Understanding animals through their movement. This project aims to develop a suite of analytical methods to understand animals' behaviour through their movement patterns. Animal movement patterns encode detailed information about their behavioural state. Collecting and analysing animal movement trajectories can provide us with completely new insights to behaviour. Recent developments in bio-logging technologies have provided an incredible amount of rich data on free-ranging animals. This project ....Understanding animals through their movement. This project aims to develop a suite of analytical methods to understand animals' behaviour through their movement patterns. Animal movement patterns encode detailed information about their behavioural state. Collecting and analysing animal movement trajectories can provide us with completely new insights to behaviour. Recent developments in bio-logging technologies have provided an incredible amount of rich data on free-ranging animals. This project will develop a suite of analytical techniques to interrogate this data through a combination of approaches, from fine scale experiments in the laboratory to tracking animal trajectories from the International Space Station. The findings will deliver major benefits to the broader community by transforming our ability to manage and conserve animal stocks.Read moreRead less
Maternal contributions to offspring development in a changing climate. This project aims to investigate how maternal contributions to offspring developmental environments affect metabolism, learning, growth, and survival of offspring. This project expects to provide mechanistic and evolutionary insights into how changes in metabolic function, brought about by changes in the developmental environment, contribute to variation in learning and life-history. Expected outcomes include an in-depth unde ....Maternal contributions to offspring development in a changing climate. This project aims to investigate how maternal contributions to offspring developmental environments affect metabolism, learning, growth, and survival of offspring. This project expects to provide mechanistic and evolutionary insights into how changes in metabolic function, brought about by changes in the developmental environment, contribute to variation in learning and life-history. Expected outcomes include an in-depth understanding of how changes in maternal investment and hormones impact offspring developing in different thermal environments and how such changes are mediated by compromised physiological function – providing significant benefits in understanding population persistence in Australia's rapidly changing climate.Read moreRead less
Animal social behaviour and emerging infectious fungal diseases in nature. This project aims to improve knowledge about the central role that animal social behaviour plays in the spread of emerging infectious fungal diseases in nature. Applying approaches from behavioural ecology, network modelling and quantitative genetics, and utilising rare empirical pre- and post-infection data, the project expects to generate new understandings about how fungal diseases spread through animal populations, ho ....Animal social behaviour and emerging infectious fungal diseases in nature. This project aims to improve knowledge about the central role that animal social behaviour plays in the spread of emerging infectious fungal diseases in nature. Applying approaches from behavioural ecology, network modelling and quantitative genetics, and utilising rare empirical pre- and post-infection data, the project expects to generate new understandings about how fungal diseases spread through animal populations, how animal social behaviour influences disease transmission, and how disease-status affects animal social behaviour. This project should have international impact, and advance current knowledge about disease dynamics. Applied outcomes should inform much-needed control strategies to benefit wildlife and preserve biodiversity. 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.
Why are warning colours in animals so rare? Toxic insects display warning colours as protection from predators who learn to associate them with an unpleasant taste. Theoretically, there is no limit to the number of species that could show warning colours but only about 5% are estimated to have them. This presents a fundamental and unresolved biological problem - what limits warning colours? This project aims to address this significant biological question by testing three hypotheses predicting w ....Why are warning colours in animals so rare? Toxic insects display warning colours as protection from predators who learn to associate them with an unpleasant taste. Theoretically, there is no limit to the number of species that could show warning colours but only about 5% are estimated to have them. This presents a fundamental and unresolved biological problem - what limits warning colours? This project aims to address this significant biological question by testing three hypotheses predicting warning signal limitations. Projected outcomes are an improved understanding of the ecological niche of these colourful insects, which may inform conservation and biodiversity management and raise awareness of these flamboyant creatures.Read moreRead less
Female multiple mating and the evolutionary origins of complex societies. This project plans to connect micro-evolutionary processes with macro-evolutionary change to provide a unified understanding of why animals live together. Evolutionary transitions to and from complex social behaviour appear linked to female multiple mating (polyandry). However, the causal pathway by which variation in polyandry results in the emergence and diversification of sociality is yet to be established. Using a vert ....Female multiple mating and the evolutionary origins of complex societies. This project plans to connect micro-evolutionary processes with macro-evolutionary change to provide a unified understanding of why animals live together. Evolutionary transitions to and from complex social behaviour appear linked to female multiple mating (polyandry). However, the causal pathway by which variation in polyandry results in the emergence and diversification of sociality is yet to be established. Using a vertebrate system we aim to integrate empirical, theoretical and comparative approaches to show: the ecological causes of individual variation in female polyandry; its effect on social behaviours that promote social complexity at the population level; and how this corresponds to divergence in social complexity across species.Read moreRead less
Population divergence and the thermal ecology of sexual conflict. This project aims to test how populations of introduced mosquitofish have adapted to local differences in water temperature (such as Tasmania versus Queensland). To what extent has natural selection (for survival) and sexual selection (the ability of males to acquire mates and/or females to resist unwanted matings) driven the local adaptation of populations? Many species have traits that evolve under intense sexual conflict – nota ....Population divergence and the thermal ecology of sexual conflict. This project aims to test how populations of introduced mosquitofish have adapted to local differences in water temperature (such as Tasmania versus Queensland). To what extent has natural selection (for survival) and sexual selection (the ability of males to acquire mates and/or females to resist unwanted matings) driven the local adaptation of populations? Many species have traits that evolve under intense sexual conflict – notably when males harass or coerce females into mating and females resist these attempts. It is assumed that sexual conflict traits are rarely affected by the local environment. The project will test the hypothesis that temperature can actually drive the evolution of such traits, specifically coercion and resistance to mating.Read moreRead less
Random network models with applications in biology. Complex biological systems consist of a large number of interacting agents or components, and so can be studied using mathematical random network models. We aim to gain deeper insights into the laws emerging as the random networks evolve in time. This can help us to deal with dangerous disease epidemics and better understand the human brain.
Discovery Early Career Researcher Award - Grant ID: DE190100831
Funder
Australian Research Council
Funding Amount
$416,670.00
Summary
The effects of mitochondrial genetic variation on physiology and behaviour. This project aims to test how mitochondrial DNA variation drives molecular, physiological, and behavioural differences between genders and among populations. This project, through the testing of a new hypothesis, expects to generate new knowledge to understand why males and females differ consistently in key health-related traits like longevity. The expected outcomes of this project will provide new discoveries that deli ....The effects of mitochondrial genetic variation on physiology and behaviour. This project aims to test how mitochondrial DNA variation drives molecular, physiological, and behavioural differences between genders and among populations. This project, through the testing of a new hypothesis, expects to generate new knowledge to understand why males and females differ consistently in key health-related traits like longevity. The expected outcomes of this project will provide new discoveries that deliver fundamental insights into the genetics of gender differences, with benefits that extend into the biomedical sciences. The project is also expected to enhance the international profile of Australian science through cutting-edge research in evolutionary genetics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100018
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding bioacoustics in plants. From lush tropical rainforests to small urban gardens, plants take advantage of the surrounding soundscape to flourish, yet how they do this is still unknown. This will be the first experimental study to explore how and why plants sense sound in their environment, hence pioneering a brand-new research area in behavioural and evolutionary ecology.