How does developmental plasticity shape adaptation to environmental change? This project aims to address how animals adapt to environmental change by examining a process largely ignored in current studies: how the environment alters animal development. This project expects to generate new knowledge in the area of the genetics of adaptation using an innovative approach to determine how genetic variation, environmental conditions, and development interact to shape adaptation to changing environmen ....How does developmental plasticity shape adaptation to environmental change? This project aims to address how animals adapt to environmental change by examining a process largely ignored in current studies: how the environment alters animal development. This project expects to generate new knowledge in the area of the genetics of adaptation using an innovative approach to determine how genetic variation, environmental conditions, and development interact to shape adaptation to changing environments. Expected outcomes of this project include enhancing predictions of how species respond to climate change and building capacity for international collaborations. The intended impact of this project is to increase our understanding of how animals respond to environmental change by determining how multiple environmental cues act together to alter development, and how the genetic makeup of the individual affects these responses.Read moreRead less
Continuous tooth replacement in mammals: revealing the fundamental processes in tooth generation and movement. This project will investigate how molar teeth are made in mammals by examining the nabarlek, or little rock-wallaby, which is one of a handful of mammals that is able to regenerate new molars throughout its life. These new teeth migrate through the bone in order to move into the correct position in the mouth. By investigating two well-studied organisms, the mouse and the tammar wallaby, ....Continuous tooth replacement in mammals: revealing the fundamental processes in tooth generation and movement. This project will investigate how molar teeth are made in mammals by examining the nabarlek, or little rock-wallaby, which is one of a handful of mammals that is able to regenerate new molars throughout its life. These new teeth migrate through the bone in order to move into the correct position in the mouth. By investigating two well-studied organisms, the mouse and the tammar wallaby, as well as the nabarlek itself, the developmental processes and genes involved in molar generation and movement will be revealed. This project will integrate findings in regenerative medicine, evolutionary biology, materials engineering and palaeontology to reveal the mechanisms and origins of this astounding capability.Read moreRead less
Sexual antagonism and the consequences of sex-specific selection. Males and females arise from essentially the same genome yet are selected in vastly different ways. This exposes gene pools to alternate episodes of feminising- and masculinising-selection, thereby promoting Sexually Antagonistic (SA) evolution. Sex chromosomes are predicted to play an important role in SA evolution because sex-linkage allows for gender-specific gene expression, but data on the role of sex-linked genes are limited ....Sexual antagonism and the consequences of sex-specific selection. Males and females arise from essentially the same genome yet are selected in vastly different ways. This exposes gene pools to alternate episodes of feminising- and masculinising-selection, thereby promoting Sexually Antagonistic (SA) evolution. Sex chromosomes are predicted to play an important role in SA evolution because sex-linkage allows for gender-specific gene expression, but data on the role of sex-linked genes are limited to Drosophila, a male heterogametic (XY) model. This project will determine the consequences of SA selection in the butterfly Eurema hecabe (a female ZW heterogamete) using experimental evolution and the feminising endosymbiont Wolbachia to force male genomes through bouts of feminising selection.Read moreRead less
Molecular switches and genetic consequences of grain retention in cereals. Grain retention at maturity was key for crop domestication and laid the basis for farming. Wheat and barley have evolved a novel mechanism for ensuring grain retention and, although the genes are known, the mechanisms for action are not. Grain dispersal in the wild relatives involves highly targeted changes in the walls of a small number of cells. This project will explore how the two identified genes control this proces ....Molecular switches and genetic consequences of grain retention in cereals. Grain retention at maturity was key for crop domestication and laid the basis for farming. Wheat and barley have evolved a novel mechanism for ensuring grain retention and, although the genes are known, the mechanisms for action are not. Grain dispersal in the wild relatives involves highly targeted changes in the walls of a small number of cells. This project will explore how the two identified genes control this process and clarify their mode of action. The genes ensuring grain retention have been so critical for domestication that the region surrounding them has become genetically fixed. The project will assess the implication of fixation on genetic diversity and develop options to bring novel variation into breeding programs.Read moreRead less
The genetics of adaptation: changing developmental trajectories in eucalypts. During their life cycles, many animals and plants undergo genetically programmed changes in form. Such changes may be dramatic and rapid as seen in insect metamorphoses or plant heteroblasty, and may have ecological, evolutionary and even economic consequences. The project aims to identify the genes controlling such transitions in Australia's eucalypts.
