Latest news with #Dickinsonia
Time of India
22-05-2025
- Science
- Time of India
Ikaria Wariootia: The earliest known animal ancestor on the planet has been discovered from South Australia
Scientists have identified Ikaria wariootia , a tiny, wormlike creature that lived over 555 million years ago, as the earliest known bilaterian — an animal with a front, back, and symmetrical sides. Detailed in the journal Proceedings of the National Academy of Sciences , this discovery from South Australia provides crucial evidence for a major evolutionary leap during the Ediacaran period: the origin of bilateral body structure, a key feature of nearly all animals today, including humans. Ikaria Wariootia: A peek into the first bilaterian animals Bilaterians are animals that exhibit bilateral symmetry, meaning their bodies have two symmetrical halves, each mirroring the other. This structure includes distinct head, tail, back, and belly, facilitating controlled movement and internal complexity. Scientists had long hypothesized that the earliest bilaterians would be simple, small, and possess basic sensory organs, but no fossil evidence had confirmed this—until the discovery of Ikaria wariootia . Measuring just 2 to 7 millimeters, this creature is about the size of a grain of rice. Dr. Scott Evans from the University of California, Riverside, explained, 'While we believed such animals existed during this time, we didn't expect them to be easy to identify. When we saw the 3D scans, we knew we had found something significant.' Using advanced 3D laser scanning, the team uncovered the fossil's cylindrical body, clear bilateral symmetry, and signs of musculature, marking a pivotal discovery in understanding early bilaterian life. Insights into ediacaran lie and the evolution of animals This discovery also changes how scientists perceive other Ediacaran organisms. While large, iconic species like Dickinsonia were previously considered evolutionary dead ends without any living descendants, smaller and simpler creatures like Ikaria may represent the earliest ancestors of bilaterians, the group that gave rise to most modern animals. "While Dickinsonia and similar large creatures were likely evolutionary dead ends, we also had many smaller organisms and suspected they might be the early bilaterians we were searching for," said Professor Droser. The identification of Ikaria wariootia bridges the gap between genetic theories and fossil records, confirming that early bilaterians had the body structure and abilities necessary for complex behaviors like directed movement and burrowing. Fossilized burrows provide evidence of purposeful movement in Ikaria Wariootia The discovery is linked to fossilized burrows known as Helminthoidichnites , found in the same geological layers in Nilpena, South Australia. For over 15 years, paleontologists speculated these burrows were created by bilaterians, but the exact organism remained unclear. The size and shape of Ikaria wariootia match these burrows, reinforcing the idea that the creature actively burrowed into oxygen-rich ocean-floor sand in search of organic matter. "Burrows of Ikaria wariootia are found deeper than any other, making it the oldest fossil with this level of complexity," said Professor Mary Droser. The fossil also shows V-shaped ridges in the burrows, indicating that Ikaria used peristaltic locomotion, contracting its muscles like modern worms. This type of movement suggests an advanced level of coordination and sensory input previously unknown in such early animals. Significance of this discovery by Proceedings of the National Academy of Sciences The discovery of Ikaria wariootia significantly reshapes our understanding of early animal evolution. Dating back 555 million years to the Ediacaran period, it is the earliest known bilaterian fossil, showing bilateral symmetry, a key feature of most modern animals. This discovery bridges the gap between genetic predictions and fossil evidence, supporting the idea that early bilaterians were small, simple creatures with complex capabilities, such as purposeful movement and burrowing. The fossil's association with Helminthoidichnites burrows suggests that Ikaria actively tunneled through oxygenated ocean-floor sand, indicating coordination and sensory input. This finding challenges prior assumptions about the pace of evolution, demonstrating that complex behaviors and body plans could have evolved much earlier than previously thought. Ikaria wariootia provides a crucial insight into the origins of animal complexity, marking a significant milestone in our understanding of the pre-Cambrian evolution of life on Earth. Fossil characteristics of Ikaria Wariootia The Ikaria wariootia fossil exhibits several key characteristics that make it a groundbreaking discovery in the study of early animal evolution. These characteristics are: Bilateral Symmetry The fossil shows clear evidence of bilateral symmetry, meaning it has a defined left and right side that mirror each other. This symmetry is a key trait of bilaterians, the group from which most modern animals, including humans, evolved. Small Size Ikaria wariootia measures just 2 to 7 millimeters long, roughly the size of a grain of rice. Its small size is consistent with its position as an early, simple bilaterian. Cylindrical Body Shape The fossil's cylindrical body, observed through 3D scanning, suggests a simple yet functional body