With the help of more than five dozen fossils, paleontologists have uncovered a tiny three-eyed predator nicknamed the “sea moth” that swam in Earth’s oceans 506 million years ago. Mosura fentoni, as the species is known, belongs to a group called radiodonts, an early offshoot of the arthropod evolutionary tree, according to a new study published Tuesday in the journal Royal Society Open Science. While radiodonts are now extinct, studying their fossilized remains can illuminate how modern arthropods such as insects, spiders and crabs evolved. One of the most diverse animal groups, arthropods are believed to account for more than 80% of living animal species, said lead study author Dr. Joe Moysiuk, curator of paleontology and geology at the Manitoba Museum in Winnipeg. Well-preserved specimens of the previously unknown Mosura fentoni also reveal something that’s never been seen in any other radiodont: an abdomen-like body region with 16 segments that include gills at its rear. This part of the creature’s anatomy is similar to a batch of segments bearing respiratory organs at the rear of the body found in distant modern radiodont relatives like horseshoe crabs, woodlice and insects, Moysiuk said. The feature, likely used to help Mosura capture more oxygen from its environment, could represent an example of evolutionary convergence, in which similar-looking structures evolve independently in different groups of organisms, he said. “The new species emphasizes that these early arthropods were already surprisingly diverse and were adapting in a comparable way to their distant modern relatives” said study coauthor Dr. Jean-Bernard Caron, the Richard M. Ivey Curator of Invertebrate Paleontology at the Royal Ontario Museum in Toronto, in a statement. A unique marine ‘moth’ No animal living today quite looks like Mosura fentoni, Moysiuk said, although it had jointed claws similar to those of modern insects and crustaceans. But unlike those critters, which can have two or four additional eyes used to help maintain orientation, Mosura had a larger and more conspicuous third eye in the middle of its head. “Although not closely related, Mosura probably swam in a similar way to a ray, undulating its multiple sets of swimming flaps up and down, like flying underwater,” Moysiuk said in an email. “It also had a mouth shaped like a pencil sharpener and lined with rows of serrated plates, unlike any living animal.” About the size of an adult human’s index finger, Mosura and its swimming flaps vaguely resemble a moth, which led researchers to call it the “sea moth.” Some of the Mosura specimens provided tantalizing traces of front claws, which helped the radiodont feed. Caron used a miniature jackhammer to remove rock overlying the head of a specimen and found a perfect outstretched spiny claw tucked beneath, Moysiuk said. “Unlike many of its relatives which have claws lined with a meshwork of spines for capturing prey, Mosura has long, smooth-sided, finger-like spines that are forked at their tips,” Moysiuk said. “It’s a bit of a puzzle how exactly it was using these to capture prey, but (we) think it might have seized smaller animals with the tips of the spines and passed them towards the mouth.” While there is no direct evidence of what Mosura ate, we know it lived alongside animals like acorn worms, bristle worms and small crustacean-like arthropods that the radiodont could have preyed on. In turn, Mosura may have been prey for other larger radiodonts, such as the shrimplike Anomalocaris canadensis, or the gargantuan jellyfish Burgessomedusa phasmiformis. “This showcases there are yet more examples of these animals, specifically, forms that were active marine predators, filling in more of the picture of how this ancient marine ecosystem functioned,” said Dr. Russell D.C. Bicknell, a postdoctoral researcher in the American Museum of Natural History’s division of paleontology. Bicknell was not involved in the new study but previously authored research on Anomalocaris canadensis. Mosura’s unexpected trunk region challenges how researchers understand radiodont body evolution and how members of the group shifted from having wormlike bodies, said Rudy Lerosey-Aubril, an invertebrate paleontologist at the Harvard Museum of Comparative Zoology who was also not involved with the new research. “It may offer a rare glimpse into developmental processes, particularly in early members of the group, before evolutionary shifts led to the more consistent body organization seen in most known species,” Lerosey-Aubril said in an email. A trove of fossils The first Mosura fentoni specimen was discovered early in the 20th century by paleontologist Charles Walcott, who was the first known person to collect fossils from British Columbia’s Burgess Shale, a 508 million-year-old fossil bed. Walcott was the director of the US Geological Survey and administrator of the Smithsonian Institution. But no research about the Mosura specimen he found was ever published, and little was known about radiodonts at the time. The other 60 fossils were collected by researchers at the Royal Ontario Museum between 1975 and 2022. “It’s only with time and study of related species that the significance of these fossils gradually became clear,” Moysiuk said. “More recently, our team started finding additional specimens at new Burgess Shale sites in Kootenay National Park, which helped to spur on this publication.” The fossils found in the Burgess Shale, located within the Canadian Rockies, represent a wide range of animals from the end of the Cambrian Period, when life diversified on a large scale. The Burgess Shale fossils are also known for being incredibly well preserved. “In this study we were able to discern traces of the nervous, digestive, and circulatory system, which are almost never preserved as fossils,” Moysiuk said in an email.“This provides unique and significant insight into life at this critical time in Earth’s history.” The team was able to spy traces that represented bundles of nerves in the eyes, which — like modern arthropods — Mosura used for image processing, Caron said. Rather than arteries and veins, Mosura also had an open circulatory system, meaning that its heart pumped blood into lacunae, or large internal body cavities. The cavities were preserved as reflective patches within the body. The discovery of numerous complete tiny radiodont specimens is remarkable, Lerosey-Aubril said. The fine details preserved within the fossil underscore the importance of the Burgess Shale, he added, and a broader picture of the full diversity of Cambrian animals will require investigating other sites that hold fossils and evidence of soft-bodied organisms. Radiodont fossils are permanently on display in the Royal Ontario Museum’s “Dawn of Life” exhibition, and a Mosura specimen will be on view at the Manitoba Museum later this year.
