New biotech methods for crop quality assurance. Quality assurance of crop products is a key for Australia to be competitive in the world marketplace. The power of molecular diagnostics has not been applied to this important but neglected part of the produce handling chain. In this project research will be undertaken that will lead to low cost on site assays to test for variety preservation, contamination, and presence of pests and diseases. It employs the tools of genomics and proteomics to p ....New biotech methods for crop quality assurance. Quality assurance of crop products is a key for Australia to be competitive in the world marketplace. The power of molecular diagnostics has not been applied to this important but neglected part of the produce handling chain. In this project research will be undertaken that will lead to low cost on site assays to test for variety preservation, contamination, and presence of pests and diseases. It employs the tools of genomics and proteomics to provide basic understanding of processes which can be developed into cost effective analyses for practical use by industry to ensure quality assurance.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101535
Funder
Australian Research Council
Funding Amount
$363,000.00
Summary
Ancient genomics of Western Australian taxa to inform conservation management. The project aims to apply genomic approaches to infer the genetic health and evolutionary history of three threatened, iconic Western Australian taxa: black cockatoos, ghost bats and woylies. Genomic data provide a powerful lens through which to study species, but the applications of genomic techniques in conservation biology have been sparse. Effective restoration and conservation initiatives require an understanding ....Ancient genomics of Western Australian taxa to inform conservation management. The project aims to apply genomic approaches to infer the genetic health and evolutionary history of three threatened, iconic Western Australian taxa: black cockatoos, ghost bats and woylies. Genomic data provide a powerful lens through which to study species, but the applications of genomic techniques in conservation biology have been sparse. Effective restoration and conservation initiatives require an understanding of species' former population sizes, connectivity and biodiversity. The project seeks to elucidate the population genetic, phylogenetic, and conservation genetic parameters of the three species at the genomic level using DNA isolated from modern and ancient sources (eg museum skins and fossils). The information gained may inform conservation efforts for some of Australia’s endangered biota.Read moreRead less
Assessment of past biodiversity through DNA preserved in bulk bone. This project aims to make a unique study of fossils to determine how the composition and biodiversity of ecosystems have changed in response to anthropogenic influences. Fossil bones provide a window through which to study past environments and how they have changed, and the stories these fossils tell can be further enhanced by ancient DNA analyses. This project plans to use bulk bone metabarcoding where hundreds of low-value (f ....Assessment of past biodiversity through DNA preserved in bulk bone. This project aims to make a unique study of fossils to determine how the composition and biodiversity of ecosystems have changed in response to anthropogenic influences. Fossil bones provide a window through which to study past environments and how they have changed, and the stories these fossils tell can be further enhanced by ancient DNA analyses. This project plans to use bulk bone metabarcoding where hundreds of low-value (fragmented) bones are collectively ground together to provide a cost-effective genetic audit of fossil assemblages. Working on bone from across Oceania and south-east Asia, this project aims to provide a historical perspective on biodiversity. Understanding former ecosystem composition and extinction may facilitate effective restoration and conservation initiatives.Read moreRead less
Tracking the evolution of devil facial tumour disease. The evolution of devil facial tumour disease could have disastrous effects on not only the Tasmanian Devil population but also other closely related species. This project will investigate the evolution of the disease in order to determine how new strains of the disease are arising.
Marsupial genomics: antimicrobial peptides and endangered species conservation. This project aims to use Australia’s unique biodiversity to tackle the global challenge of antimicrobial resistance. Rapid gene duplication and evolution of antimicrobial peptide genes in marsupials provide protection for joeys that are immunologically naïve in the pouch. By characterising immune genes in 10 marsupial species, this project will yield new antimicrobial peptides that can tackle superbugs. Genomic infor ....Marsupial genomics: antimicrobial peptides and endangered species conservation. This project aims to use Australia’s unique biodiversity to tackle the global challenge of antimicrobial resistance. Rapid gene duplication and evolution of antimicrobial peptide genes in marsupials provide protection for joeys that are immunologically naïve in the pouch. By characterising immune genes in 10 marsupial species, this project will yield new antimicrobial peptides that can tackle superbugs. Genomic information will also be used to provide significant benefits, such as improving the long term conservation of our endangered native species in a more appropriate and cost-effective way.Read moreRead less
Improving access to phylogenomic resources for under-resourced species: a new look at existing tools. This project will have an impact on our understanding of how to most effectively use existing genomic resources to benefit a wider range of species and to better design new genomic resources. By doing so, improved access to genomic resources will be provided to species that currently have few options.
