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
Evolution of the dermomyotome in vertebrates. The project seeks to understand how different muscle populations within the embryo form and have evolved within the vertebrate phylogeny. All amniote muscles, except that of the head, derive from a transient embryonic structure termed the dermomyotome. The formation of muscle from the dermomyotome of amniotes uses a highly conserved mechanism that is distinct from that deployed by bony fish and amphibians. How the dermomyotome evolved to generate th ....Evolution of the dermomyotome in vertebrates. The project seeks to understand how different muscle populations within the embryo form and have evolved within the vertebrate phylogeny. All amniote muscles, except that of the head, derive from a transient embryonic structure termed the dermomyotome. The formation of muscle from the dermomyotome of amniotes uses a highly conserved mechanism that is distinct from that deployed by bony fish and amphibians. How the dermomyotome evolved to generate the distinct types of locomotor systems we see deployed throughout the vertebrate phylogeny remains unresolved. This project aims to contribute to an understanding of how different locomotor strategies deployed at important evolutionary transitions were generated.Read moreRead less
How limbs evolved from fins: the role of somite cells. This project aims to investigate the developmental basis of vertebrate appendage diversity and how during evolution limbs became fins. The project expects to determine how specific populations of cells that regulate fin formation arise during development, the genetic basis of their function, and how their role in development has evolved in lineages with divergent appendage anatomy. Expected outcomes include understanding the molecular basis ....How limbs evolved from fins: the role of somite cells. This project aims to investigate the developmental basis of vertebrate appendage diversity and how during evolution limbs became fins. The project expects to determine how specific populations of cells that regulate fin formation arise during development, the genetic basis of their function, and how their role in development has evolved in lineages with divergent appendage anatomy. Expected outcomes include understanding the molecular basis of the fin-limb transition and the origin of divergent appendage patterning systems. This should provide significant benefits by advancing our knowledge of the relationship between evolution and development, and understanding limb defects, which are amongst the most common of human congenital malformations.Read moreRead less
Evolutionary origin of stem cells and the emergence of animal complexity. The project aims to decipher the fundamental mechanisms governing stem cell specification and formation. All animals rely on stem cells to replenish, repair and regenerate tissues. Stem cells are also often a conduit to malignant tumours. This project seeks to uncover the rules governing stem cell formation through the study of a simple and ancient animal – the marine sponge Amphimedon queenslandica. The project plans to c ....Evolutionary origin of stem cells and the emergence of animal complexity. The project aims to decipher the fundamental mechanisms governing stem cell specification and formation. All animals rely on stem cells to replenish, repair and regenerate tissues. Stem cells are also often a conduit to malignant tumours. This project seeks to uncover the rules governing stem cell formation through the study of a simple and ancient animal – the marine sponge Amphimedon queenslandica. The project plans to combine insights from the simple, experimentally-tractable sponge stem cell system with existing knowledge of stem cell specification in humans and other animals, to reveal the essential features of stem cell formation. These insights may inform future pursuits to generate, control and use stem cells in cancer and regenerative medicines.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100306
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Does spurious maternal-fetal signalling support the evolution of a placenta. This project aims to test a model that explains how the placenta has evolved as a new organ more than 100 times in fishes, reptiles, and mammals including our own ancestors. The project will assess whether regulatory components of the placenta evolve as a result of spurious maternal-fetal signalling following egg retention and eggshell loss in viviparous reptiles. Expected outcomes of this project include a new understa ....Does spurious maternal-fetal signalling support the evolution of a placenta. This project aims to test a model that explains how the placenta has evolved as a new organ more than 100 times in fishes, reptiles, and mammals including our own ancestors. The project will assess whether regulatory components of the placenta evolve as a result of spurious maternal-fetal signalling following egg retention and eggshell loss in viviparous reptiles. Expected outcomes of this project include a new understanding of how complex organs originate and evolve in animals. This will benefit society through a broader depth of understanding of our own evolutionary history and provides a framework for future studies to investigate the origin and evolution of organs more broadly in animals.Read moreRead less
