Understanding specificity and flexibility in coral symbioses. This project aims to understand why some corals can switch algal partners while others remain faithful to a single strain. This is important because corals depend on their symbiotic algal partners for survival and because some algae provide greater resilience to environmental stress than others. This project will greatly enhance our understanding of the molecular and physiological factors governing flexibility and specificity in coral ....Understanding specificity and flexibility in coral symbioses. This project aims to understand why some corals can switch algal partners while others remain faithful to a single strain. This is important because corals depend on their symbiotic algal partners for survival and because some algae provide greater resilience to environmental stress than others. This project will greatly enhance our understanding of the molecular and physiological factors governing flexibility and specificity in coral-algal symbioses. It will provide much-needed knowledge required to identify associations most appropriate for specific conditions, prioritise populations for conservation, and assess the feasibility of new approaches to managing and restoring coral reefs.
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Assessment Of The Utility Of Genomics For Sydney Rock Oyster Breeding
Funder
Fisheries Research and Development Corporation
Funding Amount
$620,000.00
Summary
Genomics is routinely used across many livestock and plant breeding industries. It is now practical, within certain considerations, to consider applying genomic selection to aquaculture breeding programs due to significant cost reductions in the last decade. Its use in aquaculture breeding programs is increasing and genomics has already been researched for oyster breeding by USC (Vu et al. 2021a; Vu et al. 2021b).
Genomic selection has the potential to reduce the cost of estimating bre ....Genomics is routinely used across many livestock and plant breeding industries. It is now practical, within certain considerations, to consider applying genomic selection to aquaculture breeding programs due to significant cost reductions in the last decade. Its use in aquaculture breeding programs is increasing and genomics has already been researched for oyster breeding by USC (Vu et al. 2021a; Vu et al. 2021b).
Genomic selection has the potential to reduce the cost of estimating breeding values, which presently is a costly and challenging exercise with SROs and also may potentially increase genetic progress and selection accuracy for the SRO BP. The research proposed in this application will evaluate if it is possible to increase genetic progress for the productivity traits of QX disease resistance and growth as well as the product quality trait of meat condition. Increased QX survival and growth are particularly important traits for the SRO industry at this current time due to Port Stephens, the second largest SRO producing estuary in NSW, reeling from the impact of QX disease outbreaks. Climate change resilience is a new trait being investigated for incorporation into the breeding program for industry to respond to this threat. We would also like to assess whether genomics can provide a pathway to increase selection for resilience.
This project has been developed in line with the Oysters Australia Strategic Plan 2020 and the FRDC R&D Plan 2020-2025. The outcomes from this project will assess the feasibility of increasing selection accuracy for traits that improve productivity (growth and meat condition) as well as reduce impacts caused by QX disease and climate change through breeding for resilience. The outcomes will assess the possibility to improve genetic selections for multiple traits such that oysters can be selected on their ability to adapt to new climate conditions, survive QX disease whilst having faster growth and better meat condition. Additionally, this project will build new knowledge skills and networks through a NSW DPI, The University of the Sunshine Coast and The University of New South Wales alliance as well as create post-doctoral study opportunities. These meet the goals in Program 1, 2 and 3 outlined in the 2020-2025 Oysters Australia Strategic Plan.
With respect to the FRDC R&D Plan 2020-2025, this project will build capacity and create knowledge through developing skills and networks between NSW DPI, The University of the Sunshine Coast and The University of NSW to breed oysters that offer oyster businesses greater profitability, reduced risk and that can adapt to changing environments.
