Adaptive evolution of coleoid (cuttlefish, octopus, squid) venoms. This project represents an opportunity for biodiscovery from the venoms of cuttlefish, octopuses and squids. The independent adaptation for venom active at the subzero Arctic and Antarctic polar waters is of particular evolutionary interest. However, their divergent, bioactive compounds are also a rich drug design resource.
Evolutionary genetics of kin recognition and task specialization in termite societies. Social insects must be able to recognize kin and task specialize in order to maintain colony cohesion and maximize colony labour, respectively. While it is known that kin recognition and task specialization are two key mechanisms underpinning insect societies, the extent to which their expression is mediated by genetic versus environmental variables is not known. This project integrates classic approaches to t ....Evolutionary genetics of kin recognition and task specialization in termite societies. Social insects must be able to recognize kin and task specialize in order to maintain colony cohesion and maximize colony labour, respectively. While it is known that kin recognition and task specialization are two key mechanisms underpinning insect societies, the extent to which their expression is mediated by genetic versus environmental variables is not known. This project integrates classic approaches to the study of animal behaviour with recent advances in molecular genetics to test, for the first time, the role that genetic variables have in mediating kin recognition and task specialization in a major group of social insects, the termites.Read moreRead less
Marine sponge–microbe interactions and the origin of animal innate immunity. This project aims to address how the animal innate immune system evolved to discriminate between potential pathogens versus beneficial symbionts by studying a marine sponge holobiont. Using advanced genomic and cellular approaches, the project will uncover deeply conserved regulatory pathways used by the cells of sponges, humans and other animals, and thereby identify cardinal rules governing animal innate immunity and ....Marine sponge–microbe interactions and the origin of animal innate immunity. This project aims to address how the animal innate immune system evolved to discriminate between potential pathogens versus beneficial symbionts by studying a marine sponge holobiont. Using advanced genomic and cellular approaches, the project will uncover deeply conserved regulatory pathways used by the cells of sponges, humans and other animals, and thereby identify cardinal rules governing animal innate immunity and its evolutionary origin. The project will provide an understanding of how beneficial microbial symbionts are recruited and maintained by animals, and are instrumental to the health of our environment and all its inhabitants.Read moreRead less
Unravelling reef fish vision through gene-editing and behavioural ecology. This project aims to enhance understanding of visual neuroscience, genetic control of vision and environmental ecology on The Great Barrier Reef (GBR). Using the anemonefish as a model, together with new genetic, photographic and behavioural approaches, the project aims to reveal novel aspects of colour vision on the reef. Outcomes beyond multiple scientific disciplines include enhanced international collaboration and bui ....Unravelling reef fish vision through gene-editing and behavioural ecology. This project aims to enhance understanding of visual neuroscience, genetic control of vision and environmental ecology on The Great Barrier Reef (GBR). Using the anemonefish as a model, together with new genetic, photographic and behavioural approaches, the project aims to reveal novel aspects of colour vision on the reef. Outcomes beyond multiple scientific disciplines include enhanced international collaboration and building capacity for improved reef guardianship. The benefits are scientific discovery in multiple areas, providing greater community understanding of complex science and a desire to preserve the GBR for future generations.Read moreRead less
The ancient symbiosis of crayfish and temnocephalan flatworms in Australian freshwaters investigated using molecules, morphology and biogeography. Freshwater parastacid crayfish are widespread and diverse in Australia's freshwaters. Associated with them (living on external surfaces) since their origins on Gondwana are very many species of temnocephalan flatworms. We will elucidate the molecular, morphological and biogeographic history of this association which appears to be ancient and specific. ....The ancient symbiosis of crayfish and temnocephalan flatworms in Australian freshwaters investigated using molecules, morphology and biogeography. Freshwater parastacid crayfish are widespread and diverse in Australia's freshwaters. Associated with them (living on external surfaces) since their origins on Gondwana are very many species of temnocephalan flatworms. We will elucidate the molecular, morphological and biogeographic history of this association which appears to be ancient and specific. The study will shed light on Australia's biological links with New Zealand and South America. It will also use the association between crayfish and temnocephalans as a model to investigate general features of symbioses, including molecular and morphological evolutionary responses and phenomena such as host-switching and cospeciation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100516
