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
Discovery of novel microRNA biogenesis and functional components. Discovery of novel microRNA components will provide new strategies for confronting a diverse array of challenges Australia faces, such as the increasing rates of certain cancers in our population, to stresses on our crop plants faced with environmental changes. The biological mechanisms underlying these disparate problems are unified by microRNA involvement in many instances. By finding microRNA controlling factors common to all h ....Discovery of novel microRNA biogenesis and functional components. Discovery of novel microRNA components will provide new strategies for confronting a diverse array of challenges Australia faces, such as the increasing rates of certain cancers in our population, to stresses on our crop plants faced with environmental changes. The biological mechanisms underlying these disparate problems are unified by microRNA involvement in many instances. By finding microRNA controlling factors common to all higher organisms, we expect our community will benefit from the increased knowledge base that will help our researchers adopt new strategies in fighting diseases and improving our agricultural industry.Read moreRead less
The Cape honey bee and the origins of virgin birth. Using honeybees, the aim is to show how a mutation in a single gene creates a new species. This gene causes a shift from sexual to asexual reproduction, allowing workers to clone themselves (virgin birth), thus turning a formerly cooperative species into a social cancer. Observing a real-time speciation event driven by a single gene is an incredibly rare opportunity and enables this project to determine the socio-genetic mechanisms that reduce ....The Cape honey bee and the origins of virgin birth. Using honeybees, the aim is to show how a mutation in a single gene creates a new species. This gene causes a shift from sexual to asexual reproduction, allowing workers to clone themselves (virgin birth), thus turning a formerly cooperative species into a social cancer. Observing a real-time speciation event driven by a single gene is an incredibly rare opportunity and enables this project to determine the socio-genetic mechanisms that reduce gene flow between neighbouring populations and to explain how expression of the gene is regulated. Further, because clonal reproduction often leads to invasiveness in social insects - a dangerous outcome - understanding the origins of virgin birth is also critical to understanding invasiveness.Read moreRead less
The role of long non-coding RNAs in the epigenetic control of gene expression during endosperm development in plants. Elucidating the molecular events underlying the biology of seed development is important in both understanding plant development and in developing new methods to enhance the productivity and qualities of grain crops. In recent years it has become clear that various classes of non-coding RNAs have important roles in gene regulation. Of these non-coding RNAs, small RNAs (20-25 nucl ....The role of long non-coding RNAs in the epigenetic control of gene expression during endosperm development in plants. Elucidating the molecular events underlying the biology of seed development is important in both understanding plant development and in developing new methods to enhance the productivity and qualities of grain crops. In recent years it has become clear that various classes of non-coding RNAs have important roles in gene regulation. Of these non-coding RNAs, small RNAs (20-25 nucleotides) are beginning to be understood however less is known about the role and complexity of long non-coding RNAs. This project would identify new regulators of seed development that may lead to novel methods to increase grain yields, ultimately benefitting the Australian grains industry.Read moreRead less
New insights into female reproductive tract formation and tubulogenesis. Aims: This project aims to improve our understanding of female reproductive tract formation by studying its developmental origins. Most of the female reproductive tract derives from a pair of embryonic tubes called Müllerian ducts, the formation of which is incompletely understood. Significance: Using chicken and mouse models and innovative genetic approaches, the project will undercover novel genes and cellular pathways in ....New insights into female reproductive tract formation and tubulogenesis. Aims: This project aims to improve our understanding of female reproductive tract formation by studying its developmental origins. Most of the female reproductive tract derives from a pair of embryonic tubes called Müllerian ducts, the formation of which is incompletely understood. Significance: Using chicken and mouse models and innovative genetic approaches, the project will undercover novel genes and cellular pathways in Müllerian duct formation. Expected outcomes: This work will enhance knowledge in the biological sciences, in the area of female reproduction and how tubes form in biological systems. Benefits: It will train research scientists, develop collaborations and enhance Australia’s high standing in the field of reproduction.Read moreRead less
Endosymbiotic DNA transfer. Interorganellar DNA movement is a major force in evolution. In higher organisms, the prokaryotic ancestors of mitochondria and chloroplasts donated many genes to the nucleus. Plants have unique potential in studies of the mechanisms that have driven genome evolution. We established experimentally that DNA moves from the chloroplast to the nucleus at high frequency and this provided us with a world lead in this scientifically new area. The relocated genes contribute to ....Endosymbiotic DNA transfer. Interorganellar DNA movement is a major force in evolution. In higher organisms, the prokaryotic ancestors of mitochondria and chloroplasts donated many genes to the nucleus. Plants have unique potential in studies of the mechanisms that have driven genome evolution. We established experimentally that DNA moves from the chloroplast to the nucleus at high frequency and this provided us with a world lead in this scientifically new area. The relocated genes contribute to the number and diversity of genes and gene function. Genetically manipulated (GM) crops use the chloroplast compartment to make high levels of protein, necessitating a full understanding of how transgenes behave within the cellular and the external environment.Read moreRead less
