Discovery Early Career Researcher Award - Grant ID: DE140101886
Funder
Australian Research Council
Funding Amount
$386,929.00
Summary
Plant microRNA targeting: defining regulatory factors additional to complementarity. Central to our understanding of microRNA biology is the identification of which genes they target. In plants, high complementarity is regarded as the sole determinant, and drives bioinformatic predictions. However, functional evidence is inconsistent with this, arguing that complementarity alone is insufficient to accurately predict targets. This project uses novel applications of next generation sequencing to c ....Plant microRNA targeting: defining regulatory factors additional to complementarity. Central to our understanding of microRNA biology is the identification of which genes they target. In plants, high complementarity is regarded as the sole determinant, and drives bioinformatic predictions. However, functional evidence is inconsistent with this, arguing that complementarity alone is insufficient to accurately predict targets. This project uses novel applications of next generation sequencing to categorise bioinformatically predicted Arabidopsis targets as either strongly or poorly regulated. These categories will be analysed to determine what factors, in addition to complementarity, are required for strong targeting. The outcomes will impact artificial microRNA design and have important implications for biotechnology. Read moreRead less
The role of long non-coding RNAs in the epigenetic control of gene expression during endosperm development in plants. Elucidating the molecular events underlying the biology of seed development is important in both understanding plant development and in developing new methods to enhance the productivity and qualities of grain crops. In recent years it has become clear that various classes of non-coding RNAs have important roles in gene regulation. Of these non-coding RNAs, small RNAs (20-25 nucl ....The role of long non-coding RNAs in the epigenetic control of gene expression during endosperm development in plants. Elucidating the molecular events underlying the biology of seed development is important in both understanding plant development and in developing new methods to enhance the productivity and qualities of grain crops. In recent years it has become clear that various classes of non-coding RNAs have important roles in gene regulation. Of these non-coding RNAs, small RNAs (20-25 nucleotides) are beginning to be understood however less is known about the role and complexity of long non-coding RNAs. This project would identify new regulators of seed development that may lead to novel methods to increase grain yields, ultimately benefitting the Australian grains industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100130
Funder
Australian Research Council
Funding Amount
$850,000.00
Summary
Systems biology: New generation DNA sequencing to functional analysis. The technique of DNA sequencing (or 'reading' the lines of the four repeating letters that make up the genetic code) illustrates how technological developments have become the main drivers in exploring the roles of genetic factors across a spectrum of research activities. Funding provided through this ARC grant will allow the purchase of the latest DNA sequencing platform, the Illumina Solexa, as well as equipment that will b ....Systems biology: New generation DNA sequencing to functional analysis. The technique of DNA sequencing (or 'reading' the lines of the four repeating letters that make up the genetic code) illustrates how technological developments have become the main drivers in exploring the roles of genetic factors across a spectrum of research activities. Funding provided through this ARC grant will allow the purchase of the latest DNA sequencing platform, the Illumina Solexa, as well as equipment that will be used to understand the biological function of the DNA sequencing results that are obtained. The equipment will allow Australian researchers to compete on an equal footing with the international leaders in understanding the roles played by genes in plants, microorganisms, animals and humans.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100225
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Western Australia single-cell isolation and genomics preparation facility. This project aims to give Western Australian researchers direct access to new platforms in single-cell isolation and single-cell RNA, genome and exome sample library preparation, so they can participate in the precision single-cell based research driving biology worldwide. This project will give researchers access to single-cell analysis techniques, integrated with other analysis methods, microscopy, and preclinical imagi ....Western Australia single-cell isolation and genomics preparation facility. This project aims to give Western Australian researchers direct access to new platforms in single-cell isolation and single-cell RNA, genome and exome sample library preparation, so they can participate in the precision single-cell based research driving biology worldwide. This project will give researchers access to single-cell analysis techniques, integrated with other analysis methods, microscopy, and preclinical imaging. The characterisation of rare and complex biological samples is expected to advance effective, socio-economically important research programmes in cell and molecular biology, sports science, plant and crop sciences, agriculture, clean energy (biofuels) resources and production, greenhouse gas reduction, environmental microbiology and marine science.Read moreRead less
