Discovery Early Career Researcher Award - Grant ID: DE120100836
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Oxidative stress as a physiological constraint on the pace of life histories. The project will draw on several areas of biology to answer a fundamental question: which mechanisms underlie the link between vital processes, like growth and reproduction, and rates of biological ageing? This research is needed to understand the basis of trade-offs that cause some individuals or species to age faster than others.
Intergenomic conflict and the evolution of uniparental inheritance of mitochondria. Why do all mammalian male sperm cells destroy their own mitochondria after fertilisation? A major evolutionary theory, the conflict hypothesis, aims to answer this question. The argument goes as follows. If an organism were to contain mitochondria from both parents, each mitochondrial lineage would be selected in an “arms race” to replicate faster than the other lineage, and this would likely be costly to the org ....Intergenomic conflict and the evolution of uniparental inheritance of mitochondria. Why do all mammalian male sperm cells destroy their own mitochondria after fertilisation? A major evolutionary theory, the conflict hypothesis, aims to answer this question. The argument goes as follows. If an organism were to contain mitochondria from both parents, each mitochondrial lineage would be selected in an “arms race” to replicate faster than the other lineage, and this would likely be costly to the organism. Uniparental inheritance of mitochondria prevents such evolutionary arms race. Sounds plausible? Yes. Has it been tested? No. This project will be the first attempt to test this intriguing hypothesis. Experimental evidence for the evolution of selfish mitochondria would provide solid support for this major evolutionary theory. Read moreRead less
Combining evolutionary, physiological and molecular approaches to understand ageing and performance. How organisms grow, behave and perform is a result of environmentally triggered molecular, physiological and biochemical reactions. Little is known about how these different levels of organisation interact to create the infinite morphological and behavioural complexities seen in adults. This project aims to integrate the fields of developmental, physiological and evolutionary biology to elucidate ....Combining evolutionary, physiological and molecular approaches to understand ageing and performance. How organisms grow, behave and perform is a result of environmentally triggered molecular, physiological and biochemical reactions. Little is known about how these different levels of organisation interact to create the infinite morphological and behavioural complexities seen in adults. This project aims to integrate the fields of developmental, physiological and evolutionary biology to elucidate how the environment moderates cell and tissue development through gene expression. This will highlight how early developmental decisions affect lifetime energetic trade-offs and efficiency, and how underlying biology manifests into emergent phenomena such as performance, behaviour, ageing and lifespan.Read moreRead less
The role of genome reorganisation in adaptation and speciation. Local adaptation and speciation are fundamental evolutionary processes that rely on changes to the genome. However, the role of genome architecture (e.g. chromosomal rearrangements, gene duplications) in driving these processes is poorly understood. This project will use advanced comparative genomics and bioinformatics to examine the role of chromosome rearrangements in driving adaptation and speciation, and evaluate rates of molec ....The role of genome reorganisation in adaptation and speciation. Local adaptation and speciation are fundamental evolutionary processes that rely on changes to the genome. However, the role of genome architecture (e.g. chromosomal rearrangements, gene duplications) in driving these processes is poorly understood. This project will use advanced comparative genomics and bioinformatics to examine the role of chromosome rearrangements in driving adaptation and speciation, and evaluate rates of molecular evolution between the X-chromosome and autosomes. Utilising Australia’s endemic mammalian fauna as a tractable model system, I will link population processes with macro-evolutionary outcomes to show how genome architecture underpins biodiversity.Read moreRead less
Parental imprinting and epigenetic inheritance in honey bees. This project aims to uncover the mechanisms behind epigenetic inheritance in bees, providing deep insights into their biology, and develop an outstanding new system for studying epigenetics. There are compelling theoretical and empirical reasons to predict epigenetic inheritance in honey bees. Further, reciprocal crosses reveal strong paternal effects suggesting that males modify their sperm to increase the reproductive success of the ....Parental imprinting and epigenetic inheritance in honey bees. This project aims to uncover the mechanisms behind epigenetic inheritance in bees, providing deep insights into their biology, and develop an outstanding new system for studying epigenetics. There are compelling theoretical and empirical reasons to predict epigenetic inheritance in honey bees. Further, reciprocal crosses reveal strong paternal effects suggesting that males modify their sperm to increase the reproductive success of their female offspring. Modification of DNA by methylation and the transfer of small RNA molecules in eggs or semen are two candidate mechanisms by which queens and drones may manipulate gene expression in their offspring.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100466
Funder
Australian Research Council
Funding Amount
$462,647.00
Summary
