Molecular switches and genetic consequences of grain retention in cereals. Grain retention at maturity was key for crop domestication and laid the basis for farming. Wheat and barley have evolved a novel mechanism for ensuring grain retention and, although the genes are known, the mechanisms for action are not. Grain dispersal in the wild relatives involves highly targeted changes in the walls of a small number of cells. This project will explore how the two identified genes control this proces ....Molecular switches and genetic consequences of grain retention in cereals. Grain retention at maturity was key for crop domestication and laid the basis for farming. Wheat and barley have evolved a novel mechanism for ensuring grain retention and, although the genes are known, the mechanisms for action are not. Grain dispersal in the wild relatives involves highly targeted changes in the walls of a small number of cells. This project will explore how the two identified genes control this process and clarify their mode of action. The genes ensuring grain retention have been so critical for domestication that the region surrounding them has become genetically fixed. The project will assess the implication of fixation on genetic diversity and develop options to bring novel variation into breeding programs.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100217
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Harnessing Mendel’s workhorse: meiotic crossovers for genetic diversity in crop breeding. Introducing genetic diversity from wild species into elite lines of wheat and barley may increase their resistance to the stresses they are exposed to in the field. Modern breeding cultivars could capture up to ten times more genetic variation. This project aims to gain fundamental insights into the genetic and environmental factors that limit the rates at which new genomic combinations can be made. This wi ....Harnessing Mendel’s workhorse: meiotic crossovers for genetic diversity in crop breeding. Introducing genetic diversity from wild species into elite lines of wheat and barley may increase their resistance to the stresses they are exposed to in the field. Modern breeding cultivars could capture up to ten times more genetic variation. This project aims to gain fundamental insights into the genetic and environmental factors that limit the rates at which new genomic combinations can be made. This will transform wheat and barley breeding methods, unlocking available genetic diversity to produce new varieties. Read moreRead less
Deciphering the genetic regulation of inflorescence development in wheat. The project aims to identify genes and molecular processes that regulate inflorescence architecture in wheat, using state-of-the-art genetic resources to identify novel biological mechanisms that regulate the development of spikelets – reproductive branches that contain grain-producing florets. The research is highly significant as little is known about how spikelet and floret numbers are determined genetically in wheat, a ....Deciphering the genetic regulation of inflorescence development in wheat. The project aims to identify genes and molecular processes that regulate inflorescence architecture in wheat, using state-of-the-art genetic resources to identify novel biological mechanisms that regulate the development of spikelets – reproductive branches that contain grain-producing florets. The research is highly significant as little is known about how spikelet and floret numbers are determined genetically in wheat, and new traits need to be identified to increase yields for the world’s growing population. Project outcomes will include new insights into the biology that underpins grain production of wheat, with expected benefits enabling sustainable increases of yields by breeders and growers to help bolster global food security.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100784
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Improving cereal grain quality using epigenetic regulators. The project aims to determine the epigenetic regulatory mechanisms that control cereal grain quality and yield under water-deficit and heat stress. The project will use next-generation sequencing to identify key epigenetic regulators and their functional target genes, which confer superior grain quality to elite genotypes under adverse environments. Project outcomes will benefit cereal breeding by providing more-tailored screening stra ....Improving cereal grain quality using epigenetic regulators. The project aims to determine the epigenetic regulatory mechanisms that control cereal grain quality and yield under water-deficit and heat stress. The project will use next-generation sequencing to identify key epigenetic regulators and their functional target genes, which confer superior grain quality to elite genotypes under adverse environments. Project outcomes will benefit cereal breeding by providing more-tailored screening strategies and superior parental germplasm with enhanced quality and yield. The development of nutritionally improved crops will benefit the Australian cereal industry and export opportunities.Read moreRead less
Defining the Brassica pan-genome and establishing methods for gene conversion based crop improvement. Gene content varies between individual varieties. The project aims to apply novel genomic tools to identify and characterise the fixed and variable gene content in the important crop canola and use this to understand genome evolution as well as develop tools to accelerate canola breeding. The project team have developed and used a high-resolution genotyping approach to demonstrate that gene conv ....Defining the Brassica pan-genome and establishing methods for gene conversion based crop improvement. Gene content varies between individual varieties. The project aims to apply novel genomic tools to identify and characterise the fixed and variable gene content in the important crop canola and use this to understand genome evolution as well as develop tools to accelerate canola breeding. The project team have developed and used a high-resolution genotyping approach to demonstrate that gene conversions, short recombination events which lead to the non-reciprocal exchange of genomic regions during meiosis, are abundant in crop genomes. The project aims to develop methods and resources to characterise gene conversion in canola and establish a basis for gene conversion based crop improvement.Read moreRead less
ARC Centre of Excellence for Translational Photosynthesis. The ARC Centre of Excellence for Translational Photosynthesis seeks to develop and harness advances in photosynthesis research, crop bioengineering, plant phenomics and computational tools to realise increased and sustainable crop yields, opening new routes to achieving the next revolution in plant productivity. It will deliver improved yield by undertaking a continuum of fundamental and applied photosynthesis research and targeting proj ....ARC Centre of Excellence for Translational Photosynthesis. The ARC Centre of Excellence for Translational Photosynthesis seeks to develop and harness advances in photosynthesis research, crop bioengineering, plant phenomics and computational tools to realise increased and sustainable crop yields, opening new routes to achieving the next revolution in plant productivity. It will deliver improved yield by undertaking a continuum of fundamental and applied photosynthesis research and targeting projects with a high probability of producing increased yield. Links with national and international institutions, consortia and breeding companies will enhance the prospects of translating genetic improvements into crops such as wheat, rice and sorghum for improved yield.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101127
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
An integrated statistical genetics framework for breeding superior wheat varieties. Genetic studies in agriculture are rapidly increasing in size and complexity in pursuit of genes behind desirable traits such as yield and water use efficiency. This project will address the need for efficient statistical methods to analyse genetic data and thus enable production of wheat varieties that will contribute to Australian food security.
Discovery Early Career Researcher Award - Grant ID: DE120100668
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
New Brassica crop species through evolutionary breeding. This projects aims to investigate natural mechanisms by which plants evolve into new species through hybridisation, using Brassica species (canola, cabbages and mustards) as a model. Understanding these processes will allow us to make new, widely adapted Brassica crop species for agricultural production.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100081
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Spectral climate chamber facilities for phenomic studies of plant light response adaptation. Climates are changing, altering planting regimes in agriculture, and disrupting local adaptation in foundation species. The genetic basis of climate adaptation will be dissected in new plant growth facilities, equipped with real-time imaging and environmental controls that can mimic dynamic seasonal growing conditions and weather stress events.
Establishing novel breeding methods for canola improvement. It is imperative to ensure reliable food production in the coming years of climate change and increasing population. Genomics offers the greatest potential to increase food production. This project will apply genomic selection methods to accelerate canola oilseed breeding to ensure continued increases in production of this important food and national export.