Manchester University, the Morrison Formation and the “Jurassic Mile”

Scientists at Manchester University have joined forces with a major American Museum and European partners to map and explore an extraordinary Jurassic dinosaur site in the Badlands of Wyoming (USA).  The University of Manchester will act as the academic leaders on this newly announced £20 million ($27.5 USD) research project to examine and eventually exhibit fossils excavated from a recently discovered palaeontological site nicknamed the “Jurassic Mile”. The “Jurassic Mile” represents deposits from the famous Upper Jurassic Morrison Formation.

Exploring the Morrison Formation in Collaboration with the Children’s Museum of Indianapolis

The University of Manchester’s Professor Phil Manning and Dr Victoria Egerton will be collaborating with scientists from the Children’s Museum of Indianapolis.  Also involved are researchers from the Natural History Museum in London and the Naturalis Biodiversity Centre in Leiden (Netherlands).  In total, more than a hundred scientists and academics from three countries will join forces to work at a dig site representing Upper Jurassic strata from the Morrison Formation of Wyoming.  They hope to uncover new data to help explain the extraordinary diversity of the dinosaur biota known from this part of Laurasia in the Late Jurassic.

Life in the Late Jurassic – An Illustration of Morrison Formation Biota

Picture credit: Julius Csotonyi

The “Jurassic Mile”

Professor Manning, Dr Egerton and the team are calling the fossil-rich, mile-square plot of land, the “Jurassic Mile.”  There are four main quarries within the multi-level, 640-acre site that offer a diverse assemblage of Morrison Formation articulated and semi-articulated dinosaurs that has also yielded associated animals and fossil plants.  In addition, trace fossils in the form of dinosaur trackways have been identified, such tracks are rare in this part of the world.

Commenting on the significance of this collaborative field work, Professor Manning stated:

“It is splendid that such an important site has been discovered at just the right time, as the science of palaeontology is adapting existing and new imaging techniques to unpick the fossil remains of extinct life.  The imaging work that we undertake at Manchester is already world-leading and this is a great opportunity to develop this research with other world-class institutions.”

A Remarkable Fossil Assemblage

Nearly six hundred specimens, weighing more than six tons, have already been collected from this site over the past two years, despite the fact that only a fraction of the area has been explored.  Fossil bones found to date include the remains of an 20-metre plus brachiosaur and a 27-metre-long diplodocid.  Giant sauropods had giant bones, one of the recent discoveries is a 2-metre-long brachiosaur scapula (shoulder bone), numerous plaster-coated burlap jackets containing articulated bones are the reward for the researchers after a successful field season.

At a press conference, held today, the discovery of an extremely well-preserved 1.5-metre-long sauropod femur (thigh bone), was announced.

Professor Phil Manning (The University of Manchester) with the Sauropod Femur

Picture credit: The University of Manchester

Dr Jeffrey H. Patchen, President and CEO of The Children’s Museum of Indianapolis commented:

“We are bringing together an extraordinary international team for the first time that will critically analyse portions of the Morrison Formation in new ways.  This project reflects a natural synergy between three world-renowned museums, their research scientists and highly-respected research universities, each providing unique elements to complete one of the most interesting chapters in the evolution of Earth.”

Prehistoric Flora and Fauna

Dr Egerton from the Department of Earth and Environmental Science (Manchester University), explained:

“The preservation quality and sheer amount of plants at the Jurassic Mile is extraordinary.  During this period, there were no flowering plants and this site provides significant insight to what these giant animals ate and how they may have grown to be so large.”

The Jurassic Mile project is already utilising cutting-edge science from the international team.  The University of Manchester scientists will employ the Stanford Synchrotron particle accelerator along with some of the most powerful computers on the planet, to help resurrect the Jurassic and unearth the lost world and forgotten lives of some of the most remarkable terrestrial animals that have ever lived.

Everything Dinosaur acknowledges the assistance of a press release from Manchester University in the compilation of this article.

For models and replicas of prehistoric animals from the Morrison Formation: Dinosaur and Prehistoric Animal Models.

Visit the Everything Dinosaur website: Everything Dinosaur.

Dinosaurs Innovated When it Came to Egg Production

Many museums include the fossilised remains of dinosaur eggs amongst their natural history collections and palaeontologists are aware that reptiles were laying eggs on land long before the dinosaurs evolved, but what we know about the evolution of reptile eggs (amniotic eggs in general), is largely based on inference and conjecture.  The problem is, for the first 100 million years or so of amniote evolution, there is very little fossil data related to reptile reproduction to study.  What we do know, is based on Middle Jurassic to Late Cretaceous fossils.

Although, dinosaur eggs are rare, the examples we do have, such as those associated with Asian oviraptorids demonstrate that dinosaur eggs had thick, hardened shells.  However, a new study suggests that it was not always like this and that the three main Sub-orders of the Dinosauria probably evolved thick, tough eggs independently.

