Population growth and climate change mean that food security is an emerging global challenge. Crop loss due to flood, drought and other weather extremes is something that disproportionately affects the world's poor, but also has widespread international impact. There is an immediate and urgent need to develop tools and strategies to improve crop tolerance to such abiotic stress.
One effective mechanism towards this goal is molecular engineering of crops to withstand prolonged abiotic stress. Group VII Ethylene Response transcription Factors (ERF-VIIs) have a key role in plant stress tolerance, in particular flooding but also salinity, high temperature, drought and oxidative stress. ERF-VIIs are readily degraded, but their stabilisation has led to improved flood tolerance in model plants and crops. Consequently, ERF-VIIs are focal points for engineering abiotic stress resistance in crops.
ERF-VII degradation is triggered by the action of Plant Cysteine Oxidase enzymes (PCOs). These enzymes are oxygen-dependent; this means that ERF-VIIs are degraded in the presence of oxygen, but stabilised upon reduced oxygen availability, as is the case when plants become flooded. Manipulation of PCO activity is therefore a feasible mechanism to increase ERF-VII stability. However, complete and permanent inhibition of PCO function is detrimental to plant health, likely because of a role for these enzymes in other biological pathways. My team is therefore seeking to target PCO activity in a very specific manner. We are pursuing both chemical inhibition of PCO function which can be applied in a temporary manner, and targeted engineering of PCO function to change its oxygen sensitivity and/or substrate selectivity. This requires a detailed knowledge of the structure and function of these enzymes. Furthermore we are trying to understand confounding factors which can influence PCO-mediated ERF-VII degradation, for example the influence of reactive oxygen and reactive nitrogen species. With this knowledge in hand we can generate PCO variants with altered properties which result in improved flood tolerance. We will validate these biochemically before introducing them into model plants and crops.