Deep Downunder: designing a deep-sea exploration and discovery capability for Australia. Exploration of the deep-sea with the modern technologies to be developed by Deep-Downunder is a first for Australia. We aim to explore and discover life at depths from 50-3000m off The Great Barrier Reef, around the seamounts of Lord Howe Island and Tasmania and in the deep canyons of WA and SA. We expect to discover new species, hope for a glimpse of giant squid at home and will answer specific questions on ....Deep Downunder: designing a deep-sea exploration and discovery capability for Australia. Exploration of the deep-sea with the modern technologies to be developed by Deep-Downunder is a first for Australia. We aim to explore and discover life at depths from 50-3000m off The Great Barrier Reef, around the seamounts of Lord Howe Island and Tasmania and in the deep canyons of WA and SA. We expect to discover new species, hope for a glimpse of giant squid at home and will answer specific questions on Australia's ocean biology, fisheries and biotechnology never before approachable. To be effective guardians of Australian waters we must learn what lies in the depths we can't see from a boat.Read moreRead less
Why conserve genetic variation? Is this misdirected effort or a crucial concern? In attempting to conserve populations of threatened plants, ecosystem managers must prioritise allocation of resources to both immediate and long-term threats, including loss of genetic variation. This study will determine the importance of maintaining existing genetic variation within populations of several species in a major Australian plant group. As well as advancing theory in the area of plant ecological genet ....Why conserve genetic variation? Is this misdirected effort or a crucial concern? In attempting to conserve populations of threatened plants, ecosystem managers must prioritise allocation of resources to both immediate and long-term threats, including loss of genetic variation. This study will determine the importance of maintaining existing genetic variation within populations of several species in a major Australian plant group. As well as advancing theory in the area of plant ecological genetics and evolutionary biology, our results will provide a stronger scientific basis for the development of conservation policy and management decisions for conserving threatened plant species. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346454
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Native plant mesocosm facility. Mesocosms allow ecological processes to be studied at scales intermediate between the field and laboratory. We will establish a native plant mesocosm, allowing us to accurately manipulate environmental factors such as soil moisture, mineral nutrients and temperature. This will enable us to assess how plants adjust resource allocation patterns and determine genotypic and phenotypic responses to varying environmental conditions. Such research will provide insight in ....Native plant mesocosm facility. Mesocosms allow ecological processes to be studied at scales intermediate between the field and laboratory. We will establish a native plant mesocosm, allowing us to accurately manipulate environmental factors such as soil moisture, mineral nutrients and temperature. This will enable us to assess how plants adjust resource allocation patterns and determine genotypic and phenotypic responses to varying environmental conditions. Such research will provide insight into how native plants persist in and adapt to changing environmental conditions. The facility will strengthen existing collaboration with NSW NPWS, enhance post-graduate and post-doctoral training, and provide improved conservation and management outcomes for native plants.Read moreRead less
Long-term changes in Mackay Whitsunday water quality and connectivity between coral reefs and mangrove ecosystems. Declining water quality is implicated in the degradation of near-shore Great Barrier Reef (GBR) ecosystems. The goal of this project is to provide a definitive answer to the question of how GBR water quality has changed since European arrival (pre-1860). Using novel geochemical proxies in long-lived coral cores and innovative remote sensing techniques, we will develop quantitative h ....Long-term changes in Mackay Whitsunday water quality and connectivity between coral reefs and mangrove ecosystems. Declining water quality is implicated in the degradation of near-shore Great Barrier Reef (GBR) ecosystems. The goal of this project is to provide a definitive answer to the question of how GBR water quality has changed since European arrival (pre-1860). Using novel geochemical proxies in long-lived coral cores and innovative remote sensing techniques, we will develop quantitative histories of water quality and mangrove distribution change. This project will deliver the first integrated assessment of how coastal water quality and associated ecosystems have varied historically, which will be immediately applicable for long-term management of coastal ecosystems lining the GBR.Read moreRead less
Connecting ecological processes controlling variation across spatial scales. Large variability in numbers and types of animals from place to place and time to time characterizes many ecological systems, particularly on the rocky shores along our coasts. It confuses interpretation and hampers predictions about conservation, impacts and climatic change. This programme is a systematic experimental analysis of the major causes of variance (availability of suitable habitat and food, influences of w ....Connecting ecological processes controlling variation across spatial scales. Large variability in numbers and types of animals from place to place and time to time characterizes many ecological systems, particularly on the rocky shores along our coasts. It confuses interpretation and hampers predictions about conservation, impacts and climatic change. This programme is a systematic experimental analysis of the major causes of variance (availability of suitable habitat and food, influences of weather) on the animals and indirectly on their food. The research will unravel the interacting influences that operate over several spatial scales to cause variability in local diversity. This will radically increase our capacity to sustain our coastal fauna.Read moreRead less
Modelling disease evolution and emergence. Approximately 75% of all emergent diseases have established in humans having switched from other species: Human Immunodeficiency Virus (HIV), Malaria, SARS (Severe Acute Respiratory Syndrome), Ebola, West Nile Virus and many more. Further, cross species infections put our biodiversity and economy at risk: plant and animal diseases entering Australia can destroy crops and at-risk native species. This project will provide for the first time the statistica ....Modelling disease evolution and emergence. Approximately 75% of all emergent diseases have established in humans having switched from other species: Human Immunodeficiency Virus (HIV), Malaria, SARS (Severe Acute Respiratory Syndrome), Ebola, West Nile Virus and many more. Further, cross species infections put our biodiversity and economy at risk: plant and animal diseases entering Australia can destroy crops and at-risk native species. This project will provide for the first time the statistical framework for scientists to assess risk of such diseases entering Australia as a key to combating them.Read moreRead less
Tracing the origins of stress in the symbionts of reef-building corals. Symbiotic dinoflagellates of corals are critical to the world's major tropical reef ecosystems. Recent work in our laboratories and others has revealed that these algae are sensitive to a wide array of stresses (including climate change) and hence may be the ?Achilles Heel? of reef ecosystems. This project will identify the key genes and processes in these algae using expressed sequence tags and microarray technology. On th ....Tracing the origins of stress in the symbionts of reef-building corals. Symbiotic dinoflagellates of corals are critical to the world's major tropical reef ecosystems. Recent work in our laboratories and others has revealed that these algae are sensitive to a wide array of stresses (including climate change) and hence may be the ?Achilles Heel? of reef ecosystems. This project will identify the key genes and processes in these algae using expressed sequence tags and microarray technology. On this basis, the underlying molecular mechanisms of these stress responses and their genetic diversity will be studied in order to better understand the differential susceptibility of reef-building corals to bleaching.Read moreRead less