Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100004
Funder
Australian Research Council
Funding Amount
$540,000.00
Summary
An automated 3D electron microscopy facility. An automated 3D electron microscopy facility: The aim of this project is to establish the next generation of electron microscopy facility, with a fully automated tool enabling 3D imaging. The automated serial section system incorporated in a scanning electron microscope circumvents the limitation of transmission electron microscopy, which provides unique insights into molecular structures and cell components at high resolution, however, the area and ....An automated 3D electron microscopy facility. An automated 3D electron microscopy facility: The aim of this project is to establish the next generation of electron microscopy facility, with a fully automated tool enabling 3D imaging. The automated serial section system incorporated in a scanning electron microscope circumvents the limitation of transmission electron microscopy, which provides unique insights into molecular structures and cell components at high resolution, however, the area and volume are limited in size to a few microns. This new type of microscope can image whole organisms and be used by non-electron microscopists. It will be housed in an open access facility and will meet a growing demand for 3D electron microscopy.Read moreRead less
A unified model of amino acid homeostasis. This project aims to develop a unified model of amino acid homeostasis in mammalian cells and apply it to brain cells. The model will be underpinned by a mathematical algorithm that allows predicting amino acid levels in the cytosol based on fundamental parameters such as transport and metabolism. This project should provide the significant benefit of enabling the prediction of essential functions such as cell growth and survival.
Identifying The Critical Components Of Growth Factor-mediated Survival Pathways
Funder
National Health and Medical Research Council
Funding Amount
$589,338.00
Summary
The regulation of cell lifespan (cell survival) is controlled by growth factors and lies at the heart of all biological processes. However, little is known of the molecular switches inside cells that either turn survival on or off. We propose to identify and characterize the molecular switches inside cells that control the balance between cell survival and death. Targeting specific components of these switches may provide new approaches for the treatment of cancer and infectious diseases.
Sugars in the real world: are cultured cancer cells a good model system for studying protein glycosylation? It is challenging to study errors in metabolism in human beings, so researchers use cells grown in the laboratory to understand disease processes. This project will determine if cultured cells accurately reflect the real changes to cell surface sugars that occur in all cancers, and the effect of these changes on the invasive properties of colon cancer cells.
Identifying genes controlling the regulatory and metabolic interactions between the energy organelles of the leaf. Plant energy metabolism underlies the synthesis of many important products in crops, and subtle changes in metabolism can enhance key plant traits, such as germination rates, early seedling vigour, biomass/yield, and tolerance to harsh environments. Furthering our understanding on the complex interplay of genes controlling energy metabolism and its impact on leaf function has potent ....Identifying genes controlling the regulatory and metabolic interactions between the energy organelles of the leaf. Plant energy metabolism underlies the synthesis of many important products in crops, and subtle changes in metabolism can enhance key plant traits, such as germination rates, early seedling vigour, biomass/yield, and tolerance to harsh environments. Furthering our understanding on the complex interplay of genes controlling energy metabolism and its impact on leaf function has potential outcomes for smart genetic manipulation either by classical breeding or genetic transformation. There are more than 10,000 genes of unknown function in plant genomes and this represents a tremendous untapped resource for future Australian R&D outcomes and insights from this research proposal will have application to all plant-based agriculture.Read moreRead less
The function of the ribbon structure of the Golgi apparatus in vertebrates. The aim of the project is to determine the function of the Golgi ribbon structure in higher order cell functions, including metabolism, cell cycle, and cell polarity in both cultured cells and whole organisms. Understanding of the functions of the Golgi has been restricted to the regulation of glycosylation and membrane transport. However, it is now recognised that the Golgi apparatus feeds into the wiring of a range of ....The function of the ribbon structure of the Golgi apparatus in vertebrates. The aim of the project is to determine the function of the Golgi ribbon structure in higher order cell functions, including metabolism, cell cycle, and cell polarity in both cultured cells and whole organisms. Understanding of the functions of the Golgi has been restricted to the regulation of glycosylation and membrane transport. However, it is now recognised that the Golgi apparatus feeds into the wiring of a range of cellular networks in higher organisms such as cell polarisation, directed migration, metabolism and autophagy. Vertebrates have evolved mechanisms for joining individual Golgi stacks into a ribbon structure. The relevance of this ribbon structure remains a mystery. The project aims to answer this major question in cell biology.Read moreRead less
Regulating nutrient uptake in intracellular parasites. Parasites impose a major economic and medical burden on human societies. In order to grow and reproduce, parasites scavenge nutrients from their animal or human hosts. As they move within and between hosts they encounter different levels of nutrients; how they adapt to these differences is poorly understood. This project aims to investigate the mechanisms by which the model parasite Toxoplasma senses and responds to the nutrients in its envi ....Regulating nutrient uptake in intracellular parasites. Parasites impose a major economic and medical burden on human societies. In order to grow and reproduce, parasites scavenge nutrients from their animal or human hosts. As they move within and between hosts they encounter different levels of nutrients; how they adapt to these differences is poorly understood. This project aims to investigate the mechanisms by which the model parasite Toxoplasma senses and responds to the nutrients in its environment, thereby shedding light on how they adapt to the different environments that they inhabit and, in the longer term, informing novel treatment strategies that aim to limit the parasites’ nutrient supply.Read moreRead less
The selective elimination of mitochondria from yeast cells: regulation and molecular mechanism . For healthy cells the quality of the mitochondrion, the cellular power plant, must be maintained. The results of this research will contribute to an understanding of the molecular mechanism for the removal of mitochondria from the cell, and ultimately inspire strategies for the treatment of diseases that result from faulty mitochondria.
Molecular control of embryonic diapause. Many species can halt growth of the early embryo (diapause). This project will use novel animal models and new proteomics techniques to clarify what signals from the uterus control diapause of the embryo. This may uncover new mechanisms for cell regulation that will be relevant to the biology of stem cells, cancer and reproductive technologies.
Moonlighting from sugar to metal. This project intends to use integrated genetics, biochemistry and omics to decipher the roles of the highly conserved OST3 proteins, which have been implicated in the disparate functions of regulating protein glycosylation and transporting magnesium. The project plans to detail the role of OST3 proteins in regulating mammalian glycosylation and reconstruct the vertebrate co-evolutionary trajectory of OST3 protein–substrate interactions. It also aims to identify ....Moonlighting from sugar to metal. This project intends to use integrated genetics, biochemistry and omics to decipher the roles of the highly conserved OST3 proteins, which have been implicated in the disparate functions of regulating protein glycosylation and transporting magnesium. The project plans to detail the role of OST3 proteins in regulating mammalian glycosylation and reconstruct the vertebrate co-evolutionary trajectory of OST3 protein–substrate interactions. It also aims to identify and characterise the regulation, mechanisms and metabolic consequences of OST3 protein-mediated magnesium transport. These outcomes may provide insights into eukaryotic biology, and allow advances in engineered systems for glycoprotein production and modulating cellular metabolism with potential research and therapeutic utility.Read moreRead less