Oldest-known ant preserved in 113 million-year-old Brazilian fossil
(Reuters) -Scientists have identified the fossilized remains of the oldest-known ant - a winged insect with fearsome scythe-like jaws that lived about 113 million years ago during the age of dinosaurs and was preserved in limestone unearthed in northeastern Brazil.
The species, called Vulcanidris cratensis, is part of a lineage called hell ants - named for their demonic-looking jaws - that prospered in a wide geographical range during the Cretaceous Period but have no descendants alive today. A previously discovered Cretaceous hell ant was named Haidomyrmex in honor of Hades, the ancient Greek god of the underworld.
A medium-sized ant about a half-inch (1.35 cm) long, Vulcanidris possessed highly specialized jaws that would have enabled it to pin down or impale prey. Like some ants alive today, it had wings and appears to have been a capable flier. It also had a well-developed stinger like a wasp.
"It would probably be confused with a wasp by an untrained eye," said entomologist Anderson Lepeco of the Museum of Zoology of the University of São Paulo, lead author of the study published this week in the journal Current Biology.
"They probably used their mandibles (mouthparts) to handle their prey in a specific way," Lepeco said.
Its mandibles moved up and down and not side to side, as they do in today's ants.
"Currently, many odd mandible shapes can be found in ants, but they usually articulate horizontally," Lepeco said.
This ant is roughly 13 million years older than the previous oldest-known ants, specimens found in France and Myanmar that were preserved in amber, which is fossilized tree sap.
The Vulcanidris anatomy is remarkably well preserved in the limestone, which was excavated decades ago in the Crato geological formation in the Brazilian state of Ceará, probably in the 1980s or 1990s, according to Lepeco. It was held in a private collection before being donated to the São Paulo museum about five years ago.
"I was looking for wasps among the fossils of the collection and was shocked when I recognized this one as a close relative of a hell ant previously described from Burmese amber," Lepeco said, referring to the fossil from Myanmar.
The specialized nature of the Vulcanidris anatomy and the fact that two hell ants lived so far from each other during this part of the Cretaceous suggest that ants as a group emerged many millions of years before this newly identified species existed.
"According to molecular estimates, ants originated between 168 million and 120 million years ago. This new finding supports an earlier age within these limits," Lepeco said.
Ants are believed to have evolved from a form of wasp. Their closest living relatives are wasps and bees.
Vulcanidris inhabited an ecosystem teeming with life. Fossils from the region show that Vulcanidris lived alongside other insects, spiders, millipedes, centipedes, various crustaceans, turtles, crocodilians, flying reptiles called pterosaurs, birds and dinosaurs including the feathered meat-eater Ubirajara. The ant's predators may have included frogs, birds, spiders and larger insects.
Ants have colonized almost everywhere on Earth, and research published in 2022 estimated that their total population is 20 quadrillion globally. That dwarfs the human population of about 8 billion.
"They are one of the most abundant groups in most environments on Earth," Lepeco said.
