An Integrated Assessment of the Impacts of Climate Change on Victorian Alpine Ecosystems: Detecting and Managing Ecological Change. Climate change threatens biodiversity in alpine areas of Australia. This project seeks to predict how plants, soils and small animals will respond to warming and the associated increased risk of bushfire. Our project uses chambers placed out in the field to simulate warming conditions, and measures plant growth and development, and small animal community structure w ....An Integrated Assessment of the Impacts of Climate Change on Victorian Alpine Ecosystems: Detecting and Managing Ecological Change. Climate change threatens biodiversity in alpine areas of Australia. This project seeks to predict how plants, soils and small animals will respond to warming and the associated increased risk of bushfire. Our project uses chambers placed out in the field to simulate warming conditions, and measures plant growth and development, and small animal community structure within the chambers. We also assess the effects of climate change on soil processes. The information is used to evaluate the ability of alpine plants and animals to deal with climate change and to identify ways managers can help maintain biodiversity in this fragile ecosystem. Read moreRead less
Unravelling the biochemical fingerprint of Australian native plants for sustainable farm forestry and other applications. Dryland salinity is an issue of national significance due to its impact on primary industries which contribute billions of dollars to our economy. However, millions of hectares of arable land are now affected by salinity, with devastating effects on crops, native plants, water quality and wildlife. This project works with the rural community and exploits the unique gene poo ....Unravelling the biochemical fingerprint of Australian native plants for sustainable farm forestry and other applications. Dryland salinity is an issue of national significance due to its impact on primary industries which contribute billions of dollars to our economy. However, millions of hectares of arable land are now affected by salinity, with devastating effects on crops, native plants, water quality and wildlife. This project works with the rural community and exploits the unique gene pool of certain Australian salinity-tolerant plants for environmental benefits (revegetation, salinity control) and simultaneous economic returns through using these for timber and perennial fodder. The project thus addresses the national priorities of preventing the expansion of salinity, putting it to sustainable uses and preserving biodiversity.Read moreRead less
Epigenetic integration of genomic and environmental information in honey bees. Environmental factors such as nutrition, drugs or childhood neglect alter gene activity without a change to the DNA code and may result in a range of conditions such as cancer, obesity and mental illness. Such epigenetic phenomena are driven by subtle and poorly understood modifications of the genome known as DNA methylation. Our aim is to study the link between DNA methylation and environmental influences. We aspire ....Epigenetic integration of genomic and environmental information in honey bees. Environmental factors such as nutrition, drugs or childhood neglect alter gene activity without a change to the DNA code and may result in a range of conditions such as cancer, obesity and mental illness. Such epigenetic phenomena are driven by subtle and poorly understood modifications of the genome known as DNA methylation. Our aim is to study the link between DNA methylation and environmental influences. We aspire to understand how environmental signals trigger the reprogramming of transcriptional control of genetic networks that lead to contrasting phenotypic and behavioural outcomes using the honey bee modelRead moreRead less
ARC Centre in Bioinformatics. The Australian Centre for Genome-Phenome Bioinformatics will examine how the genome comes to life in the mammalian cell during differentiation and development. We will model, visualise and experimentally validate the complex cellular systems and regulatory networks that control the transformation of genomic information into biological structure and function. We will develop novel approaches and tools to improve health, optimise agricultural production and exploit ne ....ARC Centre in Bioinformatics. The Australian Centre for Genome-Phenome Bioinformatics will examine how the genome comes to life in the mammalian cell during differentiation and development. We will model, visualise and experimentally validate the complex cellular systems and regulatory networks that control the transformation of genomic information into biological structure and function. We will develop novel approaches and tools to improve health, optimise agricultural production and exploit new cell technologies. The Centre will build critical mass and national focus in bioinformatics to generate the human capital and intellectual property that Australia needs to compete in advanced bioscience and biotechnology.Read moreRead less
Statistical methods for detection of non-coding RNAs in eukaryote genomes. Understanding how eukaryotic cells work is a major goal of 21st century biology. A crucial step will be to catalogue the functional components of eukaryotic genomes. Australian researchers must be involved in this process at an early stage, in order to maximise commercial opportunities, attract quality researchers and position ourselves for further advances. This project will make major contributions to international effo ....Statistical methods for detection of non-coding RNAs in eukaryote genomes. Understanding how eukaryotic cells work is a major goal of 21st century biology. A crucial step will be to catalogue the functional components of eukaryotic genomes. Australian researchers must be involved in this process at an early stage, in order to maximise commercial opportunities, attract quality researchers and position ourselves for further advances. This project will make major contributions to international efforts in this area, via the development of statistical methods for segmenting genomes, classification of those segments, and study of the resulting classes. In the long term, enhanced understanding of eukaryotic cells will lead to breakthroughs in biology, and to medical, pharmaceutical, agricultural and scientific advances.Read moreRead less
