Special Research Initiatives - Grant ID: SR0354908
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Insect-Plant Chemical Ecology Network (IPCEN). We bring together plant molecular biology, entomology and analytical chemistry to transform three leading fields of Australian research into an advanced science with far reaching capabilities in innovative research and applied outcomes. Expertise studying the biochemical pathways that produce specific plant compounds and expertise in insect recognition and response to these chemicals will be brought together. This will lead to new research outco ....The Insect-Plant Chemical Ecology Network (IPCEN). We bring together plant molecular biology, entomology and analytical chemistry to transform three leading fields of Australian research into an advanced science with far reaching capabilities in innovative research and applied outcomes. Expertise studying the biochemical pathways that produce specific plant compounds and expertise in insect recognition and response to these chemicals will be brought together. This will lead to new research outcomes and solutions to problems in agriculture, horticulture, forestry and protection of Australia's native flora. Researchers are struggling to create these links, constrained by disciplinary boundaries and geographical isolation. Key industries and researchers already support this proposal.Read moreRead less
Ecophysiological limitations that affect water and carbon balance within large tree canopies: a comparative investigation. Supply of water to forest canopies is a major control of hydrological, atmospheric and biotic processes that impinge on groundwater stability, catchment yield, the fate of pollutants and plant productivity. Fundamental aspects of water transport and distribution within plant tissues remain obscured by conflicting experimental data and conflicting theoretical models that des ....Ecophysiological limitations that affect water and carbon balance within large tree canopies: a comparative investigation. Supply of water to forest canopies is a major control of hydrological, atmospheric and biotic processes that impinge on groundwater stability, catchment yield, the fate of pollutants and plant productivity. Fundamental aspects of water transport and distribution within plant tissues remain obscured by conflicting experimental data and conflicting theoretical models that describe physiological functioning.
Potential hydraulic constraints to the exchange of water and carbon between leaf and atmosphere require investigation before accurate models and informed decisions can be made with respect to the role of forests in biosphere-atmosphere processes. I will use large trees to investigate physiological and morphological determinants of hydraulic function and consider relationships between tree size, water requirements and water supply.
This project will foster comparative analyses of hydraulic functioning in large angiosperm and conifer species to elucidate universal principles that relate form to function and explain relationships between trees and their environment.
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Population dynamics and genetic variation of plants with contrasting fire responses. We combine the traditional concerns of population viability analyses with the modern techniques of DNA fingerprinting for precise genotyping of individual plants and their seeds. We expect major breakthroughs in our understanding of how fire-killed species have survived thousands of years of frequent burning by Aborigines (by identifying seeds dispersed long distances from burnt parents); how paternity of offspr ....Population dynamics and genetic variation of plants with contrasting fire responses. We combine the traditional concerns of population viability analyses with the modern techniques of DNA fingerprinting for precise genotyping of individual plants and their seeds. We expect major breakthroughs in our understanding of how fire-killed species have survived thousands of years of frequent burning by Aborigines (by identifying seeds dispersed long distances from burnt parents); how paternity of offspring changes over the lifespan of plants which retain their seeds for many years; at what age within-plant genetic variation is at a maximum as a guide to optimal fire management; and the extent that deleterious somatic mutations explain low seed set among long-lived species.Read moreRead less
Increasing sandalwood (Santalum spicatum) recruitment in regional Western Australia through mammal conservation. The highly prized sandalwood is the basis of an industry that employs over 100 people and generates $12 million export income annually in regional WA. Natural recruitment of sandalwood is poor. This project will build on research, conducted by Murdoch University and the Forest Products Commission, that indicates natural recruitment of the tree is greatly enhance in the presence of nat ....Increasing sandalwood (Santalum spicatum) recruitment in regional Western Australia through mammal conservation. The highly prized sandalwood is the basis of an industry that employs over 100 people and generates $12 million export income annually in regional WA. Natural recruitment of sandalwood is poor. This project will build on research, conducted by Murdoch University and the Forest Products Commission, that indicates natural recruitment of the tree is greatly enhance in the presence of native rat-kangaroos who cache the seeds. This project will train an APA(I) postgraduate through an industry based project that will evaluate increased recruitment of sandalwood by native mammal caching. Many of these mammals are Conservation Dependent or Threatened with extinction.Read moreRead less
Improved growth of Pinus radiata through better modelling and management of photosynthesis and respiration. This research will use recently developed technologies to deliver the first comprehensive analysis of the effects of thinning and fertilizer on distribution of photosynthetically active proteins and nitrogenous metabolites in P. radiata. We seek to develop mechanistic and empirical understandings of photosynthesis, respiration, water use and growth and thus better model and predict effec ....Improved growth of Pinus radiata through better modelling and management of photosynthesis and respiration. This research will use recently developed technologies to deliver the first comprehensive analysis of the effects of thinning and fertilizer on distribution of photosynthetically active proteins and nitrogenous metabolites in P. radiata. We seek to develop mechanistic and empirical understandings of photosynthesis, respiration, water use and growth and thus better model and predict effects of management actions on yield of commercial softwood plantations. We will also apply similarly new but complementary and compatible technologies to assess photosynthesis, water use and respiration characteristics of a range of P. radiata genotypes of known growth potential. Our aim here is to develop new tools to help selection of high-yielding genotypes. The data collected will again be used to inform our development of a new growth model where the 'driver' of growth is respiration and where hydraulic architecture and soil water balance limits photosynthesis and water use.
