(CNN) — A massive, extinct reptile that once snacked on dinosaurs had a broad snout like an alligator’s, but it owed its success to a trait that modern alligators lack: tolerance for salt water. Deinosuchus was one of the largest crocodilians that ever lived, with a body nearly as long as a bus and teeth the size of bananas. From about 82 million to 75 million years ago, the top predator swam in rivers and estuaries of North America. The skull was wide and long, tipped with a bulbous lump that was unlike any skull structure seen in other crocodilians. Toothmarks on Cretaceous bones hint that Deinosuchus hunted or scavenged dinosaurs. Despite its scientific name, which translates as “terror crocodile,” Deinosuchus has commonly been called a “greater alligator,” and prior assessments of its evolutionary relationships grouped it with alligators and their ancient relatives. However, a new analysis of fossils, along with DNA from living crocodilians such as alligators and crocodiles, suggests Deinosuchus belongs on a different part of the crocodilian family tree. Unlike alligatoroids, Deinosuchus retained the salt glands of ancestral crocodilians, enabling it to tolerate salt water, scientists reported Wednesday in the journal Communications Biology. Modern crocodiles have these glands, which collect and release excess sodium chloride. Salt tolerance would have helped Deinosuchus navigate the Western Interior Seaway that once divided North America, during a greenhouse phase marked by global sea level rise. Deinosuchus could then have spread across the continent to inhabit coastal marshes on both sides of the ancient inland sea, and along North America’s Atlantic coast. The new study’s revised family tree for crocodilians offers fresh insights into climate resilience in the group, and hints at how some species adapted to environmental cooling while others went extinct. With salt glands allowing Deinosuchus to travel where its alligatoroid cousins couldn’t, the terror crocodile settled in habitats teeming with large prey. Deinosuchus evolved to become an enormous and widespread predator that dominated marshy ecosystems, where it fed on pretty much whatever it wanted. “No one was safe in these wetlands when Deinosuchus was around,” said senior study author Dr. Márton Rabi, a lecturer in the Institute of Geosciences at the University of Tübingen in Germany. “We are talking about an absolutely monstrous animal,” Rabi told CNN. “Definitely around 8 meters (26 feet) or more total body length.” An outlier among alligators Since the mid-19th century, fossils of Deinosuchus have been found on both sides of the ancient seaway and belong to at least two species. The largest of these, Deinosuchus riograndensis, lived on the western side, along the east coast of an island called Laramidia. Bordered on the west by the Pacific Ocean, Laramidia made up less than one-third of the landmass of North America. The continent’s other island portion was known as Appalachia. While Deinosuchus had long been classified as an alligator relative, its distribution on both sides of this vast seaway was an unsolved puzzle. If it was an alligatoroid — a group that today lives only in freshwater — how could Deinosuchus cross a sea spanning more than 620 miles (1,000 kilometers)? One hypothesis suggested that early alligators were saltwater tolerant and then later lost the trait. But that interpretation didn’t have much evidence to back it up; it hinged solely on Deinosuchus being included in the alligatoroid group, Rabi explained. Another possible explanation was that Deinosuchus dispersed across North America before the Western Interior Seaway formed and divided western and eastern populations. However, the fossil record doesn’t back that up. The seaway appeared about 100 million years ago, making it approximately 20 million years older than the earliest known Deinosuchus fossils. “The picture wasn’t very coherent,” Rabi said. For the new analysis, the researchers incorporated data from extinct crocodilians that were not sampled for the group’s earlier family trees. These “missing links” helped the team connect species that were not previously recognized to be related and reassemble the order in which certain traits emerged in the group. “Our analysis found that saltwater tolerance is a fairly ancient trait of many crocodilians, and was secondarily lost in the alligatoroids,” Rabi said. Having even a moderate tolerance for salt would have greatly benefited ancient crocodile relatives as climate shifts reshaped their habitats, said Dr. Evon Hekkala, a professor and chair of the department of biological sciences at Fordham University in New York City. “This ecological trait would have allowed lineages of crocodiles in the past to be more opportunistic in times when drastic environmental changes, such as sea level rise, were causing extinctions in less tolerant species,” said Hekkala, who was not involved in the study. Not a ‘greater alligator’ The researchers also constructed a new crocodilian family tree using molecular data from modern crocodilians to clarify features shared by all alligatoroids. The earliest alligators were far smaller than other crocodilians that lived at the same time, the team found. Alligators began to evolve the larger body sizes seen today about 34 million years ago, after the climate cooled and their competition went extinct. But when alligatoroids first appeared, Deinosuchus would have been an outlier due to its massive bulk, according to the new study. Dwarfism in early alligatoroids was another clue that giant Deinosuchus was no “greater alligator,” and it likely diverged into a different branch of the family tree before alligatoroids evolved, Rabi said. The study’s approach — combining a new molecular tree with morphology, or analysis of body and skull shapes in crocodilians — paints a clearer picture of how Deinosuchus evolved, Hekkala said. Shifting Deinosuchus away from alligatoroids “fits much better with our current understanding of ecological flexibility among the extinct and living crocodiles,” she added. “This new paper really reaches into both the evolutionary and ecological role of this amazing animal.” While Deinosuchus was one of the largest crocodilians, it wasn’t the only giant. Massive crocodilians evolved independently in aquatic environments more than a dozen times over the past 120 million years during all types of global climatic phases — including ice ages, according to the study. Even in living species, reports of individuals measuring 23 feet (7 meters) or more persisted until the 19th century, suggesting enormous Deinosuchus was the rule rather than the exception. “Giant crocs are more like the norm — of any time,” Rabi said.