"They play many roles where they occur, such as predation and herbivory, controlling populations of other organisms. They also have intrinsic relationships with specific plants and insects, protecting them from other animals. Subterranean and litter ants help in soil health, and they may also act as decomposers, feeding on dead organisms," Lepeco said.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
29 minutes ago
- Yahoo
Japan's Takeda weighs India for global trials to speed up drug launches
By Rishika Sadam and Bhanvi Satija (Reuters) -Japanese drugmaker Takeda Pharmaceutical is exploring the option of conducting global clinical trials in India to accelerate the launch of its innovative drugs in the world's most populous nation, its India head told Reuters. The plan comes at a time when India's clinical trials market is growing, powered by diverse patient pools, cost efficiency, and a fast-growing hospital network. Grand View Research expects the market to exceed $2 billion by 2030. "India is a strategic growth market for Takeda, and we are making significant long-term investments... in terms of innovation and building capabilities," said Annapurna Das, the general manager of Takeda's India operations. She did not share financial details of the investments. "We're exploring the opportunity of leveraging India's clinical trial ecosystem," Das said. Takeda is also open to partnering with local academia, healthcare providers and technology firms in India for innovation, Das said, without sharing more specifics. "At this point of time, we are still kind of exploring and evaluating how we want to go ahead," she added. Takeda's eventual aim is to integrate India's research and development "ecosystem" into its global pipeline and expand Indian patients' access to cutting-edge therapies in oncology, neuroscience, gastrointestinal health, and inflammation. The Japanese drugmaker aims to launch key cancer drugs over the next two to three years in India, with a lung cancer drug ready to hit the market this year. There's also a dengue vaccine in its launch pipeline, for which Takeda has tied up with local vaccine maker Biological E., and is awaiting approval from India's drug regulator. Takeda established an innovation centre in Bengaluru, dubbed India's "Silicon Valley", earlier this year to tap the country's tech talent to power its global digital transformation. The centre is expanding to have 750 staff working in AI, data science, engineering, and design, from just over 500 employees currently. Sign in to access your portfolio
Scientific American
19 hours ago
- Scientific American
Math Breakthroughs from Behind Bars
In 2014 Mura Yakerson, a college student at the time, decided to practice driving in a quiet area in the countryside near Saint Petersburg, Russia. Then something went wrong. While she was pulling out of a parking space, Yakerson accidentally damaged another car. This incident turned out to be the beginning of a nightmare. Because she drove away from the scene, unaware that she had hit another vehicle, a judge later charged Yakerson with leaving the place of an accident and then gave her the choice between a one-year driving ban or three days in jail. Yakerson chose incarceration. She thought that, away from distractions, she could devote herself to understanding a challenging paper by mathematician Marc Levine of the University of Duisburg-Essen in Germany. But those three days were difficult in ways that she didn't anticipate. She couldn't summon the energy to delve into Levine's work applying algebraic topology to algebraic varieties (which is just as challenging as it sounds). Instead she distracted herself with daydreams about doing 'beautiful math,' as she described it in an online essay, and completing her doctoral thesis under Levine's supervision. She later pursued graduate studies with Levine, earned her Ph.D. and, after defending her thesis, shared her extraordinary backstory with her colleagues. On supporting science journalism If you're enjoying this article, consider supporting our award-winning journalism by subscribing. By purchasing a subscription you are helping to ensure the future of impactful stories about the discoveries and ideas shaping our world today. Yakerson is not alone. Several renowned mathematicians gained invaluable experience despite the challenges of incarceration. As the ancient Greek philosopher and historian Plutarch noted while describing the accomplishments of the scholar Anaxagoras, 'There is no place that can take away the happiness of man, nor yet his virtue or wisdom.' Anaxagoras of Clazomenae: Steadfast Heretic In the fifth century B.C.E., Greek philosopher Anaxagoras refused to recognize the sun as a deity. Instead he declared that the moon shines because it reflects the sun's light and that the moon and sun were objects, not gods. These statements were heretical in Athens, where Anaxagoras lived. Exactly what happened next is still somewhat up for debate, but Plutarch records that Anaxagoras was imprisoned. Records suggest he only escaped the death penalty because of his close relationship with Pericles, an important Athenian statesman. To pass the time in prison, Anaxagoras attempted to construct a square with the same area as a circle. He tackled this feat, 'squaring a circle,' with nothing more than a string, an unmarked ruler and a pencil. Ultimately, he failed. Despite his success in theoretical astronomy, this particular task was doomed from the start. More than 2,000 years later, other scholars would determine that it couldn't be any other way. In the 19th century mathematicians discovered that squaring the circle with only a ruler and