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Glutaredoxins (GRXs) as agents of redox homeostasis in mitochondria and respiratory-associated cell functions in plants. This project will test the importance of GRXs for the reduction/oxidation mediated network in plant mitochondria and moreover, uncover details of their dynamic features. This knowledge builds the basis for manipulation of mitochondrial GRXs in order to enhance the capability of the plant to cope with naturally occurring stresses.
Defence gene expression in Arabidopsis linked to metabolic perturbation and oxidative signalling via dsr1. Through analysis of a novel pathway of how plants perceive pathogens in the environment, this project aims to link metabolic energy generation pathways with pathogen defence. This could provide novel approaches for protect plants from pathogens by altering the sensitivity of this signalling pathway.
Dissecting novel roles of succinate dehydrogenase in stomatal aperture and root elongation in plants. Succinate dehydrogenase (complex II) is part of the respiration processes in plants and new evidence shows that reactive oxygen species generated by it can influence plant development and stress tolerance. However, there are still many unanswered questions about the composition and function of this enzyme and its dual roles in plants. This project will study this protein complex in the model p ....Dissecting novel roles of succinate dehydrogenase in stomatal aperture and root elongation in plants. Succinate dehydrogenase (complex II) is part of the respiration processes in plants and new evidence shows that reactive oxygen species generated by it can influence plant development and stress tolerance. However, there are still many unanswered questions about the composition and function of this enzyme and its dual roles in plants. This project will study this protein complex in the model plant Arabidopsis and the crop plant rice, identify its role in signalling in depth to provide knowledge adding development of strategies for improving tolerance of crops to stresses.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100307
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Determining organellar gene expression in distinct cell types: a missing piece of the puzzle for the transfer of C4 photosynthesis into C3 plants. Enhancing photosynthesis in plants will boost yields in essential food crops, such as rice, and thus offers significant implications for satisfying an increasing global demand for food. This project will investigate the photosynthetic mechanisms that exist in known high performing crops, for application in plants used in adverse climates.
Functional analysis of novel mitochondrial outer membrane proteins in Arabidopsis. Mitochondria play central roles in the life and death of cells. This project will characterise the functions of proteins on the mitochondrial surface, which mediate signals that define mitochondrial function, providing novel approaches to modify mitochondrial function and plant growth.
Plant microRNA systems: investigating slicing versus translational repression and the development of an anti-viral defence mechanism. The ability to specifically switch off genes has revolutionised biotechnological approaches, from fighting diseases to developing superior crops, however the underlying mechanism is poorly understood, limiting its application in practice. Outcomes from this project will provide such knowledge, allowing its precise use in diverse applications.
Deciphering organelle transport mechanisms in plants. Plant growth, productivity and seed yield all depend on organelle function which requires metabolites and proteins
to be transported across membranes. This mechanism of transport is carried out by specific transporters that have
the ability to transport macromolecules, and regulate organelle function. We have identified new transporters that
are involved in amino acid and protein transport in the mitochondria, chloroplast and peroxisomes. We ....Deciphering organelle transport mechanisms in plants. Plant growth, productivity and seed yield all depend on organelle function which requires metabolites and proteins
to be transported across membranes. This mechanism of transport is carried out by specific transporters that have
the ability to transport macromolecules, and regulate organelle function. We have identified new transporters that
are involved in amino acid and protein transport in the mitochondria, chloroplast and peroxisomes. We will assign
function to each protein and investigate the importance in regulating organelle biogenesis. This will allow us to
modulate plant energy production for optimal growth and to withstand abiotic stress, all of which have
agriculturally beneficial consequences. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100825
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Characterization of Novel Import/Assembly Pathways in Plant Mitochondria. In addition to their central role in metabolism, plant mitochondria have emerged as important hubs for both sensing and responding to a variety of stimuli. However, as yet there are still many unanswered basic questions about how mitochondria are built in plant cells. This project aims to characterise two novel protein import/assembly pathways, specifically, the newly identified twin-arginine translocation (Tat) protein as ....Characterization of Novel Import/Assembly Pathways in Plant Mitochondria. In addition to their central role in metabolism, plant mitochondria have emerged as important hubs for both sensing and responding to a variety of stimuli. However, as yet there are still many unanswered basic questions about how mitochondria are built in plant cells. This project aims to characterise two novel protein import/assembly pathways, specifically, the newly identified twin-arginine translocation (Tat) protein assembly pathway, and the disulphide relay system of the mitochondrial intermembrane space which displays unique characteristics compared to other systems. A mechanistic understanding of these pathways can be used to design novel strategies to alter plant growth and performance.Read moreRead less
The use of molecular sponges to inhibit small Ribonucleic acid activity in plants. The deletion of gene activity is the most powerful way to understand gene function; however for genes encoding small Ribonucleic acids (RNAs) no current methodology can efficiently achieve this. Here, we aim to develop a gene silencing technology for small RNA encoding genes, which can be utilised to determine their function and used for biotechnological applications.
Discovery Early Career Researcher Award - Grant ID: DE170100346
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Improving salt tolerance by optimising ion transport in chloroplasts. This project aims to discover the ion transport mechanisms and their molecular origins in chloroplasts that differentiate halophytes from glycophytes, allowing halophytes to optimise photosynthesis during salt stress. Yield losses in crop plants are linked to the effects of salt stress on their chloroplasts, but some plants maintain growth and yield irrespective of high soil salinity. This project will use biophysics to charac ....Improving salt tolerance by optimising ion transport in chloroplasts. This project aims to discover the ion transport mechanisms and their molecular origins in chloroplasts that differentiate halophytes from glycophytes, allowing halophytes to optimise photosynthesis during salt stress. Yield losses in crop plants are linked to the effects of salt stress on their chloroplasts, but some plants maintain growth and yield irrespective of high soil salinity. This project will use biophysics to characterise mutants deficient in targeted chloroplast transporters, comparing a model glycophyte and closely related halophyte. The expected outcome of these fundamental molecular is salt-tolerant crop plants.Read moreRead less