Harnessing genetic diversity for complex traits. Genetic diversity underpins crop improvement but has become increasingly narrow in our major crops. Strategies exist for mobilising simple traits (e.g. disease resistance) from wild accessions or landraces into cultivars, but there are no effective approaches for introducing complex traits, including stress tolerance or components of yield. Using barley as an important crop and a genetic model, the project aims to address this problem by applying ....Harnessing genetic diversity for complex traits. Genetic diversity underpins crop improvement but has become increasingly narrow in our major crops. Strategies exist for mobilising simple traits (e.g. disease resistance) from wild accessions or landraces into cultivars, but there are no effective approaches for introducing complex traits, including stress tolerance or components of yield. Using barley as an important crop and a genetic model, the project aims to address this problem by applying a novel approach; partial redomestication of wild accessions by introgressing genes required for modern farming, then evaluating the resulting partially adapted germplasm in hybrids with elite cultivars. The project expects to generate new and diverse germplasm pools for breeding.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100812
Funder
Australian Research Council
Funding Amount
$451,748.00
Summary
Using evolutionary theory to advance reproductive technologies. This project aims to address the global biodiversity crisis by incorporating evolutionary theory into the study of reproductive technologies. With 41% of amphibian species now threatened with extinction, this project expects to revolutionise the field, enhancing the propagation and genetic management of threatened amphibians. Specifically, incorporating evolutionary theory into the study of amphibian reproductive technologies will i ....Using evolutionary theory to advance reproductive technologies. This project aims to address the global biodiversity crisis by incorporating evolutionary theory into the study of reproductive technologies. With 41% of amphibian species now threatened with extinction, this project expects to revolutionise the field, enhancing the propagation and genetic management of threatened amphibians. Specifically, incorporating evolutionary theory into the study of amphibian reproductive technologies will increase our capacity to predict spermiation responses and identify parental-genetic incompatibilities that may compromise offspring viability. Ultimately, this novel approach will provide significant benefits by fast-tracking the development of reproductive technologies for threatened species recovery.Read moreRead less
The evolution of cooperative communication. This interdisciplinary project will provide a broad understanding of communication in a model ecological system involving ants, lycaenid butterflies, and host-plants. The project will reveal the nature of the chemical signals used to communicate, and their role in the origin, maintenance, and loss of mutualistic and parasitic associations.
Neuro-ecology: information processing under natural conditions. Not enough is known about how sensory information is processed through the brain under natural environmental conditions. This project will shed light on how information processing changes with context and will help explain why even those animals with the smallest brains are much more versatile and robust than our most advanced robots.
Environmentally Induced Non-genetic Effects on Ageing and Fitness over Multi-generations and the Evolution of Life-history Trade-offs. This project will study trade-offs among growth, lifespan and fecundity, and test the following three predictions by employing a short-lived fish model and cutting-edge statistical and computational modelling. First, different dietary conditions not only affect the fitness of the organism, but also that of subsequent generations. Second, different nutritional eff ....Environmentally Induced Non-genetic Effects on Ageing and Fitness over Multi-generations and the Evolution of Life-history Trade-offs. This project will study trade-offs among growth, lifespan and fecundity, and test the following three predictions by employing a short-lived fish model and cutting-edge statistical and computational modelling. First, different dietary conditions not only affect the fitness of the organism, but also that of subsequent generations. Second, different nutritional effects and transgenerational effects on fitness-related traits are underpinned by epigenetic (or non-genetic) modifications. Third, such epigenetic modifications and their inheritance influence the evolution of life-history trade-offs. This project will link the emerging field of epigenetics with evolutionary theory, and reveal mechanisms of transgenerational epigenetic inheritance. Read moreRead less