To compete with corals, seaweed can boost its chemical defenses, but doing so can be a two-edged sword. The process makes seaweed more attractive to herbivorous fish, which then increase consumption by 80 percent.
Researchers say this appears to be the first demonstration that seaweed can increase production of noxious compounds in response to competition with corals. But further study with a broader range of seaweeds and corals is needed before determining whether such responses are common or rare.
“The important takeaway is that competition between corals and seaweeds can cause dramatic changes in seaweed physiology, both in terms of their growth and their defense,” says Douglas Rasher, who was a graduate student at Georgia Institute of Technology (Georgia Tech) when the research was conducted. “These changes have potentially cascading effects throughout the rest of the reef community.”
Rasher, now a postdoctoral research associate at the Darling Marine Center at the University of Maine, conducted the research with Mark Hay, professor of biology.
Hay and Rasher use coral reefs as field laboratories, studying the chemical signaling that occurs during coral-seaweed competition, and evaluating how herbivorous fish affect the interactions and long-term health of reefs.
“We previously found that chemical warfare is fairly common among seaweeds and corals, and that several seaweed species are particularly harmful to corals,” Rasher says. “This research explored the degree to which seaweed allelopathy—chemical warfare—is dynamic, how it changes in response to competition, and also whether competition changes the efficacy of other seaweed defenses used against herbivores.”
The findings may also challenge the popular notion that plants cannot change rapidly and strategically in response to their environments.
“We tend to think of plants as being fixed in their behavior,” Hay says. “In fact, plants such as these seaweeds assess their environment continuously, altering biochemically what they are doing as they compete with the coral. These algae somehow sense what is happening and respond accordingly. They may appear passive, but they are really the tricky chemical assassins of coral reefs.”
For the new study, published in Proceedings of the Royal Society B, researchers selected two seaweed species: Galaxaura filamentosa, known for its toxicity to corals, and Sargassum polycystum, which does not chemically damage corals.
They fragmented pieces of a common coral, Porites cylindrica, glued them into cement cones, and placed them on a rack on a reef located in the shallow ocean off the Fiji Islands. The fragments were then allowed to grow in the racks for two years.
At the start of the experiment, the researchers took half of the coral samples and dipped them into bleach to kill the living organisms, leaving only the calcium carbonate skeletons. The skeletons served as the control group for the experiments that followed.
More potent seaweed
The researchers collected samples from both species of seaweed, and split each sample in two. One half of each sample was assigned to a treatment group, while the other half went to the control group. The treatment group was placed into contact with living corals, while the control group was placed into contact with coral skeletons.
“These kinds of interactions show a mechanism that, once the reef begins to crash, could help maintain that decline.”
The seaweeds were then allowed to interact with the corals and coral skeletons for eight days. After that, a portion of each sample was removed and chemical compounds extracted from them and embedded into small gel strips that were then adhered to other living corals to assess the toxicity of the compounds. The researchers repeated the experiment, placing entire seaweeds in contact with corals to determine if the plants displayed the same effect.
“We saw that Galaxaura, the chemically rich seaweed and the species we knew was allelopathic, had up-regulated its chemistry to become more potent—nearly twice as damaging—when it was in contact with the living coral, compared to those individuals that had only been in contact with the coral skeletons,” Rasher says.
None of the extracts from the Sargassum damaged the corals.
Until this point, the seaweeds and corals had been protected from herbivorous fishes. The next step was to place seaweed samples—both those that had competed with the living coral and those that hadn’t—onto nylon ropes in a location accessible to fish. The researchers created 15 pairs of these samples and placed them at different reef locations.
“We saw that for the non-allelopathic seaweed, Sargassum, fishes didn’t differentiate, they consumed both the treatment and control seaweeds at equal rates,” Rasher says. “But given the option to choose between treatment and control Galaxaura, fishes consumed 80 percent more of the seaweed portions that had been in contact with a living coral.”
The researchers don’t know all the factors that may have made the chemically noxious seaweed more palatable to the fish. However, those seaweed portions that had been competing with coral had less effective chemical defenses against fish.
When the researchers took extracts from treatment seaweed and control seaweed and applied them to a palatable seaweed species not previously used in the experiment, fish preferred the seaweed coated with extracts from the portions that had been competing with corals, indicating that competition had compromised the seaweed’s chemical defenses against herbivores.
In the future, the researchers want to study chemical defenses in other seaweeds to determine if what they’ve seen is common among tropical seaweeds that engage in chemical warfare. For now, they don’t know if the chemical defenses evolved to compete with coral or perhaps for another reason, such as fighting off harmful microbes.
The fact that corals may cause seaweeds to up-regulate their anti-coral defenses could help explain why coral reefs rarely bounce back once they begin a decline and become dominated by seaweeds. The research also demonstrates the importance of studying broad interactions among numerous species within complex communities like coral reefs.
“These kinds of interactions show a mechanism that, once the reef begins to crash, could help maintain that decline,” Hay says. “There may be insights here that we could use to better manage, and hopefully restore, some of these systems. We are also hoping that what we learn may bleed over into other systems.”
The National Science Foundation and the National Institutes of Health supported the research.
Source: Georgia Tech