Shaking the dinosaur family tree: How did ‘bird-hipped’ dinosaurs evolve?


Share post:

Researchers have conducted a new analysis of the origins of “bird-hipped” dinosaurs—the group which includes iconic species such as Triceratops—and found that they likely evolved from a group of animals known as silesaurs, which were first identified two decades ago.

The researchers, from the University of Cambridge and the Universidade Federal de Santa Maria in Brazil, were attempting to solve a long-standing mystery in paleontology: where the “bird-hipped” dinosaurs, or ornithischians, came from.

Currently, there is a gap of more than 25 million years in the fossil record, making it difficult to find the branch of the dinosaur family tree where ornithischians belong.

The researchers conducted an extensive analysis of early dinosaurs as well as silesaurs, a group named after Silesaurus, first described in 2003. The researchers suggest that silesaurs progressively modified their anatomy during the Late Triassic Period, so that they came to resemble ornithischians by the Early Jurassic Period.

Two Herrerasaurus chasing a Silesaurus down a stream in the Triassic period. Two Plateosaurus are in the background [Credit: Mohamad Haghani/Stocktrek Images]

However, these ornithischian ancestors have the hip structure of the “lizard-hipped” dinosaurs, or saurischians, suggesting that the earliest bird-hipped dinosaurs were in fact lizard-hipped. The results are reported in the Zoological Journal of the Linnean Society.

Dinosaurs originated in the Late Triassic period, about 225 million years ago, and dominated life on Earth until a mass extinction event 66 million years ago. Dinosaurs have fascinated us since they were first named as such by Richard Owen in 1842.

The earliest discovered dinosaur remains were scrappy: odd-looking teeth and a few bones. By the latter half of the 19th century however, enough dinosaur remains had been found that a classification system was needed. Harry Seeley, who had been trained in Cambridge by Adam Sedgwick, developed such a classification of dinosaurs based primarily upon the shape of their hip bones: they were either saurischians (lizard-hipped) or ornithischians (bird-hipped). This classification, first published in 1888, proved reliable: all dinosaur discoveries seemed to slot neatly into one or other of these groupings.

Silesaurus skeleton [Credit: University of Cambridge]

However, in 2017, Professor David Norman from Cambridge’s Department of Earth Sciences and his former Ph.D. students Matthew Baron and Paul Barrett argued that these dinosaur family groupings need to be rearranged, re-defined and re-named. In a study published in Nature, the researchers suggested that bird-hipped dinosaurs and lizard-hipped dinosaurs such as Tyrannosaurus evolved from a common ancestor, potentially overturning more than a century of theory about the evolutionary history of dinosaurs.

Controversy aside, it has long been recognized that the bird-hipped dinosaurs are anatomically distinct from all other types of dinosaurs, even though they have nothing to do with birds. But how they came to be has remained a long-standing problem.

“It seemed to be that they originated with all other dinosaurs in the Late Triassic but exhibited a unique set of features that could not be fitted into an evolutionary succession from their dinosaur cousins,” said Norman, who is a Fellow of Christ’s College. “It was as if they just suddenly appeared out of nowhere.”

Skull of an early Ornithischian [Credit: University of Cambridge]

Recent work has begun to indicate a more varied and puzzling picture of ornithischian origins. From a phylogenetic perspective—how the dinosaur family tree branches over time—it is predicted that ornithischian remains should first appear in the fossil record about 225 million years ago.

“However, the more we’ve looked in rocks of that age, the less we’ve found,” said Norman. “The first unarguable ornithischian remains date from less than 200 million years ago, meaning there is a 25+ million-year ornithischian gap. So far, all attempts to fill that gap have failed.”

One solution to this conundrum can be traced back to a discovery in the early years of this century, when the skeleton of an unusual Late Triassic dinosaur-like animal was discovered in Poland. It was described by Jerzy Dzik and named Silesaurus (the “Silesian lizard”).

Credit: University of Cambridge

Silesaurus has long slender legs that gave it an upright dinosaur-like posture—and its hip bones are arranged like a saurischian—but it seemed to have a toothless, beak-like region at the front of its lower jaw. This was not unlike the toothless beak-like structure known as a predentary that is found in all ornithischian dinosaur skulls, although the uniquely ornithischian predentary bone was not present.

