Modern birds have evolved from some of the smaller dinosaurs and it is held to be logical that in the food-deficient aftermath of the asteroid hit, smaller life-forms were able to survive as opposed to their much larger ‘dino’ counterparts. But a study now contends that asteroid-hit did not have an effect on the evolution of birds as they had started diversifying even before the catastrophic event
An asteroid hit Earth 65 million years ago and in one stroke, started a process that resulted in the elimination of 75 per cent of life on Earth over the next decade and ended the reign of dinosaurs. It is almost unanimously held that the catastrophic event paved the way for mammals and other forms of life to thrive and for humans to ultimately develop. But did the asteroid help birds?
Modern birds have evolved from some of the smaller dinosaurs and it is held to be logical that in the food-deficient aftermath of the asteroid hit, smaller life-forms were able to survive as opposed to their much larger ‘dino’ counterparts. This eventually resulted in the evolution of the ‘normal-sized’ birds we see today.
But a study now contends that the asteroid hit did not have an effect on the evolution of birds as they had started diversifying even before the catastrophic event.
To arrive at their conclusion, the scientists studied 124 bird species.
“We found that this catastrophe didn’t have an impact on modern birds,” said Dr Shaoyuan Wu, an evolutionary biologist at Jiangsu Normal University, China
As reported by The New York Times, the international team of researchers found during the study that birds that are alive today had a common ancestor 130 million years ago. The ancestor evolved into different birds over millennia. However, the researchers say that the ‘family tree’ of this evolution was splitting steadily, both before and after the asteroid hit.
In other words, the asteroid hit in itself did not have an influence on the evolution of birds, contend the researchers.
The scientific community in general continues to study the asteroid impact that came close to eliminating life on Earth by causing huge tsunamis, massive forest fires and triggering a decade-long winter.
In honor of the Year of the Dragon, we take a look at some potential inspirations for the dragon myth.
Around the world, people are celebrating the Chinese New Year and the start to the Year of the Dragon. This got us wondering: Where did the myth of the dragon come from in the first place? Scholars say that belief in dragons probably evolved independently in both Europe and China, and perhaps in the Americas and Australia as well. How could this happen? Many have speculated about which real-life animals inspired the first legends. Here’s our run-down of the likeliest suspects.
Dinosaurs. Ancient people may have discovered dinosaur fossils and understandably misinterpreted them as the remains of dragons. Chang Qu, a Chinese historian from the 4th century B.C., mislabeled such a fossil in what is now Sichuan Province. Take a look at a fossilized stegosaurus, for example, and you might see why: The giant beasts averaged 30 feet in length, were typically 14 feet tall and were covered in armored plates and spikes for defense.
The Nile Crocodile. Native to sub-Saharan Africa, Nile crocodiles may have had a more extensive range in ancient times, perhaps inspiring European dragon legends by swimming across the Mediterranean to Italy or Greece. They are among the largest of all crocodile species, with mature individuals reaching up to 18 feet in length—and unlike most others, they are capable of a movement called the “high walk,” in which the trunk is elevated off the ground. A giant, lumbering croc? Might be easy to mistake for a dragon.
The Goanna. Australia is home to a number of species of monitor lizards, also referred to as Goannas. The large, predatory animals have razor-sharp teeth and claws, and they are important figures in traditional Aboriginal folklore. Recent studies even indicate that Goannas may produce venom that causes bite victims’ wounds to develop infections after an attack. At least in Australia, these creatures may be responsible for the dragon myth.
Whales. Others argue that the discovery of megafauna such as whales prompted stories of dragons. Ancient humans encountering whale bones would have no way of knowing that the animals were sea-based, and the idea of such gargantuan creatures might well have led people to assume that whales were predatory. Because live whales spend up to 90 percent of their time underwater, they were poorly understood for most of human history.
