First evidence of ‘living towers' made of worms discovered in nature
Nature seems to offer an escape from the hustle and bustle of city life, but the world at your feet may tell another story. Even in the shade of a fruit tree, you could be surrounded by tiny skyscrapers — not made of steel or concrete, but of microscopic worms wriggling and writhing into the shape of long, vertical towers.
Even though these miniature architects, called nematodes, are found all over Earth's surface, scientists in Germany recently witnessed their impressive building techniques in nature for the first time.
After months of closely inspecting rotten pears and apples in local orchards, researchers from the Max Planck Institute of Animal Behavior and the University of Konstanz were able to spot hundreds of the 1-millimeter-long (0.04-inch) worms climbing onto one another, amassing structures up to 10 times their individual size.
Related video
Rare video shows 12 sharks co-feed socially
To learn more about the mysterious physics of the soft, slimy towers, the study team brought samples of nematodes called Caenorhabditis elegans into a lab and analyzed them. There, the scientists noticed the worms could assemble in a matter of hours, with some reaching out from the twisting mass as exploratory 'arms' sensing the environment and building accordingly. But why the worms formed the structures wasn't immediately clear.
The team's findings, published Thursday in the journal Current Biology, show that even the smallest animals can prompt big questions about the evolutionary purpose of social behaviors.
'What we got was more than just some worms standing on top of each other,' said senior study author Serena Ding, a Max Planck research group leader of genes and behavior. 'It's a coordinated superorganism, acting and moving as a whole.'
To find out what was motivating the nematodes' building behavior, the study team tested the worms' reactions to being poked, prodded and even visited by a fly — all while stacked in a tower formation.
'We saw that they are very reactive to the presence of a stimulus,' said the study's first author, Daniela Perez, who is a postdoctoral researcher at the Max Planck Institute of Animal Behavior. 'They sense it, and then the tower goes towards this stimulus, attaching itself to our metal pick or a fly buzzing around.'
This coordinated reaction suggests the hungry nematodes may be joining together to easily hitch a ride on larger animals such as insects that transport them to (not so) greener pastures with more rotten fruit to feast on, Perez said.
'If you think about it, an animal that is 1 millimeter long cannot just crawl all the way to the next fruit 2 meters (6.6 feet) away. It could easily die on the way there, or be eaten by a predator,' Perez explained. Nematodes are capable of hitchhiking solo too, she added, but arriving to a new area in a group may allow them to continue reproducing.
The structures themselves may also serve as a mode of transport, as evidenced by how some worms formed bridges across gaps within the petri dishes to get from one surface to another, Perez noted.
'This discovery is really exciting,' said Orit Peleg, an associate professor of computer science who studies living systems at the University of Colorado Boulder's BioFrontiers Institute. 'It's both establishing the ecological function of creating a tower, and it really opens up the door to do more controlled experimentation to try to understand the perceptual world of these organisms, and how they communicate within a large group.' Peleg was not involved in the study.
As the next step, Perez said her team would like to learn whether the formation of these structures is a cooperative or competitive behavior. In other words, are the towering nematodes behaving socially to help each other out, or are their towers more akin to a Black Friday sale stampede?
Studying the behaviors of other self-assembling creatures could offer clues to the social norms of nematodes and help answer this question, Ding said.
Ants, which assemble to form buoyant rafts to survive floodwaters, are among the few creatures known to team up like nematodes, said David Hu, a professor of mechanical engineering and biology at Georgia Tech. Hu was not involved in the study.
'Ants are incredibly sacrificial for one another, and they do not generally fight within the colony,' Hu said. 'That's because of their genetics. They all come from the same queen, so they are like siblings.'
Like ants, nematodes didn't appear to display any obvious role differentiation or hierarchy within the tower structures, Perez said. Each worm from the base to the top of the structure was equally mobile and strong, indicating no competition was at play. However, the lab-cultivated worms were basically clones of one another, so it's not clear whether role differentiation occurs more often in nature, where nematode populations could have more genetic differences, she noted.
Additionally, socially cooperative creatures tend to use some form of communication, Peleg said. In the case of ants, it may be their pheromone trails, while honeybees rely on their ritual dance routines and slime molds use their pulsing chemical signals.
