How do plant roots align nitrogen uptake to soil opportunities? Improved nitrogen use efficiency (NUE) in crop plants is required to achieve sustainable plant agriculture practices that maximise productivity while minimising nitrogen fertiliser-dependent pollution. Current high-input monoculture plant production systems suffer from poor NUE and can contribute to local and global nitrogen pollution outcomes. Improving how plants manage their nitrogen uptake will improve NUE and help support Aust ....How do plant roots align nitrogen uptake to soil opportunities? Improved nitrogen use efficiency (NUE) in crop plants is required to achieve sustainable plant agriculture practices that maximise productivity while minimising nitrogen fertiliser-dependent pollution. Current high-input monoculture plant production systems suffer from poor NUE and can contribute to local and global nitrogen pollution outcomes. Improving how plants manage their nitrogen uptake will improve NUE and help support Australian plant agriculture. This project will investigate novel technologies that re-engineer nitrate transport activity. The project will also investigate the biochemical and molecular links between nitrogen uptake on root development required for improved plant growth.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100282
Funder
Australian Research Council
Funding Amount
$475,181.00
Summary
Delivering breeding-oriented genetic tools for cereal disease resistance. This project will focus specifically on delivering the genetic tools to the industry partner to assist its wheat and barley breeders to increase the accuracy and efficiency of incorporating the durable wheat stripe rust disease and barley leaf rust disease resistance into their core germplasm collections, respectively. The expected outcomes will also contribute to filling our knowledge gap in understanding the cereal rust ....Delivering breeding-oriented genetic tools for cereal disease resistance. This project will focus specifically on delivering the genetic tools to the industry partner to assist its wheat and barley breeders to increase the accuracy and efficiency of incorporating the durable wheat stripe rust disease and barley leaf rust disease resistance into their core germplasm collections, respectively. The expected outcomes will also contribute to filling our knowledge gap in understanding the cereal rust innate immune system and benefit other cereal fungal pathosystems. The wide application of the expected outcomes from the proposed project will reduce the utilisation of fungicides and subsequently will subsequently contribute to the resilience of cereal crops and sustainable global food security.Read moreRead less