The mucosal immune system of fish: analysis of the immune repertoire in gut-and gill-associated lymphoid tissues in trout. Infectious disease causes major economic loss to the aquaculture industry, highlighting the need for effective vaccination strategies. While oral or immersion vaccination represents the most cost effective means of protecting fish against infectious disease there are problems associated with inducing an effective immune response in fish that will assist our industry partner ....The mucosal immune system of fish: analysis of the immune repertoire in gut-and gill-associated lymphoid tissues in trout. Infectious disease causes major economic loss to the aquaculture industry, highlighting the need for effective vaccination strategies. While oral or immersion vaccination represents the most cost effective means of protecting fish against infectious disease there are problems associated with inducing an effective immune response in fish that will assist our industry partner (Novartis Animal Vaccines Ltd) to develop improved fish vaccines. The project will provide postgraduate training in the area of fish immunology that is vital to the developing Australian aquaculture industry.Read moreRead less
The transcriptional co-repressor C-terminal Binding Protein (CtBP) in metabolic control. This project will provide insights into the genes that regulate the storage of fat. We will learn about basic biology but will also discover mechanisms that may be used to influence fat storage in human health. We will also consolidate Australia's expertise in the use of the genetic model organism, the worm C. elegans, and validate the findings in mammalian systems. Finally, the process of training young sci ....The transcriptional co-repressor C-terminal Binding Protein (CtBP) in metabolic control. This project will provide insights into the genes that regulate the storage of fat. We will learn about basic biology but will also discover mechanisms that may be used to influence fat storage in human health. We will also consolidate Australia's expertise in the use of the genetic model organism, the worm C. elegans, and validate the findings in mammalian systems. Finally, the process of training young scientists in these modern systems, will also equip future researchers to make additional contributions to Australia's research output.Read moreRead less
RNA splicing: factors and mechanisms. Most primary gene transcripts must have their noncoding intronic sequences spliced out before the mRNA can be translated. Moreover, alternative splicing enables cells to generate a far more proteins than there are genes in the nucleus. Based on our proven success with ZNF265 we will isolate novel RNA interactors and their partners, colocalize these in intranuclear compartments, and elucidate their effect on pre-mRNA splicing. This will provide timely spin-of ....RNA splicing: factors and mechanisms. Most primary gene transcripts must have their noncoding intronic sequences spliced out before the mRNA can be translated. Moreover, alternative splicing enables cells to generate a far more proteins than there are genes in the nucleus. Based on our proven success with ZNF265 we will isolate novel RNA interactors and their partners, colocalize these in intranuclear compartments, and elucidate their effect on pre-mRNA splicing. This will provide timely spin-offs to the Human genome Project and EST sequence information, where the finding of only approx. 30,000 genes in our genome highlights the important role of alternative splicing in generating the large proteome repertoire of cells. This will bring considerable benefits to science, society, and the biotech industry.Read moreRead less
Genetic dissection of a regulatory deubiquitlyation network. The potential impact of this work is widespread, because although it is known that ubiquitlyation has regulatory consequences in multicellular eukaryotes, individual networks have not been completely described in higher eukaryotes. Knowledge gained about fundamental processes in the A. nidulans model system is directly applicable to fungi used in biotechnology in the food, beverage, enzyme and pharmaceutical production industries, and ....Genetic dissection of a regulatory deubiquitlyation network. The potential impact of this work is widespread, because although it is known that ubiquitlyation has regulatory consequences in multicellular eukaryotes, individual networks have not been completely described in higher eukaryotes. Knowledge gained about fundamental processes in the A. nidulans model system is directly applicable to fungi used in biotechnology in the food, beverage, enzyme and pharmaceutical production industries, and to fungal pathogens. Since the fungal genes that form the basis of this project are conserved in higher eukaryotes including humans, the knowledge will be transferable to these systems. A further benefit that cannot be overstated is the research education and training opportunities provided.
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A new mechanism of gene regulation. This project will advance our knowledge of how genes are switched on and off, by focusing on a very common class of gene regulatory proteins known as zinc finger proteins. The results of this study will improve our understanding of the fundamental molecular events that underpin gene regulation and how we might control it in fields such as biotechnology and gene therapy.