TraitCapture: Genomic modelling for plant phenomics under environmental stress. This project aims to develop software to integrate new hyper-spectral and 3D growth models of plant phenomics with population genomics to identify heritable developmental traits across varied environments. Genome wide association studies aim to then be used to identify causal genes. Functional structural plant models incorporating genetic variation will be used to predict growth under simulated stress environments. ....TraitCapture: Genomic modelling for plant phenomics under environmental stress. This project aims to develop software to integrate new hyper-spectral and 3D growth models of plant phenomics with population genomics to identify heritable developmental traits across varied environments. Genome wide association studies aim to then be used to identify causal genes. Functional structural plant models incorporating genetic variation will be used to predict growth under simulated stress environments. The research team unites international industry, the Australian Plant Phenomics Facility, and university statistical geneticists. TraitCapture software will use open standards applicable to both controlled and field environments enabling plant breeders to pre-select adaptive traits to increase crop productivity under environmental stress.Read moreRead less
Digging deeper to improve yield stability. This project aims to provide innovative breeding solutions that harness the ‘hidden’ part of the plant, roots, to support the development of more productive crops in the face of climate variability. The project expects to generate new insights into the biology and genetics of root development in barley, a model cereal crop, by applying cutting-edge genome editing, phenotyping and genomics technologies. Anticipated outcomes include novel methodologies to ....Digging deeper to improve yield stability. This project aims to provide innovative breeding solutions that harness the ‘hidden’ part of the plant, roots, to support the development of more productive crops in the face of climate variability. The project expects to generate new insights into the biology and genetics of root development in barley, a model cereal crop, by applying cutting-edge genome editing, phenotyping and genomics technologies. Anticipated outcomes include novel methodologies to accelerate breeding for diverse production environments, with direct applications in barley, and other major cereals including wheat and oats. This should provide significant economic and social benefits to the Australian grains industry through yield stability amidst climate variability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101748
Funder
Australian Research Council
Funding Amount
$410,716.00
Summary
Discovering hidden control elements for crop improvement. Sustainable, productive agricultural processes are essential for tackling the challenges of tomorrow’s world. The ability to optimise beneficial agricultural traits depends on the precise control of genes in a crop plant’s enormous genome. Yet, identifying valuable gene control regions is like looking for needles in a haystack. The location of these regions is often not obvious and current detection technologies are impractically expensiv ....Discovering hidden control elements for crop improvement. Sustainable, productive agricultural processes are essential for tackling the challenges of tomorrow’s world. The ability to optimise beneficial agricultural traits depends on the precise control of genes in a crop plant’s enormous genome. Yet, identifying valuable gene control regions is like looking for needles in a haystack. The location of these regions is often not obvious and current detection technologies are impractically expensive and intensive. This project aims to develop a new technology that is expected to facilitate rapid and cost-effective discovery of all the control regions in a genome, enhancing our understanding of crop genomes and unlocking new avenues for agricultural improvement, food security and economic stability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100460
Funder
Australian Research Council
Funding Amount
$380,000.00
Summary
Role of DNA methylation in response to low nutrient availability in plants. DNA methylation (mC) is a covalent modification of DNA essential for the establishment and maintenance of correct gene expression patterns and recently suggested to be responsive to some environmental cues in plants. Using cutting edge technologies, this project aims to identify nutrient stress-induced mC changes and investigate the role that these changes may play in transcriptional regulation, as well as assessing whet ....Role of DNA methylation in response to low nutrient availability in plants. DNA methylation (mC) is a covalent modification of DNA essential for the establishment and maintenance of correct gene expression patterns and recently suggested to be responsive to some environmental cues in plants. Using cutting edge technologies, this project aims to identify nutrient stress-induced mC changes and investigate the role that these changes may play in transcriptional regulation, as well as assessing whether these changes can be transmitted to the next generation to confer intergenerational stress responsiveness. Altogether this project aims to provide fundamental knowledge of the role of mC in plant gene regulation and stress response as well as paving the way for the next generation of novel crop-improvement strategies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100249
Funder
Australian Research Council
Funding Amount
$391,743.00
Summary