plan, capable of basic movement and burrowing. Musculature Evidence The fossil displays signs of musculature, which support the idea that Ikaria could move in a coordinated manner, likely using peristaltic locomotion similar to modern worms. Burrow Association The fossil is linked to Helminthoidichnites burrows, which are V-shaped and indicative of active tunneling behavior. These burrows suggest that Ikaria moved purposefully through oxygenated ocean-floor sand, searching for organic matter. Complex Locomotion The presence of V-shaped ridges in the burrows indicates Ikaria used a form of peristaltic movement, contracting muscles across its body, highlighting an early form of coordinated, complex movement. Importance of discovery of Ikara wariootia The discovery of Ikaria wariootia provides valuable insights into early animal behavior, particularly in terms of its locomotion and environmental interactions. Here are some key behavioral implications: Purposeful Movement The presence of Ikaria wariootia in association with Helminthoidichnites burrows suggests that it actively tunneled through the ocean-floor sand. This implies that Ikaria was capable of purposeful movement, likely searching for organic matter. Such behavior indicates a level of coordination and sensory input, much like modern worms, which use their muscles to move in a controlled manner. Peristaltic Locomotion The V-shaped ridges observed in the burrows suggest that Ikaria used peristaltic movement—contracting muscles along its body to propel itself forward. This form of locomotion is still seen in modern worms and other simple animals, demonstrating that early bilaterians had complex movement abilities, likely enabling them to explore their environment more effectively. Environmental Interaction The burrowing behavior highlights Ikaria's interaction with its environment, particularly its use of oxygenated sand for shelter and feeding. This shows that early bilaterians were capable of modifying their surroundings, a trait that would evolve in later species to allow more complex forms of behavior, such as constructing shelters or hunting. Sensory and Nervous System Development The ability to move purposefully and burrow suggests that Ikaria had a developed nervous system that allowed it to respond to its environment and carry out coordinated actions. The presence of muscles, coupled with coordinated movement, implies the evolution of basic sensory input and motor control, essential for more complex behaviors in future animals. Adaptation to the Environment Ikaria's ability to move through oxygenated sand in search of food suggests early adaptations for survival, allowing it to exploit available resources efficiently. This reflects a fundamental aspect of animal behavior—the need to adapt to and interact with the environment to find food, shelter, and mates. Impact of Ikara wariootia on study of early life The discovery of Ikaria wariootia provides valuable insights into early animal behavior, particularly in terms of its locomotion and environmental interactions. Here are some key behavioral implications: Purposeful Movement The presence of Ikaria wariootia in association with Helminthoidichnites burrows suggests that it actively tunneled through the ocean-floor sand. This implies that Ikaria was capable of purposeful movement, likely searching for organic matter. Such behavior indicates a level of coordination and sensory input, much like modern worms, which use their muscles to move in a controlled manner. Peristaltic Locomotion The V-shaped ridges observed in the burrows suggest that Ikaria used peristaltic movement—contracting muscles along its body to propel itself forward. This form of locomotion is still seen in modern worms and other simple animals, demonstrating that early bilaterians had complex movement abilities, likely enabling them to explore their environment more effectively. Environmental Interaction The burrowing behavior highlights Ikaria's interaction with its environment, particularly its use of oxygenated sand for shelter and feeding. This shows that early bilaterians were capable of modifying their surroundings, a trait that would evolve in later species to allow more complex forms of behavior, such as constructing shelters or hunting. Sensory and Nervous System Development The ability to move purposefully and burrow suggests that Ikaria had a developed nervous system that allowed it to respond to its environment and carry out coordinated actions. The presence of muscles, coupled with coordinated movement, implies the evolution of basic sensory input and motor control, essential for more complex behaviors in future animals. Adaptation to the Environment Ikaria's ability to move through oxygenated sand in search of food suggests early adaptations for survival, allowing it to exploit available resources efficiently. This reflects a fundamental aspect of animal behavior—the need to adapt to and interact with the environment to find food, shelter, and mates. Also read: James Webb Space Telescope identified Milky Way's cosmic twin from the universe's first billion years
Forbes
14-04-2025
- Science
- Forbes
In 2018, Dickinsonia Was Classified As The Oldest Known Animal — A Biologist Explains
