Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0452977
Funder
Australian Research Council
Funding Amount
$329,504.00
Summary
Upgrade and expansion of Newcastle Plant Growth Facility. The project will upgrade and expand the Newcastle Plant Growth Facility. The upgrades will improve glasshouse environments for the production of high quality plant material. This outcome will be achieved through increasing solar transmittance and more effective temperature control. Expansion will address unmet demand for standard and PC2 plant growth space. Together the infrastructure additions will enhance productivity and excellence ....Upgrade and expansion of Newcastle Plant Growth Facility. The project will upgrade and expand the Newcastle Plant Growth Facility. The upgrades will improve glasshouse environments for the production of high quality plant material. This outcome will be achieved through increasing solar transmittance and more effective temperature control. Expansion will address unmet demand for standard and PC2 plant growth space. Together the infrastructure additions will enhance productivity and excellence of core areas of plant biology research at Newcastle in nutrient transport, cell development as well as environment management and rehabilitation . In addition, they will underpin new collaborative initiatives at the interfaces between plant biology with transgenic delivery of reproductive vaccines and phytoremediation.Read moreRead less
Regulation of ion homeostasis by two-component signalling elements. Dryland salinity is continuously claiming Australian lands and is a serious threat to our agricultural industry, native flora and fauna, and infrastructure. Attempting to feed an increasing population whilst agricultural land is disappearing, places an ever-increasing burden on our remaining land. While there is no simple solution to this problem, understanding how plants regulate cellular ion concentrations will help to generat ....Regulation of ion homeostasis by two-component signalling elements. Dryland salinity is continuously claiming Australian lands and is a serious threat to our agricultural industry, native flora and fauna, and infrastructure. Attempting to feed an increasing population whilst agricultural land is disappearing, places an ever-increasing burden on our remaining land. While there is no simple solution to this problem, understanding how plants regulate cellular ion concentrations will help to generate plants that are suitable for restoration of damaged lands or crop plants that are more tolerant to saline soils. Furthermore, knowledge acquired from the proposed project will also be useful for generating healthier crop plants with enhanced levels of ions essential for the human diet. Read moreRead less
Reconstructing landscapes for biodiversity: From predictive modelling to future scenarios. Many landscapes around the world have been effectively denuded of natural vegetation, causing precipitous declines in native biodiversity. Mitigation of such effects in the near/medium-term future requires substantial ecological advice. We will employ our skills developed in modelling distributions of species across landscapes based on terrain, soils and climate to assess alternative landscape-reconstructi ....Reconstructing landscapes for biodiversity: From predictive modelling to future scenarios. Many landscapes around the world have been effectively denuded of natural vegetation, causing precipitous declines in native biodiversity. Mitigation of such effects in the near/medium-term future requires substantial ecological advice. We will employ our skills developed in modelling distributions of species across landscapes based on terrain, soils and climate to assess alternative landscape-reconstruction scenarios. This links use of existing data sets for initial modelling, a validation phase for testing model reliability and for refining models, and a subsequent GIS-based modelling phase in which alternative options for reconstructing landscapes are evaluated for their effectiveness in sustaining landscape-scale native biodiversity.Read moreRead less
Evaluation of the EG95 vaccine against hydatid infection in macropodid marsupials. A parasitic infection known as hydatids was introduced into Australia by Europeans and is now causing mortality in Australian wallabies and kangaroos, including amongst endangered species. A vaccine against the disease, that was developed in Australia for use in domestic livestock, is being evaluated to determine if it could be used to prevent hydatids closely monitored populations of endangered macropod marsupia ....Evaluation of the EG95 vaccine against hydatid infection in macropodid marsupials. A parasitic infection known as hydatids was introduced into Australia by Europeans and is now causing mortality in Australian wallabies and kangaroos, including amongst endangered species. A vaccine against the disease, that was developed in Australia for use in domestic livestock, is being evaluated to determine if it could be used to prevent hydatids closely monitored populations of endangered macropod marsupials, such as Petrogale penicillata.Read moreRead less
An inventory of past biodiversity in Western Australia using ancient DNA. Fossil bones and museum skins are genetic time capsules that facilitate the exploration of Australia's past biodiversity. Travelling back in 'genetic time' provides important insights into how ecosystems functioned prior to the arrival of Europeans and the feral species that accompanied them. This funding will facilitate research into the genetic heritage of endangered WA species such as Woylies and Cockatoos. Native speci ....An inventory of past biodiversity in Western Australia using ancient DNA. Fossil bones and museum skins are genetic time capsules that facilitate the exploration of Australia's past biodiversity. Travelling back in 'genetic time' provides important insights into how ecosystems functioned prior to the arrival of Europeans and the feral species that accompanied them. This funding will facilitate research into the genetic heritage of endangered WA species such as Woylies and Cockatoos. Native species face increasing pressures from climate change and invasive species. Compiling a genetic inventory of WA's past biodiversity will assist in developing scientifically sound conservation management responses. Such approaches are critically important if this biodiversity hotspot is to be preserved for future generations.Read moreRead less