Molecular systems biology of novel flower colour evolution. This project aims to discover new and potentially useful structural and regulatory genes while advancing knowledge of the chemical, genetic and ecological basis of unique evolutionary flower colour shifts. Dramatic shifts in floral colour is widespread in flowering plants, however, just how changes in flower colour occur remains poorly understood. This project will take advantage of unique Australian plants to investigate the molecular ....Molecular systems biology of novel flower colour evolution. This project aims to discover new and potentially useful structural and regulatory genes while advancing knowledge of the chemical, genetic and ecological basis of unique evolutionary flower colour shifts. Dramatic shifts in floral colour is widespread in flowering plants, however, just how changes in flower colour occur remains poorly understood. This project will take advantage of unique Australian plants to investigate the molecular mechanisms and evolutionary shift in flower colour changes. This project expects to advance knowledge on plant specialised metabolism with potential contributions to the floriculture, food and flavour industries.Read moreRead less
Unique epigenetic states in plant stem cell niches for safeguarding genome integrity. Plant stem cells are the foundation cells of all plant growth and development, including generation of the reproductive cells. Therefore, it is critical that stem cells defend against attacks that may damage the genome. A unique epigenetic state in plant stem cell niches has been discovered that may protect the genome from damage due to parasitic DNA elements. Using sophisticated genomics, genetics, and cellula ....Unique epigenetic states in plant stem cell niches for safeguarding genome integrity. Plant stem cells are the foundation cells of all plant growth and development, including generation of the reproductive cells. Therefore, it is critical that stem cells defend against attacks that may damage the genome. A unique epigenetic state in plant stem cell niches has been discovered that may protect the genome from damage due to parasitic DNA elements. Using sophisticated genomics, genetics, and cellular technologies, this project will investigate how stem cell epigenetic state is linked to genome defence, how environmental stresses can disrupt the defence system, and the role of the system in driving new genetic diversity. This knowledge is of high importance as agricultural crops enter an era of increasingly challenging conditions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100239
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
Small biological molecule tissue imaging mass spectrometry facility for Western Australia for spatial metabolomics and lipidomics. This tissue imaging facility for Western Australia will provide researchers with access to much needed instrumentation. The facility will support major research efforts in key disciplines, including agriculture and animal science, fisheries and medical science.
The roles and regulators of new plant cells linked to root transport. Plant genomics has moved to the single cell resolution, allowing precise investigations of previously hidden cell types and cell states that respond to environmental stress and that vary among differentially adapted plant populations. Here, we will extend our pioneering efforts that have mapped and discovered novel root cell types, to determine their salt and nutrient stress responses, and to elegantly dissect the underling ca ....The roles and regulators of new plant cells linked to root transport. Plant genomics has moved to the single cell resolution, allowing precise investigations of previously hidden cell types and cell states that respond to environmental stress and that vary among differentially adapted plant populations. Here, we will extend our pioneering efforts that have mapped and discovered novel root cell types, to determine their salt and nutrient stress responses, and to elegantly dissect the underling causal genetic variation. The unique cell markers and regulatory networks will be validated with tissue specific and transgenic tools that can work across a host of plant species to reveal adaptive cellular responses to harsh environmental conditions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100086
Funder
Australian Research Council
Funding Amount
$850,000.00
Summary
A Single-Molecule Super-Resolution Microscopy Facility in Western Australia. A single-molecule super-resolution microscopy facility in Western Australia:
The project aims to establish a facility combining single-molecule imaging with super-resolution microscopy to enable biologists in Western Australia to resolve and directly observe interacting macromolecules in plants, animals and organisms, Interacting macromolecules form the basis of cell biology. Imaging and characterising such interaction ....A Single-Molecule Super-Resolution Microscopy Facility in Western Australia. A single-molecule super-resolution microscopy facility in Western Australia:
The project aims to establish a facility combining single-molecule imaging with super-resolution microscopy to enable biologists in Western Australia to resolve and directly observe interacting macromolecules in plants, animals and organisms, Interacting macromolecules form the basis of cell biology. Imaging and characterising such interactions in living cells and tissues has become possible with the latest molecular imaging techniques and super-resolution optical microscopy (with spatial resolutions of 20 nanometres or better). The facility seeks to advance science across diverse regional priorities in agriculture, environment, marine ecology, medicine and health.Read moreRead less
Deciphering the regulation and function of the epigenome in eukaryotic development and stress response. The epigenome is an additional regulatory code superimposed upon plant and animal genomes that controls how they operate. This project will aim to understand the information encoded in the epigenome and how it changes in development and environmental stress, enabling manipulation of its function in crops and correction of its dysfunction in disease.