compass is impossible. This proof was itself made possible by a mathematical theory developed by Évariste Galois, who, incidentally, was also imprisoned in his lifetime, in his case for proposing a toast to the death of the French king. Tibor Radó: Escape into Infinity Hungarian-born Tibor Radó began studying engineering in the early 20th century but was forced to abandon his studies shortly after the outbreak of World War I. He served as a soldier on the Russian front and ended up in a Siberian prisoner of war camp in 1916. There he met Austrian mathematician Eduard Helly, who was also imprisoned. In the years that followed, Helly introduced the inquisitive Radó to the fundamentals of mathematical research. During the riots caused by Russia's White Army in 1919, Radó managed to escape from the prison camp and fight his way through Siberia on foot. The young man traveled more than 1,000 kilometers to his homeland of Hungary, which he finally reached in 1920. There he resumed his studies—this time, however, he chose mathematics, inspired by Helly, with whom he maintained close contact until Helly's death in 1943. Throughout his career, Radó explored the limits of mathematics. He succeeded in constructing numbers and functions that are 'uncomputable,' or beyond the reach of even the most powerful supercomputers. André Weil: Pacifist Border Crosser As geopolitical tensions increased worldwide in the 1930s, mathematician André Weil, a committed pacifist, sought to avoid French military service and emigrated to the U.S. Weil was on a research trip to Finland when World War II broke out in 1939. Shortly thereafter, he was arrested on suspicion of espionage after Finnish authorities found suspicious writings in his possession. 'The manuscripts they found appeared suspicious—like those of Sophus Lie, arrested on charges of spying in Paris, in 1870,' Weil later recalled. The authorities also uncovered rolls of paper, which Weil reported as the text of a novel by Honoré de Balzac, a letter in Russian and calling cards that displayed a pseudonymous name used by Weil and other French mathematicians. Fortunately, renowned Finnish mathematician Rolf Nevanlinna was able to convince the authorities to deport Weil to Sweden. From there, he was extradited via the U.K. to France, where he was imprisoned again for evading military service. While imprisoned in Rouen, France, Weil developed one of the most ambitious programs in mathematics, which experts are still working on today: a kind of Rosetta stone connecting seemingly disparate fields (number theory, algebra and geometry). Mathematics in Prison Today These four are just a few of many examples of imprisoned people who made important discoveries for the field or encountered mathematical concepts that would set their careers on bold new trajectories. A particularly compelling case is that of Christopher Havens, an incarcerated person who was convicted of murder in 2010. Havens founded the Prison Mathematics Project, or PMP, to make mathematical research accessible to people in prison in the U.S. As Havens discovered, accessing specialized content in prison is extremely difficult. Prison libraries are generally poorly equipped, and incarcerated people generally lack Internet access. PMP addresses that need, in part through a mentoring program by which interested people in prison can exchange ideas with mathematicians. It's been a successful project in many ways. Some incarcerated people have published their first professional publications through it. And given the long history of mathematical breakthroughs begun behind bars, I'm excited to see what mathematical breakthroughs it will produce in the future.
USA Today
20 hours ago
- USA Today
You can't see it, but a rare 'black moon' is due this week. How it happens.
You won't actually see it, but a rare black moon – this one, the second new moon in an astronomical season – will appear on Aug. 23. Weather permitting, it'll give you darker skies and extra time to stargaze and to observe the end of the Perseid meteor shower. The term "black moon" is more of a folksy name, not an official label in astronomy, says It's a rare occurrence, taking place once every 33 months. In simple terms, a black moon is an extra new moon. (A new moon, one of the eight lunar phases, is the moon you can't see.) New moons happen when the moon is between the Earth and the sun. Its illuminated side faces away from Earth, which makes it invisible to us. Can't see our graphics? Click here to reload the page. The absence of reflected moonlight during a new moon makes stars and other celestial objects easier to see. That's when amateur astronomers can get out their telescopes or binoculars to study planets, stars and other deep-sky objects. Black moons are unique because our 30- or 31-day calendar months are slightly different from 29.5-day lunar cycles. Astronomical seasons are also different, since lunar cycles don't fit neatly into them. The differences allow black moons to appear at irregular intervals. Black moons are referenced like blue moons, which are defined as the third full moon in an astronomical season containing four full moons. (Full moons are moons that are fully illuminated.) How are black moons defined? Monthly black moon: A second new moon in a calendar month. Seasonal black moon: The third new moon in an astronomical season with four new moons. There are four astronomical seasons, defined by the Earth's position in its solar orbit: Astronomical seasons usually have three new moons. If a season has four new moons, the third is labeled a black moon. SOURCE USA TODAY Network reporting and research; Reuters; NASA; National Geographic
