Half a Genome is Better than None: The Evolution of Haplodiploidy in Mites. It is our normal experience that males and females are about equally common. We also expect both sexes to receive half their genes from each parent. In many successful animal groups, however, these normal expectations are not met: males are rare and have only half as many chromosomes as females (haplodiploidy) or are non-existent. We will investigate multiple origins of haplodiploid and all-female genetic systems in a ....Half a Genome is Better than None: The Evolution of Haplodiploidy in Mites. It is our normal experience that males and females are about equally common. We also expect both sexes to receive half their genes from each parent. In many successful animal groups, however, these normal expectations are not met: males are rare and have only half as many chromosomes as females (haplodiploidy) or are non-existent. We will investigate multiple origins of haplodiploid and all-female genetic systems in a group of mites that includes many useful biocontrol agents and important parasites. The implications of this research have both pure scientific merit and potential practical value in controlling the reproduction of pests.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100083
Funder
Australian Research Council
Funding Amount
$540,000.00
Summary
A high throughput phenomics facility for pace of life traits in animals. A high throughput phenomics facility for pace of life traits in animals: This project seeks to create the first high-throughput phenomic facility for animals in Australia. The molecular revolution has brought unprecedented capacity to understand genetic variation. Genetic variation is now better understood and more easily and cheaply characterised than the physical traits that organisms exhibit. Linking phenotypic variation ....A high throughput phenomics facility for pace of life traits in animals. A high throughput phenomics facility for pace of life traits in animals: This project seeks to create the first high-throughput phenomic facility for animals in Australia. The molecular revolution has brought unprecedented capacity to understand genetic variation. Genetic variation is now better understood and more easily and cheaply characterised than the physical traits that organisms exhibit. Linking phenotypic variation to genetic variation represents the major challenge in harnessing the power of the biomolecular age. This facility will accommodate animals from marine, freshwater and terrestrial systems across a diverse array of phyla. It will allow Australian researchers to leverage advances in high throughput genomic technologies to address a major bottleneck in biology.Read moreRead less
Evolutionary models and biodiscovery tools from neurotoxic snake venoms. This project aims to identify the selection pressures that shape snake venom neurotoxins and how they interact with nicotinic acetylcholine receptors, and to elucidate their biodiscovery potential. This project aims to test these important toxins on model systems that represent natural prey items in order to determine the molecular and functional evolution of neurotoxic peptides. Expected outcomes include substantial contri ....Evolutionary models and biodiscovery tools from neurotoxic snake venoms. This project aims to identify the selection pressures that shape snake venom neurotoxins and how they interact with nicotinic acetylcholine receptors, and to elucidate their biodiscovery potential. This project aims to test these important toxins on model systems that represent natural prey items in order to determine the molecular and functional evolution of neurotoxic peptides. Expected outcomes include substantial contributions to the body of evolutionary biology knowledge, while also having the applied benefit of discovering novel compounds with potential for use in drug design and discovery. These outcomes will benefit Australian science and society by elucidating fundamental processes while revealing biodisovery resources.Read moreRead less
Integrating evolution and plasticity into predictions of population persistence in a changing climate: adaptation or extinction? To effectively manage biodiversity at a time of rapid environmental change, Australia needs accurate predictions of how human alterations to climate and habitat will affect species. This project integrates evolution and spatial ecology to develop new tools for predicting and understanding how species will respond to environmental change.
