Discovery Early Career Researcher Award - Grant ID: DE190100304
Funder
Australian Research Council
Funding Amount
$416,092.00
Summary
Understanding intramolecular regulation of ubiquitin enzymes. This project aims to combine structural, biophysical and functional studies to characterise how ubiquitin enzymes are regulated. Ubiquitination controls essential cellular pathways in all eukaryotes and this project expects to generate new knowledge regarding the vital regulation of this process. This project expects to develop broadly applicable techniques for investigating protein conformation and self-association as a means of cont ....Understanding intramolecular regulation of ubiquitin enzymes. This project aims to combine structural, biophysical and functional studies to characterise how ubiquitin enzymes are regulated. Ubiquitination controls essential cellular pathways in all eukaryotes and this project expects to generate new knowledge regarding the vital regulation of this process. This project expects to develop broadly applicable techniques for investigating protein conformation and self-association as a means of controlling catalytic activity. The project should significantly increase understanding of several modes of regulation of ubiquitin ligase catalytic activity, and how this controls a myriad of cellular processes. The project will lay the foundation for applied research anti-viral compounds, plant anti-fungals and cancer therapies.Read moreRead less
Biosynthetic LEGO: enzymatic redesign to produce new vancomycin analogues. This project aims to uncover the reengineering potential of the biosynthetic machinery that produces glycopeptide antibiotics by advancing our understanding of how the core peptide production line functions. Natural product biosynthesis often produces complex peptide structures, with one important example being the glycopeptide antibiotics. This project expects to generate new knowledge about enzymatic peptide biosynthesi ....Biosynthetic LEGO: enzymatic redesign to produce new vancomycin analogues. This project aims to uncover the reengineering potential of the biosynthetic machinery that produces glycopeptide antibiotics by advancing our understanding of how the core peptide production line functions. Natural product biosynthesis often produces complex peptide structures, with one important example being the glycopeptide antibiotics. This project expects to generate new knowledge about enzymatic peptide biosynthesis using a highly interdisciplinary approach and previously developed tools. The anticipated outcomes of this project will be an enhanced understanding of how such complex peptide biosynthesis is performed, which is knowledge vital for future efforts to reengineer such biosynthetic peptide assembly lines as a series of modular LEGO blocks to produce new bioactive peptides.Read moreRead less
Molecular evolution of a model oligomeric enzyme from bacterial extremophiles. The national benefits of this research program include insight into the sustainability of marine microorganisms that play an important role in Australia's diverse ecosystem, the development and applications of frontier technologies including high-performance computing on the world's largest supercomputer facility for life science research, and knowledge impacting on the discovery of novel antibiotics that target patho ....Molecular evolution of a model oligomeric enzyme from bacterial extremophiles. The national benefits of this research program include insight into the sustainability of marine microorganisms that play an important role in Australia's diverse ecosystem, the development and applications of frontier technologies including high-performance computing on the world's largest supercomputer facility for life science research, and knowledge impacting on the discovery of novel antibiotics that target pathogenic bacteria, like Golden Staph. This program will also train several young Australians in highly sought after skills, including bacteriology, biophysics, enzymology, molecular biology, molecular modelling, protein chemistry and structural biology. Read moreRead less
A bio-enabled synthesis for the glycopeptide antibiotics. This project aims to develop an in vitro biomimetic synthesis for glycopeptide antibiotics (GPAs) by combining peptide synthesis and crosslinking catalysed by biosynthetic Cytochrome P450 enzymes. The crosslinking step in GPA biosynthesis is essential for antibiotic activity but impedes their chemical synthesis. This project will study the in vitro behaviour and characteristics of the biosynthetic P450 enzymes. This will provide direct be ....A bio-enabled synthesis for the glycopeptide antibiotics. This project aims to develop an in vitro biomimetic synthesis for glycopeptide antibiotics (GPAs) by combining peptide synthesis and crosslinking catalysed by biosynthetic Cytochrome P450 enzymes. The crosslinking step in GPA biosynthesis is essential for antibiotic activity but impedes their chemical synthesis. This project will study the in vitro behaviour and characteristics of the biosynthetic P450 enzymes. This will provide direct benefits: the development of new glycopeptide antibiotic derivatives and the identification of new biocatalysts for complex chemical synthesis. Knowledge gained will also directly enable future reengineering of glycopeptide antibiotic production in vivo.Read moreRead less