With nematodes, however, it's still not clear how they might communicate — or if they are communicating at all, Ding said. 'The next steps for (the team) are really just choosing the next questions to ask.'
Notably, there has been a lot of interest in studying cooperative animal behaviors among the robotics community, Hu said. It's possible that one day, he added, information about the complex sociality of creatures like nematodes could be used to inform how technology, such as computer servers or drone systems, communicates.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
9 hours ago
- Yahoo
‘Superorganisms' were just seen in the wild for the first time ever
If you purchase an independently reviewed product or service through a link on our website, BGR may receive an affiliate commission. For years, scientists have watched nematodes build massive superorganisms in the form of writhing towers. But, they've only seen it happen in the lab. Now, though, researchers write that they've observed these massive, disturbing towers writhing in the wild for the first time ever. Previously, researchers believed that the behavior was meant to be an attempt to escape from the rest of the group. However, new images of the writhing towers appear to suggest they're actually used cooperatively, to benefit many worms instead of just one. Today's Top Deals Best deals: Tech, laptops, TVs, and more sales Best Ring Video Doorbell deals Memorial Day security camera deals: Reolink's unbeatable sale has prices from $29.98 The researchers reported their findings in a report published in Current Biology, writing that these towering superorganisms only existed naturally in their imaginations for the longest of times. Observing the towers also taught researchers quite a bit about how different species of nematode work together. While watching the towers, the scientists note that while many different species crawled through the worm towers, only one species, a tough larval stage known as a dauer, actually participated in building up the writing masses. This specificity in the construction of the tower points to something more than just random cooperation. These towers are truly superorganisms, then, and not just piles of writing worm bodies. This discovery also got researchers thinking: could other worms form writhing towers like this, too? To test that hypothesis, they stuck a toothbrush bristle into a food-free agar plate, then unleashed a bunch of roundworms from the species Caenorhabditis elegans into the structure. Immediately, the worms began to work together and build up a tower. Within two hours, the researchers say the C. elegans had formed a tower using the bristle as its spine. The researchers watched as some worms along the superorganism writhed and acted as exploratory arms. Others acted as bridges between gaps. To see how the superorganism would respond, the researchers tapped the top of the tower with a glass pick. Almost immediately, the worms began to wriggle and move toward the area. This, they say, shows that these towers are always growing and moving toward stimulus. It's an intriguing show of cooperation between the worms, and just one more way that worms continue to astound scientists. It also raises more questions about why these superorganisms form in the first place. Even more interesting, though, is that the roundworms didn't appear to hold any kind of class system in place. Where the nematodes only relied on the larval stage worms to create the tower, all the roundworms chimed in to help build up the mass. Researchers will need to dig deeper to see exactly why worms form these writhing superorganisms. Hopefully other species, like the parasitic hairworm, aren't capable of this same kind of behavior. More Top Deals Amazon gift card deals, offers & coupons 2025: Get $2,000+ free See the
Yahoo
2 days ago
- Yahoo
This ‘Tower of Worms' Is a Squirming Superorganism
When food runs out, certain tiny roundworms, barely visible to the naked eye, crawl toward one another and build living, wriggling towers that move as one superorganism. For the first time, we've caught them doing that in nature on video. Scientists spent months pointing their digital microscope at rotting apples and pears to finally catch a glimpse of these living towers formed by Caenorhabditis roundworms in an orchard that is just downhill from the Max Planck Institute of Animal Behavior's location in Konstanz, Germany. 'It wasn't that hard to find. It's just the people didn't have the interest or time or funding for this kind of research,' says biologist Daniela Perez, lead author of the study. Perez and her team at the Max Planck Institute of Animal Behavior then studied this behavior in a laboratory to learn more. To spur the towering, they placed groups of Caenorhabditis elegans in a dish without food, alongside a toothbrush bristle that could work as a scaffold. Dozens of worms quickly climbed on top of the bristle and one another to form a structure that moved in an eerily coordinated manner. The tower responded to the touch of a glass pipe by attempting to latch onto it; it stretched to bridge the gap between the bottom of the dish and its lid; and it even waved its tip around to probe the surrounding environment. The results were published Thursday in Current Biology. [Sign up for Today in Science, a free daily newsletter] Researchers had previously observed this towering in the lab but didn't know that it was an actual survival strategy in the wild. 'Discovering [this behavior] in wild populations is really important as it shows this is a part of how these animals live and not just a lab artifact,' says William Schafer, a geneticist at the University of Cambridge, who studies C. elegans and was not involved in the study. Why do the worms do this? The researchers think towering helps worms set out to find richer food sources. When resources are limited, 'it probably makes sense for microscopic organisms to cooperate for dispersing by forming something bigger,' says the study's senior author Serena Ding. The towers could allow some of their members to reach new places or to hitchhike on other organisms such as fruit flies. The bigger question is how the worms communicate within the towers. If the worms on top latch onto a fly, how do those at the bottom know to detach from where they're anchored? They could communicate chemically through pheromones and mechanically through movement patterns, Schafer suggests. Perez says her team plans to test this next. 'Every time we have a meeting, we end up with 10 new project ideas,' she says. 'There are so many directions we can take this.'
