Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775778
Funder
Australian Research Council
Funding Amount
$196,000.00
Summary
A microarray platform for gene expression analysis and genotyping in biological systems. This technology has substantial benefits for basic science and biotechnology. The ability to rapidly study changes in gene expression in living organisms will benefit agriculture, animal and biomedical science and biotechnology. The Affymetrix platform creates opportunities for new avenues of research, such as studying epigenetic (DNA and protein modifications) mechanisms in development, ageing and disease. ....A microarray platform for gene expression analysis and genotyping in biological systems. This technology has substantial benefits for basic science and biotechnology. The ability to rapidly study changes in gene expression in living organisms will benefit agriculture, animal and biomedical science and biotechnology. The Affymetrix platform creates opportunities for new avenues of research, such as studying epigenetic (DNA and protein modifications) mechanisms in development, ageing and disease. The project falls within the designated national research priority areas of 'promoting and maintaining good health" and the priority goals of "a healthy start to life", "aging well", "aging productively" and "preventative health care."Read moreRead less
This project concerns the basic biology of white blood cells called macrophages. Macrophages are required for the immediate defence against infection, as well as wound repair and normal turnover of tissues, but they can also produce toxic products that cause illness, especially in inflammatory diseases and cancer. We are attempting to use the availability of mouse genome information to produce a complete picture of the way that macrophages respond to a challenge from a potential disease-causing ....This project concerns the basic biology of white blood cells called macrophages. Macrophages are required for the immediate defence against infection, as well as wound repair and normal turnover of tissues, but they can also produce toxic products that cause illness, especially in inflammatory diseases and cancer. We are attempting to use the availability of mouse genome information to produce a complete picture of the way that macrophages respond to a challenge from a potential disease-causing microorganism, and the influence of genetic differences between individuals.Read moreRead less
Transcriptional Regulation Of The C-fms (CSF-1R) Gene In Macrophages.
Funder
National Health and Medical Research Council
Funding Amount
$422,310.00
Summary
This project concerns the basic biology of large white blood cells called macrophages. Macrophages are required for the immediate defence against infection, wound repair and normal turnover of tissues, but they can also produce toxic products that cause illness, especially in inflammatory diseases and cancer. We are studying a gene that is normally only produced in macrophages, but appears abnormally in many cancer cells. Our aim is understand at a molecular level exactly how the gene is control ....This project concerns the basic biology of large white blood cells called macrophages. Macrophages are required for the immediate defence against infection, wound repair and normal turnover of tissues, but they can also produce toxic products that cause illness, especially in inflammatory diseases and cancer. We are studying a gene that is normally only produced in macrophages, but appears abnormally in many cancer cells. Our aim is understand at a molecular level exactly how the gene is controlled, and why it appears in tumours.Read moreRead less
My work on human pigmentation genetics has provided a framework to understand normal variation in this physical trait and the associated genotypic risk factors for skin cancer development. The genes that determine an individual's skin phototype and the ce
Structure and function of a new class of multi-zinc finger (MZF) transcriptional regulators. An understanding of how genes are switched on and off during the development and lifetime of an organism is central to developing the ability to fight many diseases in a rational way. This project will advance our knowledge in this area at a fundamental molecular level by examining the mechanisms through which a specific set of proteins controls gene expression.