Will genetic rescue save the Tasmanian devil? This project aims to measure the long-term genetic impacts of the Save the Tasmanian Devil Program’s ‘Wild Devil Recovery’ initiative. The project will determine whether supplementing small populations with individuals that are genetically diverse reduces inbreeding depression. The project will also monitor the impact of supplementation on the evolutionary trajectory of Devil Facial Tumour Disease. The project will train a cohort of conservation scie ....Will genetic rescue save the Tasmanian devil? This project aims to measure the long-term genetic impacts of the Save the Tasmanian Devil Program’s ‘Wild Devil Recovery’ initiative. The project will determine whether supplementing small populations with individuals that are genetically diverse reduces inbreeding depression. The project will also monitor the impact of supplementation on the evolutionary trajectory of Devil Facial Tumour Disease. The project will train a cohort of conservation scientists to translate genetic data into management actions. The outputs will directly inform the management actions of the Tasmanian Department of Primary Industries Parks, Water and the Environment and will help shape other species recovery programs.Read moreRead less
Minimising adaptation to captivity for conservation of threatened species. This project aims to determine how evolutionary processes affect the successful release of captive animals. Five years ago the Tasmanian devil was destined for extinction, but scientists now believe they can prevent this. However, they have put all their eggs in one basket – a large captive insurance population which acts as a source for the wild. Adaptation to captivity can have negative consequences for released animals ....Minimising adaptation to captivity for conservation of threatened species. This project aims to determine how evolutionary processes affect the successful release of captive animals. Five years ago the Tasmanian devil was destined for extinction, but scientists now believe they can prevent this. However, they have put all their eggs in one basket – a large captive insurance population which acts as a source for the wild. Adaptation to captivity can have negative consequences for released animals and could threaten the devil programme. Using massive molecular datasets and computational models, this project intends to evaluate different captive breeding scenarios and identify optimal management practices. This will provide environmental policymakers with a new framework for protecting threatened species in Australia and around the world.Read moreRead less
Haplodiploidy: the great evolutionary innovation of the Hymenoptera. This project aims to identify a key gene that causes thelytokous parthenogenesis. Thelytoky is the ability of a female to clone herself (virgin birth), and is wide spread in the Hymenoptera which include bees, wasps and ants. Hymenopteran thelytoky is important because it facilitates some major transitions in life history, particularly social parasitism. The capacity for virgin birth is central to the invasiveness of many ant s ....Haplodiploidy: the great evolutionary innovation of the Hymenoptera. This project aims to identify a key gene that causes thelytokous parthenogenesis. Thelytoky is the ability of a female to clone herself (virgin birth), and is wide spread in the Hymenoptera which include bees, wasps and ants. Hymenopteran thelytoky is important because it facilitates some major transitions in life history, particularly social parasitism. The capacity for virgin birth is central to the invasiveness of many ant species, and enables social cancers (parasitic workers that kill colonies) in bees. The benefit of this project is that the identification of the gene should help identify potentially invasive ant species and help prevent the social cancers that affect commercial beekeeping in South Africa from spreading world-wide.Read moreRead less
Above and below-ground specialisation in Australian orchids and its implications for diversification and vulnerability. Many of Australia's unique terrestrial orchids may face heightened extinction risk because of their obligate dependence on pollinators and fungi. This project will investigate the consequences of these interactions for orchid speciation and vulnerability. The outcomes will inform both evolutionary theory and future conservation programs.