Yahoo
2 days ago
- Yahoo
Watch 'superorganism' created by tiny worms — the first time it's ever been spotted in the wild
When you buy through links on our articles, Future and its syndication partners may earn a commission. Nematodes have been spotted forming writhing towers of tiny worms in the wild for the first time, according to a report in the journal Current Biology. The bizarre behavior had previously only been observed in experimental settings, thought to be a competitive attempt to escape from the rest of the group. However, new images of these towers forming in the wild hint at a more mutually-beneficial motivation. The footage was captured by researchers in Konstanz, Germany, on fallen apples and pears at local orchards. The team from the Max Planck Institute of Animal Behavior (MPI-AB) and the University of Konstanz were then able to combine these images with follow-up laboratory experiments to demonstrate that the 'towering' behavior happens naturally, and that the worms engage in such behaviour as a means of mass transit. 'I was ecstatic when I saw these natural towers for the first time,' said senior author Serena Ding, group leader at the MPI-AB, describing the moment when co-author Ryan Greenway, a biologist at the University of Konstanz, sent her a video recording from the field. 'For so long natural worm towers existed only in our imaginations. But with the right equipment and lots of curiosity, we found them hiding in plain sight.' That curiosity also revealed some interesting aspects of worm cooperation. While the researchers observed many nematode species crawling inside the fruit, only a single species in the same developmental period — a tough larval stage known as a 'dauer' — participated in tower building. That level of species specificity in worm tower 'construction' hinted that there might be more driving the behavior than a seemingly random creature cluster. Related: Nematode resurrected from Siberian permafrost lay dormant for 46,000 years 'A nematode tower is not just a pile of worms,' said study first author Daniela Perez, a postdoctoral researcher at MPI-AB. 'It's a coordinated structure, a superorganism in motion.' The paper suggested these observations could serve as a 'missing link' into behavior of similar organisms. Such towering behavior has previously been observed in slime molds, fire ants and spider mites, but it is still relatively rare in nature. To see if other kinds of worms could also form such a 'superorganism', researchers created conditions to coach the roundworm Caenorhabditis elegans into assembling into similar structures. C. elegans is a model organism that is widely studied for both its behavior and biology. Perez stuck a toothbrush bristle into a food-free agar plate to act as a sort scaffold — then unleashed the worms. Within two hours, the C. elegans formed a tower using the bristle as its spine. Some smaller clusters of worms reached out exploratory 'arms,' while others bridged gaps between spaces. And when researchers tapped the top of the tower with a glass pick, the worms wriggled toward that stimulus. 'The towers are actively sensing and growing,' says Perez. 'When we touched them, they responded immediately, growing toward the stimulus and attaching to it.' RELATED STORIES —Why do worms come out in the rain? —Australian 'trash parrots' have now developed a local 'drinking tradition' —Wandering salamander: The tree‑climbing amphibian with a blood‑powered grip The researchers also wondered if there was some sort of worm hierarchy driving this activity. Did younger worms have to do all the work? Stronger ones? Smaller, weaker ones? It turns out that the roundworms were remarkably egalitarian in their efforts. Unlike the orchard-based nematodes, the laboratory-bound C. elegans represented a range of life stages, from larval to adult — but they all pitched in. That suggests 'towering' may be a more generalized strategy for group movement than previously thought. 'Our study opens up a whole new system for exploring how and why animals move together,' says Ding.