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Biodiversity, biogeography and molecular evolution on tropical reefs. This project aims to discover how evolutionary processes, biogeography and molecular change drive biodiversity patterns. Coral reefs support over 800,000 plant and animal species on <0.1% of the ocean. This project will examine how this biodiversity was formed by generating genomic data for reef building corals and reef associated fishes to reconstruct their evolutionary history. It will compare models of speciation, extinctio ....Biodiversity, biogeography and molecular evolution on tropical reefs. This project aims to discover how evolutionary processes, biogeography and molecular change drive biodiversity patterns. Coral reefs support over 800,000 plant and animal species on <0.1% of the ocean. This project will examine how this biodiversity was formed by generating genomic data for reef building corals and reef associated fishes to reconstruct their evolutionary history. It will compare models of speciation, extinction and range change among regions to determine how those processes contribute to the formation of biodiversity gradients and regional assemblage differences. The project expects that better understanding of evolutionary dynamics will inform conservation priorities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101150
Funder
Australian Research Council
Funding Amount
$362,000.00
Summary
Using sponge transcriptomes to understand ancestral animal development. The invention of a basic developmental program was likely a key step in the transition to multicellularity in animals, one of the major transitions in the tree of life. By combining next-generation sequencing of a representative panel of sponges and functional studies on an oviparous sponge, this project aims to identify gene interactions and networks that built the first animal embryos over 680 million years ago. Furthermor ....Using sponge transcriptomes to understand ancestral animal development. The invention of a basic developmental program was likely a key step in the transition to multicellularity in animals, one of the major transitions in the tree of life. By combining next-generation sequencing of a representative panel of sponges and functional studies on an oviparous sponge, this project aims to identify gene interactions and networks that built the first animal embryos over 680 million years ago. Furthermore, the role of Wingless (Wnt) signalling in patterning these ancestral embryos along a primordial anterior-posterior axis will be investigated. Piecing together the fundamental molecular machinery shared by all animal embryos will shed light on the molecular basis for the complex development of most animals on Earth.Read moreRead less
Evolutionary genetics of the immune system in social insects. Insects possess efficient innate immunity against pathogens, but social insects are suggested to be vulnerable due to their packed colonies of related individuals. We predict that pathogen pressure varies with life history and microhabitat details, and that this variation will be reflected in the molecular evolutionary rates of immune system genes. Sequence information will be obtained to test these predictions. The results should ....Evolutionary genetics of the immune system in social insects. Insects possess efficient innate immunity against pathogens, but social insects are suggested to be vulnerable due to their packed colonies of related individuals. We predict that pathogen pressure varies with life history and microhabitat details, and that this variation will be reflected in the molecular evolutionary rates of immune system genes. Sequence information will be obtained to test these predictions. The results should be of widespread interest as reflecting the importance of pathogens and life pattern, and increase our knowledge of insect immune systems, potentially enabling circumvention of pest defenses and better protection of beneficial species.Read moreRead less
Evolutionary immunology of social insects. Social insects are particularly abundant in Australia. They live in a wide range of habitats with social systems differing greatly in size and structure. They are both ecologically and economically important because they form a large part of terrestrial ecosystems and control much of the energy flow. Their immune system resembles the immune system of humans. Finding how the social insect immune system evolves will have the potential to help us manag ....Evolutionary immunology of social insects. Social insects are particularly abundant in Australia. They live in a wide range of habitats with social systems differing greatly in size and structure. They are both ecologically and economically important because they form a large part of terrestrial ecosystems and control much of the energy flow. Their immune system resembles the immune system of humans. Finding how the social insect immune system evolves will have the potential to help us manage them better, and yield functional insights into the human innate immune system. Placing the observed patterns in context also involves study of the associated microbes, finds how social insects interact with this important part of the environment, and may assist in land management.Read moreRead less
Origin of genomically-encoded communication in animals: deciphering the role of peptide signalling in the sea sponge Amphimedon queenslandica. The purpose of this research is to understand the evolutionary origin and essential roles of peptide communication in humans and other animals. Knowledge gleaned from this study will shed light on how peptide signalling influences animal life at its most fundamental level, including potentially how abnormal cell communication causes disease.