Marine animals that swim by jet propulsion, such as squid and jellyfish, are not uncommon. But it’s rare to find a colony of animals that coordinates multiple jets for whole-group locomotion. This week in Nature Communications, scientists report on a colonial jellyfish-like species that uses a sophisticated, multi-jet propulsion system based on an elegant division of labor among young and old members of the colony.
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“This is a highly efficient system in which no developmental stage is wasted,” said lead author John H. Costello of Providence College, an adjunct scientist and Whitman Center Investigator at the Marine Biological Laboratory in Woods Hole, Mass. MBL is an affiliate of the University of Chicago. The young members at the leading end of the colony’s propulsive unit use their little jets for turning and steering, Costello’s team found, while the older, bigger members further back provide powerful thrust as the colony migrates from deep to surface ocean.
“It’s a quite sophisticated design, for what would seem like a simple arrangement,” Costello said. The colony’s locomotive solution, the team suggested, could illuminate the design of underwater distributed-propulsion vehicles.
Nanomia bijuga belongs to a group of colonial organisms called physonect siphonophores, which are related to jellyfish, anemones and corals. Voracious predators of plankton, the physonects come to the ocean surface at night to feed and return to darker depths during the day—presumably to avoid visual predators such as fish.
The jet-producing members of the physonect colony, called nectophores, are genetically identical clones arranged in a propulsive unit called a nectosome. The nectosome is only a few centimeters in length, but it tows behind it much longer groups of reproduction and feeding units over distances that can reach 200 meters a day. It’s the equivalent of a human adult running a marathon every day while towing the equivalent of its body mass behind it.
To analyze this swimming prowess, the scientists videotaped physonects off of Friday Harbor, Wash., and then used image analysis (laser sheet illumination) to measure particle flows around the colony as it moves. This revealed the size and thrust of individual jets, along with their angle relative to the animal’s axis. The youngest individuals, they found, pushed out the least amount of water with their jets. But because they are positioned at the tip of the nectosome, far from where it connects with the rest of the colony, a small, directed force by these young members has a big effect on turning the whole colony.
“The young members have what we call a long lever arm,” Costello said. “They are like the handle of a door. If you push on a door near its hinges—its axis of rotation—the door is hard to open. But if you push on the door handle, which is far from the axis of rotation, the door opens easily. A little force placed with a big lever arm has a big effect on turning.”
The young colony members allow N. bijuya to rapidly alter course and even completely reverse its direction of swimming. As new nectophores are budded at the tip of the nectosome, the older ones move further back, where their larger contractions are useful for thrust. “These patterns permit all members of the colony to make important contributions to the propulsion and maneuvering traits that are critical for the success of N. bijuya in its natural environment,” the authors wrote.
“Just because the young ones are small,” Costello said, “it doesn’t mean they aren’t important.”
Citation: Costello JH, Colin SP, Gemmell BJ, Dabiri JO and Sutherland KR (2015) Multi-jet propulsion organized by clonal development in a colonial siphonophore. Nature Communications 6:8158 DOI: 10.1038/ncomms9158
—Prof. Kunle Odunsi