Examples of Eggs from Different Archosaurs (Avian and Non-avian Dinosaurs)

Picture credit: Royal Society Open Science

Studying Some of the World’s Oldest Dinosaur Eggs Reveals New Information

Writing in the on-line, open access journal “Scientific Reports”, a team of scientists, including Robert Reisz (University of Toronto Mississauga) and Koen Stein (Royal Belgian Institute of Natural Sciences, Brussels), have examined some of the oldest examples of dinosaur eggs known and revealed new information about the evolution of dinosaur reproduction.

The researchers examined the eggs and eggshells of three coeval, but geographically widely distributed Early Jurassic basal sauropodomorph dinosaurs (Sinemurian faunal stage).  These fossils came from Argentina, China and South Africa and include the eggs of Massospondylus and Lufengosaurus.  Their analysis showed that the basal sauropodomorph eggs all had the basic structure, they had a thin calcareous layer less than 100 microns thick.  This thin shell layer contrasts strongly with the much thicker calcareous shells associated with Late Jurassic and later dinosaur eggs.

At approximately 195 million years old, they are the earliest known eggs in the fossil record, and they were all laid by similar, herbivorous dinosaurs that ranged in size from four to eight metres in length and were the most common and widely spread dinosaurs of their time.  These types of plant-eating dinosaur were the forerunners of the giant sauropods of the Jurassic, dinosaurs such as Brontosaurus, Diplodocus and Brachiosaurus.

A Massospondylus Nesting Site (Life Reconstruction)

Picture credit: Julius Csotonyi

Putting the Dinosaur Egg Research into Context

Putting the research into context Professor Reisz explained:

“Reptile and mammal precursors appear as skeletons in the fossil record starting 316 million years ago, yet we know nothing of their eggs and eggshells until 120 million years later.  It’s a great mystery that eggs suddenly show up at this point, but not earlier.”

The researchers concluded that these Early Jurassic eggs represented a step in the evolution of dinosaur reproduction, their shells were paper-thin and brittle, proportionately much thinner than the eggs of extant birds.  However, thicker, tougher eggshells in the Dinosauria were to evolve across all three Sub-orders later.  The much thicker eggshells associated with sauropods, ornithischian dinosaurs and the Theropoda must have evolved independently.

Professor Reisz added:

“We know that these early eggs had hard shells because during fossilisation they cracked and broke, but the shell pieces retained their original curvature.”

Other authors of the scientific paper include Edina Prondvai and Jean-Marc Baele.  Shell thickness was analysed along with membrane thickness, mineral content and distribution of pores, looking for clues about why these early eggs might have developed hard shells.  The scientists concluded that hard-shelled eggs evolved early in dinosaur evolution, with thickening of the calcareous layer (greater than 150 microns), occurring independently in several groups, but a few million years later other reptiles also developed hard-shelled eggs.  One possibility is that hard and eventually thicker shells may have evolved to shield dinosaur embryos and other reptiles from predators.

Professor Reisz commented:

“The hard shells would protect the embryos from invertebrates that could burrow into the buried egg nests and destroy them.”

Linked to Increased Oxygen in the Atmosphere

Advanced mineralisation of amniote eggshell including those of dinosaurs (≥150 microns in thickness), in general occurred not earlier than the Middle Jurassic and may correspond with a global trend of an increase in atmospheric oxygen.  If there were higher levels of atmospheric oxygen, then this would facilitate more efficient gaseous exchange through the porous eggshell and across the egg membranes.  More efficient diffusion would permit the evolution of thicker eggshells, which in turn would offer greater resistance to damage and more protection from predators.

A Lufengosaurus Embryo

Picture credit: D. Mazierski

Raising Further Questions About Mesozoic Reproduction Strategies

The study raises some intriguing questions that may well lead to further research projects.  For example, palaeontologists are aware that many types of marine reptile evolved viviparity (live birth), whilst the fossil evidence for the terrestrial Dinosauria seems to indicate that they continued to rely on egg laying.  Why didn’t the highly diverse dinosaurs evolve different reproductive strategies over their 160 million years of existence?

Everything Dinosaur acknowledges the assistance of a press release from the University of Toronto in the compilation of this article.

The scientific paper: “Structure and Evolutionary Implications of the Earliest (Sinemurian, Early Jurassic) Dinosaur Eggs and Eggshells” by Koen Stein, Edina Prondvai, Timothy Huang, Jean-Marc Baele, P. Martin Sander and Robert Reisz published in Scientific Reports.

Visit the award-winning Everything Dinosaur website: Everything Dinosaur.

Galleonosaurus dorisae – A New Aussie Dinosaur

A new type of Australian dinosaur has been described from the fossilised remains of five upper jaw bones (maxillae) found at the Flat Rocks locality in the Wonthaggi Formation in the famous Gippsland Basin of Victoria.  Five small-bodied ornithopods are now known from the state of Victoria.  The new plant-eating dinosaur has been named Galleonosaurus dorisae.  The jaw bones are of different sizes and this has permitted palaeontologists to plot growth changes in these little dinosaurs as they matured.