Evolution of the alternation of generations in the land plant life cycle. This project aims to investigate the genetic and evolutionary basis of land plants’ dimorphic life cycle where a single genome can generate two body plans. Like animals, land plants spend part of their life as a diploid, where meiosis generates haploid spores. Unlike animals, these spores grow into multicellular organisms before generating gametes. The project will study a homeodomain protein encoding a gene family that co ....Evolution of the alternation of generations in the land plant life cycle. This project aims to investigate the genetic and evolutionary basis of land plants’ dimorphic life cycle where a single genome can generate two body plans. Like animals, land plants spend part of their life as a diploid, where meiosis generates haploid spores. Unlike animals, these spores grow into multicellular organisms before generating gametes. The project will study a homeodomain protein encoding a gene family that controls the haploid to diploid transition in unicellular algae and fungi. It will investigate land plant genes in a flowering plant and a liverwort. These findings could help scientists understand and manipulate important processes such as pollen and seed production.Read moreRead less
How does developmental plasticity shape adaptation to environmental change? This project aims to address how animals adapt to environmental change by examining a process largely ignored in current studies: how the environment alters animal development. This project expects to generate new knowledge in the area of the genetics of adaptation using an innovative approach to determine how genetic variation, environmental conditions, and development interact to shape adaptation to changing environmen ....How does developmental plasticity shape adaptation to environmental change? This project aims to address how animals adapt to environmental change by examining a process largely ignored in current studies: how the environment alters animal development. This project expects to generate new knowledge in the area of the genetics of adaptation using an innovative approach to determine how genetic variation, environmental conditions, and development interact to shape adaptation to changing environments. Expected outcomes of this project include enhancing predictions of how species respond to climate change and building capacity for international collaborations. The intended impact of this project is to increase our understanding of how animals respond to environmental change by determining how multiple environmental cues act together to alter development, and how the genetic makeup of the individual affects these responses.Read moreRead less
The evolution of elaborate antennae in insects. This project will address several neglected but fundamental issues in the field of chemical communication and insect diversity. These include the evolutionary importance of receptor structures in a communication system, and the basis of diversity in one of the most defining characteristics of insects: antennae. The moth species in the proposed experiments are commercial pests of crops and therefore understanding of the evolutionary processes shapin ....The evolution of elaborate antennae in insects. This project will address several neglected but fundamental issues in the field of chemical communication and insect diversity. These include the evolutionary importance of receptor structures in a communication system, and the basis of diversity in one of the most defining characteristics of insects: antennae. The moth species in the proposed experiments are commercial pests of crops and therefore understanding of the evolutionary processes shaping their communication systems and mating behaviour will contribute to better predictive knowledge of the effects of control measures used against them. The project will also involve international collaboration to learn and develop new a technique in the analysis of pheromone communication. Read moreRead less
The evolution of multipartite mitochondrial genomes in the cyst-forming nematodes. The cyst-forming nematodes are a serious pest of agricultural crops throughout the world, attacking cereal, root and legume crops. Although sporadically recorded in Australia, they have not become established here. This project will characterize unique sequences from the noncoding portion of the mitochondrial genome of a range of cyst-forming nematodes, facilitating the development of molecular diagnostic screen ....The evolution of multipartite mitochondrial genomes in the cyst-forming nematodes. The cyst-forming nematodes are a serious pest of agricultural crops throughout the world, attacking cereal, root and legume crops. Although sporadically recorded in Australia, they have not become established here. This project will characterize unique sequences from the noncoding portion of the mitochondrial genome of a range of cyst-forming nematodes, facilitating the development of molecular diagnostic screening tools for these crop pests. This program will train a number of young scientists with skills in biotechnology, preparing them to join programs safeguarding our agricultural industries.Read moreRead less
Sociality and a sense of smell: receptor organ evolution in ants. This research provides novel insights into social recognition in insects by capitalising on a new technique to investigate the role of chemosensory detection of contact pheromones. The primary impact will be to ensure that Australia maintains its high research profile in this field, and by contributing to research training through supervising and mentoring research students. Finally, our research will contribute to our understand ....Sociality and a sense of smell: receptor organ evolution in ants. This research provides novel insights into social recognition in insects by capitalising on a new technique to investigate the role of chemosensory detection of contact pheromones. The primary impact will be to ensure that Australia maintains its high research profile in this field, and by contributing to research training through supervising and mentoring research students. Finally, our research will contribute to our understanding of the 'success' of major trans-global ant pest species, information that could prove useful in management strategies.Read moreRead less