Decision-making modules in protein interaction networks. This project aims to discover how cells use proteins to make decisions. This is important for all living things, which must react to stimuli to grow, adapt, defend themselves and to die. The project’s anticipated outcome is the systems-level identification of decision-making modules in an intracellular network. Its focus is on the smallest possible modules, which contain a decision-making protein with two modifications that control protein ....Decision-making modules in protein interaction networks. This project aims to discover how cells use proteins to make decisions. This is important for all living things, which must react to stimuli to grow, adapt, defend themselves and to die. The project’s anticipated outcome is the systems-level identification of decision-making modules in an intracellular network. Its focus is on the smallest possible modules, which contain a decision-making protein with two modifications that control protein-proteins interactions. It will investigate two recurrent decision-making modules. The expected benefits of the project include new means to decipher biological complexity, and targets to modulate biosystems by genome editing or with drugs.Read moreRead less
The role and regulation of protein methylation: a study using the recently developed methylation network of yeast. Tiny changes to proteins, such as methylation, can alter the way they interact with other proteins. This project will investigate the dynamics of protein methylation during the life of the yeast cell. The project results will be of long term relevance to situations where we may want to stop cells dividing, such as cancer or infectious disease.
The effect of methylation and phosphorylation on ribosome function. This project aims to discover how cells regulate ribosome function and selectivity, by modifying their ribosomal proteins. This affects protein synthesis, a process which is central to the growth of all living things. Expected outcomes include new knowledge on the regulation of protein synthesis, improved techniques for the study of this process and an enhanced capacity for international collaboration. New avenues for the artifi ....The effect of methylation and phosphorylation on ribosome function. This project aims to discover how cells regulate ribosome function and selectivity, by modifying their ribosomal proteins. This affects protein synthesis, a process which is central to the growth of all living things. Expected outcomes include new knowledge on the regulation of protein synthesis, improved techniques for the study of this process and an enhanced capacity for international collaboration. New avenues for the artificial regulation of the ribosome may also emerge, relevant to synthetic biology and the engineering of industrial yeasts. The project should provide significant new findings for the research community, generate research citations and contribute to a highly skilled workforce by the training of staff and students.Read moreRead less
Does phosphorylation regulate the methylation of proteins? . The interaction of proteins is a fundamental requirement of life. Tiny switches on proteins affect how they interact but little is known about how these are controlled. This project will study the complex interplay between two types of switches; one is expected to control the other. This will provide new insights into how the cell functions.
Discovery Early Career Researcher Award - Grant ID: DE150100019
Funder
Australian Research Council
Funding Amount
$352,000.00
Summary
Protein network regulation: A systems-level analysis of methylation. The systems-level analysis of protein-protein interaction networks is a vital new framework for exploring protein complex formation. However key studies into the dynamics of these networks are being precluded by a lack of broad-scale data on interactions mediated by post-translational modifications, which are known regulators of protein-protein interactions. To solve this problem, this project aims to conduct an organism-wide s ....Protein network regulation: A systems-level analysis of methylation. The systems-level analysis of protein-protein interaction networks is a vital new framework for exploring protein complex formation. However key studies into the dynamics of these networks are being precluded by a lack of broad-scale data on interactions mediated by post-translational modifications, which are known regulators of protein-protein interactions. To solve this problem, this project aims to conduct an organism-wide survey of interactions mediated by an important class of post-translational modification, methylation, using an innovative mass spectrometry-based workflow. This project aims to produce fundamental new insights into the mechanisms underlying protein-protein interaction network dynamics, and into how protein complexes are formed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100204
Funder
Australian Research Council
Funding Amount
$550,000.00
Summary
A systems biology capability for the Ramaciotti Centre for Genomics. A systems biology capability for the Ramaciotti Centre for Genomics:
