Living on the edge: how do Australian plants cope with extreme temperature? Of all the climatic factors determining species distributions, temperature is arguably the most important. It is extremes – rather than averages – that drive species evolution. So it is concerning that although extreme temperature events are increasing in frequency and intensity little is known about the breadth of thermal tolerance of plants from extreme environments. This information is crucial to understand species di ....Living on the edge: how do Australian plants cope with extreme temperature? Of all the climatic factors determining species distributions, temperature is arguably the most important. It is extremes – rather than averages – that drive species evolution. So it is concerning that although extreme temperature events are increasing in frequency and intensity little is known about the breadth of thermal tolerance of plants from extreme environments. This information is crucial to understand species distribution and survival under future climate regimes. This project will ascertain the thermal breadth of Australian species growing in situ and under controlled environments. The project will contribute to development of effective conservation, restoration and rehabilitation plans for Australian native plant communities. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100629
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Evolutionary impacts of climate change in Australia’s fossil record. This project aims to identify evolutionary responses to climate change in Australia's fossil record by comparing variation in lizard and frog communities across geological time. Using X-ray techniques on museum specimens, this project will generate a large-scale database for tracking evolutionary shifts in relation to historical climatic events. Expected outcomes include the first anatomical descriptions for many species, filli ....Evolutionary impacts of climate change in Australia’s fossil record. This project aims to identify evolutionary responses to climate change in Australia's fossil record by comparing variation in lizard and frog communities across geological time. Using X-ray techniques on museum specimens, this project will generate a large-scale database for tracking evolutionary shifts in relation to historical climatic events. Expected outcomes include the first anatomical descriptions for many species, filling major gaps in our ability to place fossils in a contemporary framework. This research will demonstrate the value of our national collections for addressing important environmental issues, such as biodiversity, extinction, and future habitat change.Read moreRead less
Size matters: evolution of body size of species in deep time. Global warming is predicted to form 'sick seas' and cause widespread stunted growth of taxa and ecosystem-wide dwarfism. Exactly how this works requires substantiation of both short-term empirical and experimental research as well as evidence from the deep-time fossil record. Using the high-resolution marine fossil record from the Permian-Triassic mass extinction ~252 million years ago, the most severe in the history of animals, this ....Size matters: evolution of body size of species in deep time. Global warming is predicted to form 'sick seas' and cause widespread stunted growth of taxa and ecosystem-wide dwarfism. Exactly how this works requires substantiation of both short-term empirical and experimental research as well as evidence from the deep-time fossil record. Using the high-resolution marine fossil record from the Permian-Triassic mass extinction ~252 million years ago, the most severe in the history of animals, this project will investigate how body size of marine species and communities evolved in response to the mass extinction and rapid global warming. It is expected that the project findings will help better understand the links between global warming, anoxia, hypercapnia, euxinia, ocean acidification, and species adaptation and evolution.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100083
Funder
Australian Research Council
Funding Amount
$540,000.00
Summary
A high throughput phenomics facility for pace of life traits in animals. A high throughput phenomics facility for pace of life traits in animals: This project seeks to create the first high-throughput phenomic facility for animals in Australia. The molecular revolution has brought unprecedented capacity to understand genetic variation. Genetic variation is now better understood and more easily and cheaply characterised than the physical traits that organisms exhibit. Linking phenotypic variation ....A high throughput phenomics facility for pace of life traits in animals. A high throughput phenomics facility for pace of life traits in animals: This project seeks to create the first high-throughput phenomic facility for animals in Australia. The molecular revolution has brought unprecedented capacity to understand genetic variation. Genetic variation is now better understood and more easily and cheaply characterised than the physical traits that organisms exhibit. Linking phenotypic variation to genetic variation represents the major challenge in harnessing the power of the biomolecular age. This facility will accommodate animals from marine, freshwater and terrestrial systems across a diverse array of phyla. It will allow Australian researchers to leverage advances in high throughput genomic technologies to address a major bottleneck in biology.Read moreRead less
