Regulation Of Ca2+/calmodulin Dependent Protein Kinase Kinase-2 By Phosphorylation
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
This project will study the regulation of an enzyme called CaMKK2, which plays a pivotal role in controlling a number of important biological functions including brain development, regulation of appetite, energy metabolism and blood pressure. Understanding how this enzyme is regulated may open new avenues for treating Type 2 diabetes, obesity, and cardiovascular disease.
The dramatic increase in obesity and age-related metabolic disorders demonstrates the importance of gaining a better understanding of how cells and organisms regulate their energy stores. This project will identify novel molecular mechanisms that control the enzyme CaMKK2, which is a key regulator of whole-body energy metabolism. This will provide new opportunities to inform more effective strategies to tackle metabolic diseases, and improve health in an increasingly ageing population.
How protein tyrosine phosphatases select their substrates. Protein tyrosine phosphatases (PTPs) are enzymes that control the response of cells to divergent environmental stimuli. This project will determine how individual PTPs exert selective effects on cellular communication networks to coordinate organismal development, growth and survival.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100157
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Confocal and single molecule microscopes for systems microscopy. This project aims to establish Australia’s first system microscopy facility with dedicated live-cell confocal and single-molecule fluorescence microscopes. In systems microscopy, the imaging workflow is automated so that large and unbiased data sets of the spatiotemporal organisation of molecules and cells can be generated. Combined with statistical and bioinformatics analyses, image-derived data provides system-wide information th ....Confocal and single molecule microscopes for systems microscopy. This project aims to establish Australia’s first system microscopy facility with dedicated live-cell confocal and single-molecule fluorescence microscopes. In systems microscopy, the imaging workflow is automated so that large and unbiased data sets of the spatiotemporal organisation of molecules and cells can be generated. Combined with statistical and bioinformatics analyses, image-derived data provides system-wide information that is not easily obtainable with other approaches. The project will enable Australian researchers to image and analyse the full complexity of biological systems, potentially transforming cell biology, drug development and understanding the molecular basis of disease. It will also demonstrate how the capacity of microscopy facilities can be enhanced and bias in imaging data reduced by automating data acquisition and mining of image-based data.Read moreRead less
Mechanisms controlling enteroendocrine hormone secretion in human duodenum. This project aims to gain a deeper understanding of nutrient sensing pathways present in enteroendocrine cells within the human intestine. These cells control digestive function, blood glucose levels and food intake and are thus critical to digestion. This project will endeavour to be the first to assess the biology of human enteroendocrine cells and will use innovative approaches to deeply assess function from the level ....Mechanisms controlling enteroendocrine hormone secretion in human duodenum. This project aims to gain a deeper understanding of nutrient sensing pathways present in enteroendocrine cells within the human intestine. These cells control digestive function, blood glucose levels and food intake and are thus critical to digestion. This project will endeavour to be the first to assess the biology of human enteroendocrine cells and will use innovative approaches to deeply assess function from the level of the individual to isolated enteroendocrine cells.Read moreRead less
The role of phosphoinositides in endosomal maturation dynamics. This project aims to investigate the regulation of an intracellular compartment within a cell called endosomes, which plays critical roles in cellular homeostasis, signalling and pathogen entry. New knowledge is expected to be generated in understanding endosome maturation and the signalling events that drive this process using a unique, multidisciplinary approach combining state of the art imaging techniques and high throughput pro ....The role of phosphoinositides in endosomal maturation dynamics. This project aims to investigate the regulation of an intracellular compartment within a cell called endosomes, which plays critical roles in cellular homeostasis, signalling and pathogen entry. New knowledge is expected to be generated in understanding endosome maturation and the signalling events that drive this process using a unique, multidisciplinary approach combining state of the art imaging techniques and high throughput protein analysis. The anticipated outcomes will be to define the molecular steps that govern the membrane-bound machinery on endosomes that directs endosomal maturation. This should provide significant benefits in delineating a process that is linked to almost all aspects of cell life.Read moreRead less
Only recently has it emerged that our cells have a built-in backup mechanism that instructs cells to die in extreme cases, such as when viruses have hijacked a cell. A misfiring backup mechanism is thought to underlie a number of human diseases, including inflammatory disease. Our investigation will establish a starting point for the development of novel anti-inflammatory drugs.
Activation of invasion in Toxoplasma. Host cell invasion is critical for the establishment and maintenance of infection by the single-celled parasite Toxoplasma gondii, the causative agent of Toxoplasmosis. This project will use the latest molecular techniques to understand how invasion is activated and will define a new set of drug targets to treat Toxoplasmosis and related diseases.
Deciphering novel cross-talk between innate cytokine receptors. Understanding the basic functions of interferons, how they signal to cells, is central to understanding fundamental immunity. Interferons are crucial molecules of the immune system that are important for normal cell development and they protect the body from viral infection and cancer but can be deleterious in different autoimmune diseases and trauma settings. Preliminary Data shows there is a pathway of interferon signalling that h ....Deciphering novel cross-talk between innate cytokine receptors. Understanding the basic functions of interferons, how they signal to cells, is central to understanding fundamental immunity. Interferons are crucial molecules of the immune system that are important for normal cell development and they protect the body from viral infection and cancer but can be deleterious in different autoimmune diseases and trauma settings. Preliminary Data shows there is a pathway of interferon signalling that has previously been overlooked. This project aims to understand how this pathway works and how it contributes to the normal workings of cells. This fundamental science has future consequences for the design of vaccines and for the design of therapeutics to treat diseases that show defective interferon signalling.Read moreRead less
The role of dysregulated signalling by TORC1 in mitochondrial disease. The mitochondria are tiny subcellular compartments responsible for producing over 90 per cent of the cell's energy. Mitochondrial defects feature both in genetic diseases that directly affect the mitochondria and in most neurodegenerative diseases. These incurable diseases are expected to eclipse cancer as the second major cause of death worldwide by 2040. Using a simple model organism, Dictyostelium, previous research showed ....The role of dysregulated signalling by TORC1 in mitochondrial disease. The mitochondria are tiny subcellular compartments responsible for producing over 90 per cent of the cell's energy. Mitochondrial defects feature both in genetic diseases that directly affect the mitochondria and in most neurodegenerative diseases. These incurable diseases are expected to eclipse cancer as the second major cause of death worldwide by 2040. Using a simple model organism, Dictyostelium, previous research showed that dysregulated intracellular signalling by a cellular energy-sensing alarm protein is responsible for diverse cellular pathologies in mitochondrially diseased cells. This project will determine the role in these pathways of a second cellular stress-sensing protein complex, TORC1. New treatment possibilities may emerge.Read moreRead less