Here's why Dickinsonia challenges our previously held beliefs and changes how we view evolutionary ... More history. For the longest time, it was believed all complex animal life could be traced to the Cambrian explosion that occurred over 500 million years ago. However, the discovery of Dickinsonia, a now-iconic member of the Ediacaran biota and possibly the oldest macroscopic animal fossil recorded to date, challenges these notions and our understanding of evolution on Earth. Living approximately 558 million years ago — well before the rapid diversification of animal body plans in the Cambrian — Dickinsonia raised fundamental questions about growth, movement and the evolution of early developmental strategies. Its fossilized imprints challenged conventional narratives on the origin of complex life and provided direct clues about early animal physiology and ecology. Furthermore, the 2018 discovery of distinctive molecular signatures in fossils, particularly cholesterol derivatives, has transformed our view of these soft-bodied organisms and provided strong evidence for their classification as some of the earliest animals in evolutionary history. Dickinsonia was first discovered in the late 1940s in South Australia's Flinders Ranges. Paleontologist Reg Sprigg initially identified its distinctive quilted pattern and named it in honor of Ben Dickinson, a government official with the South Australian Mines Department. The Flinders Ranges are renowned for preserving some of the world's oldest known complex life forms. Over the ensuing decades, fossils of Dickinsonia were reported from several continents, including sites in Russia and Ukraine, suggesting a cosmopolitan distribution during the Ediacaran period. These organisms were preserved only as impressions or casts in quartz sandstones — typical of soft-bodied organisms that left little by way of hard skeletal parts. The unique traits of Dickinsonia include its bilaterally symmetric, oval shape with a pronounced anterior–posterior axis. Repeating modules or isomeres run along its length, arranged in an alternating fashion that some researchers interpret as a form of glide reflection symmetry rather than strict bilateral segmentation. Studies on Dickinsonia have thus steadily shifted its classification due to how difficult it has been for scientists to peg it to a particular species. Once hypothesized as a jellyfish, fungus or even a giant protist, science now favors an animal interpretation. For decades, Dickinsonia's placement in the Tree of Life was hotly debated. Early interpretations ranged from it being a member of the Cnidaria, a group including jellyfish and sea anemones, to suggestions that it was a fungus or even a giant single-celled protist. Morphological features alone proved insufficient to resolve its systematic position since Dickinsonia exhibits few structures similar to modern animals. However, with the emergence of innovative geochemical techniques, researchers began to look at the molecules trapped within the fossil tissues, moving beyond mere morphology. The discovery of animal-specific cholesterol derivatives in Dickinsonia fundamentally altered its classification and strongly argued against non-metazoan alternatives. This is because cholesterol and its degradation product cholestane are found exclusively in animal cell membranes, thus providing molecular evidence of an animal affinity. Researchers suspect it likely lived on shallow marine substrates where it 'crawled' slowly, feeding on microbial mats by external digestion — a behavior somewhat analogous to modern placozoans, the phylum of free-living, non-parasitic marine invertebrates. The current consensus, therefore, leans toward classifying Dickinsonia as an animal. More specifically, it may have been an early relative of simple animals like placozoans or part of a completely new branch of early animals that later gave rise to creatures with bilateral symmetry. Studies of its growth patterns have shown consistent evidence for a regulated developmental program, a signature trait of animal life. These findings have not only provided the positive evidence needed to affirm Dickinsonia's animal status but have also reshaped our understanding of the Precambrian evolutionary landscape. The discovery and classification of Dickinsonia have had profound implications for our understanding of the Cambrian explosion. This rapid burst of evolutionary innovation, beginning around 500 million years ago, gave rise to nearly all the modern animal phyla. Dickinsonia and other Ediacaran organisms were once viewed as evolutionary dead ends — enigmatic forms with no descendants. However, the mounting evidence that Dickinsonia was an animal forces us to reframe these early organisms not as isolated experiments but as integral steps in the progression toward more complex body plans. Recent research has demonstrated that Dickinsonia's biological features — their regulated modular growth, evidence of animal-specific biomolecules and locomotive trace fossils — establish them as a credible evolutionary bridge between simple, soft-bodied organisms and the complex hard-bodied animals that dominate the Cambrian fossil record. In this light, the Ediacaran biota, far from representing failed experiments, appears to have set the stage for the diversification of animal life as we know it today. Does reading about how all life on Earth possibly traces back half a billion years fill you with appreciation for nature's guiding hand? Take the Connectedness To Nature Scale and find out how deep your connection is with the natural world.
