Comparative toxicology of a fumigant and gasotransmitters: Testing a new model of fumigant toxicity in Caenorhabditis elegans. Fumigants share physical, chemical and functional properties with a medically important class of signalling molecules called gasotransmitters. This project proposes that the toxicity of fumigants is directly caused by their ability to mimic and disrupt gasotransmitter signalling. This project will test this hypothesis using the fumigant phosphine, a chemical that protect ....Comparative toxicology of a fumigant and gasotransmitters: Testing a new model of fumigant toxicity in Caenorhabditis elegans. Fumigants share physical, chemical and functional properties with a medically important class of signalling molecules called gasotransmitters. This project proposes that the toxicity of fumigants is directly caused by their ability to mimic and disrupt gasotransmitter signalling. This project will test this hypothesis using the fumigant phosphine, a chemical that protects the vast majority of the world grain supply from insect pests. This work will show us what makes a fumigant toxic. This knowledge will facilitate the discovery and effective deployment of new fumigants.Read moreRead less
REdefining metabolic Schemes and Pathways In plant leaf REspiration. Leaf respiration-related metabolism in terrestrial vegetation liberates considerable amounts of carbon dioxide, ammonia and hydrogen sulphide into the atmosphere. Such gaseous losses are detrimental to biomass production but respiration also sustains nutrient assimilation and biosyntheses. This project aims to describe flux patterns in respiratory metabolism and disentangle interactions with other pathways such as photorespirat ....REdefining metabolic Schemes and Pathways In plant leaf REspiration. Leaf respiration-related metabolism in terrestrial vegetation liberates considerable amounts of carbon dioxide, ammonia and hydrogen sulphide into the atmosphere. Such gaseous losses are detrimental to biomass production but respiration also sustains nutrient assimilation and biosyntheses. This project aims to describe flux patterns in respiratory metabolism and disentangle interactions with other pathways such as photorespiration and nitrogen assimilation. It will exploit stable isotopes to quantify metabolic partitioning and show coordination between major processes. It will establish key mechanisms by which respiration dictates plant carbon balance and contributes to identifying metabolic bottle-necks in plant primary production.Read moreRead less