Developing an integrated systems and synthetic biology platform to expand the product spectrum of acetogens. This project aims to advance a waste gas fermentation process to enable the production of sustainable aviation fuel molecules for the first time. LanzaTech are world leaders in microbial gas fermentation and have produced ethanol at large scale in China. This project aims to combine the LanzaTech process with systems biology expertise at The University of Queensland to go beyond ethanol t ....Developing an integrated systems and synthetic biology platform to expand the product spectrum of acetogens. This project aims to advance a waste gas fermentation process to enable the production of sustainable aviation fuel molecules for the first time. LanzaTech are world leaders in microbial gas fermentation and have produced ethanol at large scale in China. This project aims to combine the LanzaTech process with systems biology expertise at The University of Queensland to go beyond ethanol to deliver new value-added products such as butanediol and farnesene. To achieve this aim the project will explore, understand and overcome fundamental energy and metabolic limitations in the production microorganism. Achieving the aims will be of direct relevance to SkyNRG and the new Brisbane Bioport on their path to deliver sustainable fuel to Brisbane Airport.Read moreRead less
Toward sustainable diesel production using microbial cells: unravelling isoprenoid pathway regulation through systems biology. The methylerythritol pyrophosphate (MEP) pathway for isoprenoid production is an essential biochemical pathway. It was only fully elucidated a decade ago, and the regulatory controls over this pathway are not understood. The objective of this project is to elucidate the mechanisms by which the MEP pathway is controlled in E. coli using a novel systems biology approach. U ....Toward sustainable diesel production using microbial cells: unravelling isoprenoid pathway regulation through systems biology. The methylerythritol pyrophosphate (MEP) pathway for isoprenoid production is an essential biochemical pathway. It was only fully elucidated a decade ago, and the regulatory controls over this pathway are not understood. The objective of this project is to elucidate the mechanisms by which the MEP pathway is controlled in E. coli using a novel systems biology approach. Understanding control of the MEP pathway is required to gain insight into homeostatic control of this essential pathway, and enable biotechnological engineering of E. coli in order to produce a wide range of industrially useful isoprenoids (including biofuels, pharmaceuticals, industrial chemicals, neutraceuticals, food additives, perfumes and many more).Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100170
Funder
Australian Research Council
Funding Amount
$2,887,531.00
Summary
Scaling in biology: size control at the cell, organelle and organism level. This project aims to decipher the universal mechanisms that coordinate growth with division and thereby dictate the size of the cell. It would investigate this question from the triangulating perspective of evolution using yeast and animal models. It plans to interrogate the complex sub-networks that govern cell size using novel genome-scale reagent sets for systematic genetics and other approaches. It would integrate th ....Scaling in biology: size control at the cell, organelle and organism level. This project aims to decipher the universal mechanisms that coordinate growth with division and thereby dictate the size of the cell. It would investigate this question from the triangulating perspective of evolution using yeast and animal models. It plans to interrogate the complex sub-networks that govern cell size using novel genome-scale reagent sets for systematic genetics and other approaches. It would integrate this data in predictive mathematical models of size control that illuminate how the cell processes size-related information, and how size mechanisms evolve to impact form and function in biology. This research is expected to have commercial applications in biotechnology processes and bioengineering.Read moreRead less
Engineering cyanobacteria for high-value flavours and fragrances production. Engineering the metabolism of cyanobacteria for industrial production of flavours and fragrances has great commercial potential. Cyanobacteria capture more than 25% of the planet’s carbon. Due to their native metabolism and capacity to express complex plant proteins, they represent an attractive Synthetic Biology platform for the biosynthesis of flavours and fragrances. Combining physiological strain characterisation an ....Engineering cyanobacteria for high-value flavours and fragrances production. Engineering the metabolism of cyanobacteria for industrial production of flavours and fragrances has great commercial potential. Cyanobacteria capture more than 25% of the planet’s carbon. Due to their native metabolism and capacity to express complex plant proteins, they represent an attractive Synthetic Biology platform for the biosynthesis of flavours and fragrances. Combining physiological strain characterisation and ‘omics studies, new Synthetic Biology strategies and models will be developed. The project aims at engineering a suite of modified freshwater and marine cyanobacteria for flavours and fragrances biosynthesis. The project aims at enabling solar biomanufacturing to underpin the emergence of an advanced Australian bioeconomy.Read moreRead less