Solving Darwin's dilemma: Molecular analysis of worker sterility in social insects. One of Darwin's greatest puzzles was how natural selection resulted in worker sterility in social insects. We now know from mathematical modelling that a gene that causes sterility in workers can be at a selective advantage if it increases the reproductive success of queens. This project will take the only known gene that causes sterility, 'Anarchy' from honey bees, and determine how this gene evolved. We will de ....Solving Darwin's dilemma: Molecular analysis of worker sterility in social insects. One of Darwin's greatest puzzles was how natural selection resulted in worker sterility in social insects. We now know from mathematical modelling that a gene that causes sterility in workers can be at a selective advantage if it increases the reproductive success of queens. This project will take the only known gene that causes sterility, 'Anarchy' from honey bees, and determine how this gene evolved. We will determine if Anarchy is the same gene that causes sterility in all social insects, or only in honey bees. The project will be at the forefront of international research by providing a molecular perspective to Darwin's greatest dilemma.
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Sociogenomics of honeybees. From genes to society. This project will show how complex social behaviour of honeybees like dance communication and thermoregulation is genetically controlled. The complete sequence of the honeybee genome will be published in 2003, and a gene chip based on it will be created shortly afterwards. These new technologies will make our project technically feasible. By backcrossing, workers with different genetic tendencies to do a task can be generated within an otherwi ....Sociogenomics of honeybees. From genes to society. This project will show how complex social behaviour of honeybees like dance communication and thermoregulation is genetically controlled. The complete sequence of the honeybee genome will be published in 2003, and a gene chip based on it will be created shortly afterwards. These new technologies will make our project technically feasible. By backcrossing, workers with different genetic tendencies to do a task can be generated within an otherwise uniform background. Age-matched workers that perform a behaviour like thermoregulation can be compared to sisters that do not, and the genes that are switched on in the two groups compared.Read moreRead less
Beyond the gene: Linking herbivore behaviour to plant defense gene expression. This collaborative project investigates insect herbivore avoidance of plant defence mechanisms. Our project is novel because it integrates changes in the plant at a number of different levels and links them to insect foraging behaviour. Researchers assume that insects respond to plant defences by changing their foraging behaviour. This has not been tested directly. We use the genetically well characterised plant Arabi ....Beyond the gene: Linking herbivore behaviour to plant defense gene expression. This collaborative project investigates insect herbivore avoidance of plant defence mechanisms. Our project is novel because it integrates changes in the plant at a number of different levels and links them to insect foraging behaviour. Researchers assume that insects respond to plant defences by changing their foraging behaviour. This has not been tested directly. We use the genetically well characterised plant Arabidopsis and the world-wide pest Helicoverpa (heliothis) as a model system. Damage caused to crops by insect herbivores is a direct function of behaviour. Understanding this behaviour will lead to improved pest management and reduced economic losses.Read moreRead less
A genetic analysis of the role of an atypical hexokinase in gene regulation. This project addresses a question which is relevant to all living things-how do changes in the environment of a cell bring about a change in gene expression? The aim of this project is to investigate the role of hexokinases in gene regulation by studying the Aspergillus nidulans xprF gene, which encodes an an unusual hexokinase. Hexokinases are thought to be the glucose sensors in plants, animals and fungi, and play a ....A genetic analysis of the role of an atypical hexokinase in gene regulation. This project addresses a question which is relevant to all living things-how do changes in the environment of a cell bring about a change in gene expression? The aim of this project is to investigate the role of hexokinases in gene regulation by studying the Aspergillus nidulans xprF gene, which encodes an an unusual hexokinase. Hexokinases are thought to be the glucose sensors in plants, animals and fungi, and play a role in the development of diabetes in humans. In plants, sugars affect many processes including growth, flowering, photosynthesis, nitrogen metabolism, starch synthesis, pigmentation and response to pathogens.Read moreRead less
Epigenetic integration of genomic and environmental information in honey bees. Environmental factors such as nutrition, drugs or childhood neglect alter gene activity without a change to the DNA code and may result in a range of conditions such as cancer, obesity and mental illness. Such epigenetic phenomena are driven by subtle and poorly understood modifications of the genome known as DNA methylation. Our aim is to study the link between DNA methylation and environmental influences. We aspire ....Epigenetic integration of genomic and environmental information in honey bees. Environmental factors such as nutrition, drugs or childhood neglect alter gene activity without a change to the DNA code and may result in a range of conditions such as cancer, obesity and mental illness. Such epigenetic phenomena are driven by subtle and poorly understood modifications of the genome known as DNA methylation. Our aim is to study the link between DNA methylation and environmental influences. We aspire to understand how environmental signals trigger the reprogramming of transcriptional control of genetic networks that lead to contrasting phenotypic and behavioural outcomes using the honey bee modelRead moreRead less
