The Australian Research Data Commons (ARDC) invites you to participate in a short survey about your
interaction with the ARDC and use of our national research infrastructure and services. The survey will take
approximately 5 minutes and is anonymous. It’s open to anyone who uses our digital research infrastructure
services including Reasearch Link Australia.
We will use the information you provide to improve the national research infrastructure and services we
deliver and to report on user satisfaction to the Australian Government’s National Collaborative Research
Infrastructure Strategy (NCRIS) program.
Please take a few minutes to provide your input. The survey closes COB Friday 29 May 2026.
Complete the 5 min survey now by clicking on the link below.
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
Unique parental epitranscriptome states regulate seed development. This project aims to investigate how developing central cell epitranscriptomes are linked to seed growth, how the cell regulates the unique epigenetic states, and the role of the system in driving phenotypic diversity. Maternal and paternal effects determine growth and development of multicellular angiosperm plants. Previous work has discovered unique ribonucleic acid (RNA) epitranscriptome states dependent on the parent-of-origi ....Unique parental epitranscriptome states regulate seed development. This project aims to investigate how developing central cell epitranscriptomes are linked to seed growth, how the cell regulates the unique epigenetic states, and the role of the system in driving phenotypic diversity. Maternal and paternal effects determine growth and development of multicellular angiosperm plants. Previous work has discovered unique ribonucleic acid (RNA) epitranscriptome states dependent on the parent-of-origin in developing central cell that gives rise to the endosperm tissue of the seed that impacts on growth of the seed. This project expects to provide economic benefits by increasing yield of agricultural crops during increasingly challenging conditions.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
Australian Laureate Fellowships - Grant ID: FL160100155
Funder
Australian Research Council
Funding Amount
$2,715,383.00
Summary
Harmonising genes for modern agriculture. Harmonising genes for modern agriculture. This project aims to fully understand how a plant distinguishes self from non-self genes and to develop ways of precisely enhancing, repairing, updating, and/or redirecting genetic traits in harmony with the genome. The world’s food security relies on modern crops that are continually updated with genetic traits for higher yield and protection against changing environmental stresses. A crop plant’s genes determin ....Harmonising genes for modern agriculture. Harmonising genes for modern agriculture. This project aims to fully understand how a plant distinguishes self from non-self genes and to develop ways of precisely enhancing, repairing, updating, and/or redirecting genetic traits in harmony with the genome. The world’s food security relies on modern crops that are continually updated with genetic traits for higher yield and protection against changing environmental stresses. A crop plant’s genes determine its growth, development, survival and agronomic fitness. The ability to precisely edit genes in crop plants is tantalizingly close but significant barriers must be overcome. Anticipated outcomes are safer, higher yielding and more sustainable crops.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
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.
The hunt for Ribonucleic Acid riboswitches and genetic sensors of metabolic flux in plants. Ribonucleic Acid (RNA) contains both structural and sequence information that coordinates feedback of metabolic processes in response to environmental change, thereby promoting cellular adaptation and survival. This project will discover ancient RNA modules and structural switches in plants that sense chemical reactions and regulate pathway flux.
Towards genome methylation based crop improvement. Deoxyribonucleic acid (DNA) methylation is a form of genetic control that regulates crop performance and the crop's response to the environment. Improving understanding of the inheritance of methylation in relation to crop performance will provide the basis for methylation based breeding for climate resilient crops.