ɬÀï·¬

Ten years ago, coral researchers didn’t think coral had immune cells. said she thought that was ridiculous; so, she proved them wrong.

Corals are invertebrate animals that form multicellular colonies under the sea and comprise over . Like the interdependent inhabitants of a city, specialized coral gastrodermal cells harbor algae, forming a mutually beneficial endosymbiotic relationship. To make the community even more complex, coral and algae also partner with bacteria and viruses. All invertebrates, including corals, have innate immune systems that use genetically encoded, nonspecific inflammation to fight off pathogens. Like other animals, corals boast immune receptors on their cells — similar to smoke alarms in a home — that bind to pathogen-associated molecular patterns, such as foreign genetic material, and set off warning signals to the host.

Researchers have long debated how corals eliminate those pathogens. Traylor­­–Knowles, an associate professor in marine biology and ecology at Miami University, hypothesized that corals, like other invertebrates and mammals, rely on immune cells that act as garbage trucks to neutralize invaders. These cells, known as , engulf pathogens and destroy them using lysosomal vesicles and free radicals.
 
To settle the debate on coral immune cells, Traylor­­–Knowles’ team, and her collaborator , an assistant professor of microbiology and immunology at Ben Gurion University of the Negev, Israel, used fluorescence-activated cell sorting to isolate coral phagocytes, which can be technically difficult. Next, using high-resolution microscopy, they demonstrated that eat and digest bacterial and fungal proteins.

“Functional studies in corals have been a huge challenge,” Traylor­­–Knowles said. “But we are getting there.”
The team’s next goal is to find out what makes coral the immune system unique. Unlike organisms that live more independently, corals have a complex system that keeps them from destroying their .

“We know there are novel immune factors in coral,” Traylor­­–Knowles said. “We just haven’t figured out how the puzzle pieces fit together yet … Corals are (messy), but that’s what makes them so interesting.”

Traylor­­–Knowles is building on her basic research findings to rescue dying corals in the ocean.

“I first became interested in corals because I wanted to understand how we can help animals that have been (messed) up by humans,” she said.

The Traylor­­–Knowles and Rosental teams have identified candidate coral stem cells, much like those found in humans. Taking inspiration from bone marrow transplants, they wondered if these stem cells could rescue dying corals.

“The idea was to transfer stem cells … from one coral to a sensitive one, and this would enable resilience, for instance, to heat,” Rosental said. “This is the exact parallel from humans when we transfer the ability to create missing immune cells.”
  To test this hypothesis, the team used Nematostella vectensis, a sea anemone model for corals, because lab manipulations are difficult in corals. The team at Ben Gurion treated the sea anemone with lethal-dose chemotherapy, which mimics environment-induced damage. Next, they transplanted donor, healthy stem cells into the irradiated sea anemone. To isolate the coral stem cells, Rosental said, they used tools like those used in humans during a bone marrow transplant. Once transferred, the healthy stem cells integrated into the host and then proliferated, differentiated and rescued the sea anemone.

“My dream is that we use this as another therapeutic for coral,” Traylor­­–Knowles said. “There’s no way it’s going to save all corals, but it can be added to the toolbox to give corals a chance until humans get their act together.”

The team is perfecting their stem cell identification and isolation techniques in stony corals so they can soon establish a transplantation protocol. Traylor­­–Knowles said stem cell-based therapies may someday rescue bleached corals in the ocean.

"I wish that these things could solve the problem, but the ultimate issue is climate change,” Traylor­­–Knowles said. “There's only so much we can do, and it's really just buying time. But we have to try."