An Integrated Biotechnological Process for Production of Lactic Acid from Carbohydrate-Waste Streams by Rhizopus sp. Lactic acid is the most widely occurring multifunctional organic acid. It has enormous applications in food and food-related industries, and great potential use for production of biodegradable and biocompatible polylactate polymers. The aim of this research is to develop an innovative biotechnological process, incorporating simultaneous saccharification and fermentation, which int ....An Integrated Biotechnological Process for Production of Lactic Acid from Carbohydrate-Waste Streams by Rhizopus sp. Lactic acid is the most widely occurring multifunctional organic acid. It has enormous applications in food and food-related industries, and great potential use for production of biodegradable and biocompatible polylactate polymers. The aim of this research is to develop an innovative biotechnological process, incorporating simultaneous saccharification and fermentation, which integrates the production of lactic acid with the treatment of high strength food industry ?effluent? streams - carbohydrate waste streams. The proposed SSF process will cultivate an identified fungal Rhizopus sp strain on the waste streams, as production substrates, leading to an environmentally friendly and economically sustainable new technology for the food industry.Read moreRead less
Synthetic phenazines for enhanced biogas production from renewable and non-renewable resources. Methane (biogas) has a large role to play in meeting the energy needs of the human race globally whilst reducing greenhouse gas emissions. Microbial communities are responsible for biogas production from non-renewable (coal) and renewable (food waste) resources. This project seeks to: increase biogas yields by redirecting electron flow towards biogas producing microbes using electrochemically active p ....Synthetic phenazines for enhanced biogas production from renewable and non-renewable resources. Methane (biogas) has a large role to play in meeting the energy needs of the human race globally whilst reducing greenhouse gas emissions. Microbial communities are responsible for biogas production from non-renewable (coal) and renewable (food waste) resources. This project seeks to: increase biogas yields by redirecting electron flow towards biogas producing microbes using electrochemically active phenazines; understand the molecular mechanism by which phenazines increase biogas yields; and, assess the environmental consequence of phenazine application to coal seam gas production and anaerobic digestion of food waste. Phenazines are likely to emerge as a safe and cost-effective technology for improved biogas generation.Read moreRead less
Nanoscale Particle Control by Rigid Biomineralised Surfaces. The proposed research will increase understanding of the strategies diatoms use to sort particles. Our hypothesis is that in the process of understanding how these diatom surfaces control particles, blueprints for microfluidic devices will be identified. The appeal of diatoms goes beyond consideration of the geometrical patterning on their surfaces, because their frustules (the diatomic shells) are made primarily out of silica, a mater ....Nanoscale Particle Control by Rigid Biomineralised Surfaces. The proposed research will increase understanding of the strategies diatoms use to sort particles. Our hypothesis is that in the process of understanding how these diatom surfaces control particles, blueprints for microfluidic devices will be identified. The appeal of diatoms goes beyond consideration of the geometrical patterning on their surfaces, because their frustules (the diatomic shells) are made primarily out of silica, a material also used in nanofabrication. We expect that some of the strategies and patterns used by cells will be able to be directly transferred to microfluidics, and bypass years of empirical development in nanofabrication and lab-on-a-chip devices.Read moreRead less
Rejuvenating adult stem cells. This project aims to uncover intimate links between metabolic regulation and longevity in adult stem cells, the source of all cells in the body. Understanding why we age and whether ageing is preventable are research challenges which must be first attacked at a cellular level. This project will try to rejuvenate aged stem cells by interfering with a prospective molecular master switch of aging and also develop an approach to identify and select youthful stem cells. ....Rejuvenating adult stem cells. This project aims to uncover intimate links between metabolic regulation and longevity in adult stem cells, the source of all cells in the body. Understanding why we age and whether ageing is preventable are research challenges which must be first attacked at a cellular level. This project will try to rejuvenate aged stem cells by interfering with a prospective molecular master switch of aging and also develop an approach to identify and select youthful stem cells. The results are expected to be important beyond informing the science of ageing, in the areas of tissue engineering, wound healing, embryology and cancer.Read moreRead less
Enhancement of monopartite geminivirus pathogenicity by satellite DNA beta encoded betaC1 protein: the role of host factors. Australian incursions of geminiviruses are uncontrollable due to their unique mode of spread by whiteflies. The first incursion in Darwin in 1970 has spread to Far Northern Queensland. The second in SE Queensland in 2006 is estimated to cause $500 million loss to horticulture. Our $2 billion cotton industry is threatened by cotton leaf curl diseases from South Asia, where ....Enhancement of monopartite geminivirus pathogenicity by satellite DNA beta encoded betaC1 protein: the role of host factors. Australian incursions of geminiviruses are uncontrollable due to their unique mode of spread by whiteflies. The first incursion in Darwin in 1970 has spread to Far Northern Queensland. The second in SE Queensland in 2006 is estimated to cause $500 million loss to horticulture. Our $2 billion cotton industry is threatened by cotton leaf curl diseases from South Asia, where DNA beta enhances virus replication and disease severity. DNA beta has the potential to enter Australia with several different geminiviruses and to spread into others by co-infection, which requires research on detection and pathogenesis of DNA beta.Read moreRead less
New biocatalysts for selective chemical oxidations under extreme conditions. This project will identify and design new enzyme biocatalysts which function under extreme conditions such as elevated temperature and high concentrations of peroxides. These enzymes will be sourced from microorganisms which are located in extreme biological environments e.g. hot springs (the so-called extremophiles). The expected outcome of this project are the identification of robust enzymes which can catalyse select ....New biocatalysts for selective chemical oxidations under extreme conditions. This project will identify and design new enzyme biocatalysts which function under extreme conditions such as elevated temperature and high concentrations of peroxides. These enzymes will be sourced from microorganisms which are located in extreme biological environments e.g. hot springs (the so-called extremophiles). The expected outcome of this project are the identification of robust enzymes which can catalyse selective oxidation reactions in complex organic molecules, such as steroids. The new biocatalysts developed in this project will have significant benefit in the development of new routes to access bespoke molecules of value in fine chemical synthesis and drug development.
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Safer gene editing tools for Australian livestock and biotech industries. Editing the genome of an organism in an efficient and safe fashion is critical for the livestock and biotechnology industries. While CRISPR-Cas9 has become the method of choice for genome editing, it is known to introduce unwanted "on-target" and "off-target" mutations, limiting its utility. To address this the CI team created a novel genome editing platform technology termed Crackling-CAST that is almost 100% accurate, w ....Safer gene editing tools for Australian livestock and biotech industries. Editing the genome of an organism in an efficient and safe fashion is critical for the livestock and biotechnology industries. While CRISPR-Cas9 has become the method of choice for genome editing, it is known to introduce unwanted "on-target" and "off-target" mutations, limiting its utility. To address this the CI team created a novel genome editing platform technology termed Crackling-CAST that is almost 100% accurate, while retaining the efficiency of the classical Cas9 system. This project will exemplify the capabilities of the novel gene targeting platform in cell types used by the biotechnology and livestock sectors, ensuring its global uptake by these industries and delivering significant economic benefits for Australia. Read moreRead less