Building giants: the origins of extreme biology in baleen whales. Baleen whales are unlike any other animal. They have evolved unparalleled specialisations for feeding, hearing, smell, cognition and – above all – the largest ever body size. These extreme features underlie the unmatched dominance of baleen whales in today's oceans. The origins of these key adaptations required major changes in the anatomy and function of the skull and teeth. However, exactly how and when the extreme innovations o ....Building giants: the origins of extreme biology in baleen whales. Baleen whales are unlike any other animal. They have evolved unparalleled specialisations for feeding, hearing, smell, cognition and – above all – the largest ever body size. These extreme features underlie the unmatched dominance of baleen whales in today's oceans. The origins of these key adaptations required major changes in the anatomy and function of the skull and teeth. However, exactly how and when the extreme innovations of baleen whales began remains an outstanding question in animal biology. This proposal aims to combine exceptional Australian fossils with recent advances in 3D imaging, biomechanics, and evolutionary analysis to discover how the secrets to the success of baleen whales first evolved.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101052
Funder
Australian Research Council
Funding Amount
$372,959.00
Summary
All you can eat: evolution of feeding in the largest animals on Earth. This project aims to establish how Baleen whales, the largest animals on Earth and major ecosystem engineers, evolved their signature filter-feeding strategy. Unlike other mammals, whales are toothless, and instead use a keratinous, comb-like sieve to filter vast amounts of small prey from seawater. Various approaches, including biomechanics, three-dimensional imaging, geochemistry and quantitative palaeobiology will unravel ....All you can eat: evolution of feeding in the largest animals on Earth. This project aims to establish how Baleen whales, the largest animals on Earth and major ecosystem engineers, evolved their signature filter-feeding strategy. Unlike other mammals, whales are toothless, and instead use a keratinous, comb-like sieve to filter vast amounts of small prey from seawater. Various approaches, including biomechanics, three-dimensional imaging, geochemistry and quantitative palaeobiology will unravel how and when filter feeding emerged, how it diversified over time, and whether its evolution correlated with past environmental change. The project is expected to reveal clues on how whales became one of the greatest ecological actors in the sea, and will benefit conservation by providing a glimpse into their future.Read moreRead less
Dark canaries: new multidisciplinary understanding about the origins, radiation and response to environmental change of southern hemisphere bats. This project will overhaul global understanding of the origins of bats, their flight patterns and the role of echolocation in resource partitioning in an environmentally changing Australia. It will also provide information vital for conservation and novel biomimetic understanding of the modulation of ultrasound for medical and engineering purposes.
Was there an unusual environment with equally remarkable inhabitants in Early Cretaceous southeast Australia? After more than two decades of effort, there is strong evidence that Early Cretaceous southeastern Australia was inhabited by a remarkably diverse polar terrestrial vertebrate fauna adapted to the coldest environment known to have existed anywhere in the late Mesozoic. In this unusual terrestrial habitat for that time, temnospondyl amphibians and allosaurid dinosaurs survived long ....Was there an unusual environment with equally remarkable inhabitants in Early Cretaceous southeast Australia? After more than two decades of effort, there is strong evidence that Early Cretaceous southeastern Australia was inhabited by a remarkably diverse polar terrestrial vertebrate fauna adapted to the coldest environment known to have existed anywhere in the late Mesozoic. In this unusual terrestrial habitat for that time, temnospondyl amphibians and allosaurid dinosaurs survived long after becoming extinct elsewhere. Here, too, are found what may be the oldest known and yet remarkably advanced placental mammals, the group to which we belong. To further corroborate or refute these hypotheses, some of which are highly contentious, is the aim of this project.Read moreRead less
Biogeography and evolution of Australia's fossil reptiles: A global perspective. Large marine reptiles such as plesiosaurs, and missing links such as legged snakes, are spectacular animals that have captured public attention. This collaboration will directly enhance public museum displays by collecting and preparing these spectacular fossils; many of the fossils found by the CIs are now centerpieces of museum displays (e.g. the SA museum). Also, it will also promote awareness and sustainable u ....Biogeography and evolution of Australia's fossil reptiles: A global perspective. Large marine reptiles such as plesiosaurs, and missing links such as legged snakes, are spectacular animals that have captured public attention. This collaboration will directly enhance public museum displays by collecting and preparing these spectacular fossils; many of the fossils found by the CIs are now centerpieces of museum displays (e.g. the SA museum). Also, it will also promote awareness and sustainable use of the environment: it will facilitate CI Kear in running earthwatch-style ecotourism field trips which promote sustainable use of finite fossil resources by making them commercially valuable to local communities as a source of tourism revenue.Read moreRead less
