Discovering how termites use vibrations to make foraging decisions. Termites are pests affecting one third of Australian homes. The annual cost of treatment and damage repair is over $20 billion worldwide. Yet, little is known about how termites make foraging decisions based on vibrations. This project will study the key features in vibration signals produced by termites to unlock the secrets of their foraging behaviour.
What drives parasite spread through social networks: lessons from lizards. Australia's biodiversity is continually threatened by new epidemics of local and foreign diseases and parasites. This project will enhance our understanding of how these diseases spread, allowing more effective controls to be developed to protect wildlife species, animal populations and, ultimately, Australian ecosystems.
Parasite transmission through social networks in the pygmy bluetongue lizard. Australia's biodiversity is continually threatened by new epidemics of diseases and parasites, some local, others from overseas. This project will provide information on how they spread so that more effective management of these diseases can be developed to protect wildlife species, animal populations and, ultimately, Australian ecosystems.
Evolving with sexually transmitted infections. This project aims to understand how sexually transmitted infections (STIs) affect the evolution of host mating systems. STIs threaten the health of most sexually-reproducing organisms. In evolutionary terms, their mode of transmission imposes distinct selection patterns on hosts. This project will use an Australian beetle and its sexually transmitted mite to investigate how STIs lead to evolutionary changes in host mating behaviour and explore the g ....Evolving with sexually transmitted infections. This project aims to understand how sexually transmitted infections (STIs) affect the evolution of host mating systems. STIs threaten the health of most sexually-reproducing organisms. In evolutionary terms, their mode of transmission imposes distinct selection patterns on hosts. This project will use an Australian beetle and its sexually transmitted mite to investigate how STIs lead to evolutionary changes in host mating behaviour and explore the genetic basis for STI resistance. This project is expected to affect the evolution of host mating biology and lead to sex-specific optimal levels of disease resistance, which can influence disease dynamics and host-disease coevolution.Read moreRead less
Mechanisms of colour production and the evolution of animal signals. This project aims to reveal how diverse colours are produced in reptiles and the information these colours convey about individual health, condition and performance. The project evaluates how stress affects both pigment deposition and the nano-structure of cells and tissues, which together produce colour. By comparing similar colours generated by two entirely different classes of pigment (carotenoids and pteridines), this proje ....Mechanisms of colour production and the evolution of animal signals. This project aims to reveal how diverse colours are produced in reptiles and the information these colours convey about individual health, condition and performance. The project evaluates how stress affects both pigment deposition and the nano-structure of cells and tissues, which together produce colour. By comparing similar colours generated by two entirely different classes of pigment (carotenoids and pteridines), this project will provide new insights into the evolution of animal coloration, and will significantly enhance our understanding of pteridines, one of the most prevalent but least understood classes of pigment in vertebrates.Read moreRead less
Adapting to a changing world: mothers as drivers of evolutionary change. This project will improve our understanding of how organisms will adapt to the unprecedented speed and magnitude of human-induced environmental change. By identifying how mothers modify their offspring to better match the prevailing environment, it will address the role of mothers in directing and accelerating adaptation in our changing world.
Not lost in translation: how to get information from other species' calls? Information reduces life's uncertainties, and so underlies adaptive decisions in a changing world. However, the importance of information gained from other species is largely overlooked, despite the flow of information, just like resources, affecting individual fitness and population viability. This project aims to use a novel integration of visual and acoustic ecology to test how animals gain reliable information about p ....Not lost in translation: how to get information from other species' calls? Information reduces life's uncertainties, and so underlies adaptive decisions in a changing world. However, the importance of information gained from other species is largely overlooked, despite the flow of information, just like resources, affecting individual fitness and population viability. This project aims to use a novel integration of visual and acoustic ecology to test how animals gain reliable information about predators by eavesdropping on the alarm calls of other species. Thus, the project focuses on alarm calls because information about danger is critical to animal survival. The outcomes of the project could help us to understand how natural information webs form and function, and so refine predictions about the impact of environmental change on animal communities.Read moreRead less
Lucky in Love: the role of chance in sexual selection. Is luck important in the lives of animals? This project aims to ascertain how much variation in male mating success is attributable to male quality, traits or resources and how much is attributable to luck. Mating is the most important evolutionary process. Male mating success should be highly predictable: males with the best genes, most preferred displays or highest quality resources should attract females. Male mating success is, however, ....Lucky in Love: the role of chance in sexual selection. Is luck important in the lives of animals? This project aims to ascertain how much variation in male mating success is attributable to male quality, traits or resources and how much is attributable to luck. Mating is the most important evolutionary process. Male mating success should be highly predictable: males with the best genes, most preferred displays or highest quality resources should attract females. Male mating success is, however, surprisingly difficult to predict and we currently write off up to 90 per cent of the variance as noise. This project aims to quantify the relative importance of deterministic and stochastic sources of variation in male mating success. Ignored variance may be an untapped opportunity to understand selection.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
The fitness consequences of age-dependent changes in cognitive abilities. This project aims to investigate health-related topics in invasive fish. The evolution of large brains suggests that smarter individuals have more offspring due to natural and sexual selection. This project aims to test if the ability to perform cognitively challenging tasks predicts reproductive success. In addition, many life history traits show a trade-off between early and late life performance. This project will test ....The fitness consequences of age-dependent changes in cognitive abilities. This project aims to investigate health-related topics in invasive fish. The evolution of large brains suggests that smarter individuals have more offspring due to natural and sexual selection. This project aims to test if the ability to perform cognitively challenging tasks predicts reproductive success. In addition, many life history traits show a trade-off between early and late life performance. This project will test this prediction to see if individuals with above average cognitive performance when young are below average when old, that is faster 'cognitive senescence', or whether some individuals stay relatively smarter than others throughout their lives.Read moreRead less