Deceptive signals in spiders. Animal communication involves a diversity of signals including visual displays, sounds and odours. Understanding the function of signals is difficult because humans cannot detect some signals such as UV light. This project investigates the functions of visual signals in two spider systems: the decorations in orb-webs and the colouration of crab spiders. We analyse whether these signals are cryptic or conspicuous. Do they attract prey or hide the spiders from predato ....Deceptive signals in spiders. Animal communication involves a diversity of signals including visual displays, sounds and odours. Understanding the function of signals is difficult because humans cannot detect some signals such as UV light. This project investigates the functions of visual signals in two spider systems: the decorations in orb-webs and the colouration of crab spiders. We analyse whether these signals are cryptic or conspicuous. Do they attract prey or hide the spiders from predators? Our project will make a significant contribution to understanding the evolution of these signals, and will, at least in part, help resolve century old debates surrounding their function.Read moreRead less
On the move: the study of self-organised movement of animal groups with and without leadership. This project will uncover the common principles that control the movement of large groups of organisms. We will focus on swarming honey bees, hopping bands of billions of locusts and millions of crickets marching in unison. The outcomes of our research will be broadly applicable to other collective phenomena, even to traffic and crowd control in humans.
Understanding social cancers: Intra-specific parasitism by honeybee workers. Our project will study the conditions under which normally altruistic honeybee workers parasitise other colonies. Thus we will explore a fundamental question: how is the expression of selfish behaviour normally controlled? Outcomes of this project will be important to our understanding of insect societies but will also have application for those studying the development of tumours in multicellular organisms, the develop ....Understanding social cancers: Intra-specific parasitism by honeybee workers. Our project will study the conditions under which normally altruistic honeybee workers parasitise other colonies. Thus we will explore a fundamental question: how is the expression of selfish behaviour normally controlled? Outcomes of this project will be important to our understanding of insect societies but will also have application for those studying the development of tumours in multicellular organisms, the development of metazoan bodies, and social cohesion in human and non-human societies. Our project will also help protect Australia's honey industry from the devastating social parasites that have ruined the industry in South Africa.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101281
Funder
Australian Research Council
Funding Amount
$384,589.00
Summary
Mechanisms influencing the evolutionary trajectories of extended phenotypes. Although we know how the environment and predator-prey interactions shape traits, we have a poor grasp of the evolution of extended phenotypes. The webs of spiders have switched repeatedly between two- and three-dimensional forms over time, so are excellent models for assessing extended phenotype evolution. This project will use innovative experiments to assess whether the prey capture performance of webs or their visib ....Mechanisms influencing the evolutionary trajectories of extended phenotypes. Although we know how the environment and predator-prey interactions shape traits, we have a poor grasp of the evolution of extended phenotypes. The webs of spiders have switched repeatedly between two- and three-dimensional forms over time, so are excellent models for assessing extended phenotype evolution. This project will use innovative experiments to assess whether the prey capture performance of webs or their visibility to insects drove the repeated This project will provide insights into the interactive roles of the environment and prey in shaping extended phenotype diversification. Read moreRead less
Antimicrobial defences in the evolution of sociality. Disease microorganisms were probably important selective agents during the evolution of most species. Social insects, the ants, bees, wasps and termites, may have been especially vulnerable because their colonies contain large numbers of closely related individuals living in close proximity; ideal conditions for contagious diseases. We will explore the evolution of antimicrobial defences in social insects and related groups. Social insects ....Antimicrobial defences in the evolution of sociality. Disease microorganisms were probably important selective agents during the evolution of most species. Social insects, the ants, bees, wasps and termites, may have been especially vulnerable because their colonies contain large numbers of closely related individuals living in close proximity; ideal conditions for contagious diseases. We will explore the evolution of antimicrobial defences in social insects and related groups. Social insects are important ecologically and economically and understanding their relationships with microbial diseases will facilitate their conservation and control. Knowledge of these interactions may also prove useful to human societies becoming increasingly vulnerable to disease.Read moreRead less
Antimicrobial Defences and Evolution of Sociality. Microbial diseases threaten all societies, human or otherwise. Insect societies present ideal conditions for contagious disease, specifically crowding of closely related individuals. We propose a gradient in the strength and breadth of antimicrobial defences from the solitary to the social condition and this is correlated with increasing crowding and decreasing genetic diversity. To test this hypothesis, we compare the microbial environments o ....Antimicrobial Defences and Evolution of Sociality. Microbial diseases threaten all societies, human or otherwise. Insect societies present ideal conditions for contagious disease, specifically crowding of closely related individuals. We propose a gradient in the strength and breadth of antimicrobial defences from the solitary to the social condition and this is correlated with increasing crowding and decreasing genetic diversity. To test this hypothesis, we compare the microbial environments of nests and colonies, and the antimicrobial mechanisms, of solitary, semi-social and social insects. Outcomes from this research on disease regulation will inform the use, management and conservation of these economically and ecologically important animals.Read moreRead less
Unlocking the paradox of imperfect mimicry. This project aims to resolve why some mimics resemble their models closely, whereas others are only superficially similar. The existence of imperfect mimics makes understanding the biology of mimicry difficult. This project addresses the difficulty by evaluating competing hypotheses. It will combine morphometrics, colourmetrics and phylogenomics with predator behaviour across several independent lineages of mimetic arthropods. Predicted outcomes includ ....Unlocking the paradox of imperfect mimicry. This project aims to resolve why some mimics resemble their models closely, whereas others are only superficially similar. The existence of imperfect mimics makes understanding the biology of mimicry difficult. This project addresses the difficulty by evaluating competing hypotheses. It will combine morphometrics, colourmetrics and phylogenomics with predator behaviour across several independent lineages of mimetic arthropods. Predicted outcomes include advancing the understanding of mimicry by distinguishing between competing hypotheses. The project will generate open access genomic, morphological and behavioural databases for the scientific and public communities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100026
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Startle displays: a new route to resolving the aposematism paradox. This project aims to propose an empirical evaluation of startle displays as the ‘missing link’ in antipredator defences. The evolutionary origin of warning colouration is considered paradoxical in that conspicuous mutant prey should be attacked and killed as they evolve, denying predators any chance to learn to avoid them. Startle displays, however, are antipredator defences that exploit predator reflexes through a sudden transi ....Startle displays: a new route to resolving the aposematism paradox. This project aims to propose an empirical evaluation of startle displays as the ‘missing link’ in antipredator defences. The evolutionary origin of warning colouration is considered paradoxical in that conspicuous mutant prey should be attacked and killed as they evolve, denying predators any chance to learn to avoid them. Startle displays, however, are antipredator defences that exploit predator reflexes through a sudden transition from camouflage to warning colouration. This work merges theory on antipredator defences, deepens knowledge of their fitness costs and benefits, and provides a new resolution to a classic evolutionary paradox.Read moreRead less