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In vitro propagation (through somatic embryogenesis) of rush and sedge species important for land rehabilitation. This project aims to transform existing propagation methods for rushes and sedges (recalcitrant, but key colonizer species) for restoring critical biodiversity in Australian mine-site restoration. This will be achieved through the process of somatic embryogenesis and will result in cost effective and efficient mass propagation. Significantly, this somatic embryogenesis research will ....In vitro propagation (through somatic embryogenesis) of rush and sedge species important for land rehabilitation. This project aims to transform existing propagation methods for rushes and sedges (recalcitrant, but key colonizer species) for restoring critical biodiversity in Australian mine-site restoration. This will be achieved through the process of somatic embryogenesis and will result in cost effective and efficient mass propagation. Significantly, this somatic embryogenesis research will provide the springboard for development of seed analogues (coated, desiccated somatic embryos) with subsequent economies from bypassing more costly nursery production of whole plants, utilizing existing infrastructure for direct seeding of restoration sites, and reducing dependence on dwindling reserves of wild-harvested seed.Read moreRead less
A new approach to control of plant parasitic nematodes. Plant parasitic nematodes are the fourth most important plant pathogens worldwide. The aim of this project is to develop ?proof-of-concept? of a new strategy for nematode control, based on a synthetic ?cell death? resistance gene, in which tight specificity of expression of the resistance gene is provided using two gene promoters. The work focusses on finding the best combination of promoters which are switched on by infection of plants w ....A new approach to control of plant parasitic nematodes. Plant parasitic nematodes are the fourth most important plant pathogens worldwide. The aim of this project is to develop ?proof-of-concept? of a new strategy for nematode control, based on a synthetic ?cell death? resistance gene, in which tight specificity of expression of the resistance gene is provided using two gene promoters. The work focusses on finding the best combination of promoters which are switched on by infection of plants with nematodes. It is based on an Australian patent which has wide applicability in plant biotechnology. Nematode control will benefit horticultural and broadacre farming by reducing pathogen losses and improving quality.Read moreRead less
Long-term survival of Phytophthora cinnamomi in black gravel soils on mining leases in the jarrah (Eucalyptus marginata) forest. Approximately 41% of the 5750 plant species in Western Australia are susceptible to Phytophthora cinnamomi a pathogen recognised as a key threatening process to Australia's biodiversity by the Federal Government. This project will enhance our understanding of how the pathogen survives in soil and tolerant plant species. It will determine how the pathogen is able to su ....Long-term survival of Phytophthora cinnamomi in black gravel soils on mining leases in the jarrah (Eucalyptus marginata) forest. Approximately 41% of the 5750 plant species in Western Australia are susceptible to Phytophthora cinnamomi a pathogen recognised as a key threatening process to Australia's biodiversity by the Federal Government. This project will enhance our understanding of how the pathogen survives in soil and tolerant plant species. It will determine how the pathogen is able to survive long-term as dormant propagules and how this dormancy can be broken. This project will be relevant to managers of natural ecosystems and to the horticultural industries throughout Australia and will assist in developing effective ways to manage this ecologically devastating plant pathogen. Read moreRead less