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Discovery Early Career Researcher Award - Grant ID: DE230101231
Funder
Australian Research Council
Funding Amount
$390,295.00
Summary
The effect of nutrition on male life history traits in humans. This project will provide answers to fundamental questions in evolutionary biology while identifying diet compositions that will benefit human health and well-being. Using a longitudinal public-health database, the Raine Study, and a theoretical framework from the field of Nutritional Ecology, the project will provide new knowledge on how nutrition affects key life-history traits in humans including immune function, reproductive heal ....The effect of nutrition on male life history traits in humans. This project will provide answers to fundamental questions in evolutionary biology while identifying diet compositions that will benefit human health and well-being. Using a longitudinal public-health database, the Raine Study, and a theoretical framework from the field of Nutritional Ecology, the project will provide new knowledge on how nutrition affects key life-history traits in humans including immune function, reproductive health, physical appearance, and healthy ageing. A systematic literature review on how diet impacts these life-history traits in animals generally, and an experimental study of the effect of diet on health and reproduction in the house mouse (a lab analog species for humans) will complement the Raine Study findings.Read moreRead less
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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Early Career Industry Fellowships - Grant ID: IE230100040
Funder
Australian Research Council
Funding Amount
$447,127.00
Summary
Unravelling the genetics of Kangaroo paws for climate-resilient gardens. The project will produce the first DNA-anchored plant lineage map of Kangaroo paws and gain novel insights into their resilient growth characteristics. Using novel genome and data-driven strategies, this project addresses the knowledge gap around the genetic heirloom of more than 200 iconic Kangaroo paw varieties to speed up the breeding of new varieties with enticing leaf patterns and flower colour combinations. While unra ....Unravelling the genetics of Kangaroo paws for climate-resilient gardens. The project will produce the first DNA-anchored plant lineage map of Kangaroo paws and gain novel insights into their resilient growth characteristics. Using novel genome and data-driven strategies, this project addresses the knowledge gap around the genetic heirloom of more than 200 iconic Kangaroo paw varieties to speed up the breeding of new varieties with enticing leaf patterns and flower colour combinations. While unravelling the inheritability and breeding barriers, immediate industry adoption will boost horticultural breeding programs long-term. This project uses cutting-edge science to enhance industry capacity for providing new Kangaroo paws for climate-resilient urban green spaces on the national and international market.Read moreRead less
Next generation high throughput lipidomics using adaptive modelling. This project aims to develop a unique high-throughput method to capture the lipidomic profile of human plasma suitable for large human population screening. Lipids are fundamental to every biological system, but our understanding of their regulation in humans have been largely superficial. By incorporating a new lipidomics approach, with genomic data, this project aims to expand our understanding of human biology by identifying ....Next generation high throughput lipidomics using adaptive modelling. This project aims to develop a unique high-throughput method to capture the lipidomic profile of human plasma suitable for large human population screening. Lipids are fundamental to every biological system, but our understanding of their regulation in humans have been largely superficial. By incorporating a new lipidomics approach, with genomic data, this project aims to expand our understanding of human biology by identifying regulators of lipid metabolism. The large diversity in humans necessitate sufficient sample sizes to identify true genetic regulators, but to date techniques capturing phenotypic data (lipids) have been largely limited. It is anticipated that this study will identify new regulators of lipid metabolism in humans.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100042
Funder
Australian Research Council
Funding Amount
$462,846.00
Summary
Developing a multimodal imaging pipeline for antisense technology. Antisense molecules represent a revolutionary drug discovery platform for life science, but to understand their distributions in cells and tissues is challenging. By integrating nanobiotechnology approaches, this project expects to develop and apply innovative imaging workflow to track antisense molecules in cells and tissues with nanoscale precision. Expected outcomes include new knowledge of the trafficking of these molecules a ....Developing a multimodal imaging pipeline for antisense technology. Antisense molecules represent a revolutionary drug discovery platform for life science, but to understand their distributions in cells and tissues is challenging. By integrating nanobiotechnology approaches, this project expects to develop and apply innovative imaging workflow to track antisense molecules in cells and tissues with nanoscale precision. Expected outcomes include new knowledge of the trafficking of these molecules across cells and tissues and refined imaging methods. This project should provide more strategic delivery of antisense molecules to specific cells and tissue, which will have significant downstream economic and social benefits to the Australian community. Read moreRead less
