Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775726
Funder
Australian Research Council
Funding Amount
$306,270.00
Summary
Australian Mirror of the UCSC Genome Database and Browser. Modern medical, biological, agricultural, and environmental research and industries are being transformed by access to genomic information that details the DNA sequence of various species, as well as of different strains and individuals within populations. This information is being generated at an exponentially increasing speed, and requires large computational resources. This facility will provide Australian researchers, R&D organizati ....Australian Mirror of the UCSC Genome Database and Browser. Modern medical, biological, agricultural, and environmental research and industries are being transformed by access to genomic information that details the DNA sequence of various species, as well as of different strains and individuals within populations. This information is being generated at an exponentially increasing speed, and requires large computational resources. This facility will provide Australian researchers, R&D organizations and industry with state-of-the-art genomic data storage and analysis capability, which will permit both public and proprietary access, and accelerate Australian research and development in genetic medicine, pharmaceuticals, animal breeding and biodiversity.Read moreRead less
Beyond the genome: unravelling the intricacies of epigenetic regulation using the honey bee model. Epigenetic mechanisms, such as DNA methylation, provide the interface between genome and environment. Abnormalities in epigenetic regulation lead to cancer and other diseases. The project will be using the alternative phenotypes in honeybees, fertile queens and sterile workers, to understand how dietary factors control conditional gene expression by methylation
Novel bioinformatics approaches for biological inference from comparative genomics data. Unlocking the potential of the human and other genome sequences depends almost entirely upon comparative genomics techniques. We will develop powerful bioinformatic models, implemented as high-performance computing solutions, for the examination of gene sequences. Improving these models, which represent the initial building block for all comparative genomics techniques, will be beneficial across genomics dep ....Novel bioinformatics approaches for biological inference from comparative genomics data. Unlocking the potential of the human and other genome sequences depends almost entirely upon comparative genomics techniques. We will develop powerful bioinformatic models, implemented as high-performance computing solutions, for the examination of gene sequences. Improving these models, which represent the initial building block for all comparative genomics techniques, will be beneficial across genomics dependent industries. A major outcome from this work will be an integrated software/hardware product optimised for statistical examination of very large-scale genomics data.Read moreRead less
Dissecting a RNA-histone variant interaction and its role in splicing. This project aims to define the molecular details of how a chromatin component, histone H2A.B, binds RNA and influences RNA splicing. This is unprecedented for histones, which are typically associated with DNA and transcriptional regulation. Over 90 per cent of human genes may be alternatively spliced. This explains how complex organisms develop from a limited set of genes, but how alternative splicing decisions are made is u ....Dissecting a RNA-histone variant interaction and its role in splicing. This project aims to define the molecular details of how a chromatin component, histone H2A.B, binds RNA and influences RNA splicing. This is unprecedented for histones, which are typically associated with DNA and transcriptional regulation. Over 90 per cent of human genes may be alternatively spliced. This explains how complex organisms develop from a limited set of genes, but how alternative splicing decisions are made is unclear. The intended outcome is to reveal links between chromatin, RNA splicing and gene expression regulation to explain how multicellular organisms have evolved. The translation of this knowledge will ultimately provide long-term economic and health benefits for Australia.Read moreRead less
Understanding how dynamic changes in chromatin composition control genome function. DNA is tightly packaged in eukaryotic cells as chromatin. Important genetic processes, such as transcription, require manipulation of chromatin structure to access the DNA. The cell sets up specialised chromatin structures to regulate these processes. Currently, precise molecular details of these specialised structures are limited. This project will push the envelope of an in vitro model chromatin system and dete ....Understanding how dynamic changes in chromatin composition control genome function. DNA is tightly packaged in eukaryotic cells as chromatin. Important genetic processes, such as transcription, require manipulation of chromatin structure to access the DNA. The cell sets up specialised chromatin structures to regulate these processes. Currently, precise molecular details of these specialised structures are limited. This project will push the envelope of an in vitro model chromatin system and determine the architecture of several chromatin states with unique functional implications inside the cell. This will unravel the molecular instructions that define how our genomes are organised, significantly advancing our knowledge of fundamental eukaryotic genome biology and paving the way for the future development of new tools and therapies.Read moreRead less
Genome-wide discovery of translation control mechanisms. This project aims to reveal currently unknown molecular details of protein synthesis, a step of gene expression that is central to all of life. To achieve this, innovative methods based on next-generation sequencing will be deployed in the yeast model organism. Yeasts are of importance as pathogens as well as in the food and biotechnology industry sector. Thus, new knowledge generated in this project will help solve problems of invasive pa ....Genome-wide discovery of translation control mechanisms. This project aims to reveal currently unknown molecular details of protein synthesis, a step of gene expression that is central to all of life. To achieve this, innovative methods based on next-generation sequencing will be deployed in the yeast model organism. Yeasts are of importance as pathogens as well as in the food and biotechnology industry sector. Thus, new knowledge generated in this project will help solve problems of invasive pathogenic behaviour and biomass production.Read moreRead less
Tracking factor footprints to reveal the intricacy and control of translation initiation. Messenger ribonucleic acid (RNA) translation is required for all of life and knowledge of how it works is central to modern life sciences. This project will develop novel ways of studying translation, generating entirely new descriptions of its inner workings that may transform knowledge of gene function and its use in medical and biotechnological processes.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100068
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Mass spectrometry platform for high throughput genotyping, epigenetic analysis and validation of genome wide sequencing studies. This facility will provide a platform for Australian researchers to quantitatively measure genetic information in a rapid, accurate and cost-efficient manner. This technology will enhance Australia's ability to perform basic research into the genetic and epigenetic mechanisms of cellular function.