Molecular genetic analyses of trinucleotide repeat expansions. Several neuronal diseases like Huntington's disease, Frederick's ataxia and fragile X syndrome are caused by expansion of trinucleotide repeat sequences in the deoxyribonucleic acid (DNA). These diseases show progressive severity in subsequent generations. Here we use a simple plant model with a very similar DNA mutation to study the genetic basis of repeat expansions over several generations across populations. This proposal will im ....Molecular genetic analyses of trinucleotide repeat expansions. Several neuronal diseases like Huntington's disease, Frederick's ataxia and fragile X syndrome are caused by expansion of trinucleotide repeat sequences in the deoxyribonucleic acid (DNA). These diseases show progressive severity in subsequent generations. Here we use a simple plant model with a very similar DNA mutation to study the genetic basis of repeat expansions over several generations across populations. This proposal will improve our mechanistic understanding of genetic diseases in populations. In addition, this proposal is expected to lead to identification of potential targets and technologies that would be of interest to Australian industry.Read moreRead less
microRNAs: discovery and analysis in mouse development. MicroRNAs (miRNAs) are a new class of regulatory molecule, recently found to be abundant and strongly conserved in several eukaryotic species, encoded by genes that are transcribed into short stem-loop structures and then processed into ~22nt single-stranded RNAs by the RNAi pathway. We have cloned novel miRNAs, and obtained the first evidence for regulation of a miRNA in a mammal. We propose to continue cloning novel miRNAs by the tried m ....microRNAs: discovery and analysis in mouse development. MicroRNAs (miRNAs) are a new class of regulatory molecule, recently found to be abundant and strongly conserved in several eukaryotic species, encoded by genes that are transcribed into short stem-loop structures and then processed into ~22nt single-stranded RNAs by the RNAi pathway. We have cloned novel miRNAs, and obtained the first evidence for regulation of a miRNA in a mammal. We propose to continue cloning novel miRNAs by the tried method, and to explore bioinformatics-based methods of identification. We will also study the expression of miRNAs in mouse embryos at successive stages, and develop a microarray assay for miRNA expression.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347245
Funder
Australian Research Council
Funding Amount
$630,000.00
Summary
Functional Genomics Analysis - linking a multicentred facility. The aim of this project is to enhance and network the functions and activities of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CGRCGFA), a joint venture that services five major universities in the Sydney-Newcastle area. This application is for equipment that will improve the speed of DNA analyses, and for a laboratory information management system that will standardise the handling of data and sample information ....Functional Genomics Analysis - linking a multicentred facility. The aim of this project is to enhance and network the functions and activities of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CGRCGFA), a joint venture that services five major universities in the Sydney-Newcastle area. This application is for equipment that will improve the speed of DNA analyses, and for a laboratory information management system that will standardise the handling of data and sample information at all nodes of the CVRCGFA.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0232455
Funder
Australian Research Council
Funding Amount
$545,000.00
Summary
The Molecular Analysis of Variation and Gene Function. The aim of this project is to establish the nodes of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CVRCGFA) which is a joint venture that serves the five major universities and three Institutes in the Sydney-Newcastle region. The primary focus of this application is to create new facilities at the hubs of CVRCFGA that are integral to the analysis of molecular variation in a range of organisms. The study of molecular vari ....The Molecular Analysis of Variation and Gene Function. The aim of this project is to establish the nodes of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CVRCGFA) which is a joint venture that serves the five major universities and three Institutes in the Sydney-Newcastle region. The primary focus of this application is to create new facilities at the hubs of CVRCFGA that are integral to the analysis of molecular variation in a range of organisms. The study of molecular variation will enable researchers to understand better how organisms interact with each other, how they respond to environmental stress and aid in the identification of complez traits.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453724
Funder
Australian Research Council
Funding Amount
$532,824.00
Summary
Functional Genomics - Linking Genomics and Proteomics. This application is to enhance the capacity of the Ramaciotti Centre for Gene Function Analaysis (RCFGA) and its Nodes to support research in Functional Genomics by expanding its ability to link genomic analysis (including transcriptomics) with proteomic and cell biological analysis. It will provide access to novel methods for analysing interactions of proteins with other molecules by enabling the manufacture of protein arrays as well as DN ....Functional Genomics - Linking Genomics and Proteomics. This application is to enhance the capacity of the Ramaciotti Centre for Gene Function Analaysis (RCFGA) and its Nodes to support research in Functional Genomics by expanding its ability to link genomic analysis (including transcriptomics) with proteomic and cell biological analysis. It will provide access to novel methods for analysing interactions of proteins with other molecules by enabling the manufacture of protein arrays as well as DNA microarrays and to analyse the data obtained from them. This is a vital component to maintain gene function analysis at the cutting edge of current technology.Read moreRead less