The Human Brain. The most fascinating explanation involves an unexpected animal: the human. In his book An Instinct for Dragons, anthropologist David E. Jones argues that belief in dragons is so widespread among ancient cultures because evolution embedded an innate fear of predators in the human mind. Just as monkeys have been shown to exhibit a fear of snakes and large cats, Jones hypothesizes that the trait of fearing large predators—such as pythons, birds of prey and elephants—has been selected for in hominids. In more recent times, he argues, these universal fears have been frequently combined in folklore and created the myth of the dragon.
New findings, including the discovery of Eoneophron infernalis, suggest that dinosaurs, particularly caenagnathids, were not declining in diversity before the asteroid impact, contradicting earlier theories of their vulnerability.
Were dinosaurs already on their way out when an asteroid hit Earth 66 million years ago, ending the Cretaceous, the geologic period that started about 145 million years ago? It’s a question that has vexed paleontologistslike us for more than 40 years.
In the late 1970s, debate began about whether dinosaurs were at their peak or in decline before their big extinction. Scientists at that time noted that while dinosaur diversity seemed to have increased in the geologic stage that spanned 83.6 million to 71.2 million years ago, the number of species on the scene seemed to decrease during the last few million years of the Cretaceous. Some researchers have interpreted this pattern to mean that the asteroid that struck the Gulf of Mexico was simply the final blowfor an already vulnerable group of animals.
However, others have argued that what looks like a decrease in the diversity of dinosaurs may be an artifact of how hard it is to accurately count them. Fossil formations might preserve different dinosaurs more or less often based on factors like their favored environment and how easily their bodies fossilized there. The accessibility of various outcrops could influence what kinds of fossils researchers have so far found. These biases are a problem because fossils are what paleontologists must rely on to conclusively answer how healthy dinosaur populations were when the asteroid hit.
At that crucial moment, what was really happening to dinosaur diversity? Discovery, identification and description of new dinosaurs provide vital clues. This is where our work comes in. Close examination of what we’d thought was a juvenile specimen of an already-known species of dinosaur from this time period revealed that it was actually part of an adult from a completely new species.
Our work focusing on the life stage of our specimen demonstrates that dinosaur diversity may not have been declining before the asteroid hit, but rather that there are more species from this time period yet to be discovered – potentially even through reclassification of fossils already in museum collections.
Clues Inside the Bones of a Birdlike Dinosaur
Our new study focused on four hindlimb bones – a femur, a tibia, and two metatarsals. They were unearthed in South Dakota, in rocks of the Hell Creek Formation, and date to the final 2 million years of the Cretaceous.
The only known species of caenagnathid from this time and region was Anzu, sometimes called the “chicken from Hell.” Covered in feathers and sporting wings and a toothless beak, Anzu was between roughly 450 and 750 pounds (200 and 340 kilograms). Despite its fearsome nickname, though, its diet is a matter of debate. It was likely an omnivore, eating both plant material and small animals.
Because our specimen was significantly smaller than Anzu, we simply assumed it was a juvenile. We chalked up the anatomical differences we noticed to its juvenile status and smaller size – and figured the animal would have changed had it continued to grow. Anzu specimens are rare, and no definite juveniles have been published in the scientific literature, so we were excited to potentially learn more about how it grew and changed throughout its lifetime by looking inside its bones.
Just like with a tree’s rings, bone records rings called lines of arrested growth. Each annual line represents part of a year when the animal’s growth slowed. They would tell us how old this animal was, and how fast or slow it was growing.
We cut through the middle of three of the bones so that we could microscopically examine the internal anatomy of the cross-sections. What we saw completely uprooted our initial assumptions.
Teal markers point to lines of arrested growth on the cross-section of fossilized bone. Toward the outside of the bone, the lines are much closer together, reflecting less growth per year. Researchers counted exactly six lines, meaning this animal was between 6 and 7 years old when it died. Credit: Holly Woodward
In a juvenile, we would expect lines of arrested growth in the bone to be widely spaced, indicating rapid growth, with even spacing between the lines from the inside to the outside surface of the bone. Here, we saw that the later lines were spaced progressively closer together, indicating that this animal’s growth had slowed and it was nearly at its adult size.
