Sino-Australian neurogenetics initiative. This project will undertake large population studies to identify genes that are associated with motor neuron disease, schizophrenia and intracranial haemorrhage. The project will determine genetic markers, aid development of diagnostic tools and identify new therapeutic targets for these common heritable neurological diseases.
The role of short tandem repeat DNA variation in the evolution of human psychological diversity. The proposed work addresses fundamental questions about human nature. It ties together the evolutionary processes that have shaped us as a species with the way our genes influence: our personalities, the way we think and how we behave. It introduces a novel approach to addressing questions about the role of genetics in human variation that will contribute substantially to the way we understand, perce ....The role of short tandem repeat DNA variation in the evolution of human psychological diversity. The proposed work addresses fundamental questions about human nature. It ties together the evolutionary processes that have shaped us as a species with the way our genes influence: our personalities, the way we think and how we behave. It introduces a novel approach to addressing questions about the role of genetics in human variation that will contribute substantially to the way we understand, perceive and manage important aspects of human diversity.Read moreRead less
Kingdom switching microbial pathogens: the bioinformatics of mutation in the genomes of viruses and bacteria affecting crops, livestock and people. Some organisms that cause infectious diseases have moved between plants and vertebrates, either recently or repeatedly over evolutionary time. Switching between plants and vertebrates strongly influences the way these microbes mutate and evolve. We will search the genomic sequence databases for information about how the choice of host influences muta ....Kingdom switching microbial pathogens: the bioinformatics of mutation in the genomes of viruses and bacteria affecting crops, livestock and people. Some organisms that cause infectious diseases have moved between plants and vertebrates, either recently or repeatedly over evolutionary time. Switching between plants and vertebrates strongly influences the way these microbes mutate and evolve. We will search the genomic sequence databases for information about how the choice of host influences mutations in viral and bacterial genomes and model the evolutionary processes involved. This project will advance our understanding of the fine structure of microbial genomes and the importance of selection pressures on genes. It will lead to better disease management strategies for humans, and for domestic crops and livestock.Read moreRead less
Molecular and genetic analysis of epigenetic components in a model plant. Australia is a major exporter of agricultural food crops thus producers must maintain their competitive advantage in order to compete on the world stage. Food crops unfortunately have large, complex genomes that are not sequenced and a generation time of months that makes research outcomes slow to achieve. This project proposes to utilise a model plant that has a small completely sequenced genome and a short generation tim ....Molecular and genetic analysis of epigenetic components in a model plant. Australia is a major exporter of agricultural food crops thus producers must maintain their competitive advantage in order to compete on the world stage. Food crops unfortunately have large, complex genomes that are not sequenced and a generation time of months that makes research outcomes slow to achieve. This project proposes to utilise a model plant that has a small completely sequenced genome and a short generation time making it ideal to study the fundamental biological process of RNA silencing. Discoveries and outcomes from this project may have the potential to benefit Australian crops, ecosystems and human health.Read moreRead less
Beyond the genome: unravelling the intricacies of epigenetic regulation using the honey bee model. Epigenetic mechanisms, such as DNA methylation, provide the interface between genome and environment. Abnormalities in epigenetic regulation lead to cancer and other diseases. The project will be using the alternative phenotypes in honeybees, fertile queens and sterile workers, to understand how dietary factors control conditional gene expression by methylation
CENTRE for INTEGRATIVE LEGUME RESEARCH. Legumes are essential for environmental sustainability and are important for maintaining human health. The Centre combines innovative genomic approaches to investigate the causal phenotypic links required for regulation of legume growth. The unique coexistence of multiple pluripotent meristems in shoots, roots, flowers and nodules permits the discovery of new paradigms governing legume architecture, reproductive differentiation and root-nodule developmen ....CENTRE for INTEGRATIVE LEGUME RESEARCH. Legumes are essential for environmental sustainability and are important for maintaining human health. The Centre combines innovative genomic approaches to investigate the causal phenotypic links required for regulation of legume growth. The unique coexistence of multiple pluripotent meristems in shoots, roots, flowers and nodules permits the discovery of new paradigms governing legume architecture, reproductive differentiation and root-nodule development. New knowledge of the plant growth processes through mechanistic analysis of organ induction provides the tools to optimise the legume's productivity, quality, and environment adaptation.Read moreRead less