Establishing Vibrio natriegens as Ultra-Rapid Host for Synthetic Biology. This project aims to harness Vibrio natriegens, the world’s fastest-growing bacterium, as a microbial cell factory for synthetic biology and biotechnology. The project expects to develop new genetic tools and genetically-engineered microbes that can rapidly transform cheap feedstocks, such as plastic waste, into valuable chemicals and bioplastics. Expected outcomes include new knowledge on the mechanisms driving V. natrieg ....Establishing Vibrio natriegens as Ultra-Rapid Host for Synthetic Biology. This project aims to harness Vibrio natriegens, the world’s fastest-growing bacterium, as a microbial cell factory for synthetic biology and biotechnology. The project expects to develop new genetic tools and genetically-engineered microbes that can rapidly transform cheap feedstocks, such as plastic waste, into valuable chemicals and bioplastics. Expected outcomes include new knowledge on the mechanisms driving V. natriegens’ rapid growth, as well as building Australian multidisciplinary research capacity in synthetic biology that can translate this potential into bio-manufacturing processes. Significant benefits include the means to cut plastic pollution in our environment and to provide the basis for a carbon-negative chemical industry.Read moreRead less
Investigating a novel genetic strategy for insect resistance in crops. Plants are in a constant battle with insect pests and there is an increasing reliance on chemical inputs for control. However there are incoming bans on some pesticides, and new approaches are required for pest management. The aim of this project is to develop a new strategy which exploits the dependence of herbivorous insects on phytosterols. Here, we will apply the latest genomics technologies in plants to produce non-utili ....Investigating a novel genetic strategy for insect resistance in crops. Plants are in a constant battle with insect pests and there is an increasing reliance on chemical inputs for control. However there are incoming bans on some pesticides, and new approaches are required for pest management. The aim of this project is to develop a new strategy which exploits the dependence of herbivorous insects on phytosterols. Here, we will apply the latest genomics technologies in plants to produce non-utilizable sterols which will not support insect growth and reproduction, but will still allow the plant to function normally. We will demonstrate this in the important crop canola. Translation of this knowledge will support breeding for crop resilience, leading to durable resistance and more sustainable crop production.Read moreRead less
The developmental and evolutionary origins of vertebrate fins and limbs. This project aims to investigate the origin of paired appendages, a major event in early vertebrate history that changed ecological opportunity and fuelled the radiation of jawed vertebrates. This project expects to generate new knowledge on the mechanism that drove this innovation, which despite over a century of debate, remains one
of the great unknowns of comparative vertebrate evolution. Expected outcomes of this projec ....The developmental and evolutionary origins of vertebrate fins and limbs. This project aims to investigate the origin of paired appendages, a major event in early vertebrate history that changed ecological opportunity and fuelled the radiation of jawed vertebrates. This project expects to generate new knowledge on the mechanism that drove this innovation, which despite over a century of debate, remains one
of the great unknowns of comparative vertebrate evolution. Expected outcomes of this project include uncovering the anatomical changes underpinning the origin of the vertebrate appendicular system. This should provide significant benefits as it will inform our own natural history and provide a paradigm for studying gene network
conservation, phylogenetic modifications, and the acquisition of novel structures.Read moreRead less
Novel biological and genetic disease control tools for the barley industry. This project places Australian barley breeders at the forefront of disease resistance by providing them with novel tools to develop varieties with enhanced protection against fungal diseases. The aims are to produce fungal strains with multiple virulence genes for fast and cost-effective testing of barley lines, untangle the fungal/host gene interaction for resistance breeding and identify new sources of resistance. The ....Novel biological and genetic disease control tools for the barley industry. This project places Australian barley breeders at the forefront of disease resistance by providing them with novel tools to develop varieties with enhanced protection against fungal diseases. The aims are to produce fungal strains with multiple virulence genes for fast and cost-effective testing of barley lines, untangle the fungal/host gene interaction for resistance breeding and identify new sources of resistance. The outcomes will lead to the commercialisation by Australian breeding companies of barley varieties with durable fungal resistance. This will benefit the Australian economy by providing sustainability and protection for barley breeding thereby significantly reducing crop losses for this important global agricultural commodity.Read moreRead less
Control of crop-microbe symbiosis by new plant hormones. This project aims to discover how plants use hormone-like chemicals, called butenolides, to control symbiotic relationships with soil fungi. It will use multidisciplinary and collaborative techniques to establish how butenolide metabolism affects the diversity of fungal colonisation. Expected outcomes of this project include a deeper understanding of how plants regulate the competency of roots to host symbiotic fungi, and how this affects ....Control of crop-microbe symbiosis by new plant hormones. This project aims to discover how plants use hormone-like chemicals, called butenolides, to control symbiotic relationships with soil fungi. It will use multidisciplinary and collaborative techniques to establish how butenolide metabolism affects the diversity of fungal colonisation. Expected outcomes of this project include a deeper understanding of how plants regulate the competency of roots to host symbiotic fungi, and how this affects plant growth. As such, it will generate knowledge of how cereals such as barley could be modified to improve their nutrient use efficiency. Benefits of this project include the potential to reduce fertiliser inputs, thereby improving the competitiveness and environmental impact of Australian agriculture.Read moreRead less