Discovery and characterization of new classes of small regulatory RNAs in mammals. The project will reaffirm and enhance Australian leadership in the most rapidly developing area of molecular biological and genetic research, by the application of ultra high-throughput sequencing technologies to discovery of regulatory RNAs, thereby to identify the characteristics of important regulatory pathways that underpin mammalian development, brain function and species diversity. The results of this resear ....Discovery and characterization of new classes of small regulatory RNAs in mammals. The project will reaffirm and enhance Australian leadership in the most rapidly developing area of molecular biological and genetic research, by the application of ultra high-throughput sequencing technologies to discovery of regulatory RNAs, thereby to identify the characteristics of important regulatory pathways that underpin mammalian development, brain function and species diversity. The results of this research will have wide implications and applications in biotechnology, genetic engineering, animal breeding, medical science and advanced informatics.Read moreRead less
The genetics of social regulation of reproduction in honey bees. The aim is to characterise the genes that regulate worker reproduction in honeybees and to understand how the effects of these genes are regulated by the social environment. There is an inherent conflict between the interests of each worker (that can increase its biological fitness by laying eggs) and the collective workers (that are disadvantaged by their half sister's reproduction). How sterility is normally maintained in socia ....The genetics of social regulation of reproduction in honey bees. The aim is to characterise the genes that regulate worker reproduction in honeybees and to understand how the effects of these genes are regulated by the social environment. There is an inherent conflict between the interests of each worker (that can increase its biological fitness by laying eggs) and the collective workers (that are disadvantaged by their half sister's reproduction). How sterility is normally maintained in social insects remains an important unsolved mystery of biology. To solve this mystery we will use genomic techniques characterize the genes that control sterility and show how they are regulated by the social environment.Read moreRead less
STUDIES OF NF-E4, A NOVEL FETAL/ERYTHROID SPECIFIC FACTOR INVOLVED IN FETAL GLOBIN GENE REGULATION
Funder
National Health and Medical Research Council
Funding Amount
$753,810.00
Summary
Sickle cell anemia and thalassemia are the commonest genetic disorders worldwide. Those affected suffer devastating clinical sequelae and mortality in the first twenty years of life remains high. A cure for these diseases is dependent on the replacement of the affected or absent hemoglobin protein chains with normally functioning hemoglobins. This is evident in rare patients who co-inherit a natural mutation which elevates fetal hemoglobin (HbF), as these patients have a dramatically ameliorated ....Sickle cell anemia and thalassemia are the commonest genetic disorders worldwide. Those affected suffer devastating clinical sequelae and mortality in the first twenty years of life remains high. A cure for these diseases is dependent on the replacement of the affected or absent hemoglobin protein chains with normally functioning hemoglobins. This is evident in rare patients who co-inherit a natural mutation which elevates fetal hemoglobin (HbF), as these patients have a dramatically ameliorated clinical course. Therefore, treatment strategies which could reactivate fetal globin gene expression after birth should be explored for these diseases. To achieve this goal we must further our understanding of the normal mechanisms of developmental regulation of globin gene expression. To this end we have recently identified a novel gene which is critical for fetal globin expression. The studies we propose here will further define the function of this gene and assess its potential for gene therapy for sickle cell disease and thalassemia.Read moreRead less
The functional genomics of locust migratory behaviour. Unravelling the molecular genetic basis of locust migratory behaviour will place Australia at the forefront of international biological research and simultaneously contribute to the development of new and safer ways to manage these notorious agricultural pests. We will use genomics and gene expression analyses to identify the suite of genes involved in the behavioural changes that catalyse locust swarm formation and migration. This collabor ....The functional genomics of locust migratory behaviour. Unravelling the molecular genetic basis of locust migratory behaviour will place Australia at the forefront of international biological research and simultaneously contribute to the development of new and safer ways to manage these notorious agricultural pests. We will use genomics and gene expression analyses to identify the suite of genes involved in the behavioural changes that catalyse locust swarm formation and migration. This collaborative study will enhance international relations with China, foster the development of gene-focused locust control strategies, and provide an exemplar study of an important and complex problem faced by Australia and international community.Read moreRead less
Regulation of the EphA3 receptor tyrosine kinase in vertebrate development. The Eph/ephrin system has a critical role in normal embryonic development. Amongst vertebrates, the EphA3 gene is one of the most highly conserved genes in this system with critical roles in development of the visual system and in other developmental processes. Understanding how this gene is regulated will help us to understand the critical role of EphA3 in the basic biology of humans and other animals. This knowledge ma ....Regulation of the EphA3 receptor tyrosine kinase in vertebrate development. The Eph/ephrin system has a critical role in normal embryonic development. Amongst vertebrates, the EphA3 gene is one of the most highly conserved genes in this system with critical roles in development of the visual system and in other developmental processes. Understanding how this gene is regulated will help us to understand the critical role of EphA3 in the basic biology of humans and other animals. This knowledge may also shed light on the basis of congenital abnormalities and other pathological processes and possibly help us to understand how to prevent or treat these conditions.Read moreRead less