Its teeth were also constricted at the top of the roots, and the crowns of the teeth were leaf-shaped in profile: a type of tooth shape seen in many early ornithischians. Dzik speculated about the possible ornithischian similarities of Silesaurus, but the suggestion was dismissed or ignored by most researchers.

In the years that followed, more Silesaurus-like creatures were discovered, mostly in South America. Many of these specimens were fragments, but the toothless tip of the lower jaw and the leaf-shaped teeth were common.

Ornithischia family-tree [Credit: University of Cambridge]

The accumulation of these specimens attracted the attention of several researchers. Their analyses suggested that silesaurs were close relatives of true dinosaurs. Either they were placed on a branch just before the origin of true dinosaurs or, in some instances, they appeared as a sister group to Ornithischia. In 2020, Mauricio Garcia and Rodrigo Müller from the Universidade Federal de Santa Maria in Brazil proposed that silesaur-like creatures could sit on the branch of Dinosauria that led to Ornithischia.

“This work attracted our attention in Cambridge,” said Norman. “A few years ago, I devised a research project aimed directly at the problem of how the Ornithischia came to be, and Matt was the research student on the project.”

Norman and Barron began to collaborate with Rodrigo and Mauricio, enlarging the original analysis to include a range of ornithischian dinosaurs, as well as dinosaur ancestors. The outcome of their collaboration is a family tree that depicts silesaurs as a succession of animals on the stem of the branch leading to Ornithischia.

Anatomy transformation [Credit: University of Cambridge]

“Silesaurians progressively modified their anatomy during the Late Triassic, so that they come to resemble ornithischians,” said Norman. “We have been able to trace this transition through the development of the toothless beak, the development of leaf-shaped coarse-edged teeth typical of those seen in the herbivorous ornithischians, modifications to the shoulder bones, changes in the proportions of the pelvic bones, and finally a restructuring of the muscle attachment areas on the hind legs.”

The research suggests that ornithischians did not arise from nowhere. Rather, they first appeared in the Late Triassic in the guise of silesaurs that gradually rearranged their anatomy with the passage of time until recognizable ornithischians had evolved by the beginning of the Jurassic Period.

However, there is another aspect to this explanation, which is that the earliest ornithischians of the Late Triassic had none of the anatomical characteristics of true ornithischians: they lacked a predentary and, most importantly, retained the early saurischian hip construction.

“So, the very earliest ornithischians were, technically, saurischian,” said Norman. “From a taxonomic perspective, classifying silesaurs as early ornithischians seems counterintuitive. But, taking a Darwinian perspective, the unique anatomical characteristics of ornithischians had to evolve from somewhere, and where better than from their nearest relatives: their saurischian cousins.”

Author: Sarah Collins | Source: University of Cambridge [September 21, 2022]



Related articles

History of Antarctic ice sheets holds clues for our future

A new study from researchers at The Australian National University (ANU) on how the world's largest ice sheet...

Ancient outcrops give new depth limit for deep-sea burrows

Scientists have found fossil evidence of deep-sea marine life burrowing up to eight metres below the seabed --...

Whales in the desert?

In Cerro Colorado, located in the Ica Desert of Peru, sedimentary sequences dating back nine million years have...

How the chicxulub impactor gave rise to modern rainforests

Tropical rainforests today are biodiversity hotspots and play an important role in the world's climate systems. A new...

Bird beak revealed by laser imaging informs early beak function and development

Confuciusornis was a crow-like fossil bird that lived in the Cretaceous ~120 million years ago. It was one...

Oldest frog relative found in North America

A team of paleontologists led by Virginia Tech's Michelle Stocker and Sterling Nesbitt of the Department of Geosciences...

Fossil teeth from Kenya solve ancient monkey mystery

The teeth of a new fossil monkey, unearthed in the badlands of northwest Kenya, help fill a 6-million-year...

Research reveals unexpected insights into early dinosaur’s brain, eating habits and agility

A pioneering reconstruction of the brain belonging to one of the earliest dinosaurs to roam the Earth has...