Research

Novel ultraviolet radiation filters from extreme environments

Novel ultraviolet radiation filters from extreme environments

Current synthetic ultraviolet radiation (UVR)-filtering compounds are toxic to marine life and persist in the environment for many years. Using a synthetic biology approach, we are exploring microorganisms from high UVR ecosystems, such as hot and polar deserts, as a source of novel biosunscreens that are safe for use across a variety of cosmetic, health and industrial applications.

Industrial applications of cyanobacterial toxins

Industrial applications of cyanobacterial toxins

Cyanobacteria produce a variety of potent toxins, which pose a significant threat to food and water quality. However, due to their specific inhibition of certain eukaryotic enzymes, these toxins are also valuable research tools and drug leads. For example, the neurotoxic saxitoxins have shown clinical promise as long-lasting and non-addictive pain blockers. We are using synthetic biology to characterise, modify and express cyanotoxin biosynthesis pathways to provide a sustainable source of highly pure toxin analogues for industry and research.

Microbial endophytes as a novel source of bioactive compounds

Microbial endophytes as a novel source of bioactive compounds

Plants harbour a diverse range of microbial symbionts within their tissues that promote growth and provide resistance to pests, diseases, drought, and salinity. By characterising the microbial and molecular diversity in these ‘endophyte’ communities, we aim to discover novel microorganisms, enzymes and bioactive compounds of industrial significance, including biopesticides, antibiotics, plant growth promotors, and heavy metal-binding molecules.

Biosynthetic hooks for enigmatic marine toxins

Biosynthetic hooks for enigmatic marine toxins

Many species of marine microalgae and cyanobacteria produce potent neurotoxins, some of which are transferred via the food web to fish, molluscs and other marine animals. Our integrated genomic and synthetic biology approach, targeting key biosynthesis genes, will reveal pathways for the production of these toxins. In addition to providing unprecedented insight into toxin ecology and biosynthesis, the data generated will enable improved management of seafood safety and provide a foundation for the future development of novel neuroactive diagnostic tools and therapeutics.

Global analysis of specialised metabolism in Cyanobacteria

Global analysis of specialised metabolism in Cyanobacteria

Previous genomic studies on Cyanobacteria have focused mostly on their capacity to synthesise toxins. We are using the latest bioinformatic tools to screen for known and novel biosynthetic gene clusters. This curated dataset will be used to prioritise strains, enzymes and compounds of ecological, industrial and biomedical significance. Additionally, this investigation will advance our fundamental understanding of the natural history and evolutionary trajectory of specialised metabolism in these ancient and ecologically significant photosynthetic prokaryotes.

Environmentally sensitive insect control technologies

Environmentally sensitive insect control technologies

Despite the aggressive nature of Ae. vigilax and the continuous increase in Ross River Virus (RRV) transmission across Australia, there are no available reports on the biological control of either Ae. vigilax or RRV transmission. Using a synthetic biology approach, this study will investigate bacterial ‘parasites’ as potential extracellular and intracellular control agents of Ae. vigilax and RRV.

Mitigating the risk of freshwater cyanobacterial blooms

Mitigating the risk of freshwater cyanobacterial blooms

Freshwater cyanobacterial blooms impact the quality and utility of potable and recycled water, posing a significant risk to the economy, the environment and public health. To understand the causes of cyanobacterial blooms and the risk they pose, we are using the latest -omic techniques to examine how the microbial communities within these systems interact with each other and their surrounding environment to form blooms and produce toxins and other harmful metabolites. Such knowledge will inform risk assessments and strategies for the mitigation of future bloom events, improving the security of our increasingly valuable water resources.

AMR and metal co-resistance

AMR and metal co-resistance

Our research program investigates microbial community evolution, persistence, and resistance in polluted, and hospital‑associated environments. We focus on how both antimicrobial and metal resistance are maintained within complex microbial communities, enabling survival and adaptation under chronic selective pressure. By characterising these resistance dynamics, we seek both to inform strategies for mitigating antimicrobial resistance in healthcare environments and to explore opportunities to exploit microbial resilience for environmental remediation and related applications.

Uncovering Hidden Viruses at the One Health Interface

Uncovering Hidden Viruses at the One Health Interface

This project uses metatranscriptomic sequencing to characterise the diversity of viruses circulating in flying foxes and mosquitoes in regional New South Wales. By mapping these viromes and identifying viruses with zoonotic potential, it aims to build a One Health–informed surveillance framework to support early detection and prevention of emerging infectious diseases.