TraitCapture: Genomic modelling for plant phenomics under environmental stress. This project aims to develop software to integrate new hyper-spectral and 3D growth models of plant phenomics with population genomics to identify heritable developmental traits across varied environments. Genome wide association studies aim to then be used to identify causal genes. Functional structural plant models incorporating genetic variation will be used to predict growth under simulated stress environments. ....TraitCapture: Genomic modelling for plant phenomics under environmental stress. This project aims to develop software to integrate new hyper-spectral and 3D growth models of plant phenomics with population genomics to identify heritable developmental traits across varied environments. Genome wide association studies aim to then be used to identify causal genes. Functional structural plant models incorporating genetic variation will be used to predict growth under simulated stress environments. The research team unites international industry, the Australian Plant Phenomics Facility, and university statistical geneticists. TraitCapture software will use open standards applicable to both controlled and field environments enabling plant breeders to pre-select adaptive traits to increase crop productivity under environmental stress.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100460
Funder
Australian Research Council
Funding Amount
$380,000.00
Summary
Role of DNA methylation in response to low nutrient availability in plants. DNA methylation (mC) is a covalent modification of DNA essential for the establishment and maintenance of correct gene expression patterns and recently suggested to be responsive to some environmental cues in plants. Using cutting edge technologies, this project aims to identify nutrient stress-induced mC changes and investigate the role that these changes may play in transcriptional regulation, as well as assessing whet ....Role of DNA methylation in response to low nutrient availability in plants. DNA methylation (mC) is a covalent modification of DNA essential for the establishment and maintenance of correct gene expression patterns and recently suggested to be responsive to some environmental cues in plants. Using cutting edge technologies, this project aims to identify nutrient stress-induced mC changes and investigate the role that these changes may play in transcriptional regulation, as well as assessing whether these changes can be transmitted to the next generation to confer intergenerational stress responsiveness. Altogether this project aims to provide fundamental knowledge of the role of mC in plant gene regulation and stress response as well as paving the way for the next generation of novel crop-improvement strategies.Read moreRead less
The role of chlorophyll f in photosynthesis. The knowledge of energetic limits of oxygenic photosynthesis will provide opportunities for improving the efficiency of photosynthesis by using a wider range of the solar spectrum. This project aims to understand the roles of newly discovered chlorophyll f in central photoreactions and its biosynthesis.
Functional genomics of light stress resistance in the model organism Chlamydomonas: combining molecular genetics, transcriptome and proteome analysis. This project aims at combining molecular genetics, transcriptome and proteome analysis to identify genes and pathways underlying high light stress tolerance in previously isolated mutants of the chlorophyte Chlamydomonas reinhardtii. Comprehensive profiles of transcriptome-proteome linkage will be constructed without the complications of multicel ....Functional genomics of light stress resistance in the model organism Chlamydomonas: combining molecular genetics, transcriptome and proteome analysis. This project aims at combining molecular genetics, transcriptome and proteome analysis to identify genes and pathways underlying high light stress tolerance in previously isolated mutants of the chlorophyte Chlamydomonas reinhardtii. Comprehensive profiles of transcriptome-proteome linkage will be constructed without the complications of multicellularity for this unicellular photosynthetic model organism. We will establish a public proteome reference database and provide new microarrays and molecular markers beneficial for research in Chlamydomonas. We expect to advance understanding of high light resistance mechanisms so that it will eventually be applicable to improve productivity in crop plants growing under various environmental stress conditions.Read moreRead less
The genetic basis of leaf lamina establishment and growth. This study will help reveal how the development of leaves is coordinated by tissue patterning genes and the plant growth hormone auxin. All plants grow in this way, and the findings, made using a model laboratory plant, will be applicable to crop species as well.
Discovery Early Career Researcher Award - Grant ID: DE190100249
Funder
Australian Research Council
Funding Amount
$391,743.00
Summary
Molecular systems biology of novel flower colour evolution. This project aims to discover new and potentially useful structural and regulatory genes while advancing knowledge of the chemical, genetic and ecological basis of unique evolutionary flower colour shifts. Dramatic shifts in floral colour is widespread in flowering plants, however, just how changes in flower colour occur remains poorly understood. This project will take advantage of unique Australian plants to investigate the molecular ....Molecular systems biology of novel flower colour evolution. This project aims to discover new and potentially useful structural and regulatory genes while advancing knowledge of the chemical, genetic and ecological basis of unique evolutionary flower colour shifts. Dramatic shifts in floral colour is widespread in flowering plants, however, just how changes in flower colour occur remains poorly understood. This project will take advantage of unique Australian plants to investigate the molecular mechanisms and evolutionary shift in flower colour changes. This project expects to advance knowledge on plant specialised metabolism with potential contributions to the floriculture, food and flavour industries.Read moreRead less