Gene regulatory networks in heart development. In humans, structural and functional malformations of the heart are very common and are associated with a high economic and emotional burden. In this project, we will study how genetic networks initiate and control heart development at a molecular level. We will establish and employ state-of-the-art technologies and bioinformatics tools to explore the function of cardiac regulatory genes in detail. Our work will contribute both to discover new cardi ....Gene regulatory networks in heart development. In humans, structural and functional malformations of the heart are very common and are associated with a high economic and emotional burden. In this project, we will study how genetic networks initiate and control heart development at a molecular level. We will establish and employ state-of-the-art technologies and bioinformatics tools to explore the function of cardiac regulatory genes in detail. Our work will contribute both to discover new cardiac pathways for a better understanding of heart formation and disease, and to develop advanced techniques that will contribute to strengthen Australian basic and strategic research.Read moreRead less
Differential expression and functional analysis of genes controlling metamorphosis and early neurogenesis of a model lower animal, the coral Acropora. This study will analyse, at a molecular level, the response of coral larvae to stimuli inducing settlement from the plankton and the process of establishment of a sessile, calcified colony. The knowledge gained will facilitate induction of settlement on demand in the most effective way. We will characterise known candidate genes which may be invo ....Differential expression and functional analysis of genes controlling metamorphosis and early neurogenesis of a model lower animal, the coral Acropora. This study will analyse, at a molecular level, the response of coral larvae to stimuli inducing settlement from the plankton and the process of establishment of a sessile, calcified colony. The knowledge gained will facilitate induction of settlement on demand in the most effective way. We will characterise known candidate genes which may be involved in settlement, and reveal a more complete picture using subtractive hybridisation. Studies of the nervous system and the changes that it undergoes at metamorphosis will promote understanding of the control of metamorphosis, and insights into how more complex nervous systems may have evolved.Read moreRead less
A new paradigm of gene regulation - implications in embryogenesis and disease. The proposed analysis of a new paradigm of gene regulation will provide a new key to understanding genome function and inform some of the most compelling biological issues of our time such as stem cell biology, tissue and organ regeneration and genetic programming. The insights and technologies developed in this program will be widely applicable in biotechnological and pharmacogenomic research in Australia and worldwi ....A new paradigm of gene regulation - implications in embryogenesis and disease. The proposed analysis of a new paradigm of gene regulation will provide a new key to understanding genome function and inform some of the most compelling biological issues of our time such as stem cell biology, tissue and organ regeneration and genetic programming. The insights and technologies developed in this program will be widely applicable in biotechnological and pharmacogenomic research in Australia and worldwide, and assert Australia's leadership in this area of research.Read moreRead less
Lungfish Paired Fins and the Origin of Limbs as an Evolutionary Novelty. This project will utilise a uniquely Australian animal, the lungfish, to address a hitherto unresolved problem of considerable scientific significance - how a fish fin evolved into a tetrapod (four-legged animal) limb. The Australian lungfish is the most primitive of the four surviving genera of lobe-finned fish and is recognised as the closest living ancestor to the tetrapods. It is listed as 'vulnerable' in its native ha ....Lungfish Paired Fins and the Origin of Limbs as an Evolutionary Novelty. This project will utilise a uniquely Australian animal, the lungfish, to address a hitherto unresolved problem of considerable scientific significance - how a fish fin evolved into a tetrapod (four-legged animal) limb. The Australian lungfish is the most primitive of the four surviving genera of lobe-finned fish and is recognised as the closest living ancestor to the tetrapods. It is listed as 'vulnerable' in its native habitat. Macquarie University, however, has the only captive breeding population of lungfish in the world. We are thus uniquely placed to address critically important questions concerning the evolution of fish into tetrapods. Read moreRead less
Understanding the control of male germ-line development by the germline-restrictive silencing factor in plants. The world population is currently increasing at an unprecedented rate, with a concomitant requirement to double the food production from the same amount of arable land. To ensure global political and social stability, equitably increasing sustainable food production without compromising environmental integrity remains a major challenge. This proposal investigates the molecular mechanis ....Understanding the control of male germ-line development by the germline-restrictive silencing factor in plants. The world population is currently increasing at an unprecedented rate, with a concomitant requirement to double the food production from the same amount of arable land. To ensure global political and social stability, equitably increasing sustainable food production without compromising environmental integrity remains a major challenge. This proposal investigates the molecular mechanisms underlying male germ line initiation and development in plants. Switching off male gamete development in some crop plants will create male sterile lines, which, when crossed with genetically distinct lines, will have the potential to produce hybrids that yield 20-30 percent more crop without additional inputs. Read moreRead less