Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100239
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
Small biological molecule tissue imaging mass spectrometry facility for Western Australia for spatial metabolomics and lipidomics. This tissue imaging facility for Western Australia will provide researchers with access to much needed instrumentation. The facility will support major research efforts in key disciplines, including agriculture and animal science, fisheries and medical science.
Re-engineering rice root architecture to maximise water use efficiency. This project aims to discover gene networks responsible for producing deeper and more branched roots in rice plants. The roots of plants are the primary mechanism for absorbing water and nutrients from the soil. Manipulating roots to penetrate deeper with greater branching allows plants to thrive with less water and less nutrients. The project will identify key genes and proteins responsible for this process, and alter their ....Re-engineering rice root architecture to maximise water use efficiency. This project aims to discover gene networks responsible for producing deeper and more branched roots in rice plants. The roots of plants are the primary mechanism for absorbing water and nutrients from the soil. Manipulating roots to penetrate deeper with greater branching allows plants to thrive with less water and less nutrients. The project will identify key genes and proteins responsible for this process, and alter their expression in order to assess the role of these regulatory elements in root development in rice plants. The project expects to provide new, more sustainable varieties of rice which will help provide enhanced food security.Read moreRead less
Defining factors that influence protein turnover in plants. This project aims to discover how the functions of different proteins change as they age, and to define factors that dictate protein stability inside plants. This project will change protein turnover rates in plants by altering a regulator of this process to assess the role of this regulator in different plant developmental transitions. Expected outcomes include showing how protein abundance can be altered in plants for our future agric ....Defining factors that influence protein turnover in plants. This project aims to discover how the functions of different proteins change as they age, and to define factors that dictate protein stability inside plants. This project will change protein turnover rates in plants by altering a regulator of this process to assess the role of this regulator in different plant developmental transitions. Expected outcomes include showing how protein abundance can be altered in plants for our future agricultural and biotechnology needs. This will provide significant benefits, such as discovering processes inside plant cells that maintain the quality of different kinds of proteins and propose how different kinds of proteins can be stabilised for plant biotechnology applications.Read moreRead less
Transport systems that underpin nitrogen efficient maize. This project aims to define the nitrogen transport network involved in the uptake, storage and redistribution of inorganic nitrogen (nitrate and ammonium) over the developmental life cycle of maize. This information will provide novel insight into the genetic control of nitrogen use in maize and other cereal crops.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100008
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Laser microdissection microscopy system for cell and development biology. The University of Newcastle has invested heavily in its biological and life sciences to create a research nexus focusing on national research priorities in biotechnology and environmental protection. The live cell laser microdissection platform will be utilised by scientists researching such strategically important areas as developmental biology, intracellular signalling cascades, cell cycle dynamics, plant development and ....Laser microdissection microscopy system for cell and development biology. The University of Newcastle has invested heavily in its biological and life sciences to create a research nexus focusing on national research priorities in biotechnology and environmental protection. The live cell laser microdissection platform will be utilised by scientists researching such strategically important areas as developmental biology, intracellular signalling cascades, cell cycle dynamics, plant development and microbiology. Moreover, this component of the University's research portfolio plays a major role in the postgraduate training of young Australian scientists who will, in turn, fuel future developments in both the life sciences and biotechnology industries.Read moreRead less
What is the function of gamma-aminobutyric acid-gated anion channels in plants? The project will identify the molecular basis of gamma-aminobutyric acid (GABA) signalling in plants. This is significant because GABA regulates proteins that release molecules involved in root-soil interactions, growth, and fertilisation. The project's discoveries will allow improvement of these agronomic traits that ultimately determine crop yield.
Functional network analysis of plant metabolism in response to salinity and temperature through targeted proteomics. This project will measure changes in plant metabolism and provide methods and a pipeline for quantification and modelling. It will assess nitrogen linked metabolism under environmental stress experienced in Australian wheat cropping systems and build fundamental knowledge of changes in networks of nitrogen metabolism in model plants.
A signalling pathway for future crop improvement. This project aims to decipher a mechanism that controls plant gas exchange – the process that emits oxygen, loses water, absorbs carbon dioxide and is essential for plant growth for food, fibre and fuel production. When plants encounter stressful conditions such as drought, high temperatures or flooding, they adapt their physiology to maintain viability and re-establish growth. This project will manipulate stress-induced gamma-aminobutyric acid’s ....A signalling pathway for future crop improvement. This project aims to decipher a mechanism that controls plant gas exchange – the process that emits oxygen, loses water, absorbs carbon dioxide and is essential for plant growth for food, fibre and fuel production. When plants encounter stressful conditions such as drought, high temperatures or flooding, they adapt their physiology to maintain viability and re-establish growth. This project will manipulate stress-induced gamma-aminobutyric acid’s capacity to control plant gas exchange to help secure future food production, through improving crop tolerance to stresses such as low water availability and high temperatures – conditions associated with a changing Australian climate.Read moreRead less
Dissecting chloride transport in plants to secure an untapped source for improving plant productivity. Chloride and nitrate are central to physiological processes that determine crop yield and food production, but their uptake and transport within the plant body are antagonistic. This project will gain a fundamental understanding of the mechanisms underlying this antagonism. This will provide new tools for improving salinity tolerance and the efficiency of fertiliser use, which can be used for t ....Dissecting chloride transport in plants to secure an untapped source for improving plant productivity. Chloride and nitrate are central to physiological processes that determine crop yield and food production, but their uptake and transport within the plant body are antagonistic. This project will gain a fundamental understanding of the mechanisms underlying this antagonism. This will provide new tools for improving salinity tolerance and the efficiency of fertiliser use, which can be used for the development of new crop varieties. Improving these traits will be essential if we are to successfully address the threats to Australian and global food security posed by salinity, and the rising economic and environmental costs of inefficient fertiliser use.Read moreRead less
Cell wall invertase regulates fruit and seed development through sugar signals, sugar transporters and plasmodesmal gating. This project seeks to understand the molecular and cellular events controlling carbohydrate allocation in fruit and seed by focusing the coupling between sugar metabolism and transport using tomato as a model. The information generated may provide technological opportunities to improve fruit and seed development hence, crop yield.