Functional evolution and therapeutic potential of snake venom coagulotoxins. This project aims to identify and understand the factors that influence the useful function of key residues (parts of larger compounds) in Australian snake venom coagulotoxins, which alter blood-clotting ability. In recent years, snake venom compounds have been demonstrated as useful models from which to synthesise therapeutic drugs to improve health and well-being. This project will test these important toxins on model ....Functional evolution and therapeutic potential of snake venom coagulotoxins. This project aims to identify and understand the factors that influence the useful function of key residues (parts of larger compounds) in Australian snake venom coagulotoxins, which alter blood-clotting ability. In recent years, snake venom compounds have been demonstrated as useful models from which to synthesise therapeutic drugs to improve health and well-being. This project will test these important toxins on model systems that represent natural prey items in order to determine the molecular and functional evolution of blood-clot forming enzymes. Expected outcomes include substantial contributions to the body of evolutionary biology knowledge, as well as narrowing the search for the ultimate drug candidates.Read moreRead less
Nettles & toxic toupees: the molecular weaponry of venomous caterpillars. This project aims to investigate the structure, function and evolution of peptide toxins in venoms made by caterpillars in superfamily Zygaenoidea. Caterpillars in this group are covered in spines that inject pain-causing venoms, and this protects them from vertebrate and invertebrate predators. This project will test if peptides in this venom cause pain by pharmacological modulation of mammalian ion channels and signallin ....Nettles & toxic toupees: the molecular weaponry of venomous caterpillars. This project aims to investigate the structure, function and evolution of peptide toxins in venoms made by caterpillars in superfamily Zygaenoidea. Caterpillars in this group are covered in spines that inject pain-causing venoms, and this protects them from vertebrate and invertebrate predators. This project will test if peptides in this venom cause pain by pharmacological modulation of mammalian ion channels and signalling receptors, and if they have insecticidal properties. The first three-dimensional structures of caterpillar venom peptides will also be solved. Genomes of representatives of two different zygaenoid families will be produced, and genomic techniques will be used to elucidate how venom use evolved at the molecular level.Read moreRead less
Understanding evolution of dominant bacteria inhabiting the rodent gut . The gut microbiome is central to animal health and immune function, however we have an incomplete understanding of how this important symbiotic ecosystem evolved. By approaching this knowledge gap from a historical perspective and using real-time observation, this project will address how the gut community evolved with the rodent host and how members of that community respond to new selective pressures. The significance of ....Understanding evolution of dominant bacteria inhabiting the rodent gut . The gut microbiome is central to animal health and immune function, however we have an incomplete understanding of how this important symbiotic ecosystem evolved. By approaching this knowledge gap from a historical perspective and using real-time observation, this project will address how the gut community evolved with the rodent host and how members of that community respond to new selective pressures. The significance of these findings is in their capacity to inform our understanding of the relationship between host and microbe, not only within a key model system, but by extrapolation to other host-microbe systems. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100218
Funder
Australian Research Council
Funding Amount
$373,172.00
Summary
Can species interactions drive diversification? Species interactions may drive the evolution of species diversity but we currently lack the empirical evidence to demonstrate conclusively how this occurs. Using a group of closely-related species native to Australia's rainforest, this study will test how species interactions drive the evolution of mating traits and the formation of new species.
Discovery Early Career Researcher Award - Grant ID: DE170100354
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
How adaptation increases the intensity of sexual conflict. This project aims to test a theory that a species’ adaptation to its environment may cause sexual conflicts where gene variants increase the fitness of one sex but decrease it in the other. When populations harbour large numbers of these sexually antagonistic genes, adaptation is hampered and extinction becomes more likely. This project will fuse experimental evolution with quantitative genetic approaches to test this theory. Understandi ....How adaptation increases the intensity of sexual conflict. This project aims to test a theory that a species’ adaptation to its environment may cause sexual conflicts where gene variants increase the fitness of one sex but decrease it in the other. When populations harbour large numbers of these sexually antagonistic genes, adaptation is hampered and extinction becomes more likely. This project will fuse experimental evolution with quantitative genetic approaches to test this theory. Understanding sex differences in adaptation and the evolution of sexual dimorphism could enable scientists to predict levels of sexually deleterious variation under changing environmental conditions. Its findings are expected to provide new insights into sex differences in adaptation.Read moreRead less
Detecting sex differences in natural selection. This project aims to develop new genomic approaches for understanding how genetic mutations can differentially affect reproductive success in males and females. Applying novel tests, this project aims to uncover previously hidden genetic conflicts between the sexes. This will provide significant benefits, such as new tools that will be broadly applicable to the wider research community, and help to answer key questions in genetics and evolutionary ....Detecting sex differences in natural selection. This project aims to develop new genomic approaches for understanding how genetic mutations can differentially affect reproductive success in males and females. Applying novel tests, this project aims to uncover previously hidden genetic conflicts between the sexes. This will provide significant benefits, such as new tools that will be broadly applicable to the wider research community, and help to answer key questions in genetics and evolutionary biology in the current genomic era.Read moreRead less