The project aims to introduce a complete systems biology capability to the Ramaciotti Centre for Genomics. This is intended to provide a complete systems biology workflow, including improved data analysis for next-generation sequencing, tissue preparation and imaging, and mass spectrometry for proteomics and metabolomics. This would enable a truly systems app ....A systems biology capability for the Ramaciotti Centre for Genomics. A systems biology capability for the Ramaciotti Centre for Genomics:
The project aims to introduce a complete systems biology capability to the Ramaciotti Centre for Genomics. This is intended to provide a complete systems biology workflow, including improved data analysis for next-generation sequencing, tissue preparation and imaging, and mass spectrometry for proteomics and metabolomics. This would enable a truly systems approach to biological problems, supporting researchers and projects that focus on microbial and mammalian metabolism, carbohydrate chemistry and synthetic biology. Read moreRead less
The Regulatory Network of Histone Methylating and Demethylating Enzymes. This project aims to discover how cells regulate histone methylation enzymes. This process ultimately affects which genes can be turned on or off inside cells; something which is central to growth and development in all animals, all plants and some microbes. Expected outcomes include new knowledge on the regulation of histone methylation, improved techniques for the study of this process and enhanced capacity for internatio ....The Regulatory Network of Histone Methylating and Demethylating Enzymes. This project aims to discover how cells regulate histone methylation enzymes. This process ultimately affects which genes can be turned on or off inside cells; something which is central to growth and development in all animals, all plants and some microbes. Expected outcomes include new knowledge on the regulation of histone methylation, improved techniques for the study of this process and enhanced capacity for international collaboration. New avenues for the artificial regulation of genes may also emerge for synthetic epigenetics. The project should provide significant new findings for the research community, generate research citations and contribute to a highly skilled workforce by the training of staff and students.
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Mechanisms of gene regulation. This project aims to determine the molecular basis of specific gene targeting. Transcription factor complexes regulate gene expression by binding to DNA at specific sites, modifying and looping chromatin, and recruiting the basal transcription machinery. Using blood cell transcription factor complexes as a model, this project will reveal interactions between sets of proteins that fine-tune DNA binding and recruit accessory proteins that regulate gene expression. Th ....Mechanisms of gene regulation. This project aims to determine the molecular basis of specific gene targeting. Transcription factor complexes regulate gene expression by binding to DNA at specific sites, modifying and looping chromatin, and recruiting the basal transcription machinery. Using blood cell transcription factor complexes as a model, this project will reveal interactions between sets of proteins that fine-tune DNA binding and recruit accessory proteins that regulate gene expression. The mechanistic detail provided is expected to inform the artificial up- or down-regulation of genes in biotechnological applications and ultimately treat disease which have a genetic component.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL200100096
Funder
Australian Research Council
Funding Amount
$3,367,940.00
Summary
Mapping the genetic and lifestyle landscape of Healthy Ageing. This project aims to dissect how genes interact with the environment to control healthy ageing using a multidisciplinary approach combining state-of-the-art omics technologies, metabolic and ageing phenotyping and genetic analysis and a highly diverse model system. The project is expected to establish fundamental new understanding of the ageing process by identifying genes that regulate ageing either alone or in response to diet; by ....Mapping the genetic and lifestyle landscape of Healthy Ageing. This project aims to dissect how genes interact with the environment to control healthy ageing using a multidisciplinary approach combining state-of-the-art omics technologies, metabolic and ageing phenotyping and genetic analysis and a highly diverse model system. The project is expected to establish fundamental new understanding of the ageing process by identifying genes that regulate ageing either alone or in response to diet; by defining the mechanism by which such genes control ageing and by identifying biomarkers that predict different ageing outcomes. This knowledge will contribute to future strategies based on genetic testing and biomarkers to optimise healthy ageing in humans. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100191
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
An advanced mass spectrometer for applications in phospho-proteomics, glycomics and top-down sequencing of proteins. This cutting-edge mass spectrometry facility will benefit the Hunter Valley research community comprising 100 researchers in this field. It will enable the researchers to enhance their research productivity in areas of national importance, including better understanding the etiology of disease states, reproductive health and the regulation of plant growth.