This was no juvenile. Instead, it was an adult of an entirely new species, which we dubbed Eoneophron infernalis. The name means “Pharaoh’s dawn chicken from Hell,” referencing the nickname of its larger cousin Anzu. Traits unique to this species include ankle bones fused to the tibia, and a well-developed ridge on one of its foot bones. These weren’t features a young Anzu would outgrow, but rather unique aspects of the smaller Eoneophron.
Expanding the Caenagnathid Family Tree
With this new evidence, we started making thorough comparisons with other members of the family to determine where Eoneophron infernalis fit within the group.
It also inspired us to reexamine other bones previously believed to be Anzu, as we now knew that more caenagnathid dinosaurs lived in western North America during that time. One specimen, a partial foot bone smaller than our new specimen, appeared distinct from both Anzu and Eoneophron. Where once there was one “chicken from Hell,” now there were two, and evidence for a third: one large (Anzu), weighing as much as a grizzly bear, one medium (Eoneophron), humanlike in weight, and one small and yet unnamed, close in size to a German shepherd.
Comparing Hell Creek with older fossil formations such as the famous Dinosaur Park Formation of Alberta that preserves dinosaurs that lived between 76.5 million and 74.4 million years ago, we find not only the same number of caenagnathid species, but also the same size classes. There, we have Caenagnathus, comparable to Anzu, Chirostenotes, comparable to Eoneophron, and Citipes, comparable to the third species we found evidence for. These parallels in both species count and relative sizes offer compelling evidence that caenagnathids remained stable throughout the last part of the Cretaceous.
Our new discovery suggests that this dinosaur group was not declining in diversity at the very end of the Cretaceous. These fossils show that there are still new species to be discovered, and support the idea that at least part of the pattern of decreasing diversity is the result of sampling and preservation biases.
Did large dinosaurs go extinct the way a Hemingway character quipped he went broke: “gradually, then suddenly”? While there are plenty of questions still outstanding in this extinction debate, Eoneophron adds evidence that caenagnathids were doing quite well for themselves before the asteroid ruined everything.
The dirty little secret in the world of dinosaurs is that paleontologists have no means of telling what sex adinosaur was. Mary Schweitzer with North Carolina State University and the North Carolina Museum of Natural Sciences is the first to develop a method that tells what sex a Tyrannosaurus rex was. The discovery wasreported in the March 15, 2016, edition of the journal Scientific Reports.
The discovery was assisted by the fact that the dinosaur in question, called MOR1125, was pregnant when it died. The specimen had one of the few known fetal dinosaurs with it when it was first found in 2005. The researchers found a second means of determining sex by examining the bone growth and chemistry of this dinosaur.
The study found that female dinosaurs like their bird descendants develop a medullary bone. The structure is not permanent in birds or dinosaurs. The temporary bone serves to supply shell for the animal’s eggs. This is the first known discovery of a medullary bone in a dinosaur.
Microscopic examination of the medullary bone from the pregnant T. rex showed a bone structure that is very similar to the medullary bone of modern birds. The scientist also compared the amount of keratan sulfate in the dinosaur bone and the bones in a chicken and an ostrich. The chemical analysis of the dinosaur bone had similar amounts of keratan sulfate as modern birds. The chemical test provides a means of determining the sex of a dinosaur chemically without the presence of a medullary bone provided some bone marrow is still present in the fossil.
The tiny, intact skeleton of a baby rhinoceroslike dinosaur has been unearthed in Canada.
The toddler was just 3 years old and 5 feet (1.5 meters) long when it wandered into a river near Alberta, Canada, and drowned about 70 million years ago. The beast was so well-preserved that some of its skin left impressions in the nearby rock.