Life and environments of the Lower Cretaceous Winton Formation, western Queensland: The Winton Dinosaur Project. This proposal is for research into vertebrate assemblages from newly discovered fossil sites in the Winton Formation, western Queensland. These sites indicate that the Winton Formation is one of the most palaeontologically productive Lower Cretaceous continental sequences in Australia. Within it are preserved vertebrates (including several new types of dinosaurs, crocodilians, turtles ....Life and environments of the Lower Cretaceous Winton Formation, western Queensland: The Winton Dinosaur Project. This proposal is for research into vertebrate assemblages from newly discovered fossil sites in the Winton Formation, western Queensland. These sites indicate that the Winton Formation is one of the most palaeontologically productive Lower Cretaceous continental sequences in Australia. Within it are preserved vertebrates (including several new types of dinosaurs, crocodilians, turtles, lungfish and freshwater sharks), invertebrates, plants and trace-fossils of a restricted biome over a relatively short time span. Research into these new sites will provide us with our first-ever detailed window on northern Australia's Lower Cretaceous lowland and coastal environments during the final break-up of Gondwana.Read moreRead less
Cretaceous marine reptiles from the Eromanga Sea - a research project focussing on the fossils of Outback Queensland. The Eromanga Sea covered large tracts of north and central Australia between 140 and 95 million years ago. Major faunal components of this inland-sea were marine reptiles, such as plesiosaurs, ichthyosaurs and sea turtles. North Qld has extensive marine fossil deposits remaining to be systematically explored. Many world-significant specimens from these strata are housed in the Au ....Cretaceous marine reptiles from the Eromanga Sea - a research project focussing on the fossils of Outback Queensland. The Eromanga Sea covered large tracts of north and central Australia between 140 and 95 million years ago. Major faunal components of this inland-sea were marine reptiles, such as plesiosaurs, ichthyosaurs and sea turtles. North Qld has extensive marine fossil deposits remaining to be systematically explored. Many world-significant specimens from these strata are housed in the Australian, Queensland and Richmond Marine Fossil museums. This project intends to resolve fundamental questions concerning the evolution, environment, lifestyle and distribution of Cretaceous marine reptiles by improving their fossil record and analysing newly discovered Australian specimens, including the world's first plesiosaur embryo.Read moreRead less
The Cambrian Population Explosion of Arthropods in Australia: Ediacaran origins, evolution and biodiversity. This project addresses key questions on the origin and diversification of life, by investigating the evolution of the most important fossil group (arthropods) across arguably the most important event after the origin of life (the Cambrian explosion of macroscopic life). It will also excavate, promote and conserve two key geological resources of national importance, in the Flinders Ranges ....The Cambrian Population Explosion of Arthropods in Australia: Ediacaran origins, evolution and biodiversity. This project addresses key questions on the origin and diversification of life, by investigating the evolution of the most important fossil group (arthropods) across arguably the most important event after the origin of life (the Cambrian explosion of macroscopic life). It will also excavate, promote and conserve two key geological resources of national importance, in the Flinders Ranges and Kangaroo Island. Also, it will lead to increased knowledge of the palaeoecology and geology of the economically-important Adelaide geosyncline, and benefit rural SA communities through ecotourism, a rural schools education program, and public outreach.Read moreRead less
Old brains, new data - early evolution of structural complexity in the vertebrate head. Of the all the complex structures biology has provided, the evolution of the vertebrate brain and its sensory organs is perhaps the most enigmatic. The fossil record occasionally provides a chance to trace this evolution, but only with the use of novel X-ray scanning techniques can these secrets be detailed in three dimensions. Exploiting the exceptional fossil record from Australia and China, this team will ....Old brains, new data - early evolution of structural complexity in the vertebrate head. Of the all the complex structures biology has provided, the evolution of the vertebrate brain and its sensory organs is perhaps the most enigmatic. The fossil record occasionally provides a chance to trace this evolution, but only with the use of novel X-ray scanning techniques can these secrets be detailed in three dimensions. Exploiting the exceptional fossil record from Australia and China, this team will for the first time collect a vast comparative data base which will yield clues on the early evolution of the ear, eye and brain. Read moreRead less
Origin of jaws - the greatest unsolved mystery of early vertebrate evolution. The 2008 discovery of an unborn embryo in the 380 million-year-old "Mother Fish" from the famous Gogo fossil deposit in NW Australia has attracted a collaboration of Australian, American and Chinese scientists to a new international collaboration. The team will study spectacular new fossils from central Australia and southern China, the oldest known back-boned animals with jaws and a hard skeleton. Innovative 3D X-ray ....Origin of jaws - the greatest unsolved mystery of early vertebrate evolution. The 2008 discovery of an unborn embryo in the 380 million-year-old "Mother Fish" from the famous Gogo fossil deposit in NW Australia has attracted a collaboration of Australian, American and Chinese scientists to a new international collaboration. The team will study spectacular new fossils from central Australia and southern China, the oldest known back-boned animals with jaws and a hard skeleton. Innovative 3D X-ray computer tomography, and the Australian synchrotron, will be used to investigate ancient cells and preserved soft tissue structures, to search for evidence that copulation and internal fertilization, as in modern mammals, might have originated when jaws first evolved. Read moreRead less