Scientists discover how a ‘terror crocodile’ became a dinosaur-eating giant
TruthLens AI Suggested Headline:
"New Research Reveals Evolutionary Insights into Deinosuchus, the Giant 'Terror Crocodile'"
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TruthLens AI Summary
A recent study has shed light on the evolutionary history of Deinosuchus, an enormous extinct reptile that lived approximately 82 to 75 million years ago and was known for its predatory behavior towards dinosaurs. With a body length comparable to that of a bus and teeth resembling bananas, Deinosuchus thrived in the rivers and estuaries of North America. The reptile, often referred to as the 'terror crocodile,' was initially classified alongside modern alligators due to its broad snout and perceived evolutionary relationships. However, new fossil analyses and genetic data have indicated that Deinosuchus actually belongs to a different branch of the crocodilian family tree. This new classification reveals that Deinosuchus retained salt glands that allowed it to tolerate saltwater environments, a trait that modern alligators lack. This adaptation was crucial for its survival and dominance in diverse habitats, particularly as sea levels rose during a period of climate change, enabling it to navigate the Western Interior Seaway that divided North America at the time.
The findings from this study, published in the journal Communications Biology, highlight the ecological flexibility of Deinosuchus, which adapted to various environments and thrived in marshy ecosystems filled with large prey. Senior study author Dr. Márton Rabi noted that Deinosuchus was a formidable predator, capable of growing to lengths exceeding 26 feet. The research also contradicts previous hypotheses that suggested early alligators were saltwater tolerant before losing that trait. Instead, the study indicates that saltwater tolerance was an ancient characteristic among many crocodilian ancestors. The construction of a new crocodilian family tree, utilizing both molecular data and morphological analysis, has clarified the evolutionary pathway of Deinosuchus, distinguishing it from its alligatoroid relatives. This research not only enhances our understanding of the evolutionary history of crocodilians but also underscores the significance of ecological adaptability in the face of environmental changes throughout history.
TruthLens AI Analysis
The discovery of Deinosuchus, a colossal reptile that preyed on dinosaurs, sheds light on the evolutionary adaptations of ancient crocodilians, particularly their ability to thrive in saline environments. This revelation could captivate public interest, especially among those fascinated by paleontology and evolutionary biology. The article seems to aim at enhancing understanding of how ancient creatures adapted to changing climates, which resonates with current discussions on climate resilience in modern species.
Scientific Interest and Public Engagement
By detailing the unique characteristics of Deinosuchus and its significance in the ancient ecosystem, the article engages readers who are curious about prehistoric life and evolution. The use of vivid comparisons, such as describing teeth the size of bananas, adds a dramatic flair that can capture the imagination of the audience. The article appears to aim at raising awareness about biodiversity and the adaptations necessary for survival, reflecting broader themes of resilience in the face of environmental changes.
Potential Omissions
While the article provides significant information about Deinosuchus, it does not delve into the implications of its extinction or how the adaptations observed could relate to modern crocodilians. This could lead readers to overlook the broader context of extinction events and the lessons they may hold for today’s species facing climate change.
Reliability and Manipulation
The report presents credible scientific findings from fossil analysis and genetic studies, which lends it a high degree of reliability. However, the excitement surrounding discoveries in paleontology can sometimes lead to hyperbolic representations, which may induce a sense of urgency or fear regarding current environmental issues. The potential for manipulation lies in emphasizing the terror aspect of Deinosuchus without adequately contextualizing its ecological role, possibly skewing public perception.
Connections to Broader Themes
In relation to other news, this article can be connected to ongoing discussions about climate change, biodiversity, and the resilience of species. It enhances the narrative around how life on Earth has adapted to shifting environments, a topic that is increasingly relevant given current global ecological challenges.
Community Response and Impact
The article likely resonates with communities interested in science, education, and environmental stewardship. It appeals to those who advocate for conservation and the understanding of historical ecosystems as a means to inform current practices. This discovery may inspire educational initiatives or support for conservation efforts, emphasizing the need to learn from the past.
Market and Economic Considerations
While the article may not directly influence stock markets or economic indicators, it could indirectly support businesses focused on education, tourism related to paleontology, or environmental conservation initiatives. Companies involved in scientific research or educational outreach may find opportunities in increased public interest sparked by such discoveries.
Geopolitical Relevance
In a broader context, the themes of adaptation and resilience can mirror discussions around global strategies for dealing with climate change and environmental policy. The historical perspective provided by the article may influence how contemporary issues are framed, encouraging a more proactive approach to environmental stewardship.
Artificial Intelligence Influence
It is possible that AI tools were utilized in drafting this article, particularly in organizing data or presenting findings in an accessible manner. The structure and clarity of the information suggest that AI might have played a role in enhancing readability and engagement. However, there is no explicit indication of manipulation through biased language or targeting particular groups, maintaining a focus on scientific discovery.
This analysis underscores the article's reliability based on its scientific foundation while recognizing the potential for narrative framing to influence public perception. The excitement generated by discoveries like Deinosuchus can promote interest in science and conservation, indicating a positive outcome for societal awareness.