This project will explore alternative methods to what is presently used for SRO breeding to assess feasibility of genomic selection and what might be required today to move towards genomic selection in the future. This project will start compiling a reference library for SROs that can be used in the future and promote innovation in SRO breeding to integrate the technology developed from this project. Moreover, costs associated with genomic selection are reducing which increases the value proposition for incorporation into the future. The ultimate success and transfer of outcomes from this project to end user beneficiaries will be through incorporation of these new technologies into the SRO breeding program. Objectives: 1. Collect tissue samples using non-lethal methods and tagging to identify oysters 2. Sequence the whole genomes of selected individuals at high read depth, which will serve as the genotype resource for the project 3. Identify the associations between genotypes and phenotypes and compile a list of genetic markers and the genes associated with QX survival, whole weight and meat condition to then use modelling (for genomic predictions) to give individuals breeding values Read moreRead less
Real-time phylogenetics for food-borne outbreak surveillance. The project aims to introduce, for the first time, real-time evolutionary analysis of agricultural pathogens so that outbreaks affecting crops and the food supply can be managed precisely and rapidly. An expert team will implement a large-scale data analytics framework in user-friendly software that integrates Australian infectious disease genomics data with global data. Underpinning this work are new theory and algorithms that apply ....Real-time phylogenetics for food-borne outbreak surveillance. The project aims to introduce, for the first time, real-time evolutionary analysis of agricultural pathogens so that outbreaks affecting crops and the food supply can be managed precisely and rapidly. An expert team will implement a large-scale data analytics framework in user-friendly software that integrates Australian infectious disease genomics data with global data. Underpinning this work are new theory and algorithms that apply Sequential Monte Carlo to update phylogenetic analyses continuously as new data arrives. Expected outcomes include new knowledge of statistical algorithms for evolutionary analysis, relevant to biological disciplines beyond infectious disease; and enhanced capacity for infectious disease analysis. Read moreRead less
Ancestral state reconstruction and the evolution of Australian marsupials. This project aims to investigate the diversification and evolvability of Australian marsupials, by enabling genomes, ecology and 3D skeletal shape to synergistically inform evolutionary inference. This project expects to generate new knowledge of the processes that have promoted and maintained marsupial biodiversity, by tracing their evolution across a fossil gap that spans half of their history. Expected outcomes of this ....Ancestral state reconstruction and the evolution of Australian marsupials. This project aims to investigate the diversification and evolvability of Australian marsupials, by enabling genomes, ecology and 3D skeletal shape to synergistically inform evolutionary inference. This project expects to generate new knowledge of the processes that have promoted and maintained marsupial biodiversity, by tracing their evolution across a fossil gap that spans half of their history. Expected outcomes of this project include improved methods for merging fossils into the tree of life and for reconstructing the ecology and morphology of ancestors on phylogenetic trees. This should provide significant benefits, such as a coherent evolutionary context for informing research on marsupial biology, ecology and conservation.Read moreRead less
Asgard archaea: the first eukaryotic cells? . This project aims to uncover the role of unique microorganisms (Asgard archaea) in the origin of eukaryotes. These archaea may represent a ‘missing-link’ in eukaryotic evolution and are in abundance in the stromatolites in Shark Bay, Western Australia. Employing an innovative and interdisciplinary approach of cutting-edge molecular biology and high-resolution microscopy, this project expects to generate insights into fundamental aspects of evolution ....Asgard archaea: the first eukaryotic cells? . This project aims to uncover the role of unique microorganisms (Asgard archaea) in the origin of eukaryotes. These archaea may represent a ‘missing-link’ in eukaryotic evolution and are in abundance in the stromatolites in Shark Bay, Western Australia. Employing an innovative and interdisciplinary approach of cutting-edge molecular biology and high-resolution microscopy, this project expects to generate insights into fundamental aspects of evolution and cell biology. Expected outcomes include the discovery of unique branches of life and the proposal of new models for the emergence of eukaryotes. This research should allow for benefits across a spectrum of environmental and social gains, including improved ties with Indigenous communities.Read moreRead less
Precision Epigenetics: Targeting The Epigenome To Treat Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,940,576.00
Summary
Epigenetic marks are changes made to the DNA that allow genes to be switched off in some cells and switched on in others. These marks are critical to normal development and often go wrong in disease. We aim to find genes that add epigenetic marks to the DNA and understand how they co-operate at the molecular level to switch genes off. Our focus is on one such gene, SMCHD1. We are developing new drugs against SMCHD1 to treat incurable neurodevelopmental disorder PWS and muscular dystrophy FSHD.
Overcoming The Barriers To Treatment Of Multi-drug Resistant Gram-negative Bloodstream Infections In Australian Children
Funder
National Health and Medical Research Council
Funding Amount
$447,603.00
Summary
There is a critical need to develop new treatments for children with antibiotic resistant infections. The most important bacteria causing resistant infections are known as Gram-negative bacteria. Doctors treating children with resistant Gram-negative infections are faced with few antibiotic options. This project will discover the most important resistant infections in Australian children, and trial a new antibiotic to help doctors to use it in the right children and at the right dose.
Optimizing Immunotherapy Treatment For Breast Cancer Patients
Funder
National Health and Medical Research Council
Funding Amount
$1,938,014.00
Summary
The first steps in introducing immunotherapy for breast cancer patients have been taken in 2019. However, there is much work to do optimize immunotherapy for all breast cancer patients. My research, involving both lab and clinical trials, will develop new treatment strategies and identify new biomarkers to distinguish responders and non-responders. This will allow individualised selection of patients for evaluation of different immunotherapy approaches, with the aim of improving their survival.