ARC Centre of Excellence in Biotechnology and Development. The Centre will create a multidisciplinary research team focusing on the molecular mechanisms that drive the specification and differentiation of male germ cells. This research will improve our fundamental understanding of how complex regulatory networks control the expression of a complex phenotype, the spermatozoon. It will also create a platform of knowledge from which we can stimulate the growth of the Australian Biotechnology indust ....ARC Centre of Excellence in Biotechnology and Development. The Centre will create a multidisciplinary research team focusing on the molecular mechanisms that drive the specification and differentiation of male germ cells. This research will improve our fundamental understanding of how complex regulatory networks control the expression of a complex phenotype, the spermatozoon. It will also create a platform of knowledge from which we can stimulate the growth of the Australian Biotechnology industry, the protection of the Australian Environment and the well-being of the Australian people. Key issues for this Centre include testicular cancer, male infertility, contraception, pest animal control, environmental impacts on human health and gene pharming.Read moreRead less
Dissecting a RNA-histone variant interaction and its role in splicing. This project aims to define the molecular details of how a chromatin component, histone H2A.B, binds RNA and influences RNA splicing. This is unprecedented for histones, which are typically associated with DNA and transcriptional regulation. Over 90 per cent of human genes may be alternatively spliced. This explains how complex organisms develop from a limited set of genes, but how alternative splicing decisions are made is u ....Dissecting a RNA-histone variant interaction and its role in splicing. This project aims to define the molecular details of how a chromatin component, histone H2A.B, binds RNA and influences RNA splicing. This is unprecedented for histones, which are typically associated with DNA and transcriptional regulation. Over 90 per cent of human genes may be alternatively spliced. This explains how complex organisms develop from a limited set of genes, but how alternative splicing decisions are made is unclear. The intended outcome is to reveal links between chromatin, RNA splicing and gene expression regulation to explain how multicellular organisms have evolved. The translation of this knowledge will ultimately provide long-term economic and health benefits for Australia.Read moreRead less
Understanding how dynamic changes in chromatin composition control genome function. DNA is tightly packaged in eukaryotic cells as chromatin. Important genetic processes, such as transcription, require manipulation of chromatin structure to access the DNA. The cell sets up specialised chromatin structures to regulate these processes. Currently, precise molecular details of these specialised structures are limited. This project will push the envelope of an in vitro model chromatin system and dete ....Understanding how dynamic changes in chromatin composition control genome function. DNA is tightly packaged in eukaryotic cells as chromatin. Important genetic processes, such as transcription, require manipulation of chromatin structure to access the DNA. The cell sets up specialised chromatin structures to regulate these processes. Currently, precise molecular details of these specialised structures are limited. This project will push the envelope of an in vitro model chromatin system and determine the architecture of several chromatin states with unique functional implications inside the cell. This will unravel the molecular instructions that define how our genomes are organised, significantly advancing our knowledge of fundamental eukaryotic genome biology and paving the way for the future development of new tools and therapies.Read moreRead less
Genome-wide discovery of translation control mechanisms. This project aims to reveal currently unknown molecular details of protein synthesis, a step of gene expression that is central to all of life. To achieve this, innovative methods based on next-generation sequencing will be deployed in the yeast model organism. Yeasts are of importance as pathogens as well as in the food and biotechnology industry sector. Thus, new knowledge generated in this project will help solve problems of invasive pa ....Genome-wide discovery of translation control mechanisms. This project aims to reveal currently unknown molecular details of protein synthesis, a step of gene expression that is central to all of life. To achieve this, innovative methods based on next-generation sequencing will be deployed in the yeast model organism. Yeasts are of importance as pathogens as well as in the food and biotechnology industry sector. Thus, new knowledge generated in this project will help solve problems of invasive pathogenic behaviour and biomass production.Read moreRead less