Mito-nuclear coevolution as an engine of biodiversity. This project aims to advance understanding of the processes that drive speciation and generate biodiversity. It will use Australia’s native social bees to test whether genetic diversity in mitochondrial genomes drives biodiversity at the population level, combining molecular and field studies in this uniquely tractable natural system. The expected outcome is a significant advance in knowledge of how coevolution between the two genomes of euk ....Mito-nuclear coevolution as an engine of biodiversity. This project aims to advance understanding of the processes that drive speciation and generate biodiversity. It will use Australia’s native social bees to test whether genetic diversity in mitochondrial genomes drives biodiversity at the population level, combining molecular and field studies in this uniquely tractable natural system. The expected outcome is a significant advance in knowledge of how coevolution between the two genomes of eukaryotic cells - mitochondrial and nuclear - affect the observable diversity of the natural world. The project is also expected to benefit the management and conservation of Australian native bees, which are vital pollinators in our natural and agro-ecosystems. Read moreRead less
Evolution in action or the demise of iconic Australian flora? The project aims to investigate the evolutionary history and conservation status of a group of closely related Grevillea species, in the light of increasing pressure from landscape modification. This project will incorporate leading methodologies for massively parallel sequencing, pollinator preference and breeding capacity in order to detect the patterns and processes underpinning divergence in widely distributed species. A phylogene ....Evolution in action or the demise of iconic Australian flora? The project aims to investigate the evolutionary history and conservation status of a group of closely related Grevillea species, in the light of increasing pressure from landscape modification. This project will incorporate leading methodologies for massively parallel sequencing, pollinator preference and breeding capacity in order to detect the patterns and processes underpinning divergence in widely distributed species. A phylogenetic framework will provide the evolutionary relationships among taxa. This project is expected to inform requirements for long-term species persistence and, for threatened species within the group, guide the decision making of biodiversity managers as to what actions are required and where best to invest limited funds.Read moreRead less
How males alter their mates' ageing rates and lifespans. The proposed project investigates how males affect the lifespan, ageing and subsequent reproduction of their mates. It seeks to draw on and adapt tools and approaches used in molecular genetics and physiology to test predictions from evolutionary theories of sexual conflict, life-histories and ageing in an organism of biomedical and ecological significance, the house mouse. It is expected that this approach will allow the study, in unsurpa ....How males alter their mates' ageing rates and lifespans. The proposed project investigates how males affect the lifespan, ageing and subsequent reproduction of their mates. It seeks to draw on and adapt tools and approaches used in molecular genetics and physiology to test predictions from evolutionary theories of sexual conflict, life-histories and ageing in an organism of biomedical and ecological significance, the house mouse. It is expected that this approach will allow the study, in unsurpassed detail, of the costs males impose on females via mating, insemination, territoriality and via conflict over how many offspring to have and how to invest in their care.Read moreRead less
From developmental stability to organismic senility: Hox genes and telomere impact on life history evolution. Australia benefits from training researchers and technicians in new, break-through biotechnology and from applying this knowledge to relevant, cutting-edge questions in highly publicized research fields. This project contains both these ingredients. Our model species (a lizard) has a relatively high level of offspring malformations (ca 15%), which makes it much more likely to detect thei ....From developmental stability to organismic senility: Hox genes and telomere impact on life history evolution. Australia benefits from training researchers and technicians in new, break-through biotechnology and from applying this knowledge to relevant, cutting-edge questions in highly publicized research fields. This project contains both these ingredients. Our model species (a lizard) has a relatively high level of offspring malformations (ca 15%), which makes it much more likely to detect their underlying genetic mechanism. Furthermore, we can also assess how these animals survive and reproduce in relation to how quickly they age, which can be measured by assessing the shortening of telomeres per unit time. Thus, this collaboration provides an opportunity to train Australian researchers and in that process generate very high profile research.Read moreRead less
Form, Function and Fitness: Multidisciplinary Evolutionary Biology Using Lizards as Models. What explains variation in reproductive success and its evolutionary consequences, within and among populations and species? Addressing this fundamental question in evolutionary biology requires a multidisciplinary approach, integrating ecology, genetics, behaviour and biochemistry. Using lizards as models, I will test (i) the degree to which variation in male signals reflects differences in immunogenotyp ....Form, Function and Fitness: Multidisciplinary Evolutionary Biology Using Lizards as Models. What explains variation in reproductive success and its evolutionary consequences, within and among populations and species? Addressing this fundamental question in evolutionary biology requires a multidisciplinary approach, integrating ecology, genetics, behaviour and biochemistry. Using lizards as models, I will test (i) the degree to which variation in male signals reflects differences in immunogenotype and stress tolerance, (ii) the degree to which paternity is determined by male genes, or male-female genetic similarity, (iii) whether offspring survival depends mostly on genes or on maternal investments, and (iv) how the relative importance of these factors vary among populations and species.Read moreRead less