Improved models to understand the genomic architecture of complex traits. This project aims to improve modelling of the genetics underlying complex traits. The project will develop and test models for using genome-wide genetic data to investigate how much heritability (genetic effect) underlies traits of interest, where it lies in the genome, and how much of it is shared across traits. The new models will be implemented in statistical algorithms in a freely-available software package. This proj ....Improved models to understand the genomic architecture of complex traits. This project aims to improve modelling of the genetics underlying complex traits. The project will develop and test models for using genome-wide genetic data to investigate how much heritability (genetic effect) underlies traits of interest, where it lies in the genome, and how much of it is shared across traits. The new models will be implemented in statistical algorithms in a freely-available software package. This project expects to increase understanding of biological mechanisms, the efficiency of genetic association analyses and the accuracy of genomic prediction, including the effects of interventions. The project will adapt human models to a wider range of organisms, in particular bacteria.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775763
Funder
Australian Research Council
Funding Amount
$189,000.00
Summary
High throughput orthogonal mass spectrometer for biotechnology research in WA. The new 'orthogonal' mass spectrometer will be housed at the WA State Agricultural Biotechnology Centre at Murdoch University (SABC). The SABC is a multi-user university centre that provides equal access for researchers from all universities, state government and industry to major facilities. The equipment will provide a competitive advantage to researchers undertaking fundamental and applied projects that underpin ....High throughput orthogonal mass spectrometer for biotechnology research in WA. The new 'orthogonal' mass spectrometer will be housed at the WA State Agricultural Biotechnology Centre at Murdoch University (SABC). The SABC is a multi-user university centre that provides equal access for researchers from all universities, state government and industry to major facilities. The equipment will provide a competitive advantage to researchers undertaking fundamental and applied projects that underpin new developments in plant and animal agriculture. Outcomes include: development of new molecular markers to speed crop improvement and quality, animal genetic improvement and health, and support for new biotechnology companies. This will benefit the community through more productive, competitive and sustainable agriculture.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100225
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Western Australia single-cell isolation and genomics preparation facility. This project aims to give Western Australian researchers direct access to new platforms in single-cell isolation and single-cell RNA, genome and exome sample library preparation, so they can participate in the precision single-cell based research driving biology worldwide. This project will give researchers access to single-cell analysis techniques, integrated with other analysis methods, microscopy, and preclinical imagi ....Western Australia single-cell isolation and genomics preparation facility. This project aims to give Western Australian researchers direct access to new platforms in single-cell isolation and single-cell RNA, genome and exome sample library preparation, so they can participate in the precision single-cell based research driving biology worldwide. This project will give researchers access to single-cell analysis techniques, integrated with other analysis methods, microscopy, and preclinical imaging. The characterisation of rare and complex biological samples is expected to advance effective, socio-economically important research programmes in cell and molecular biology, sports science, plant and crop sciences, agriculture, clean energy (biofuels) resources and production, greenhouse gas reduction, environmental microbiology and marine science.Read moreRead less
Evolution of the biofabrication of mineralized structures in animals. Shells and skeletons are produced by a wide range of animals. These highly-order crystalline structures are genetically-encoded and produce high-performance composite materials that exceed present capabilities in human engineering. This international collaboration will elucidate the molecular mechanisms controlling the fabrication of these architectures. This knowledge will contribute significantly to the development of materi ....Evolution of the biofabrication of mineralized structures in animals. Shells and skeletons are produced by a wide range of animals. These highly-order crystalline structures are genetically-encoded and produce high-performance composite materials that exceed present capabilities in human engineering. This international collaboration will elucidate the molecular mechanisms controlling the fabrication of these architectures. This knowledge will contribute significantly to the development of materials for advanced electronics and energy transducers, human bone therapeutics and marine-based products such as pearls and cements, through the identification of genes underlying biofabrication networks and the development of in vitro bioproduction systems.Read moreRead less