The nature and consequences of environmentally-generated phenotypic variation in natural populations. The ambient environment can generate both heritable and non-heritable variation in individual traits, but the role of such variation in evolution is poorly understood. This project will use a powerful model organism, the Australian neriid flies, to elucidate the evolutionary implications of environmentally-generated variation.
Species and gene turnover across environmental gradients - a landscape-level approach to quantify biodiversity and resilience for climate adaptation. Biodiversity corridor planning in Australia desperately needs to progress beyond the simple linking up of remnant vegetation, based on aerial maps and start incorporating ecosystem features which will promote climate adaptation. This project will develop a new genomics method to assess ecosystem resilience for use in national biodiversity corridor ....Species and gene turnover across environmental gradients - a landscape-level approach to quantify biodiversity and resilience for climate adaptation. Biodiversity corridor planning in Australia desperately needs to progress beyond the simple linking up of remnant vegetation, based on aerial maps and start incorporating ecosystem features which will promote climate adaptation. This project will develop a new genomics method to assess ecosystem resilience for use in national biodiversity corridor planning.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100202
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Interplay between plasticity and senescence. This project aims at bridging two fundamental human stressors together in a quantitative genetic framework. The environment changes globally on a huge scale coupled with effect on the age-structures and genetic composition of countless populations by over-harvesting and exploitation. This project will provide significant benefits, such as potential strategies of dealing with future human-induced changes more effectively.
Exposing genetic quality: whole-organism performance and life-history trade-offs under genetic and phenotypic stress in the field cricket Teleogryllus commodus. This project will provide fundamental knowledge by answering several important evolutionary questions concerning the relationship between performance and reproductive fitness, and in doing so will pave the way for future integration between traditionally separate disciplines. If funded, the project will enhance Australia's reputation for ....Exposing genetic quality: whole-organism performance and life-history trade-offs under genetic and phenotypic stress in the field cricket Teleogryllus commodus. This project will provide fundamental knowledge by answering several important evolutionary questions concerning the relationship between performance and reproductive fitness, and in doing so will pave the way for future integration between traditionally separate disciplines. If funded, the project will enhance Australia's reputation for integrative evolutionary research, and will contribute to the training of young scientists in this and related areas. Finally, the proposed work will provide important information to conservationists and animal breeders on the potential effects of inbreeding, and on factors affecting the spread of invasive species.Read moreRead less
Predicting adaptive responses to climate change in Australian native bees. This project aims to understand how insects will adapt to climate change by examining a largely overlooked but economically important group of species: Australian native bees. Native bees are important pollinators of both crops and native plants, but their sensitivity to changes in climate are unknown. Expected outcomes include new knowledge of the resilience of native bees to climate change, and new effective tools for p ....Predicting adaptive responses to climate change in Australian native bees. This project aims to understand how insects will adapt to climate change by examining a largely overlooked but economically important group of species: Australian native bees. Native bees are important pollinators of both crops and native plants, but their sensitivity to changes in climate are unknown. Expected outcomes include new knowledge of the resilience of native bees to climate change, and new effective tools for predicting climate change resilience that can be applied to many species. The intended benefits include increasing our understanding of the potential for native bees to act as future pollinators in Australia’s natural and agro-ecosystems, and guide policy and management decisions to better protect and conserve our bee fauna.Read moreRead less
Mobility, stasis or extinction? The response of plants to long-term environmental change. This study of Australian plants will improve our ability to predict how plants and vegetation will respond to climate change by investigating the ability of plants to survive climate change. In particular, this project is designed to generate simple principles that can be used in management of species and vegetation at risk from climate change.
The role of epigenetic modifications in bovid adaptation to environmental change. This project will explore the role of epigenetic change, where gene expression is regulated without changing the deoxyribonucleic acid (DNA) sequence, in how animals adapt to rapid climate change. This project will trace epigenetic markers in ancient bison and cows through 30,000 years of climate change, and identify key adaptive genes for the cattle industry.
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
Adaptive capacity of marine invertebrates in a climate change ocean. As the oceans simultaneously warm and acidify, prospects for marine biota are of concern. This project aims to determine the potential for phenotypic adjustment and evolutionary adaptation. To discern the roles of phenotype and genotype in marine invertebrate stress tolerance this project endeavours to use selection experiments, long-term rearing and quantitative genetics . A focus on vulnerable calcification systems could dete ....Adaptive capacity of marine invertebrates in a climate change ocean. As the oceans simultaneously warm and acidify, prospects for marine biota are of concern. This project aims to determine the potential for phenotypic adjustment and evolutionary adaptation. To discern the roles of phenotype and genotype in marine invertebrate stress tolerance this project endeavours to use selection experiments, long-term rearing and quantitative genetics . A focus on vulnerable calcification systems could determine genetic mechanisms underlying impaired growth. Investigation of species from the east Australia latitudinal thermal gradient, a global change hot spot could generate insights into biological responses and adaptive potential in a changing ocean and on time scales relevant to resource managers to understand the challenges faced by marine biota.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100957
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Using ancient fossils and new methods to unravel Australian mammal evolution in deep time. This project will explore the evolution of Australia's unique mammal fauna by studying fossil mammals recently discovered at Tingamarra, a 55 million year old fossil site in north-eastern Queensland. In particular, it will help us understand the origin, radiation and diversification of Australia's iconic marsupials.