Optimised distributed stimulation of muscle. The project aims to extend to humans, a method of producing a non-fatiguing, smooth, submaximal muscle contraction. The method using multiple electrodes, stimulated at different times, with those times being adjusted for optimum smoothness at low stimulation rates. This will enable the gathering of information about the mechanics of muscle undergoing near physiological contractions, which will be of interest to researchers in Biomechanics. It will ....Optimised distributed stimulation of muscle. The project aims to extend to humans, a method of producing a non-fatiguing, smooth, submaximal muscle contraction. The method using multiple electrodes, stimulated at different times, with those times being adjusted for optimum smoothness at low stimulation rates. This will enable the gathering of information about the mechanics of muscle undergoing near physiological contractions, which will be of interest to researchers in Biomechanics. It will also be a step towards the restoration of function to spinal cord injured patients.Read moreRead less
Discovery of the molecular mode of action of karrikins in plants. Karrikins are a newly-discovered family of naturally-occurring plant growth regulators that stimulate seed germination and seedling vigour. They were discovered in smoke and while they are centrally important in fire ecology they have far wider significance since species from non-fire-prone regions also respond to karrikins. Our research will discover how karrikins work at the molecular level in plant cells. Our discoveries will b ....Discovery of the molecular mode of action of karrikins in plants. Karrikins are a newly-discovered family of naturally-occurring plant growth regulators that stimulate seed germination and seedling vigour. They were discovered in smoke and while they are centrally important in fire ecology they have far wider significance since species from non-fire-prone regions also respond to karrikins. Our research will discover how karrikins work at the molecular level in plant cells. Our discoveries will be applied to improve growth of crop plants, to stimulate germination of weeds so that they can be eradicated, and in restoration ecology to revegetate degraded land such as minesites. Australia's world-leading position in this new important research area will be enhanced.Read moreRead less
Differential expression and functional analysis of genes controlling metamorphosis and early neurogenesis of a model lower animal, the coral Acropora. This study will analyse, at a molecular level, the response of coral larvae to stimuli inducing settlement from the plankton and the process of establishment of a sessile, calcified colony. The knowledge gained will facilitate induction of settlement on demand in the most effective way. We will characterise known candidate genes which may be invo ....Differential expression and functional analysis of genes controlling metamorphosis and early neurogenesis of a model lower animal, the coral Acropora. This study will analyse, at a molecular level, the response of coral larvae to stimuli inducing settlement from the plankton and the process of establishment of a sessile, calcified colony. The knowledge gained will facilitate induction of settlement on demand in the most effective way. We will characterise known candidate genes which may be involved in settlement, and reveal a more complete picture using subtractive hybridisation. Studies of the nervous system and the changes that it undergoes at metamorphosis will promote understanding of the control of metamorphosis, and insights into how more complex nervous systems may have evolved.Read moreRead less
Evolution of halophytes: a phyloinformatic approach to understanding and exploiting the traits underlying salt-tolerance in plants. Salinity is an increasing burden on the Australian economy & environment, with >2 million ha of salt-affected land, at an annual cost to agriculture over $187 million. One solution is to exploit naturally salt-tolerant plants to increase productive agricultural land and restore salt-affected environments. To do this, we must increase basic knowledge of the diversity ....Evolution of halophytes: a phyloinformatic approach to understanding and exploiting the traits underlying salt-tolerance in plants. Salinity is an increasing burden on the Australian economy & environment, with >2 million ha of salt-affected land, at an annual cost to agriculture over $187 million. One solution is to exploit naturally salt-tolerant plants to increase productive agricultural land and restore salt-affected environments. To do this, we must increase basic knowledge of the diversity & distribution of salt-tolerance. This project is the first to use DNA sequences from thousands of species to understand the evolution of salt-tolerance in order to provide the foundation for the development of new crop varieties, selection of species that can be developed for bioremediation, and identification of traits that will be profitable targets for breeding programs. Read moreRead less
Vision and remote sensing: using nature's technology to examine the health of The Great Barrier Reef and Moreton Bay. We aim to use what is known and what we will discover about animals visual systems to examine environmental health on The Great Barrier Reef and Moreton Bay. Technology and knowledge from 8 university departments, 4 industry partners, and 7 international collaborators will be combined to both learn and provide information. The innovative aspect of our approach is to examine the w ....Vision and remote sensing: using nature's technology to examine the health of The Great Barrier Reef and Moreton Bay. We aim to use what is known and what we will discover about animals visual systems to examine environmental health on The Great Barrier Reef and Moreton Bay. Technology and knowledge from 8 university departments, 4 industry partners, and 7 international collaborators will be combined to both learn and provide information. The innovative aspect of our approach is to examine the world with the eyes of birds, fish and invertebrates. Tricks animals employ to solve visual tasks will be implemented at scales of instrumentation from hand-held to remote sensing and used to address problems such as coral reef bleaching.Read moreRead less