Engineering the defence-vigour balance for increased crop yield. This project aims to investigate a novel hypothesis to increase seed yield and vigour. Translating from a model system it will test whether the deliberate inactivation of a gene in tomato and banana, by RNA interference or genome editing, enhances performance. A dysfunctional gene in the viral defence pathway of the model plant species N. benthamiana boosted its seed yield and vigour. This project will investigate the enhancement, ....Engineering the defence-vigour balance for increased crop yield. This project aims to investigate a novel hypothesis to increase seed yield and vigour. Translating from a model system it will test whether the deliberate inactivation of a gene in tomato and banana, by RNA interference or genome editing, enhances performance. A dysfunctional gene in the viral defence pathway of the model plant species N. benthamiana boosted its seed yield and vigour. This project will investigate the enhancement, determine the consequences to the plant's defences, measure the balance between defence and vigour, and examine the risk of disease to such yield-enhanced crops. This is a radical departure from conventional approaches to crop improvement but if successful would provide an additional solution to the problem of future food security.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