Writing in the Journal of Palaeontology, the researchers which include Matthew Herne (University of New England, New South Wales) and Alistair Evans (Monash University, Melbourne), used detailed CT-scans of the fossil material to gain fresh insights into the structure and morphology of the cranial anatomy and dentition of small Australian ornithopods.  The research leading to the establishment of this new genus has also helped to define more clearly other small ornithopods known from the Gippsland Basin and the Otway Basin located on the opposite side of Port Phillip Bay.

A Life Reconstruction of the Newly Described Ornithopod Galleonosaurus dorisae

Picture credit: James Kuether

Galleonosaurus dorisae – “Galleon Lizard”

When the scientists were examining the maxillae, their shape reminded them of the upturned hull of an old-fashioned sailing ship – a galleon.  It was the morphology of the jaw that inspired the genus name “Galleon Lizard”.  The species or trivial name honours Doris Seegets-Villiers for her geological, palynological, and taphonomic work on the Flat Rocks fossil vertebrate locality.

Jaw Fossils and a Tooth with a CT-scan of the Fossil Material

Picture credit: Herne et al

Niche Partitioning in Ornithopods

The plethora of vertebrate fossils at the Flat Rocks site, suggests that several more dinosaurs await discovery.  However, for the moment, the researchers are confident that Galleonosaurus shared its habitat with at least one other small, light, fast-running ornithopod – Qantassaurus intrepidus.  The jaws of Qantassaurus are more robust and more powerful.  The researchers were able to confirm that Q. intrepidus is uniquely characterised by a deep, foreshortened dentary (lower jaw).  This suggests that the robust Q. intrepidus and the more gracile jawed G. dorisae fed on different vegetation, they did not compete directly for food, an example of niche partitioning.

Dr Herne described Galleonosaurus:

“We know it would have been a two-legged, quite agile plant-eating dinosaur.  It seems that Galleonosaurus was no doubt closely related to possibly as many as four or five other species that look a little bit similar and were similar sizes, but we can tell they’re different by the anatomy of the jaws and the teeth.”

A Lush Conifer Dominated Rift Valley with an Immense Volcanic Mountain Chain to the East

Extensive research on the Otway Formation material to the west of Port Phillip Bay in conjunction with research on the geology of the Gippsland Basin have permitted scientists to build up a picture of what life was like in this part of Australia during the Early Cretaceous.  The dinosaurs lived in an extensive rift valley that had formed as Australia began to separate from Antarctica.

Conifer forests dominated and at such high latitudes, the lush environment would have been subjected to long periods of extensive daylight in the summer, but conversely the winters would have been cold with little daylight each day.  Although the Earth’s climate was much warmer than today during the Early Cretaceous, it is quite possible that these little dinosaurs would have had to endure winter temperatures close to freezing.

Gondwana in the Early Cretaceous (Barremian Faunal Stage)

Picture credit: Herne et al

A Skeletal Reconstruction of the Skull of Galleonosaurus and the Anatomical Position of Jaw Material

Picture credit: Herne et al

A Phylogenetic Analysis of Galleonosaurus dorisae

The scientists conclude that a highly diverse, small-bodied ornithopod fauna flourished in the periodically disturbed, high-latitude, riverine floodplain environment of the Australian-Antarctic rift valley during the Early Cretaceous (Barremian to Early Albian faunal stage).  A phylogenetic analysis places Galleonosaurus as the earliest member of the Elasmaria, a clade of Gondwanan ornithopods distantly related to the Hypsilophodonts.

The Five Victorian Ornithopods – Spanning 12 million years

The Lower Cretaceous rocks either side of Port Phillip Bay were laid down at different times during the Cretaceous.  The Gippsland Basin deposits close to the town of Inverloch, were laid down around 125 million years ago, however, the Otway Basin deposits (Eumeralla Formation), represent younger material laid down in the Early Albian (113 million years ago).

1. Leaellynasaura amicagraphica – named in 1989 (Early Albian faunal stage), from the Eumeralla Formation (Otway Basin).
2. Atlascopcosaurus loadsi – also named in 1989 from the Eumeralla Formation.
3. Diluvicursor pickeringi – named in 2018 (Eumeralla Formation).  To read an article about the discovery of this dinosaur: Fast-running Ornithopod from Victoria.
4. Qantassaurus intrepidus named in 1999 from the Wonthaggi Formation (Gippsland Basin) – older strata associated with the Barremian faunal stage of the Early Cretaceous.
5. The newly described Galleonosaurus dorisae (2019), also from the Wonthaggi Formation.

Dr Herne stated:

“The interesting thing about that whole coast line is it gives us a decent age range over quite a long period.”

A spokesperson from Everything Dinosaur commented:

“It is likely that many more small dinosaurs are going to be named and described in the future.  Fossil finds from Victoria will, most likely, lead to further revisions of Gondwanan ornithopod taxonomy.”

For models and replicas of ornithopods and other dinosaurs: Dinosaur and Prehistoric Animal Models.