Investigating the role of gene loops in regulating gene expression. The ability to identify functional variants in regulatory elements will have implications for researchers in multiple fields of biology, from molecular medicine to agriculture. Transfer of expertise and application of the knowledge generated by our research to such fields stands to improve diagnosis of disease predisposition and to improve quality of animal and plant products. These outcomes will benefit all Australians. This kn ....Investigating the role of gene loops in regulating gene expression. The ability to identify functional variants in regulatory elements will have implications for researchers in multiple fields of biology, from molecular medicine to agriculture. Transfer of expertise and application of the knowledge generated by our research to such fields stands to improve diagnosis of disease predisposition and to improve quality of animal and plant products. These outcomes will benefit all Australians. This knowledge will also improve the education of Australian University students as it contributes to the development of advanced curricula and access to more powerful research methods. In addition, the project will foster important collaborations between Australian researchers and those overseas.Read moreRead less
Characterisation of heavy metal transport genes in the plant Arabidopsis: potential roles in metal detoxification and accumulation. Plants have considerable potential for the bioremediation ("phytoremediation") of contaminated soils, including soils polluted with heavy metals. Progress has been made in understanding the physiological and biochemical mechanisms by which plants accumulate and detoxify heavy metals. One important aspect of metal detoxification is the transport of metals across cell ....Characterisation of heavy metal transport genes in the plant Arabidopsis: potential roles in metal detoxification and accumulation. Plants have considerable potential for the bioremediation ("phytoremediation") of contaminated soils, including soils polluted with heavy metals. Progress has been made in understanding the physiological and biochemical mechanisms by which plants accumulate and detoxify heavy metals. One important aspect of metal detoxification is the transport of metals across cell membranes. The recently completed genome project for the model plant Arabidopsis has identified a family of genes encoding heavy metal transport proteins. This project aims to investigate the roles of these genes in metal detoxification. In the longer term this knowledge can be applied to the improvement of phytoremediation processes.Read moreRead less
Mechanisms of zinc transport and homeostasis in the plant, Arabidopsis. Zinc-deficiency is one of the most widespread factors limiting crop production and affects many soils of south-east and south-west Australia. Certain zinc-efficient (ZE) crop cultivars are able to grow well under zinc deficient conditions but the genetic basis for ZE is not well understood. Using a model organism such as Arabidopsis to identify genes in plants that are important in zinc transport and homeostasis will ultimat ....Mechanisms of zinc transport and homeostasis in the plant, Arabidopsis. Zinc-deficiency is one of the most widespread factors limiting crop production and affects many soils of south-east and south-west Australia. Certain zinc-efficient (ZE) crop cultivars are able to grow well under zinc deficient conditions but the genetic basis for ZE is not well understood. Using a model organism such as Arabidopsis to identify genes in plants that are important in zinc transport and homeostasis will ultimately allow us to assess whether the homologous genes in crop species are responsible for ZE. This may contribute to more rapid and directed strategies in breeding ZE crop cultivars.Read moreRead less
This is a study of the biological system of epigenetics. Every cell in our body has the same genetics, or library of information contained in the form of DNA sequence. Epigenetics is the system that controls how this DNA is used in a particular situation, or what books are opened and read. During embryonic development, cells know what they want to become, e.g., a muscle cell, and, once they take on an identity, remember that they are when they duplicate themselves during growth. Epigenetics does ....This is a study of the biological system of epigenetics. Every cell in our body has the same genetics, or library of information contained in the form of DNA sequence. Epigenetics is the system that controls how this DNA is used in a particular situation, or what books are opened and read. During embryonic development, cells know what they want to become, e.g., a muscle cell, and, once they take on an identity, remember that they are when they duplicate themselves during growth. Epigenetics does not achieve this through changing genetics the library always stays intact. Rather, it acts by using proteins or chemicals to make DNA functional in one way, or another. Genomic imprinting is a special type of epigenetics. While an embryo has received identical genetic information from each of its parents, the epigenetic information received from each parent was not entirely the same. Some genes which behave differently according to what parent they came from. For example, a gene that makes a growth factor protein is active only if received from the father. If received from the mother, it is inactive, and makes no protein. Genes behaving in this way are known as imprinted genes. We are trying to discover what epigenetic mechanisms are behind this behaviour of imprinted genes. One way we are approaching this problem is to study germ cells the cells giving rise to eggs and sperm. These cells are unusual in that their imprinted genes behave in the same way regardless of whether they were received from the mother or father, i.e., like any other gene. If we can understand why this is the case, we will be better able to understand why imprinted genes behave the way they do in the rest of the cells of the body. Broadly, the mechanisms we uncover should further our understanding of germ cell development, gene expression, and disease. Perturbations in the epigenetic profile are likely causes of human disease, including cancer.Read moreRead less
Integration of Cellular Gene Regulation Processes. This research program aims to identify specific transcriptional regulatory networks in yeast, to determine how some of these networks interact with each other and within these networks to identify the roles of genes whose functions are currently unknown. It will identify systems regulating genes concerned with one-carbon metabolism, cellular responses to oxidative stress and developmental changes associated with meiosis. It will provide a fra ....Integration of Cellular Gene Regulation Processes. This research program aims to identify specific transcriptional regulatory networks in yeast, to determine how some of these networks interact with each other and within these networks to identify the roles of genes whose functions are currently unknown. It will identify systems regulating genes concerned with one-carbon metabolism, cellular responses to oxidative stress and developmental changes associated with meiosis. It will provide a framework to test regulatory network models and to analyse the molecular basis of interactions between control systems. This research will eventually provide the ability to predict how cells respond to drugs and other environmental stimuli.Read moreRead less