"We found they were moving more than a kilometer offshore almost on a daily basis and that those movements were synced with tidal cycles," lead author Davis explained. "We concluded that they were likely going offshore to spawn because many coral reef fishes sync their spawning excursions to tidal cycles. However, the extent of these large movements had not been previously reported in this species, which is new information that managers can use when designing spatial protections."

According to MSI research biologist Jennifer Caselle, co-author on both papers, this research demonstrates the need for multiple tools to comprehensively understand the and behavior of coral reef parrotfishes.

"Our studies on Palmyra are providing information on a species whose abundance has been reduced greatly due to overfishing in most areas of the world," Caselle said. "Yet this is the type of fish that people want to bring back to help save , so it's important to understand their behavior."

Explore further: Scientists find that the space bullethead parrotfish use is influenced more by competition than by fear of predators

Related Stories

Study finds parrotfish are critical to coral reef health

January 23, 2017

An analysis of fossilized parrotfish teeth and sea urchin spines by researchers at Scripps Institution of Oceanography at the University of California San Diego showed that when there are more algae-eating fish on a reef, ...

Algae fortifies coral reefs in past and present

August 28, 2017

The Great Barrier Reef, and most other large reefs around the world, owe their bulk in large part to a type of red algae that grows on corals and strengthens them. New research led by Anna Weiss, a Ph.D. candidate at The ...

Fish social lives may be key to saving coral reefs

April 10, 2017

The social eating habits of fish may play a central role in protecting coral reefs, according to a study from the University of California, Davis, published April 10 in the journal Proceedings of the National Academy of ...

Recommended for you

Understanding how to control 'jumping' genes

June 22, 2018

A team of Texas A&M University and Texas AgriLife Research scientists have made a new discovery of how a single protein, Serrate, plays dual roles in controlling jumping genes.


Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Click here to reset your password.
Sign in to get notified via email when new comments are made.