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