Drivers of phenotypic evolution in a vulnerable alpine ecosystem. This project aims to deliver a comprehensive, integrated understanding of the capacity for resilience and drivers of response of highly vulnerable alpine species and communities to climate change. The project aims to determine how communities of interacting alpine plants, soil invertebrates and microbes can cope with or evolve to novel climatic conditions. The mountains are water towers critical to power supply and Australia's agr ....Drivers of phenotypic evolution in a vulnerable alpine ecosystem. This project aims to deliver a comprehensive, integrated understanding of the capacity for resilience and drivers of response of highly vulnerable alpine species and communities to climate change. The project aims to determine how communities of interacting alpine plants, soil invertebrates and microbes can cope with or evolve to novel climatic conditions. The mountains are water towers critical to power supply and Australia's agricultural productivity. Understanding physiological tolerance and the potential for rapid evolutionary responses of plants, animals and communities is necessary to predict impacts of climate change on the future productivity of the vulnerable Australian Alps and to provide novel options for climate adaptation. Read moreRead less
Biological bet hedging in a variable ocean. This project aims to investigate how the functioning of photosynthetic plankton changes as they respond to increasing environmental variation, a significant uncertainty in ocean forecasts. The project will advance knowledge about phytoplankton nutrient acquisition strategies in increasingly variable environments. Expected outcomes include improved predictions of ocean ecosystem services. This knowledge will enhance food security, assisting the fisherie ....Biological bet hedging in a variable ocean. This project aims to investigate how the functioning of photosynthetic plankton changes as they respond to increasing environmental variation, a significant uncertainty in ocean forecasts. The project will advance knowledge about phytoplankton nutrient acquisition strategies in increasingly variable environments. Expected outcomes include improved predictions of ocean ecosystem services. This knowledge will enhance food security, assisting the fisheries, aquaculture and environment sector to develop effective adaptation strategies, and thereby safeguard the social and economic wellbeing of the communities that rely on them.Read moreRead less
The Eocene high latitude Australasian 'tropics' in a changing climate: resolving conflicting evidence. Between 45 to 30 million years ago, high latitude subtropical floras in Australia and New Zealand experienced significant climate change, leading to the evolution of present day vegetation. Understanding the effects of this climate change on extinction and speciation will produce more accurate predictions about modern floras when faced with climate change.
Keeping pace with a changing climate: can Australian plants count on rapid evolution? Integrating field and common-garden experiments with cutting-edge genomic technology, this project will answer the critical question of whether Australia's flora can count on evolution to keep pace with a rapidly changing climate. The project outcomes will inform science-based policies integrating social-economic development and biodiversity conservation.
Multi-trait plasticity in response to a changing climate. This project aims to understand the effect of climate change on natural populations. Phenotypic plasticity (the ability to change phenotype with environment) determines natural populations’ immediate response to environmental change. However, studies of plasticity frequently rely on simplifying assumptions, and understanding the genomic and epigenomic mechanisms underlying plasticity is only just emerging. This project will combine a fine ....Multi-trait plasticity in response to a changing climate. This project aims to understand the effect of climate change on natural populations. Phenotypic plasticity (the ability to change phenotype with environment) determines natural populations’ immediate response to environmental change. However, studies of plasticity frequently rely on simplifying assumptions, and understanding the genomic and epigenomic mechanisms underlying plasticity is only just emerging. This project will combine a fine-scale temperature-manipulation experiment with genomic and multivariate statistical analyses of a native Australian alpine plant. The intended outcome is a comprehensive analysis of whether multi-trait phenotypic plasticity is adaptive; whether it can evolve; and the epigenomic mechanisms that drive it. The project will predict the likely effect of temperature change on alpine plants, and so generate information internationally relevant to the management of populations adapting to climate change and locally relevant to the conservation of Australian montane flora.Read moreRead less