The fossil is the smallest intact skeleton ever found from a group of horned, plant-eating dinosaurs known as ceratopsids, a group that includes the iconic Triceratops.
“The big ones just preserve better: They don’t get eaten, they don’t get destroyed by animals,” said study co-author Philip Currie, a paleobiologist at the University of Alberta. “You always hope you’re going to find something small and that it will turn out to be a dinosaur.”
Paleontologists had unearthed a few individual bones from smaller ceratopsids in the past. But without intact juvenile skeletons, such bones aren’t very useful, as scientists don’t really know how each bone changes during each stage of the animals’ lives, Currie said.
The team was bone-hunting in Dinosaur Provincial Park in Alberta when Currie came upon what looked like a turtle shell sticking out from a hillside. Upon closer inspection, the fossil turned out to be a frill, the bony decorative headgear that surrounds the back of the head in ceratopsids.
When the team excavated, they found the fossilized skeleton of a tiny dinosaur they identified as a Chasmosaurus belli, a species commonly found in the area.
Drowning victim
Amazingly, almost the entire skeleton was intact, although sometime in the past, a sinkhole had opened up below the beast and the forelimbs had fallen away into an abyss. The fossil was so well-preserved that the tiny, rosettelike pattern on its skin was imprinted in the rock below the dinosaur.
Based on its size, the team estimates the dinosaur was about 3 years old — just out of infancy — when it perished. (Like humans, these dinosaurs typically take about 20 years to reach maturity, at which point they have 6.5-foot-long [2 meters] skulls and weigh 3 to 4 tons.)
The fossil was found in sediments associated with watery environments and didn’t have any bite marks or trace of injury, so it’s likely the dino toddler likely drowned.
“I think it may have just gotten trapped out of its league in terms of water current,” Currie told LiveScience.
Soon after, the baby dinosaur was buried by sediments and left untouched for millions of years.
Growth rates
Aside from being cute, the new fossil helps paleontologists understand how these plant-eating dinosaurs grew. Paleontologists can then better identify and age the myriad individual bones from juveniles discovered over the years.
Already, the team has learned that Chasmosaur juvenile frills look different from those on adults, and that limb proportions don’t change much as they grow. Predatory theropods such as Tyrannosaurus rex have disproportionately long limbs as juveniles, presumably to keep up with the adults in the pack.
By contrast, “in Chasmosaurians, the proportions are essentially the same, which probably means the adults were probably never moving that fast,” Currie said. “There was never priority for these animals to run to keep up with the adults.”
Writing in Plos One journal, the team used fossils and DNA analysis to show that one bee group suffered a serious decline at the time of this collision.
The researchers chose to study bees within the subfamily known as Xylocopinae – which included the carpenter bees.
This was because the evolutionary history of this group could be traced back to the Cretaceous Period, when the dinosaurs still walked the Earth.
Previous studies had suggested a widespread extinction among flowering plants during the Cretaceous-Paleogene (K-Pg) extinction event 66 million years ago.
And it had long been assumed that the bees that depended upon these plants would have met the same fate.
Yet, unlike the dinosaurs, “there is a relatively poor fossil record of bees,” said the paper’s lead author Sandra Rehan, a biologist at the University of New Hampshire in Durham, US. This has made the confirmation of such an extinction difficult.
The impact that wiped out the dinosaurs created opportunities for other animals
However, the researchers were able to use an extinct group of Xylocopinae as a calibration point for timing the dispersal of these bees.
They were also able to study flower fossils that had evolved traits that allowed them to be pollinated by bee relatives of the Xylocopinae.
“The data told us something major was happening in four different groups of bees at the same time,” said Dr Rehan.
“And it happened to be the same time as the dinosaurs went extinct.”
The findings of this study could have implications for today’s concern about the loss in diversity of bees, a pivotal species for agriculture and biodiversity.
“Understanding extinctions and the effects of declines in the past can help us understand the pollinator decline and the global crisis in pollinators today,” Dr Rehan explained.
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