A three-eyed ‘sea moth’ was an ocean predator 506 million years ago
TruthLens AI Suggested Headline:
"Discovery of 506-Million-Year-Old 'Sea Moth' Enhances Understanding of Early Arthropod Evolution"
CNN
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TruthLens AI Summary
Paleontologists have recently identified a new species of ancient marine predator known as Mosura fentoni, or the 'sea moth,' which swam in Earth's oceans approximately 506 million years ago. This discovery, made possible by analyzing over sixty fossils, adds to the understanding of early arthropods, a diverse group that includes modern insects, spiders, and crustaceans. Mosura fentoni is classified within a group called radiodonts, which are now extinct but are significant for understanding the evolutionary history of arthropods. The well-preserved fossils reveal unique anatomical features, including an abdomen-like region with 16 segments that housed gills, paralleling respiratory structures found in modern relatives like horseshoe crabs and insects. This similarity suggests evolutionary convergence, indicating that different organisms can develop similar adaptations independently. Lead study author Dr. Joe Moysiuk emphasized the surprising diversity of these early arthropods, which adapted in ways reminiscent of their modern counterparts.
The 'sea moth' is characterized by its jointed claws and a distinctive third eye located in the center of its head. Unlike modern arthropods that typically possess two or four eyes for orientation, Mosura's prominent third eye sets it apart. It likely swam similarly to a ray, utilizing multiple sets of swimming flaps. The creature's mouth, shaped like a pencil sharpener and lined with serrated plates, was uniquely adapted for feeding. Although direct evidence of its diet remains elusive, Mosura is presumed to have preyed on smaller marine organisms that coexisted with it, while potentially becoming prey for larger marine predators. The fossils, primarily discovered in the Burgess Shale in Canada, are noted for their exceptional preservation, offering insights into the nervous, digestive, and circulatory systems of this ancient species. This research not only sheds light on the evolutionary pathways of radiodonts but also highlights the importance of fossil sites like the Burgess Shale in understanding the Cambrian period's biodiversity.
TruthLens AI Analysis
The article presents an intriguing discovery in paleontology, highlighting the existence of a prehistoric predator known as Mosura fentoni, which swam in the oceans 506 million years ago. This finding adds a new dimension to our understanding of early arthropods and their evolutionary adaptations.
Purpose of the Publication
The primary aim of this news piece is to inform the public about significant paleontological findings that can enhance our understanding of evolutionary biology. By introducing Mosura fentoni, the article seeks to illustrate the diversity and adaptability of early arthropods, thereby engaging readers with the narrative of evolution and extinction.
Public Perception
This discovery is likely to generate fascination and curiosity among readers, especially those interested in natural history and evolutionary science. The mention of unique anatomical features, such as the three eyes and segmented body, serves to captivate the audience and highlight the complexity of ancient marine life.
Potential Omissions
While the article focuses on the discovery of a specific species, it does not delve deeply into the broader implications of this finding on current environmental issues or the ongoing extinction crisis among modern marine species. By emphasizing the uniqueness of Mosura fentoni, there may be a subtle avoidance of discussing present-day biodiversity challenges.
Manipulative Elements
The report does not appear to contain overt manipulative elements, as its language is primarily descriptive and factual. However, the framing of the species as a “sea moth” could evoke a sense of whimsy, potentially captivating a wider audience. This choice of terminology may subtly influence the reader's emotional response.
Trustworthiness of the News
The article relies on credible sources, including paleontologists and their research published in a peer-reviewed journal. The factual presentation of the fossil evidence and the accompanying scientific commentary enhance its reliability. However, the excitement generated by such discoveries can sometimes overshadow the complexities and uncertainties inherent in paleontological research.
Societal Implications
The discovery may encourage further interest in paleontology and evolutionary biology, potentially influencing educational content or funding for related research. It could also inspire discussions about the resilience and adaptability of life, relevant themes in the face of current environmental crises.
Target Audience
This article likely appeals to audiences interested in science, particularly those with a focus on paleontology, biology, and natural history. It may also resonate with educational institutions and science enthusiasts looking to promote awareness of evolutionary science.
Market Impact
While this discovery may not directly impact financial markets or specific stocks, it could influence investments in scientific research or education sectors. Public interest in evolutionary studies can lead to increased funding or support for museums and educational programs, indirectly affecting related industries.
Global Power Dynamics
The article does not directly address current global power dynamics; however, it contributes to the broader discourse on the importance of scientific research and education in shaping informed societies. The emphasis on evolutionary understanding can tie into discussions on biodiversity conservation and environmental stewardship, relevant in today's global context.
AI Involvement
There is no clear indication that artificial intelligence was used in drafting this article. However, AI models could be employed in analyzing fossil data or predicting evolutionary trends. If AI were involved, it might have guided the analysis of paleontological findings, shaping the narrative to highlight significant discoveries.
The analysis of the article suggests a well-researched and credible representation of a significant paleontological discovery. While it engages the public's imagination about ancient life forms, it also reflects the ongoing importance of studying evolutionary history.